Sony Super CD: More Bits, More Bucks, Mo' Betta?

Reader dcigary pointed to this "nice writeup on the new Sony Super CD." Though the explanation of the difference between supposedly revolutionary "DSD" recording over conventional digital seems to get by with a knowing mumble, the piece does mention the price (high) and that competition from audio-only DVDs may cripple acceptance of the new format. Even if I like the idea of ultra-fidelity, my faith in the Nyquist theorum is too strong to spend a grand and a half on a CD player anytime soon ...

Re:Sorry.

[Mike+Monett]

Correction. Site D shows the nice input/output waveforms.

Had it correct in the original, before Windows crashed.

What SACD is all about and why DVD audio is better

[XNormal]

Virtually all audio A/D and D/A converters today use sigma-delta, also commonly referred to as "one-bit" conversion.

In a sigma-delta A/D converter the audio signal is sampled with a high sampling frequency (typically a few MHz) and low sample resolution (1 bit). An error feedback mechanism is used to ensure that most of the energy of the quantization noise is "shaped" into high frequencies, giving excellent fidelity in the audio band. One bit is inherently linear - no need for carefully matched resistor networks such as those used on older A/D converters. This stream is then filtered and decimated using digital signal processing techniques to a lower sampling rate (e.g. 44100Hz) while gaining sample depth on the way (16 bits and higher).

For D/A conversion the process is reversed: the 44100Hz signal is interpolated up to a high sampling rate and then the sample depth is reduced down to one bit. Again, error feedback is used to ensure that the quantization noise resulting from the low resolution is shaped to high frequencies. This bitstream is then low-pass filtered and used as the audio signal. Again, with much better linearity than D/A converters based on carefully adjusted resistor networks.

The Sony SACD skips the decimation and interpolation stage. It stores the noise-shaped bitstream directly on the disc. The beauty of this idea is in its simplicity: it performs much less transformations on the sigma-delta signal and therefore should offer inherently higher fidelity and wider bandwidth.

If sigma-delta converters were available 20 years ago when the CD was invented they would probably have chosen this method for its simplicity. But at that time the analog conversion technique known was resistor networks so PCM was used.

Remember that at the time the CD was really stretching the limits of consumer technology. No other consumer product prior to the CD player used so many new and advanced technologies: lasers, error correction, digital signal processing. If they could have used this technique it would have reduced the cost of CD players significantly. For example, this bitstream is much more tolerant to bit errors because unlike PCM there is no "most significant bit" that can cause a large error if corrupted.

Using this technique today, though, is insane. There is no real savings in simplicity when a million digital transistors cost close to nothing. If you want higher fidelity, 96kHz and 24 bits is more than enough.

Let's say you want something simple like a graphic equalizer on your SACD player. If it's analog such a complex circuit will introduce lots of noise. If you implement it digitally it would take insanely large amounts of CPU power to process a signal sampled at over 2mHz. Manufacturers will probably end up downconverting it to PCM at 96kHz or lower, doing the signal processing and then converting back to sigma delta for playback. This will lose all of DASD's alleged advantages.

BTW, for the purpose of preserving analog masters DASD is really a good idea because they contain useful information at very high frequencies such as the tape bias signal and the intermodulations it creates. Preserving this information will allow future signal processing techniques to create accurate models of the nonlinearities of the magnetic medium and use this high frequency information to reconstruct the original recording with better fidelity down in the audio band. For home use SACD is a very bad idea. Just about the only good thing I can see about it is that it can be marketed effectively because it's such a "radical new concept".

The DVD audio uses conventional, well proven PCM with somewhat higher sampling frequency and bit depth than CD. Why use a higher sampling frequency when we can't hear over 20kHz? It turns out that while we can't hear a sinewave at frequencies higher than 20kHz the high frequency components of complex waveforms make a noticable difference even up to 26kHz. To take a good safety margin and maintain integer ration a 96kHz sampling rate was used. This does not significantly hurt the data rate required because non-lossy compression is used on DVD audio. A compressed 96kHz signal takes about 30% more space than a compressed 48kHz signal. 16 bits is, again, almost enough. In fact, with proper in-band noise shaping the noise floor is inaudible in all but very extreme circumstances. 24 bits is therefore a very good safety margin.

Another reason why DVD-audio is superior is because it supports Ambisonics. Ambisonics is a surround sound system. It was not crated for cinematic effects. Ambisonics was designed for music and for reconstructing the subtle spatial cues of the ambience of the recording venue. With a proper arrangement of speakers it can create true 3D sound - including the height dimension. Imagine listening to a recording and feeling the height of the concert hall!

Please never ask "how many channels does Ambisonics use" because it's not a relevent question. Ambisonics deconstructs the 3D sound field mathematically using a four component representation (XYZW). This representation can be processed with a simple linear matrix for playback on different speaker configurations and numbers of channles with varying levels fidelity of 3D soundfield reconstruction. This includes the popular 5.1 setup used on home theaters (it's probably going to be the default settings for DVD-Audio players) .

DVD-Audio is also backward compatible with DVD players although a DVD-audio player will be required to take advantage of all the features and full quality.

More information about DVD-Audio here

----

Subliminal messsage: "...informative, informative"

[XNormal]

----

Re: 22050Hz

[Andy+Dodd]

A few articles ago, someone suggested that Malda & company implement a "Just plain wrong" moderation option.

It's mathematically provable (and the end result of said proof is the Nyquist theorem) that all you need to do is sample a signal at 2x its maximum frequency, and you can recover that signal EXACTLY.

Sample the signal, later pass that sampled signal through a low-pass filter. Afterwards, the only difference between the final signal and the original is a constant multiple. (For example, if you sample with infinite impulses, which have infinite height and zero width but an area of one, the end signal is 1/T (where T is the period) times the original.) The aforementioned technique is "ideal sampling" - which never occurs in the real world. With practical sampling, you get a different multiple than 1/T. But the end result is the same.

One bit. Here's how.

[Chris+Johnson]

It's one bit. On or off. Here's how it works: imagine a waveform- at any point the angle of the wave might be up / or down \ or just flat -

The way the Sony thing works is like this: at each point the encoder asks 'am I above or below the actual wave form?' If it's above, it reduces the angle of its recording by X degrees. If it's below, it increases it by that much. It is constantly overshooting and crossing over the actual waveform- at about 2 megahertz, not some mere 96K. At no point does it record the signal voltage itself- it only follows the changes in angle, at a rate so high that it's way beyond anything that will be recorded, and it's kind of 'lossy' as it'll almost never be _exactly_ on the target waveform- the oscillation of it tracking the waveform will be higher than 96K anyhow and it will be a _sine_ oscillation, not the square-stepped, nasty distortions of raw PCM sampling, so it won't even need to be filtered.

I'd love to see this actually catch on- as far as sound is concerned, nothing else should be needed. The interesting thing is this- could this format be _synthesised_ digitally? I'm picturing some future sort of audio workstation where you have all the modern gimmicks like pitch correction, EQ plugins etc, but you never resample anything- just overlay all the different sample rates you end up with, seamlessly :)

It would be interesting to see the venerable Yamaha DX-7 redone with this technology for its audio outputs! :)

Re: A visual aid

[Dahan]

Now, I tell Goldwave to do a low pass filter, with a cutoff frequency of 919Hz.

Whoops, I guess I should've done a filter with a cutoff frequency of 1378Hz (22050/16)... no matter, it still works great :) I'll fix my pictures...

Clock accuracy

[trauma]

On a somewhat-related note, it is remarkably interesting what effect a more accurate clock signal has on the quality of a 44.1KHz recording

Thank you, thank you. This phenomenon (sometimes known as "clock jitter") also explains, in large part, the age-old argument as to why digital-to-digital copies are not always perfectly identical, despite the notion that "it's only copying numbers/bits, it has to be perfect". Any digital recording references a time base, and any variation in that time base skews the way the audio sounds when you play it back. Commercial recording studios pay very large sums for centralized, highly accurate clock sources to which each piece of equipment that handles a digital audio stream is synced.

Some more on this technology

[Kiwi]

SACDs do not utilize PCM audio at a higher encoding rate, the way the upcoming DVD/A standard will. Instead, it uses a special encoding with, basically, allows you to have higher frequencies at lower resolution or lower frequencies at higher resolution, where the base resolution is a low bit rate in the megahertz range.

Arny Kruger has a lot of misgivings about this method. First of all, it is a lot harder to code DSP for this instead of PCM. Second of all, there are apprantly problems with high-frequency artifacts that this encoding technique uses.

I also have a lot of misgivings about this method. Personally, I think the average listener thinks 16/44.1 is good enough, and has no need to listen to something at a even higher bit rate. The popularity of MP3s indicate that 16/44.1 is better sounding than what the average consumer needs.

- Sam

You've got it wrong

[The+Mayor]

Even if I like the idea of ultra-fidelity, my faith in the Nyquist theorum is too strong to spend a grand and a half on a CD player anytime soon ...

You've got it all wrong. You see, humans have an approximate range of hearing between 20Hz and 20KHz (assuming no hearing loss). Now, Nyquist theory says that you must sample at twice the frequency of the highest frequency you wish to preserve. We use 44.1 KHz for this. Sounds good so far, right?

Well, what many neglect to mention about Nyquist theory is that you must run the resulting output through a filter. The filter, according to the theory, is a brick-wall filter. Of course, these things don't exist. Filters have a roll off. As a result, people invented the concept of oversampling. This way, you move the sampling frequency way above 44.1 KHz, and you can put a filter in at, say, 100 KHz. Nice, right? Wrong. Filters have audible effects *well* below their -6dB level.

That said, there's still another problem. People have an approximate dynamic range for their hearing of 120dB. Using 16 bit samples (like CDs), you end up with only 96dB of theoretical dynamic range. So people invented the concept of running a low level noise input when digitizing. This ends up pushing the dynamic range above 96dB. This is how most modern CD players can claim a dynamic range of about 102dB. Sounds good, right? Wrong. You're increasing the dynamic range, but you're also increasing the noise. This is not good.

Of course, for 1980, CDs were pushing the limits of technology. Now they're not. Now we have DVDs. With DVDs and compression, you can get 5 channels of sound digitized with 24-bit sampling at a sample rate of 96kHz. Now that kicks ass. Of course, all the different parties messed around with the standards committees long enough to pretty much kill DVD-Audio (it was finally released a few months ago, but there is way too little material released under the format).

So, if you want a cheap CD player that truly sounds good, I recommend you get a DVD player, and listen to music on DVDs or DVD-As. Even a cheap one can have a pretty poorly built filter and sound OK. Of course, cheaper D2A converters have their own problems, like jitter. But that's a story for another time.

Look, if you don't believe me about this quality issue, go to your local high-end (and I don't mean that they carry Denon and Yamaha...I'm talking about equipment like Wadia and Krell), and ask them to do some listening tests with a Krell compared to your $189 Technics (or whatever). If you don't hear a difference, then you either have hearing loss or you aren't used to paying attention to sound quality. Like many elements of perception (sight, hearing, etc), the more you work the sense, the more acute it becomes.

Re:You've got it wrong

[plone]

"Like many elements of perception (sight, hearing, etc), the more you work the sense, the more acute it becomes."

exactly, that is why audiophiles arent as crazy as some people make them out to be. I recall reading a review on a $65000(!) turntable where the listener could correctly identify which brand of skins where on the drums. Now, would that be possible with regular cd? Would it even be possible with SACD?

Re:You've got it wrong

[The+Mayor]

Oh, yes, I did neglect the problem of aliasing, too. This is another reason for oversampling...Oops...

Re:You've got it wrong

[Doktor+Memory]

that is why audiophiles arent as crazy as some people make them out to be. I recall reading a review on a $65000(!) turntable where the listener could correctly identify which brand of skins where on the drums.

Let's get this straight. You read a review of an insanely overpriced piece of equipment in a magazine dedicated to selling insanely overpriced pieces of audio equipment to idiots with $65,000 to spend on a turntable (a magazine funded entirely by ad revenues from the companies which make those $65,000 turntables), in which it was asserted that a nameless one of those idiots was able to use that $65,000 turntable to perform some god-like feat of auditory recognition, and you believed it?!

Did you know that the word "gullible" isn't in the dictionary?

Obviously, I missed the boat with this whole "tech startup" thing. If I really wanted to be raking in the cash for zero effort, I should have gone into "high-end audio design"...just find some old warehouse full of 1930s tube amps, slap `em inside some shiny cases, hire some hack "reviewer" to tell a bunch of nouveau riche idiots that it'll make their penises 0.00000021mm longer, and then just sit back and wait for the cash to roll in.

Re:Yet another psuedo-standard (minidiscs bite)

[BrendanHeading]

Erm, full size Minidisc decks *do* have digital inputs *and* outputs. The portable ones don't - the reason being fairly obvious (why would you need a digital output for a walkman-type application ?). This is nothing to do with the question of software piracy. You need to get a proper Minidisc deck that has a digital out to do the stuff you're describing.

15 kHz square wave = 15 kHz sine to human ear.

[Andy+Dodd]

ANY signal, especially a periodic signal, can be represented as a sum of sine waves. (This is the basis of the Fourier transform.)

What is a 15 kHz square wave? It's a 15 kHz sine wave plus sine waves at multiples of 15 kHz. The human ear can't hear those multiples, hence can't tell the difference.

What's my point? My point is that if you sample at 44.1 kHz, you catch ALL of the portions of your signal that are human-hearable. Yes, a human can tell the difference between a 500 Hz sine and a 500 Hz square - that's because there are many harmonics with the human hearing range. But I can assure you, if you play a 15 kHz sine wave and a 15 kHz square/triangle/sawtooth wave, you won't be able to tell the difference.

Re:15 kHz square wave = 15 kHz sine to human ear.

[Chris+Johnson]

What is a 15K square wave?

Pulses of infinitely intense sound pressure changes occurring 30,000 times a second.

What is a 15K sine wave?

The gentlest possible oscillation of sound pressure, 30,000 times a second.

Now, maybe your tweeters aren't up to putting out infinite sound pressure levels- technically the nature of a square wave is that no matter how faint it is you need to put infinite force into the transients in order to keep it square. Most people's speakers are not capable of putting out such intense pulses, cleanly or not. Many might be so bad that they can't produce the pulses at all- in which case the speaker is producing a sine wave, and no wonder you can't hear a difference.

There are, however, plenty of speakers out there that will try a lot harder to render the edges of that 15K square wave. Electrostatics. Fancy tweeters. Horn-loaded designs such as Klipsch uses. I'm currently using very fragile inverted domes with a variation on horn loading; I suggest that my speakers can produce louder sounds in the supersonic range than yours can. Since square waves are made up of transients of theoretically infinite force, it matters whether the speaker is able to produce loud sounds that high up- it translates to ability to make the square wave _be_ a square wave acoustically.

I've tried this sort of thing. A sine wave up in that range is like a clear blue light (pardon the synesthetic imagery but I'm not sure how to explain this) where a square of the same frequency is a lot whiter and sounds _discrete_ somehow- it's sort of like a super-high-frequency-sound equivalent of a strobe light and doesn't sound _smooth_. Instead it makes you squint and kind of hurts, the edge goes right through your skull. Neither note is very musical, or can be stood for long :)

Amusingly, sampling at 44.1K cannot properly capture _either_ because there's an intermodulation distortion that is waaaay beyond what people consider acceptable for total harmonic distortion. Now if you were talking about a 14700 hz note, you'd get a lot closer as that gives you three samples per cycle- either way you are producing a pulse wave at 1/3 width but at least it doesn't warble :)

Re:15 kHz square wave = 15 kHz sine to human ear.

[nathanh]

What is a 15K square wave? Pulses of infinitely intense sound pressure changes occurring 30,000 times a second.

It's a sum of multiple sine waves. The 15kHz square wave would have a natural harmonic at 15kHz and a second harmonic at 45kHz at 1/3 the amplitude and a third harmonic at 75kHz at 1/5 the amplitude and so on.

You can't hear any of the harmonics except the natural harmonic at 15kHz. Don't pretend you can. Don't pretend anybody else can. No human has proven in an A/B test that they can hear any frequencies equal to or above 45kHz.

What is a 15K sine wave? The gentlest possible oscillation of sound pressure, 30,000 times a second.

A single sine wave at 15kHz. You'll hear this.

Now, maybe your tweeters aren't up to putting out infinite sound pressure levels- technically the nature of a square wave is that no matter how faint it is you need to put infinite force into the transients in order to keep it square.

No amplifier would ever pass frequencies above 22kHz to the speakers. High frequencies like this could easily damage crossovers, speakers, etc. It would certainly damage the output stage of the amplifier.

There are, however, plenty of speakers out there that will try a lot harder to render the edges of that 15K square wave. Electrostatics. Fancy tweeters. Horn-loaded designs such as Klipsch uses. I'm currently using very fragile inverted domes with a variation on horn loading; I suggest that my speakers can produce louder sounds in the supersonic range than yours can. Since square waves are made up of transients of theoretically infinite force, it matters whether the speaker is able to produce loud sounds that high up- it translates to ability to make the square wave _be_ a square wave acoustically.

The thing is, we people who know mathematics know that the only frequency in a square wave below 20kHz is the 15kHz sine wave. The nearest frequency to that 15kHz sine wave is at 45kHz.

You claim you can hear this 45kHz harmonic. Either you're hearing distortion (which I'm sure an audiophile would never admit to) or you're full of shit. I'm willing to bet on the latter.

Amusingly, sampling at 44.1K cannot properly capture _either_ because there's an intermodulation distortion that is waaaay beyond what people consider acceptable for total harmonic distortion. Now if you were talking about a 14700 hz note, you'd get a lot closer as that gives you three samples per cycle- either way you are producing a pulse wave at 1/3 width but at least it doesn't warble :)

What a load of techno-babble! You don't know what you're talking about.

Re:15 kHz square wave = 15 kHz sine to human ear.

[DeeKayWon]

There are, however, plenty of speakers out there that will try a lot harder to render the edges of that 15K square wave.

And assuming these speakers are meant for people to hear the output from, they're wasting their time and effort. It's absolutely true that speakers can't ever render a perfect square wave because the components inside act like a mechanical lowpass filter. But to human ears, it doesn't matter. What the mechanical lowpass filter has messed with isn't in our range of hearing. The output is no longer square, but it's still periodic at 15kHz. We still hear the 15khZ fundamental, and everything else doesn't exist according to our ears.

Re:15 kHz square wave = 15 kHz sine to human ear.

[Chris+Johnson]

Read some stereo review magazines- in particular, the sort that throw a lot of test equipment at the problem. They _routinely_ graph the frequency response of amplifiers from fractional Hz to well beyond a megahertz.

Among other random terms of abuse I spotted the interesting claim that no power amplifier ever passes higher than 20K as it would hurt the speakers and damage the output stage of the amplifier. Apart from directing attention to even hoary old warhorses of the audio mag trade like Stereo Review, I think I had better let this claim pass without further comment :)

Re:15 kHz square wave = 15 kHz sine to human ear.

[nathanh]

You really are amazing, Chris Johnson. You clearly don't know anything about signals. Your understanding of Fourier is non-existent. You've had numerous people point out the hideous flaws in your arguments. That one about 14.7kHz pulses was a hoot! How you managed to score 5 points for some of your nonsense is simply beyond me.

Now you're claiming audio amplifiers amplify linearly up to the megahertz range? Hell, the science department at the university is going to be over the moon about this. They pay thousands of dollars for equipment that can do this and all they needed was a NAD amp at $200 from the local hifi dealer!

You're an idiot, Chris Johnson. I haven't seen a single sensible word out of you yet.

PS: I'll read a stereo review magazine the day hell freezes over. These are the same idiots that recommend colouring your CDs in with green marker pens, demagnetizing your CDs, and using gold CDRs instead of blue CDRs "to improve the warmth and depth of the recording". They know less than you do and that's really saying something.

Re: 22050Hz

[The+Mayor]

It has nothing to do with what you hear. It has to do with the filtering. Take a look at my other post--I go into much more detail there. You *need* a sample rate of much higher than 44.1kHz in order to accurately reproduce the input signal using *real* (i.e. not theoretical) filters.

Re:Is there a catch?

[BrendanHeading]

It is important to stress that SCMS only applies to recordings that have been laid down with the SCMS bit set in the data stream. This technology is also included in the consumer CDR machines, although thankfully it does not apply to computer CDRs or professional decks. If you make a digital recording yourself (ie from a tape deck or record player, or in a live environment), or if you buy a box that can strip the SCMS bit from the digital stream, you can make as many copies as you like. Precisely why you'd want to make copies of copies of commercial CDs (other than for piracy reasons) is beyond me so therefore I don't really see how this can be a legitimate criticism of the MD format. Agreed that pre-recorded MDs, like pre-recorded tapes, are rather moot.

Re: 22050Hz

[The+Mayor]

That is, of course, assuming that you have a THEORETICAL brick wall filter, which don't exist. Using real-world filters, you end up with audible effects *under* 22.05kHz. This is the reason that oversampling was invented.

Re:Incorrect... (Re:Nyquist theorem)

[Paul+Komarek]

A lot of what you (nathanh) say is true. But it's clear you don't have the best ears on the planet--do more music listening, even on mediocre equipment, and you'll hear the things you claim can't be heard.

Quit getting so excited about what you know. Just because you've read about signals somewhere doesn't mean you understand human auditory function. And remember that we don't really understand any of this stuff--we're just constructing models. If I can hear what you say I can't, then your _model_ is wrong, not my ears. After all, the models are trying to conform to reality, not vice-versa as you seem to argue.

I am a mathematics grad student, familiar with some signal processing, and critically inclined. I also am passionate about music. I find your comment "Most audiophiles are full of shit" offensive--I know several audiophiles and none of them are full of shit. Some are musicians, some are electrical engineers. All of them have highly trained ears.

I don't care that "most people's speakers have trouble doing better than -3dB at anything over 18kHz anyway"--mine are spec'd -2db at 22kHz, and they only cost $450 for the pair (Sound Dynamics 300ti). I take exception to your comment "So it's hardly any loss at all to throw away the sine waves over 20kHz"--hardly any loss to whom? I would benefit from better-sounding recordings. I do care about the high-range.

Finally, not everything can be represented by sinusoids, as you claim. Fourier claimed, IIRC since I'm not going to check, that all L2(0,1) functions could be represented by an infinite sum of sinusoids. I don't understand why all changes in air pressure must necessarily be in L2(0,1)--and unless a patient physicist tried explaining it to me, I probably wouldn't believe it anyway.

-Paul Komarek

Re:Incorrect... (Re:Nyquist theorem)

[twinpot]

Some can, some can't. A bit like some wine buffs, or art critics.

Interestingly, a group listening to watermarked digital recordings had something like an 80% success rate in correctly identifying which tracks were watermarked.

Also of interest is that women are often more able to detect the changes/differences when doing blind audio tests

Re:Incorrect... (Re:Nyquist theorem)

[BrendanHeading]

First, the low pass filter at 22.1khz is applied as a standard part of the digital mastering process. You can't get away from it. That will be a problem for those of us who insist on having their inaubible sine waves reproduced (how much real music actually contains these types of signals at these frequencies in the first place?) this is a bit of a problem. If you're someone who values 30khz signals and sees it as a shortcoming that everything above 22.05khz is cut, I find it interesting how you swear by good vinyl. Even if it could produce 30khz results (which I contend is completely impossible) the master tapes used to cut the master have much of the bass removed and everything above 15khz is cut. If that stuff wasn't removed you risk either damaging the home user's stylus or damaging your own master cutting lathe. On top of that the analogue master tapes used to cut vinyl LPs are themselves incapable of reproducing 30khz signals. Generally speaking I have very little time for "audiophiles". First they tell us they can perceive differences between different types of CDR (one has "better controlled bass" than the other, they say..) then they tell us that the crazy, unpredictable journey of a little diamond bouncing off moulded vinyl canyons is somehow superior to precise, digitally locked a/d - d/a convertors. These "audiophiles" would do themselves some good to talk to an LP mastering engineer, or to the musicians who actually record the material in the first place. Ask them which - vinyl or CD - is closest to the master tape that they laid down in the studio. Then get back to us.

Re:Similar note - 16 bits is all you need.

[BrendanHeading]

Let's talk about real life :

Reality Check 1 : 24-bit a/d convertors are not yet available at these sampling frequencies (they will be available soon, I'm sure - but not yet). Just like back when CD came out, the best a/d convertors only went up to 14 bits. Hence one of the several reasons for the need for modern "digital remasters"

Reality Check 2: If you can find a source that produces a signal with a resolution that goes anywhere near the digital equivalent of 24 bits then you'll really have something. 30ips, two inch multitrack analogue tape on the best equipment available will give you a resolution equivalent to about what an 18-bit a/d convertor might give you.

I cannot understand why people are hitting us with this shite about interpolation errors and resolution when the analogue master tapes even at their very best barely exceed the (negligible) limitations imposed by CD.

Re:Better IS Better

[twinpot]

Nah, none of that ghetto blaster stuff. If you want to really feel it, listen to some serious organ music. Now that you CAN feel (and the water in your glass dances quite nicely!).

WHATever...

[Chris+Johnson]

Believe what you want, but there was an old quad format that operated by adding amplitude modulated 50K tones. I'm told it worked. There's not much room for theory here: it would either work or not, you're saying it couldn't, and what I hear it did work in the real world. Not that quad ever became mainstream :)

Console yourself with the fact that after relatively few playings the AM quad information would be scraped off the LPs anyhow ;)

Cables

[trauma]

What MIT claims does have some basis in scientific fact. (Although I can't speak for their methods, I don't know anything about the company.) Audio frequency AC (or higher) in a wire exhibits what is called the "skin effect"; in a nutshell, the higher the frequency of a signal the more it reacts electromagnetically with the metal in the wire, the end result being that higher frequencies are phase-shifted more than lower frequencies and actually migrate to the outside of the wire, rather than travelling down the middle or uniformly through it. This is why certain components in microwave circuitry are constructed as hollow tubes; the "middle" is useless. This is also often why high-end wires sound different.

Re:Better IS Better

[lewp]

My only gripe with this whole discussion (the majority of which is far beyond my meat and potatoes understanding of high end audio) is the fact that people dislike the format because it's proprietary. I mean the people responsible for DVD seem to be doing everything they can to make sure that they say how and on what equipment we can play our own discs, so how can we dock Sony's solution points for being proprietary when we don't even know if they have similar evil up their sleeves.

Maybe I'm way off here, but I'd almost rather take my chances letting Sony run the show than go through more DVD BS. I can't WAIT to see what happens when they control the movies I watch AND the music I listen to.

Re:Nyquist theorem

[marius]

When discussing audio, square waves are moot anyway. A square wave by it's nature won't travel in an analog world on copper wire, which is likely what's running to your speakers. The only way to faithfully transmit a square wave down the line is to use fiber all the way, and I know your speaker cones don't connect to fiber.

Informative - (Bitstream versus PCM debate)

[kanenas]

http://www.meridian-audio.com/ara/bitstrea.htm

So what about other new formats?

[Valissystem]

So what about other new sound formats? I know that there is a HDCD (High Definition CD) that is backwards compatible. I know that they are out there as I own a couple, although I don't have a player for them; they play fine on a standard CD player. Does anyone have a URL for any technical information that compares the newer formats. I now know of HDCD, SACD, DVD-Audio (which is not strictly compatible with standard DVD's). Any others I should know of?

Re: 22050Hz

[pallen]

First, although the mic's may not be able to pic up sound above 22Khz, (which I think they can, but anyway) you need a sampling rate at least double the highest frequency to represent the wave accuratly (in practice, you need 4 or 8 times to get a _true_ representation of the sound.) (Consult any textbook about digital representation of sound for reason why)
The higher bit depth will not make much difference.
Think about it, CD uses 16 bit depth. 2^16=65536,
so if the sound has a maximum amplitude range of half that, (32768), then it will be constantly varying by that much in every wave. Now if we say that we take a sample at every one of those values, at 44Khz, this would take (32768/44000)=0.7447
so 1/ that gives the frequency = 1.34Hz. As the human ear can't usually hear below 20Hz, that kind of accuracy is not necassary(sp?).

Re:Similar note - 16 bits is all you need.

[nathanh]

If you do the math, you'll see that the maximum error you obtain with 16-bit sampling is all you need given that line-out signals are 3 volts peak-peak. I don't remember the exact voltage, and I'm too tired to re-work it now. (3 volts divided by 2^16...) But the maximum error of a 16-bit sampled signal is FAR lower than the minimum electrical noise added by even the best super-high quality amplifiers with gold-plated speaker wire contacts and the like.

Now while this is entirely true it gets more interesting than this in real-life. There is a need for better than 16-bit resolution. Here's why.

You know that you reconstruct your signal from the samples by using zero-order-hold on each sample, then applying an ideal low-pass filter at half the sampling rate.

Sadly you can't make ideal low-pass filters for any money. In fact it's hard to make even good low-pass filters. The solution is to interpolate the signal first then use a much cheaper and less accurate low-pass filter.

Linear interpolation (first-order-hold) is common but produces nasty results. Bandlimited interpolation (sinc pulses) is a much better method but difficult to implement. In practise you'd use something halfway between the two.

However all interpolation methods rely on the sample being as close to perfect as possible. If you're using first-order-hold then you will only get the error from the nearest two samples. But if you're using bandwidth interpolation then the sinc function means ALL THE SAMPLES are used to create your interpolated sample.

In practise several dozen samples will be combined to create your interpolated sample. The errors from all these samples combine to create one huge error on your interpolated sample.

24-bit samples greatly reduce interpolation errors. 16-bit sampling is only good enough if we have perfect DACs and ideal low-pass filters. 24-bit samples will allow the use of practical DACs and cost-effective low-pass filters.

Yet another psuedo-standard

[Chmarr]

It always seems the way with sony. THey come up with a technology, some good, some bad, but they keep it all to themselves and the technology goes nowhere but for very small niche environments.

This one sounds like it'll be no more popular than minidisks.

Re:Yet another psuedo-standard

[jilles]

I don't know about these minidisks. I live in the netherlands but I have no use for them. Nor do I know anybody who owns one. Apparently if you buy a Sony stereo set it has a player. So I think it's more or less a failure everywhere.

Of course there are people who buy this shit, but I think philips cd recorder (for in your stereo set) has been a bigger hit.

In any case, I don't care for sony's new super audio cd. I won't consider buying one until there is a massive amount of content for it. I think it's rather naive to tie a streaming format to hardware these days. What about playing these things on my PC? Can create mp3 from it? Can I convert my existing music collection?

Answer: probably not. So, no thanks. Both philips and Sony have made some mistakes in the hardware/content area. Philips had the CDI (do you americans even know what that is?) which was soon nicknamed the poorman's cdrom. I think a lot of people regret buying one. Both philips and sony had their video tape formats, sony currently has their minidisk which was obsolete at introduction time.

This thing has failure written all over it. The media of the future is DVD, nobody wants yet another completely incompatible cd standard.

Re:Yet another psuedo-standard

[mrscorpio81]

Well, I am one of the few, the proud, the USA minidisc users. They are quite popular in the tape trading communities, because they allow your average joe to have a digital recorder at half the cost of a comparable DAT Walkman. I myself own a Sharp model, and you can hear a full mp3 of the song "Tired of Sex" from the Weezer show that I taped in Chicago at the C>A>R>S page off my website. I love it for its portability, I mean the way I got it into the concert was wearing a baseball jockey without the plastic cup...I fit the recorder, my binaural mics, the battery box, and 2 minidiscs in that pouch! I wish minidisc would take it's intended role as the replacement for the cassette, but it needs to have more market presence and blank media needs to drop in cost. Oh well.

Re:Yet another psuedo-standard

[mrscorpio81]

Plus, one thing you didn't mention is that the SACD should appease the Hi-Fi market much better than DVD-A...DVD-A is going to use a 96khz, 24-bit audio format, which is MUCH nicer than CD's, but the sampling rate of the SACD is in the mhz...that's going to sound amazing, and I'll go as far to say that it's without a doubt better than the highest quality analog (unlike CD's).

Re:Yet another psuedo-standard

[DagSverre]

In case you hadn't noticed, minidiscs are amazingly popular many places in Europe, it's just in US it's a failure. I know of perhaps 30 people with minidiscs (not just Sony, but also Sharp and one have a Phillips I think...)

Re:Yet another psuedo-standard

[turpie]

", sony currently has their minidisk which was obsolete at introduction time. "

This part isn't exactly true IMHO as the MD was released in the early 90's long before things like the Zip disk came along. However it was probably obsolete by the time it became "popular".
If Sony had pushed it harder we might have managed to get rid of the Floppy and had 100MB disks long before now.

Re:Yet another psuedo-standard

[Polo]

Now wait a minute, this has every chance of being the smashing success that the Sony Elcassette was!

Re:Yet another psuedo-standard

[tru+junglist]

This one sounds like it'll be no more popular than minidisks.

im not sure about america, but in europe minidiscs have become extremely popular. two or three years ago when they were first marketed here in france, it was admittedly a niche interest. but now almost everybody i know has traded in the discmans for an md player

Re:Yet another psuedo-standard

[Qube]

It always seems the way with sony. THey come up with a technology, some good, some bad, but they keep it all to themselves and the technology goes nowhere but for very small niche environments.

Take a look at this list. Count the number of non-Sony manufacturers making MD products. Consider that Sony co-created the CD format with Philips and that's a long way from a niche technology.

FWIW, I think SACD stands a much better chance of acceptance (even though I'm not willing to upgrade CD players yet, the single-disc Sony SACD player is about 400ukp from the discount hifi shops), because:

• They've got players out there and in shops now, whereas the DVD-A players are still obscenely priced boxes that are still doing their rounds with the hifi press.
• Backwards compatibility with CD - there can be a layer on the disc that has a plain CD-Audio version, meaning it'll play on all your existing CD players and record shops can just stock the SACD, rather than CD and DVD-A. Who'd buy a disc that they can play on their main player, but not in the kitchen or in their car?
• Support from Sony, who (like it or not) sell a lot of records - therefore a sizeable chunk of releases on SACD, and industry support from the start.
• While I don't doubt there'll be SDMI-watermarking-whatever bullshit, at least there's stuff like digital outputs so you can record to MD, DAT, PC, etc at a decent quality. DVD-A spec doesn't allow any digital outputs (Oh no! they'll steal our music!)

I don't find it compelling enough to upgrade for a long time (I'd rather sit and wait and see what happens), but my money's on SACD winning this one. The only thing in DVD-A's favour is that people are familiar with the name (then watch the disappointment when they realise their DVD-Video player won't play them..)

--
qube

Re: 22050Hz

[Kiwi]

First of all, things above 22kHz aren't picked up by ordinary mics... Even the ultra-high-end Neumann U87Ai only claims 20-20kHz frequency response

Then again, the U87 is a large-diaphram condenser, and is more about giving a "warm" instead of an "accurate" sound.

B&K makes mics with a reponse up to 40khz (I know they are called DPA mics today, but I still call them B&Ks). B&Ks (and Genelecs) are what people use when they want a really accurate sound, as opposed to a "warm", "larger than life" sound.

That said, I agree with what you are saying. People can not hear about 20khz, and people that think they can will need to run some double-blind scientific tests to back up their claims before I will seriously listen to them.

- Sam

Re:Wrong!

[gargle]

You can reconstruct a signal sampled at the Nyquist rate ONLY by using sinc interpolation functions. These functions do not have compact support (that is they live on the whole real line) and therefore you can never create them and use them.

Yes, but in any case a band limited signal will not be time limited, so perfect reconstruction is not possible.

You use something similar, something close but then you can't reconstruct exacly. The "solution"? Sample at a frequency higher than the Nyquist rate.

Yes, a higher sampling rate will allow the use of a sloppier interpolation filter. But it still won't be exact reconstruction because a time limited interpolation filter will not be frequency limited.

Is there a catch?

[doogles]

It seems most new technologies now have a catch: DVDs and the mess over DeCSS and the MPAAs desire to sue, MP3 encoding and the RIAA drooling to sue anyone who even looks at an MP3, intellectual property right, DMCA, who owns what, etc.

I'm obviously a huge fan of new technology, but is there a catch somewhere in Super CD? The article was big on technical, not on much else. Anyone have any insight to this?

Re:Is there a catch?

[cmg]

Low end DAT decks record the SCMS bit into the stream. When I record live music ( allowed by the band ), It means I can only make one generation of copies without switching to a more expensive model of deck. These machines have the habbit of making everything copy protected even when it shouldn't be.

Re:Is there a catch?

[mrscorpio81]

I posted about having a clip from the Weezer show I taped in another thread, it's the C>A>R>S page off my website...I think it turned out pretty well, if I do say so myself. I wouldn't be the least bit surprised if the consumer level stuff has some sort of digital copy protection, though on second thought that confuses me because you can make direct digital transfers to mp3 with an adapter? Anywho I have a pro recorder, therefore I don't have to worry about such copy protection schemes :)

Re:Is there a catch?

[Howie]

MD has it's own SCMS-alike copy-protection - you can't digitally copy a recording you made on a minidisc. They also managed to make an interesting looking data format (MD-Data) out of the same discs in such a way as to make them *really* annoying - the computer can't read Audio MD at all, or (more importantly) write it. The data format has pretty much died now - it would have been something like 200Mb on a $3 2-inch disk - quite neat.

It would be a whole lot less annoying if Sony didn't continually run ads suggesting MD let's you record, re-record and edit to your heart's content. Which is true, as long as it's not from another Minidisc.

Why anyone would buy pre-recorded MDs is beyond me. I have an MD walkman which is a HUGE improvement on my old Sony tape walkman - track skips, CD-ish sound, recording - and I can see the point for a car system, but I'll be keeping my CDs for now thanks.

I wouldn't buy any Sony new media format for at least a year or so, to see if (a) they license it (b) they don't just get bored with it (c) they don't screw it up in some other way. Oh, and if it really works, the price will drop a lot - CD players and recorders both started out damn expensive.

Re:Is there a catch?

[Technician]

Betcha biffy it's the thing to get people into SMDI complyant players and media! Sony of all hardware people are the first I'd suspect of this. After all they were the ones with the crippled minidisk.

Re:Is there a catch?

[alexdw]

You could always set the SCMS bit low with a pocket knife... :-)

Re:Is there a catch?

[theancient1]

How is their Minidisc crippled? I hadn't heard of that.

Of course, that this is the same company that brought us the Music Clip MP3 player... one of those nifty devices that asks you to convert all of your MP3s to some "secure" format. Their PlayStation uses specially-formatted CDs that can't be copied. Aren't they a member of SDMI too?

For what it's worth, my ears aren't that sensitive. How many people out there are saying, "the audio quality of these CDs is really driving me to insanity, when oh when will someone come up with a better format?"

Re:Is there a catch?

[Coward+Anonymous]

AFAIK MD's are crippled by a Digital-Analog-Digital copy protection system. In other words, the output from the MD for recording may be digital but the original digital signal goes through a deliberately noisy analog stage before being converted back to digital and out the jack.
Anyone know otherwise?

Re:Good ideas

[Paul+Komarek]

newer DATs are doing 96kHz at 24bits.

also, audio DATs don't use the same format as computer back-up DATs, unfortunately. supposedly sgi once released a computer DAT drive that could read audio dats, but this device appears to be rare.

-Paul Komarek

Re:This is just stupid.

[avandesande]

But you can hear beat waves from the interfering high fequency waves.

Nyquist theorem

[darkwiz]

Nyquist's theorem states that the highest frequency that can be represented is one half the sampling rate. This is obvious because you must be able to detect at least a peak and a valley of the sound wave.

Nyquist's theorem does not imply, however, that the representation of the maximum [or near maximum] frequencies will be highly accurate as far as the shape of the wave form is concerned. At and around 1/2 sampling freqency, the wave forms become basically nothing but square waves [alternating between a single high, and a single low point]. In order to deal with this, some sound decoders will attempt to interpolate the waves, but they cannot reproduce the original sound accurately. This is why higher sampling frequencies ARE relevent to higher audio fidelity. Higher bit resolutions are arguable though...

Re:Nyquist theorem

[OmegaDan]

thats very true :) but look atthe same incorrect arguments modded up to +5 on this discussion ... Leave digital audio to the professionals!

Re:Nyquist theorem

[Pig+Bodine]

This is either misleading or wrong depending on how generous my interpretation is. Here is the best I can do at explaining the sampling theorem.

The Nyquist sampling theorem: a signal that is bandlimited to a maximum frequency F is EXACTLY determined by samples taken at a frequency 2*F

In vague terms that might not be all that clear (I wish I could draw a picture!), the reason for this is that if you look at the the frequency components of a sampled signal they are the same as for the original signal, but replicated periodically along the frequency axis. The faster the sampling, the wider the spacing. If they are sampled fast enough then because they are all bandlimited these replications don't intersect and you can recover a pure replication of the original signal by just filtering a portion of the spectrum that includes the copy you want and excludes the others. If they intersect you have what is called aliasing, where each copy of the signal corrupts the others and none is retrievable. The Nyquist frequency is the frequency at which aliasing sets in; anything faster than 2*F and your samples will suffice to recover the bandlimited signal; anything slower than that and you are screwed.

It's actually a bit more complicated than that, but not in the way you suggest. In practice, the process for reconstruction of an analog signal from a digital signal (i.e. DAC) involves applying a zero-order-hold (i.e. producing an analog signal by holding the value of the previous digital signal until the next comes along). This gives a square-shaped signal that has the same frequency components as the original signal, and still replicated over the entire frequency spectrum, but multiplied by the sinc function sin(x)/x. You get the original signal by low-pass filtering to pick up the frequency-replicated version of the signal you want while compensating for the distortion caused by multiplication by sin(x)/x. If you can design sufficiently good low-pass filters with an x/sin(x) shape, you will still get the original signal exactly, assuming only that it was bandlimited to a maximum frequency F.

Further, there are ways to deal with both aliasing and the restriction that you have a good low-pass filter at the end. For the first, you just low-pass filter the original analog signal before sampling. This ensures that there is no aliasing and that you, at least in theory, have enough information to reconstruct all frequency components less than F exactly. For the second, you use oversampling purely in the digital domain. The idea for oversampling is that if the signal really was limited to a maximum frequency of F and your sampling rate is 2*F, the signal is completely determined by its samples and you can accurately interpolate what the samples would have been if you had sampled at 4*F, 8*F, 16*F. This process is exact and (as I mentioned before about the effect of a higher sampling rate on the spacing of replications of the spectrum) it creates a significant gap between the replicated versions of the signal. This gap means that the cut-off on your low-pass filter doesn't have to be exact---it can gradually (rather than sharply) drop off in the regions in which the oversampled signal has no frequency components. Note that oversampling is done through digital interpolation of a signal sampled at a lower rate and has nothing to do with the sampling rate on a CD (or whatever medium). In fact the chief purpose of oversampling is not to improve sound quality, but to allow people to use crappier analog filters for the DAC process.

It's late here in Australia. That's long-winded and probably not clear to anyone who doesn't know it, but the gist of it is what I put in bold above: 2*F is sufficient to recover the signal exactly if you want to put enough care into designing the hardware. Contrary to what you say, Nyquists theorem states that for a band-limited signal, the shape of the wave form CAN be accurate if you put enough care into designing the hardware.

FWIW, none of this is obvious. My jaw dropped the first time I saw an explanation of the sampling theorem. It's really an amazing, counter-intuitive idea.

Re:Nyquist theorem

[Cuthalion]

Okay, what everyone's missing here, is:

Yes, you can exactly reproduce signals with the maximum frequency up to half of the sampling rate. But wait, you say, rate/2 hz square waves get turned into sines! I say: No! A rate/2 hz square wave has [infinitely] many frequency components above it's base frequency. By saying that a 22khz square wave has no frequency components above 22khz is just a lie! (tidbit: This is true of any signal whose value or any of it's derivitives are not continuous)

Re:Nyquist theorem

[Pig+Bodine]

You seem to have missed the word bandlimited. Audio signals are always filtered in advance to ensure that they are bandlimited and the response of the human ear is itself bandlimited, so this isn't a big assumption. You are talking about sampling a signal with exactly one frequency component at exactly its Nyquist frequency. To recover a signal exactly you need to sample at faster than the Nyquist frequency. Samples that are only marginally faster than you propose will suffice to exactly recover the signal you are describing. A way to do this is: make an analog square wave from the digital samples and then apply an analog filter to remove harmonics and (at the same time) eliminate multiplication of the frequency components by sin(x)/x. If the signal was bandlimited and you design your filter well enough (admittedly a non-trivial design problem), this gives you the signal exactly. If you don't know what the function sin(x)/x has to do with it, you need to go back and study sampling theory before spouting off.

What you call "mathematical justification" not only explains your example, but shows that you are talking about sampling at a threshold for which for all higher sampling frequencies you can recover the bandlimited signal exactly. You've pinpointed the fastest sampling for which reconstruction can still fail (and, in fact, sampling at exactly the Nyquist frequency wouldn't have failed here if you had selected a signal with a continuous frequency distribution instead of a single frequency---this isn't the simplest case, but, in fact, it is an extreme case). Use the frequency domain. You can't get much intuition about this without looking at Fourier transforms.

Re:Nyquist theorem

[rnbc]

No, it would not register a signal of amplitude zero if the proper reconstruction method (sum of "sinc" functions) is used.

The problem is that such a method is not feasible in practice.

Normally CDs 44.1/16 are converted into 200kHz/18 or something like that using a DSP witch emulates the "sinc", and than some cheap DAC using linear interpolation is used.

That ruins the CD quality, not the technical specs of the CD itself.

Really good DACs are able to fully reproduce whatever the human ear can hear, and Im one of those guys that (bieng 24) easly spots bats and hears 15625kHz PAL TVs...

My mother is 55 and still hears bats and PAL tvs also... so I definetly have a good pair of biological transducers :-)

Re:Nyquist theorem

[cheese_wallet]

Actually you are both wrong. The first post was incorrect in saying the higher frequencies look like a square wave. That is pretty unlikely. It totally depends on your digital to analog converter. It would probably closely resemble a triangle wave.

As to the second person quoting some DSP book... digital to analog conversion is a one way process. Yes, yes, it is true that a set of samples from a band limited signal, sampled at twice the highest frequency content (probably) uniquely represents that signal... but that says nothing about reconstruction. Think about pgp signatures (I hope that is a good example). Perhaps that theorem is just referring to frequency content?

Draw a sine wave and a triangle wave of the same frequency and phase. Sample at twice this frequency with the first sample being the peak of the first triangle cycle... Whoa! look! the samples are exactly the same!

Re:Nyquist theorem

[OmegaDan]

Thank GOD (or god substitute) someone else understands this ... Alot of nazis read the nyquist limit thereom and think they know everything about digital audio ... just ask someone for an oponion on 24/96 audio cards on #audioappz on effnet ...

I do have to take issue with the statement "At and around 1/2 sampling freqency, the wave forms become basically nothing but square waves" though ... I believe most sigma-delta (or is it delta-sigma? I can't remember ... :) DAC's actually output a curve between any two points, and not just a voltage drop ... if it was just a voltage drop, the sound would be hollow and metallic because of the harmonics created by that voltage drop. In effect you'd have 1/2 cycle of a square wave at each voltage drop, and if we recall our mechanics, a square wave is a sine wave with odd harmonics (3, 5, 9, etc...) ... Ideally the curve would be sinusodial so it wouldn't create any harmonics.

Re:Nyquist theorem

[phliar]

At and around 1/2 sampling freqency, the wave forms become basically nothing but square waves [alternating between a single high, and a single low point]

This is such bullshit!

The Nyquist theorem says that if you have a bandwidth-limited signal with a bandwidth of n Hz, then sampling at 2n Hz recovers the signal exactly.

Drill that phrase into your heads: band-limited. Each time you start to construct mythical counterexamples with square waves, think of bandwidth. Think audio, and read up on Fourier transforms.

This means that if I take a music stream and pass it through a low-pass filter of 22.05 kHz, then there is no difference in the output stream whether I give you the low-pass filtered music or I sampled at 44.1 kHz, transmitted those samples, then passed them through a low-pass filter. None. No "basically nothing but square waves".

However, for a digital format like CD, there are other variables besides sampling frequency: what is the resolution? The higher the resolution, the better the S/N ratio of the system. Low resolution means that there will be a higher noise level because of aliasing. (Any reasonable audio system will use dithering when performing the D/A step - the analog of anti-aliasing in the visual world.) Higher bit-resolution is not just an academic issue. CDs use 16-bit resolution, which is probably adequate for music - it represents an uncertainty of 1.5e-6 or around 98 dB. Using 24 bits would give us 104 dB (each additional 8 bits add about 6dB) but it would be ridiculously hard to make good A/D converters.

Another factor is the encoding curve - how are the sound levels translated to numbers? The CD format uses a 16-bit linear curve. The choice of a linear encoding was poor. Human ears have a log response curve i.e. we can hear differences in loudness better in soft sounds than in loud sounds. This is why sound levels are measured in dB, which is logarithmic. (A difference in 3dB represents a sound twice as loud.) [The telephone industry has understood all this much better than the audio industry - the mu-law (and A-law, used in Europe) curve is logarithmic.]

Basically if you have a bandwidth limited signal with a certain S/N ratio, there is a sampling frequency and resolution you can use that will result in a signal indistinguishable from the original.

There are a few engineering issues: a perfect "brick-wall" low-pass filter cannot be made. When recording a CD one would probably use a low-pass filter that starts falling off around 18 or 20 kHz or use over-sampling at 2x or 4x the 22.05 kHz frequency. Inaccuracies in the clock when recovering a signal add noise. Etc. etc. etc.

For an excellent treatment see http://www.vgard.net/digital aud io/digitalaudio.html.

Re:Nyquist theorem

[Detritus]

If you put the output of the DAC through a 20 kHz low pass filter, the odd-order harmonics are removed and you have sine waves again.

Re:Nyquist theorem

[Dahan]

Nyquist's theorem does not imply, however, that the representation of the maximum [or near maximum] frequencies will be highly accurate as far as the shape of the wave form is concerned. At and around 1/2 sampling freqency, the wave forms become basically nothing but square waves [alternating between a single high, and a single low point].

Umm, ever hear of low pass filtering? Say you sample a 22kHz pure sine wave at 44ksamples/second and end up with alternating max/min sample, i.e., a 22kHz square wave. You're not supposed to just use that as-is; you have to put it through a low pass filter, with a 22kHz cutoff frequency, which will get you your 22kHz pure sine wave back again.

The Nyquist theorem does in fact imply that you can reconstruct your original signal perfectly... of course, Nyquist theorem is just math... in the real world, you can't make an ideal lowpass filter with an immediate rolloff, but that's not Nyquist's problem :)

Re:Nyquist theorem

[jovlinger]

What about phase? How do you differentiate between a wave that is out of phase with the samples (in the extreme looking like a zero-amplitude wave) from a low aplitude in-phase wave.

ascii-art (ignore ".", used 'cause crappy slashdot doesn't have pre tag or nbsp:

|...---...............
|.//...\\.............
|/.......\ ...........
+----A--B-\----A--B--.
|..........\......./..
|...........\\...//...
|.............---.....


If I sample at A I get back the original waveform, but if I sample at B, I get back one of only half the amplitude, when I really wanted a full waveform that was phase shifted -pi/4.

Re:Nyquist theorem

[Zoyd]

darkwiz said:
At and around 1/2 sampling freqency, the wave forms become basically nothing but square waves [alternating between a single high, and a single low point]. In order to deal with this, some sound decoders will attempt to interpolate the waves, but they cannot reproduce the original sound accurately.

An accurate reproduction of the original sound wave would be a pure sine. This is because any departures in the original wave from pure sine have to be harmonics (at much higher frequencies, but sine waves themselves with any aberations in their shapes from pure sine in turn further harmonics which are themselves sine waves, and so on...) and therefore out of the range of frequencies that we are concerned with.

Now, you could argue that reproducing these higher frequency sine waves is important for the pure reproduction of sound, but that is another subject. To the question of whether interpolation can accurately reproduces waves of any given frequency simply by creating pure sine waves, the answer is "yes" since there is no such thing as a sound wave that is not a pure sine wave.

-Zoyd

Re:Nyquist theorem

[Afty]

So I'm just a Slashdot newbie, but it seems to me that this post has been proven factually incorrect by all the "Incorrect!" posts following it ¥and I know it's incorrect because I took a class on Fourier methods and sampling theory© Why then is it still moderated up to a 5 while all the correct responses are down at the 1-2 level?

Re:Nyquist theorem

[n+xnezn+juber]

Maybe you should read that DSP book (by the way Oppenheim & Willsky is not a DSP book, it is a simple signals/systems book... a very common undergraduate electrical engineering textbook). Ok, this may be counter-intuitive because you obviously have had no formal education in signal processing but that triangle wave you drew has actually has many, many frequencies higher than the frequency that you are talking about. How can that be? If you low-pass filter the triangle wave (basically it means smoothing out all the edges) what do get? You get a sine wave exactly like the one you first drew. I suggest you learn a little more about fourier analysis before posting about things like this.

Re:Nyquist theorem

[h4x0r-3l337]

Now apply your argument to a 22kHz pure square wave input signal, and you will see why despite Nyquist highger sampling rates are important.

Re:Nyquist theorem

[jab]

Any waveform can be decomposed into a set of sines and cosines with certain amplitudes. This is called a fourier transformation. For more details (including how this works for discrete samples vs. continuous functions and finite vs. infinite signals, I suggest "Signals and Systems Made Ridiculously Simple" by Zohar Z. Karu or "Discrete Time Signal Processing" by Oppenheim and Schaefer, depending on which direction you prefer to dive.) The mathematics are not obvious as postulated in the above post, and they are actually quite interesting. Once you think of a signal as a collection of sines and cosines, the question is, "How can I make sure *all* those sinusoids are reproduced. The Nyqist Theorum says your must sample at least two times per period to reconstruct a sine wave. So, for example, if you want to reproduce a 20 KHz tone, your sampling rate must be at least 40 KHz. A reasonable question is: how do I reproduce the sinusoids from samples, and the answer is "sinc interpolation" or "low pass filtering". Because it is impossible to build an ideal low pass filter, and expensive to make a good one, CD players sample at little generously at a bit over 44kHz. Since the upper range of human hearing is 20KHz (for children, us adults are lucky if we can hear 18KHz) the CD sampling rate can accurately reproduce all the frequencies you can hear.

However, one thing I learned as an engineer and when I was an intern at Bose Corp in college is that audiophiles tend to be a bit nuts and can convince themselves of anything, like that $3000 speaker cables with aligned metal grains improve sound quality. There's all sorts of impassioned claims that never stand up to double blind testing. So if you don't believe me -- that CD's work great and there is no need to fiddle with sampling rate and you will never tell the difference from a higher sampling rate -- it's ok, I'm used to it. Besides, who am I to complain if people are passionate about music :)

Re:Nyquist theorem

[DeeKayWon]

No, I can't. Sure the input signal has a bunch of odd harmonics with a fundamental of 22kHz, but they're well beyond the range of human hearing. So while the input was a square, it might as well have been sine.

Re:Nyquist theorem

[darkwiz]

The pi/2 problem is related to my original post. Unless you can guarantee this, Nyquist's theorem does not hold. A simple example is if your sampling occured at the zero cross for a sampfreq/2 sine wave. This would register as a signal amplitude of zero, not whatever it really was. No amount of mathematical justification can take away this fact. If you don't know the correct amplitude, you don't know anything about the wave. The only possible work around would be to have a dragging amplitude maximum locator, but then you would have to be continuously adapting your sampling phase, and this becomes ridiculous.

Re:Nyquist theorem

[Dahan]

A 22kHz square wave has many (well, an infinite) number of harmonics above 22kHz. Nyquist's theorem applies to a bandlimited signal. Sure, higher sampling rates are important if you really want to capture a 22kHz square wave (take a look at the sampling rate that digital sampling oscilloscopes use... they're in the gigasample/second range; Tektronix has one that goes up to 20GS/s). Higher sampling rates aren't particularly important for audio signals intended for humans to listen to though.

Re:Nyquist theorem

[nathanh]

Nyquist's theorem states that the highest frequency that can be represented is one half the sampling rate. This is obvious because you must be able to detect at least a peak and a valley of the sound wave.

Entirely correct.

Nyquist's theorem does not imply, however, that the representation of the maximum [or near maximum] frequencies will be highly accurate as far as the shape of the wave form is concerned. At and around 1/2 sampling freqency, the wave forms become basically nothing but square waves [alternating between a single high, and a single low point]. In order to deal with this, some sound decoders will attempt to interpolate the waves, but they cannot reproduce the original sound accurately. This is why higher sampling frequencies ARE relevent to higher audio fidelity. Higher bit resolutions are arguable though..

You fail! This idea that the signal is not perfectly represented just because you have only two sample points is complete nonsense. Only two sample points are needed because you know the encoded signal must have been low-pass filtered at half the sampling rate before sampling (otherwise you would have introduced aliasing errors). Given this information you can entirely reproduce the original signal as it was before sampling. Nyquist's theorem states that you can exactly reproduce the signal if sampled at twice the signal's maximum frequency. I quote Oppenheim and Willsky:

The sampling theorem establishes the fact that a bandlimited signal is uniquely represented by its samples.

In layman's terms: you don't need more bits to reproduce the original signal. You just need a perfect low-pass filter on your output and infinite precision on your PCM samples. A sine wave with sampling points at the exact peaks and troughs will produce a square wave of the same frequency after sampling/modulation. This square wave will contain the frequency you want plus odd harmonics. The harmonics are naturally going to be higher frequencies and so they will be removed by an appropriately picked low-pass filter. And what's the appropriate cut-off frequency for your low-pass filter? 1/2 the sampling rate, of course. The result is the original sine wave.

Now in practise they actually do sample at higher than the low-pass cut-off frequency, but this is because of other limitations. The PCM samples are only 16-bit, not infinite precision. Also there is no such thing as an ideal low-pass filter: realistic (and affordable) filters will take several kHz to drop from 0dB to -9dB. Also you need exactly -/2 phase difference between your sampling pulse train and the source signal. There are also aliasing issues but at this point the discussion gets heavily into mathematics.

Higher resolution is what is actually needed but this is expensive to achieve. Increasing the sampling rate is far more practical (considering how fast CPUs are) and a heck of a lot cheaper. This is the real reason DVD audio samples at 96kHz. It's not because you can hear 48kHz tones but because it lets the DVD manufacturers use cheap DACs and cheap low-pass filters without sacrificing fidelity.

Re:Nyquist theorem

[Pig+Bodine]

I was wondering the same damn thing. Slashdot moderation is pretty useful, but on technical areas that are a little outside the mainstream here it occasionally falls flat on its face in a really spectacular way. This isn't just sour grapes: My post wasn't all that great in terms of clarity (I shouldn't post at 2am after a night out drinking), but others made the same points better than I did and didn't get moderated up. They were both lucid and right while the highly rated post they were responding to was just plain wrong.

Sorry for the rant... For the most part I like the moderation here, but every now and then it seems more important to post early and be able to pretend you know what you are talking about than to be able to get the facts right.

Gedanke-experiment

[Chris+Johnson]

Is it physically possible to have a 5K pulse wave that's very thin? Not 22K, _5K_. But so thin that the pulse is 1/4 of the duration of the wave.

If you try to sample this at 44.1 and reconstruct it, you're hosed- you have substantial problems based on the fact that the pulse would be quite accurately tracked by a 20K rate but you're trying to force a 22.05K rate to track it. It doesn't help to throw away all the very obvious and unavoidable over-20K components (come on, _5K_ and you get only a couple of harmonics? That's nuts): you're still hosed by the interference pattern that is produced, because these are not simply a pile of sine-tones: they are sine-tones (lots of them) AT SPECIFIC TIMES. Just because 20K is lower than 22.05K doesn't mean 22.05K is going to do even a remotely acceptable job of sampling it.

Remember that we are talking about a _5K_ wave here, not something absurdly high. Do you not think you can hear the difference between a really thin pulse wave and a sine at _5K_? Yet the pulse only needs to be about 1/4 width to cause really severe problems with sampling- specifically, a rapidly cycling distortion component that will go from 0% distortion to severely, severely distorted at a rate fast enough to make up an entirely new, harmonically unrelated tone! This is only lessened by throwing away frequencies over 20K, not entirely fixed. You can lessen it a lot more effectively by throwing away all frequencies over _10K_ but come on- whoever heard of a pulse wave with only two harmonics? Our 5K pulse wave would be unrecognizable- this has to be considered distortion.

I'm afraid Nyquist is mostly crap- it would be fine if all musical frequencies were exact subdivisions of 44.1K, but when you start dealing with real-world frequencies, you start having these intermodulation problems, and the problem is not that you're not having the supersonic frequencies, the problem is that the resulting intermodulation effects are cyclical degradations of continuous tones and produce _inharmonic_ tones. It's very hard to hear slight differences in harmonic tones but it's not hard to hear problems when there are inharmonic tones being synthesized.

Extra credit- what inharmonic tone is generated by the distortion on a 5K 1/4 width pulse wave sampled at 44.1K? Use as much treble-rolloff as you want, it'll always be the same intermodulation frequency. Anybody good enough at math to say what frequency is generated as intermodulation distortion? :)

Re:Gedanke-experiment

[Naysayer]

The 5k pulse wave you are talking about contains many many high-frequency sine waves. That is what makes it sound "clicky". Because you're a computer guy, you are used to thinking about square waves. But square waves are not a good way of thinking about these problems.

All I can say is, signal processing research has been going on for a very long time (over 100 years) and has been participated in by a lot of very smart people. So before you start calling its foundations "mostly crap" I'd recommend you do a bit of reading.

It's clear from your talk of "real-world frequencies" that you haven't even the slightest notion of signal processing, and furthermore you're not even reading the replies in this thread (there are at least two messages by other people explaining what's wrong with the "square wave" idea more thoroughly than I did).

If you want a simple illustration of why your basis of thought is faulty, here's a question for you: What is the frequency content of a single pulse in the midst of silence? That is, take your pulse wave of whatever period you want, and stretch it out and out until you just have one pulse. What is the frequency content there? You might say "zero" but this is not even close to correct. There is sound after all.

-Jonathan.

A simple glance

DVDs were once considered as to CDs as Beta-max to Videos. Obviously Betamax was superior, but was it adopted: No.

Why? Perhaps simply, skipping all technical discussion on sociology and big business intervention, VHS was too far established.

Well, I see DVD as its own new world, incomparable to VHS, but this seems to be the betamax of the DVD world -- given the rapid acceptance of DVD in the western world (America picked it up faster than the Japanese even) does anyone believe that people who come out of their comfort zones and invest in a new technology after DVD has entered its full swing?

Not that new, not that cheap

[Watts]

Sony has had SACD for quite a while now. I remember picking up some audiophile magazines over a year ago and reading about it. They've released a lot of Sony Classical stuff on it.
However, a lot of the systems to play SACD cost over $1K for the cd player. Not to mention you're not going to get the nice dolby surround of DVD at the same price....

Re:Not that new, not that cheap

[K8Fan]

Sony has had SACD for quite a while now. I remember picking up some audiophile magazines over a year ago and reading about it. They've released a lot of Sony Classical stuff on it.

This is very old news indeed. An audio-video store I consult with has had demo units of both the Sony SuperAudio CD and DVD-Audio for months.

The ironic part of course is, the only people who listen closely enough to music to hear the difference between these enhanced formats and regular CDs are the same folks who will be able to hear the effect of the audio watermarking. The watermarking must be audible, as they wish it to be detectable even when all the inaudible portions of the music are thrown away by a process like MPEG encoding. They want it audible when the music is recorded to cassette. And, possibly most important from their perspective, they want it audible when the music is played though the compressor at the radio station - so they can automatically log all the plays and get their ASCAP and BMI money from the stations.

I've heard A/B comparisons at the Consumer Electronics Show and the Custom Electronic Design & Installation Association show. They both do sound better than standard CDs - though not that much better than the standard-CD compatible HDCD process. And the most annoying part is that they are both entirely unecessary. A standard DVD can provide 5.1 channels of uncompressed audio at up to 24 bits at 96 khz. As a Dolby engineer explained to me, this is enough dynamic range to reproduce the sound of a jet engine starting in an totally silent enviorment.

Both SuperAudio CD and DVD Audio are basically a rip off. To date, the most impressive 5.1 channel demos I've heard, of better than CD quality systems have been DTS - which works with most existing DVD players and requires only an additional decoder. Virtually all Dolby Digital decoder equipped audio componets also feature DTS.

Re:*ahem*

[Dahan]

As I said, due to the way Goldwave (and all other sampled sound processing programs) works, I repeated each sample 16 times. 14700/16 = 918.75, and 22050/16 = 1378.125 (I used the wrong cutoff frequency originally, but I fixed it). If it makes you feel better, think of pictures 2 through 4 as 14700Hz waveforms viewed on a digital sampling scope with a sampling frequency of 705600Hz. If I didn't repeat the samples, I obviously wouldn't be getting any harmonics over 22050Hz to filter out.

And yes, the 14700 does have the second harmonic (and all higher ones) obliterated by the 22.05K lowpass. That's why it works. That's exactly my point... really, we're talking about some of the foundations of signal processing here. This has been studied in depth by many people; if it were wrong, I think someone would've noticed by now.

Real world filters do cause phase changes (note that the bottom picture is offset from the original), but my demonstration was to show that even though the sampled waveform looks all funky, when you filter it, you're left with a pure sine wave--the same as what you started with. You said "Or that a 1/3 width pulse wave at 14.7K with a 22K filter is EXACTLY a sine wave? I would suggest that it is not...", but my pictures show that yes, it in fact is exactly a sine wave.

As I mentioned in one of my other posts, in the real world, things don't come out perfectly. I do think that a higher sampling rate can have some benefit (though to tell the truth, it's not a benefit that I'd be willing to spend any extra money on). My dispute is with those who are saying that even in a completely theoretical world, Nyquist's theorem is incorrect.

Re:Lesson in hearing and sampling

[Big+Ol'+Troll]

I agree that you can accurately reproduce a sine wave if you sample at twice the frequency of the original. Problem is that anything other than a sine wave has higher order components. Fourier tells us this. Reproducing a square wave or something that approximates it requires infinite bandwidth using the sum of sine waves.

I've mentioned this in another post. If you sample a sine and triangle wave four times a cycle, there is no differentiating the results if the sample times coincide with zero crossings and peaks. Now you can throw any sort of DSP at it while chanting Nyquists theorm, but the reproduction is not going to be accurate. Nyquist's theorem applies to sine, but when higher order components are involved the sampling frequency increases accordingly.

I do not have any problem with CD as a storage mechanism, just the standard format. It would be possible to exceed the specifications of DVD or SACD in terms of bits per sample and samples per second at the cost of reduced play back time.

Re:Yet another psuedo-standard (minidiscs bite)

[BrendanHeading]

You're not being very fair on Sony here. The portable MD units are aimed at the walkman market who would normally use tape walkman devices to take their music on the move. That market doesn't need a digital output. There are slightly higher-end units that have digital outs, although I'd suspect these'd be somewhat out of your price range. Prior to MD you wouldn't have been able to record bands digitally *at all*, so I can't see what you're complaining about.

The piracy issue can't be a serious reason for not having a digital out. If they were worried about piracy, they wouldn't include any digital ins. I suspect leaving the digital outs off is to do with selling the full size units and trying to keep the size (and price) of the portable units down.

Your problem can be rectified by purchasing a full size unit. This way you can still record digitally, then bring the recording home, stick it in your full size unit and feed it into your computer via the digital out on that. The full size units are relatively cheap these days.

Re:MP3s DO sound fine.

[dboyles]

No, what the MP3 revolution shows is that almost all music fans value the content more than the technical reproduction.

I think you're mistaken. Content doesn't play a role here. Essentially everything available in MP3 format is also available in an uncompressed digital format. But most the vast majority of MP3 listeners can't hear or don't care about the extremely large quality loss that is inherent in the MP3 compression algorithm.

This is the same group of people that use the term "high end car audio" without a hint of irony.

Please! Most people think (cough) MP3s sound fine.

[hatless]

So here's a digital format that should please nearly all the classical music afficionados out there who spend tens of thousands of dollars constructing acoustically-perfect "listening rooms". Nothing bad about that. At the very least, it finally creates a reasonably lossless way to digitize analog material for archival and preservation purposes--although any archivist will tell you that the real archives themselves for long-term preservation should be old-fashioned stamped analog discs.

These two markets--archivists and money-is-no-object audiophiles--should be covered with about 20,000 of these devices. So what about the rest of us? I have serious doubts that the difference between this and DVD-Audio can be heard on even a $3,000 home theater system.

Sony (and presumably Philips/Magnavox) intend to build support for this into all of their players starting sometime soon, maybe a year from now. The thing is, nearly all the DVD players being sold today can play the competing DVD-Audio discs. None, not even Sony's, and not any of those millions of Playstation2s shipping in the next year, can play SACDs.

Ultimately, this is about patent royalties. Sony and Philips have been collecting royalties on every CD player and CD drive sold for over a decade now, and SACD is about trying to do it again for another decade. DVD-A is the format endorsed by everyone in the industry except Sony and Philips. Is it a good professional archival format? Nah. Is it both better and more flexble than CD? Yep.

So here's the ugly truth. The MP3 revolution seems to have proven that most people have tin ears. Ask a hundred people. 98 of them will tell you that 128Kbps MP3 is "CD quality". Fact is, it's inferior to Minidisc, to FM radio and--in many respects--analog cassettes. But it doesn't have hisses and pops, and that's all most folks really notice. Heck, 320Kbps MP3 sounds crappy next to a CD, even on a $400 stereo.

If people think MP3 is "good enough"--when it can't even hold a candle to CD--why is the mass market going to embrace SACD over DVD-A? Especially when they'll have DVD-A players available from dozens of manufacturers and SACD players most likely available from... three?

CD will be superseded, not because most people want higher-resolution sound quality they can't hear on Britney Spears remixes, but (1) because DVD-A and SACD players will offer things like 6-channel sound and bundled-in DVD video clips, and (2) because the record industry will stop making CDs, just like they stopped making LPs, in order to force everyone to buy the new players and buy yet another copy of Billy Joel's Greatest Hits to go with the LP, cassette and CD they already have.

The best format won't win. The more ubiquitous one will. The question remains which coalition will blink first. Will the Sony-Philips side break down and allow their record companies to start making DVD-As once they see SACD players aren't selling well, or will companies like Matsushita start paying royalties and buying chips from Sony because the Sony/Philips DVD-A embargo has made it impossible to get record stores to carry DVD-As?

Music is not signal processing.

[ponos]

It seems that too many of you consider music in the same terms as computer files. I prefer to consider audio equipment (decent audio equipment) as a part of the chain from the composer to your ears. You do not criticize a piano for not generating a perfect 440 Hz sine tone. You do not speak about Steinway and Bosendorfer pianos in terms of "S/N ratios" and "frequency response". I believe that if a new product indeed brings a better overall musical EXPERIENCE, which is of course totally subjective in nature, it is a good product. That being said, I don't see why vinyl shouldn't sound better than CD or even DVD-audio and why tube amplifiers with 0.5 % THD cannot give more musical satisfaction than 0.001 % THD solid state equipment. Technical analysis is indeed useful in comparing products of a similar "breed" and technology. Saying that 50 db dynamic range (vinyl) or 20 KHz upper frequency (CD) is not enough is in itself absurd and can only obtain relative value in comparing similar technical solutions. (turntable A vs turntable B) Human auditory perception is extremely complex and aesthetic appreciation is even more so. Do not treat music (which is about pleasure) the same way you treat a document (which is about precision and information). That having been said, I have to add that I am aware of both the Nyquist theorem and FFT and I do not choose to see music that way out of (technical) ignorance. I just prefer to see a high quality piece of audio equipment as an instrument and not as a tech-gadget. Petros P.S. It is sad, however, that we are sometimes forced to support and buy inferior products as a result of marketing strategies.

Re:What's with Sony's fetish for making new format

[K8Fan]

In the tradition of geekdom and Usenet, I will point out a minor problem with your numbers: (24 bits)*(96kHz)*(5 channels) = 11.5 Mbits / sec 1x DVD speed delivers only 10 Mbits / sec. Therefore, a 24 bit, 96kHz, 5.1 channel disc wouldn't be legal DVD-Video.

Yes, but using 2:1 or 2.5:1 lossless compression is so easy, that halves the data rate. I'm not sure what compression Meridian Lossless Compressions achieves, but I'm pretty sure it exceeds 2.5:1.

Re:Yet another psuedo-standard (minidiscs bite)

[p0d]

I do part time work for a sound company and we have a minidisc deck with S/PDIF out on it....though MDs do suck for pro applications, we got it cheap (100 bucks) on digibid, any serious live recording is done to DAT or DA-38 if you can afford it. Don't cheapen your band with minidiscs..."if bad sound could kill.."

Re:Incorrect... (Re:Nyquist theorem)

[Gladiator]

>>There is no need to sample higher than 96kHz >>for audio purposes

Unless you're oversampling which will give you higher amplitude resolution using fewer AD bits.

Re:Lesson in hearing and sampling

[The+Cookie+Monster]

but a recent Stereophile Magazine article has mentioned...

Steriophiles don't have a clue, but thanks to a slashdotter posting in the SDMI threads, you don't have to take my word for it, you can see for yourself. I've also noticed one reply to your message already pointing out that steriophiles fall over in double blind tests.

The example they gave is along the lines that even an untrained listener is capable of differentiating between someone playing a trumpet down the hall and a recording

The conclusion automatically being that it must be the bit-depth or sample rate that lets us tell, when so many other factors are being ignored - like the sound source is comming from two origins (stereo) rather than one, the volume is not that of real trumpet, the music is continuous like a recording, not stopping, repeating, practicing.

After listening to much stereo equipment I can tell you there is something missing in today's recordings.

While I'm quite open to 44Khz not being enough, and believe that 16bit isn't ideal, I think that is far overshadowed by the fact that (unless it's a solo) you're trying to recreate a 3d sound environment with two speakers - which can never fly unless you start going binaural.

...there are 4 samples per cycle...

I can tell you that your fear here is misplaced, look up Nyquists theorem, every waveform up to 22Khz can be perfectly reproduced from a CD recording (With the exception of some 44Khz noise 90db quieter than the CD's maxmimum volume, and recording mechanisims in practice not being perfect). I know it's non intuitive, but look it up. Yes I can hear the difference between a sine and a square wave, but you have to stop thinking about it that way because you don't connect the dots with straight lines, you fit a wave to the dots.

There is more to audio gear than simply outputing digital samples at two times the upper limit of "audible" sound.

Agreed, but I think you should be looking beyond the storage mechanism, DVD Audio can store sound perfectly with frequencies up to 96Khz at 132db dynamic range. The problem is not the storage format.

Re:No catch; it's consistent with open source phil

[WzDD]

Actually, if BSD hadn't been involved in a licensing war with AT&T at the time, Linus would have used it. He has stated this, unfortunately I don't have a reference. To paraphrase, the comment was "It looked like BSD was going to disappear under pressure from AT&T. If this hadn't been the case I would probably have just used BSD instead".

If you say these sorts of things without knowing what you're talking about then you just sound silly.

Re:Incorrect... (Re:Nyquist theorem)

[Eivind]

Actually, a square wave at Xhz consists of an infinite number of sin waves One of which has the frequency X, and the others having frequencies 3X 5X 7X and so on.

If you've got a graphical calculator, or gnuplot, ask it to plot:

sin(x) - sin(3x)/3 + sin(5x)/5 - sin(7x)/7 + sin(9x)/9

With these first 5 you get a pretty good representation of the square wave, but perfect it can never be, for that you'd need an infinite number of terms.

Notice however that the 5th part here has the frequenzy 9x, so if you want your system to be able to represent it, it follows that X must be smaller than 1/9th of the highest frequency your equipment can handle.

People can hear frequencies up to something in the 20Khz range, that means they can hear the components of a signal whose frequencies are lower than that.

So yeas, to represent a square wave at 22Khz fairly well you'd need to sample at atleast 100Khz, preferably 200Khz. But if the purpose is to play music for human ears then it simply /does not matter/. Because the human ear will only hear those components whose frequencies are less than 20-something Khz.

Most "audiophiles" are idiots. Fed by marketing hype from companies who're happy to feed idiots expensive equipment that serves no purpose. For instance most audiophiles do not understand what the term "digital" means. One of the things it means is that /any/ pickup-mechanism that reads a 1 as a 1 and a 0 as a 0 is equally good. It's entirely pointless spending money on more expensive and "better" cables and pickup-assemblies to read and transmit the ones and zeroes. As long as every 0 stays a zero and every 1 stays a 1, it makes No difference at all

Re:Nyquist rate, yeah, but...

[Chris+Johnson]

No- actually it cannot get the _corners_ of the square wave but it can get the vertical part substantially more vertical than DVD audio. The rate of voltage change will keep on accelerating right until it has to reverse the rate of change and stop. DVD audio will stop at 48K. Frequency-wise this is not much of an issue but if you think about the amount of transient voltage involved with the sides of the squarewave (which demands, in theory, INFINITE voltage), there's a huge difference here. The Sony system will pack a huge amount more voltage into the sides of the squarewave- how much more I'm not sure but it could be several orders of magnitude more voltage. There's some risk of ringing that follows the edges- but when was the last time you looked at squarewaves produced by CD players? >:)

Re:Incorrect... (Re:Nyquist theorem)

[Scott+Ransom]

Sorry, nathanh. Almost all of what you have said has been very accurate. But your aliasing calculation isn't: aliased freqs appear at the _sampling_ rate minus the freq in question, not at the frequency minus the Nyquist as you claim.

Therefore the original poster was correct about his 24kHz signal. It will appear at 44.1k-24k=21kHz.

Re:Sorry.

[gargle]

I was trying to figure out what you were talking about when I saw another post you wrote and realised that you didn't have a clue about signal processing...

Better transducers would be better

[Zigurd]

The actual criterion to measure music reproduction against is not the theoretical best reproduction of the recording. What does that mean, anyway? You want to hear what was going on in a modern recording studio? No, you want to hear music. Music is dynamics, both large-scale, as in how loud is loud, and how soft is soft, and small-scale, as in reproducing the "attack" in a single note. All this talk of frequencies beyond the range of normally measurable human hearing has a slight effect on this at best.

CDs are great becuase they removed a transducer from one end of the playback process: no need for a needle or a tape head. Now you get the signal, and, most importantly, the dynamics of the signal nearly perfectly. Now you need speakers that can take this dynamic range to your ears.

Most speakers, especially most small speakers, fail to do this. They may be "accurate" in terms of response to the range of frequencies put through them, But that won't reproduce the performance, which is in the dynamics. You can A/B test them endlessly against each other, and find interesting and subtle differences, but here is the real test: Take a pianist and a real concert grand piano, and some recordings of a piano, and see if the speakers you think are perfect can fool you into thinking they are the piano. Usually, there is no contest. Any idiot half deaf from a thrash metal concert could tell the difference, because the piano puts so much energy into the air that very few loudspeakers can come close. The piano shakes the floor, makes the windows rattle, and you can feel it in your bones. By contrast, even really good speakers make it sound as if the lid is shut and there is a pile of coats on top of the paino. There is no way a small speaker can do what a piano, cello, bass fiddle, tympani, baritone horn, etc. can do. Put them in a concert hall together, and you have a real challenge.

I would much rather have a pair of Klipschorns (if I only had a room with corners) than a pair of similarly priced near-audiophile conventional speakers even though the K-horns would no doubt be hideously less linear. They would be efficient enough to come close to reproducing the dynamics of real musical instruments. The fact is, no two pianos have the same response up and down the scale, nor the same resonances either, nor do two rooms, so why worry about getting close to absolute linearity? The same argument holds even more as music gets more complex: An orchestra can be close miced, or not, recorded in long takes, or cut and pasted from small snippets, multitracked or not, etc. All those engineering decisions make absolute reproduction a joke. Reproduction of what? I'd rather hear how hard those bows are coming down on those strings. That is where the information is.

Re:What's with Sony's fetish for making new format

[K8Fan]

Sony will introduce one format, and Panasonic will introduce another. Sony has their "Memory Stick", so Panasonic introduced "SD Memory". DVD-RAM, DVD-RW, DVD+RW, etc.

They are not doing it to actually innovate, but to make money from licencing the technology. CD is an old enough technology that the patents are either due to expire, or have already expired. So they have to introduce some new patented technology so they can keep that revenue stream going. Remember that they have introduced several stupid formats (anyone remember the El-cassette? Philips' DCC?) for every one that succeeds.

If they goal was simply to make better audio available, they would be releasing regular DVDs without video tracks. 5.1 24-bit 96khz. No, instead they want you to buy a whole new machine that essentially does they same thing, except is broken by disabling the digital output! Seriously, both DVD-Audio and SuperAudio CD do not have any way to output anything other than multiple analog audio channels. Mega-stupid. Their fear of people copying their tracks has rendered both formats worthless. The worst thing to happen to Sony was when they purhased Columbia.

Re:Nyquist rate, yeah, but...

[daknapp]

No- actually it cannot get the _corners_ of the square wave but it can get the vertical part substantially more vertical than DVD audio.

You're right that the described format has a much higher frequency response; that response does not have a sharp falloff, as one would see in a PCM-encoding format, but the frequency response becomes less and less accurate for higher frequencies.

The problem with a 1-bit stream is the accuracy, not the frequency response. For a given signal amplitude, the accuracy of a 1-bit stream goes like the square root of the number of samples. So to get a 1% accuracy, the player needs to read 10,000 samples. At a sampling rate of 2.82 MHz, that takes about 3 ms!

So there is a tradeoff -- you gain frequency response at the expense of signal accuracy. In CD audio, you have 16 bits, or an accuracy of about 1 in 64,000, but in this new format, the relative amplitude of the waveform is only good to about 2% averaged over a millisecond.

Re:Incorrect... (Re:Nyquist theorem)

[nathanh]

Sorry, yes. The previous poster wrote "22050 + 150 = 24000". I was pointing out that "22050 + 1950 = 24000". I should have completed the entire line of reasoning rather than just point out the mistake.

Re:Incorrect... (Re:Nyquist theorem)

[jareds]

I find your comment "Most audiophiles are full of shit" offensive--I know several audiophiles and none of them are full of shit. Some are musicians, some are electrical engineers. All of them have highly trained ears.

Can audiophiles make these distinctions in double-blind tests? I assume they can't, or people wouldn't be so condescending towards them all the time. Feel free to correct me if I'm wrong.

Re:And yet people can hear the difference...

[gini_]

Problem is that these supposed differences cannot be verified with appropriate tests which makes them quite useless. People who claim to hear differences between amplifiers and cd-players are not wery keen to do blind tests or anything.

Re:*ahem*

[Dahan]

And just to show you that it even works with a 918Hz sine wave, I've made another picture. Reconstructing the samples gives you a stepped sine wave... yes, it has harmonics in it, but none of them are under 22050Hz. Filtering 'em out once again gives you a nice clean sine wave.

Re:Incorrect... (Re:Nyquist theorem)

[pod]

Purchasing high quality speakers and not using high quality speaker wire nullifies your investment in high quality speakers.

Of course it does... it makes the noise comine out of the cables sound way better!

So the big question

[pod]

Given the several huge threads above arguing about what Nyquist theorem really is and means, and given that Timothy never explained what it was or provided a link to an explanation, do you think he used the term correctly in context of the linked article? Do you think _he_ knows what it is?

Re:It's subliminal

[QuasEye]

Course, it doesn't hurt that those are both good, complex, pieces of art that stand up to years of repeated listening. I've got a copy of Abbey Road in my car that's a dub onto normal tape from another tape made from a well worn vinyl record. It's been there for about 7 years now, and I still listen to it every so often. Your argument is interesting, but I really believe that content is the most important thing.

"If I removed everything here that I thought was pointless, there would be like two messages here."

Re:Please! Most people think (cough) MP3s sound fi

[Frizzle+Fry]

cd's will be replaced to "force everyone to buy the new players and buy yet another copy of Billy Joel's Greatest Hits to go with the LP, cassette and CD they already have." I doubt that. After all, won't the dvd players that play audio dvd's also play cd's? If I was buying one, that is certainly a feature I would require, and the same must be true of a lot of other people.

Care about freedom?

Re:Yet another psuedo-standard (minidiscs bite)

[King+of+the+World]

#174

rats! Be gone!

[levendis2]

I think the real advantage of the $1200 SACD player reproducing 100kHz is that I won't have to buy the $49.99 Ultrasonic Rodent Repeller from one of those high-end catalogs.

More Bits, More Bucks, Mo' Betta?

[Nailer]

> More Bits, More Bucks, Mo' Betta?
I believe the particular hip-hop phraseology you're looking for is `Mo Money, Mo Problems'.

Word.

Re:Similar note - 16 bits is all you need.

[Art+Tatum]

I'm not exactly an expert here, but won't a higher bit rate give you better dynamic range?

Sorry.

[Chris+Johnson]

Intermodulation distortion.

Even a signal as solidly within the passband as a 14.7K _sine_ wave will completely fail to be recovered exactly. This wave gets three samples per cycle to capture a symmetrical wave. The only possible result is a pulse wave of 1/3 pulse width- that's what's in the data, there is no other possible result. When you apply a theoretically perfect brick-wall filter to that and perfectly get rid of the sampling artifacts YOU STILL HAVE IRREGULARITIES. Substantial ones, by audio measuring standards- many percent.

If you do a 14.6 sine wave, not only do you get basically a 1/3 width pulse wave, but you get a subcarrier.

Can't you _see_ this?? Doesn't your math acknowledge this? These are not only measurable distortions but the problem is still present even _completely_ in the theoretical realm.

Are you arguing that a 14.7K sine sampled at 44.1K is a symmetrical waveform? Or that a 1/3 width pulse wave at 14.7K with a 22K filter is EXACTLY a sine wave? I would suggest that it is not...

Re:Sorry.

[n+xnezn+juber]

Ok, Chris... I replied to one of your posts and I thought you at least had a clue of what your were talking about. And then I see this post. I'm sorry but you have no understanding of digital signal processing and fourier series. I mean this whole-heartedly that you are missing the fundmental mathematical concepts to understand why a 14.7kHz sine wave can be perfectly reproduced with 44.1kHz sampling and the appropriate filter.

For your education I pulled a couple links from the web:

Site A has two pictures of a sine wave being sampled. This web page is totally wrong. They do not understand aliasing... that picture they are showing with the straight lines shows the reason that you need to have a low-pass filter. With the appropriate low-pass filter, there sine wave in the above picture will be reproduced exactly.

Site B shows the frequency domain. You're probably seen a similiar plot of the horizontal axis being frequency and vertical axis being magnitude. Don't worry about the math if you don't understand it. Just look at the pictures. The top picture shows the sampling period being less than half the period of the highest frequency in the original signal (the bell shaped thing centered at frequency 0. This is like your 14.7kHz sine wave sampled at 44.1kHz. The second is when the period of sampling T equals half the period of the highest frequency (see how the edges of that waveform exactly touch each other?). The bottom picture shows what happens when the sampling period is greater than half the period of the highest frequency. That portion of the bell shaped thing that overlaps one another is sampling noise. In other words everything that is overlapping is lost.

Site C is another site that does not understand nyquist's theorem. They are completely thinking in terms of the time domain instead of the frequency domain. Not to mention that they don't realize you always have to low-pass filter a sampled signal.

Site D actually is correct and should be understandable to even the least mathematically inclined.

Re:Sorry.

[Mike+Monett]

Low-pass filtering will not reconstruct the input sine wave as you believe. I have uploaded a short
SPICE analysis of the first 10us of the waveforms in your first example, (http://euphoria.org/home/help/nyquist.html)

The SPICE analysis is at

http://www.geociti es. com/Athens/Atlantis/1798/misc/294f998d.htm

Turn javascript off to kill the web bug.

As you can see, the output waveform after low-pass filtering resembles more closely the "connect-the-dots" stick figure than it does the sine wave input signal.

Re:Sorry.

[n+xnezn+juber]

Ok, for some reason, /. doesn't like the long URL from Site B so here it is... broken into two lines:
http://www.eeap.aston.ac.uk/
teltec/tutorials/Digital%20Baseband%20Transmission /Slides/nyquist%20theorem.htm

Re:Sorry.

[n+xnezn+juber]

For reference:

Site A
Site B: http://www.eeap.aston.ac.uk/
teltec/tutorials/Digital%20Baseband%20Transmission /Slides/nyquist%20theorem.htm
Site C

Ok, I thought I had already explained the problem with Site A but here it goes...

First see where he says "the sampling rate here is below the Nyquist frequency" with respect to the first picture? He is wrong. Count the samples from left to right. There are seven samples in the first three periods of the sine wave.

Let's say that each vertical line is 1us. The sampling frequency is (1/10^(-6)) 1MHz. The frequency of the sine wave is (3/(7*10^(-6))) 428.571kHz.

Ok now that you realize he has no idea what he's talking about, look at his bottom picture. He actually thinks that the waveform produced after reconstruction is that jagged edged horrid looking thing. That waveform has tons of high frequency components. If he would understand that #1 those samples are not connect the dots. And #2 whatever waveform you reproduce must be low-pass filtered so those jagged edges should never be there. You'll find that the result is exactly the same sine wave you sampled.

Next he explains the waveform he produced as "aliasing" which again he is completely wrong. Aliasing is the result of a signal being sampled at too low a frequency but it has NOTHING to do with his web page. If you look at the corrrected URL for Site B (I added a reply to my post because /. added an extra space because the URL was too long) you can see where the bell-shaped things are overlapping. That is aliasing. Did you actually believe what you read about Site A after my first comment?

Now to Site C! First of all, Nyquists theorem states that the sampling frequency must be greater than the highest frequency in the sample (look it up!). So your argument about the samples being exactly on all the zero-crossings is irrelevant and incorrect.

Now in the actual site, that first picture is misleading because the waveform on the left is not a sinusoid. It is just something he hacked together in a paint program. It doesn't have the right slopes. The waveform on the right does look like a sinusoid. Now where I said this guy was thinking in the time-domain instead of the frequency-domain... when he said "sampling long enough doesn't work for real live video" he is misunderstanding that that even the most complex waveform can be made periodic by simply stating that the period is infinitly long. It's called Fourier Transform (as opposed to Fourier Series). You resultantly get infinite frequencies but if you cutoff, you are getting virtually the exactly same waveform since the high frequency components are so small.

His "good news" section is even worse. He draws pictures of the sampled waveform in two ways. In the middle he connects the dots and makes the same error as Site A. He doesn't low-pass filter the waveform. Oh, maybe I should explain what low-pass filtering is... if you go to Site B, low-pass filtering throws away all those bell shaped things except the one centered at 0, the middle one. If he low-pass filtered the middle or right waveform he would get EXACTLY the same waveform as the one on the left. There was a nother poster somewhere in this thread that actually did exactly what we are talking about by sampling a waveform, reproducing it with "sample-and-hold" and then low-pass filtering. You'll be surprised at the results he got (I was not).

The more samples/cycle means it is easier to reproduce the waveform they originally sampled because it is easier to design a low-pass filter when the (again go to Site B) space between those bell-shaped things is larger.

Re:Sorry.

[n+xnezn+juber]

Ok, here's the short, short version. Both of my previous attempts to reply haven't gone though. Your spice simulation is using something called sample-and-hold (zero-order-hold). You need a very specific magnitude and phase response of the low-pass filter to get the right output waveform. But if you sample using only delta functions, you can use any old simple filter (i.e. butterworth). If you have access to MATLAB, try playing with fft. If you still don't understand the flaws in your simulation, I'll explain further (or even put together a matlab script to demonstrate).

Re:Sorry.

[Mike+Monett]

Site A and C are correct. There is a problem with the url for site B.

Site C shows a nice input/output waveform but does not address the problem of how to achieve it.

Site A and C show you cannot reconstruct a waveform with two samples per cycle. In fact, as one site mentions, if the samples happen to fall on the zero-crossing, the resulting output is zero regardless of the amplitude of the sampled waveform.

Tektronix and Hewlett-Packard use 4 to 5 samples/cycle in their discussions on sampling scopes. The more samples/cycle, the better.

Re:Similar note - 16 bits is all you need.

[nathanh]

You're not wrong here: there are no cheap and commercially available 24-bit dacs, and noones hi-fi comes even close to 24-bit fidelity from source to speaker, but you're missing my point.

Just as in playback where the 44.1kHz signal is oversampled, during recording the signal is often recorded at much higher frequencies. The extra data samples allows you to reduce error and this lets you increase the sample size. It isn't a direct measurement that gives them 24 bits per sample. It's an indirect calculation based on nearby samples with a realistic 20-bit ADC (or whatever studios use these days).

Now it doesn't matter that at no stage will a 24-bit DAC or ADC be used. You get 24-bits of information per sample into a 44.1kHz recording by sampling at a higher frequency. You can use the extra information during playback because your sample interpolation will be more accurate.

It's a matter of information. Increasing the stored sample size increases the amount of info on the disc. More information lets you reproduce the original signal more accurately. Ignore the practicality of the stored info: 24-bit isn't a very practical sample size, but it is more info, and the recording studio will have used clever techniques to ensure that they are using all 24 bits even if they don't have 24 bit ADCs.

Re:Incorrect... (Re:Nyquist theorem)

[SETY]

I'm not an audiophile.
You are/claim to be one.
Question : What would make all the audiophiles happy for frequency ranges of a cd? If the cd had information from say .5Hz to 25,000Hz would that be everything the human body could detetct (ears, bones, etc)? Is there some agreement on this in your community?
I am guessing that it would be difficult to record at that frequency range.

Re:Nyquist really has little to do with it

[glindsey]

Yes, an SACD has a sample rate of 2.82MHz, but that's with one bit per sample (per channel). Yep, that's right---a single bit per sample. In fact, the signal-to-noise ratio on a SACD is very likely negative--there is more noise than signal.

I'm sure I'll lose karma for being so nitpicky, but... if there's more noise than signal, the signal-to-noise ratio will be between 0 and 1. Not negative.

Re:Nyquist rate, yeah, but...

[Chris+Johnson]

Um- to be specific, it should approach perfect accuracy for all audio frequencies- and as it starts to pass a megahertz (I'm guessing as it starts to pass 500 kilohertz) you gradually go beyond 100% distortion, until you have thousands of percent distortion at a couple megahertz :)

It's a lossy format in a peculiar way- this particular method is wildly more accurate at low frequencies than high ones. The thing is, 'high' is relative >;) to this format, 100K is 'low'. The really low frequencies are almost arbitrarily accurate- and again, the ability to delineate high-energy transients is many orders of magnitude better than bandlimited formats. I must admit I am not terribly worried about 10,000% harmonic distortion... at two megahertz. I don't believe I can hear even the most outrageously powerful sound waves at 2 megahertz. Would those be microwaves? Maybe these new players will cook people in front of them if you turn them up loud enough (and have tweeters that can put out loud 2 million hertz signals ;) )

The problem

[Veteran]

The problem with all digital recording methods is the DAC - the digital to analog converter. The real virtue of a higher sampling rate is that it makes the DAC job much easier to do accurately.

CD's do a great job on s/n ratio - they don't do such a great job of accurately reproducing a wave form. There is a clearly audible difference between CD's and Analog records on top quality audio equipment.

Even the best audio equipment does a really poor job of reproducing sounds. The proof is to make a recording in an anechoic chamber of a speakers output and then compare that signal with a synched up input signal on an oscilloscope set up in differential mode. If the two were identical the output would look like a straight line, instead it looks like a bowl of spaghetti; the phase and amplitude distortions are terrible.

I know that there are tests that 'show' that the ear is not sensitive to phase differences, but those tests were badly flawed; the phase distortion of the reproducing equipment was so bad that of course no one could hear differences. One phase distortion sounded just as bad as another. Most of the differences in speaker sounds have to do with the phase response of the speakers.

The ear is basically a Fourier analyzer, and phase does matter when you do Fourier transforms.

Re:General Niftiness :)

[n+xnezn+juber]

You're 100% right. 16 bits is not enough for mastering and mixing. The intermediate values of the mixing must be preserved as accurately as possible to ensure the best possible final result. When the final output is obtained, 16 bits may be enough for listening to. I don't know where your statement about an undigitized output and the 16 bit quantized output is coming from though. I don't think anyone has ever said that the result of 16 bit sampling can exactly reproduce the undigitized output. But are you asserting that the difference is a really big audible difference?

As for the 44.1kHz? If the audio is already sampled at 44.1kHz, you'd better have a serious cutoff at 22kHz or else you're getting alot more distortion at higher frequencies. What exactly are you talking about when you say that amp designers go for pass band into the MHz? If there is any power above 22kHz it is purely noise (that is if the input is a CD, LP is arguable at this point). Now is the higher sampling frequency better? Of course! Just like the 24bit sampling, it makes it easier to reproduce high quanlity recordings.

You seem to be quite an audiophile. I am not. But I wonder, have you ever really tested the validity of your gut feeling about these technologies. I feel that your statements are an amalgam of audiophile "common knowledge" but don't represent the physics and mathematics of sounds and frequency analysis.

Re:And yet people can hear the difference...

[chrischow]

ah you mean audiophile bores who claim their vinyl sounds better than CD... crack crack crack

It's subliminal

[Chris+Johnson]

High fidelity audio _sells_ better. From Dark Side Of The Moon to Led Zeppelin 4, the audio that's been best balanced, most extended in frequency (note: doesn't mean just 'boosted frequency extremes' but genuine extension for a broader passband) and cleanest in the time domain (no ringy EQ crud) has _sold_ better than its competition.

Ever heard of a book called 'The Hidden Persuaders' by Vance Packard? (expose of the advertising industry) This book exposed how advertising people were able to persuade consumers to buy one thing rather than another. With music, the audio quality is the 'hidden persuader'.

Re:It's subliminal

[Doktor+Memory]

From Dark Side Of The Moon to Led Zeppelin 4, the audio that's been best balanced, most extended in frequency (note: doesn't mean just 'boosted frequency extremes' but genuine extension for a broader passband) and cleanest in the time domain (no ringy EQ crud) has _sold_ better than its competition.

Oh, yeah, that explains why Michael Jackson's "Dangerous" outsold Nirvana's "Nevermind" two to one... oh wait, that didn't happen.

Re:What more bit depth really gains you

[Art+Tatum]

I don't see how better bit depth wouldn't get you broader dynamic range.

SACD has been around for quite a while

[porky_pig_jr]

Where you've been living, on a Moon or what? SACD specs have been published a few years ago, SACD players also have been available, for at least a year.

Re:Incorrect... (Re:Nyquist theorem)

[Doktor+Memory]

Question: What would make all the audiophiles happy for frequency ranges of a cd?

Answer: quintuple the price, trace the edges with a green magic marker, slap a bunch of pseudoscientific gibberish on the front and then congratulate them on having a more "well-trained ear" than the rest of those damn hoi-polloi.

The best way to deal with "audiophiles" is to consider them a form of free entertainment, and proof that cocaine isn't god's only way of telling you that you have too much money.

Um, wrong. High-frequency response matters.

[hatless]

Vinyl does sound better than a CD. I'm not talking about the S/N ratio, either. Sure, CDs have better silence than vinyl and they generally don't warp or pop. But because they're higher-resolution than a CD you not only get the very high frequencies that you wouldn't think matter. You also get better reproduction of complex harmonics. This is what all that headroom 100KHz frequency response gets you. And the sampling rate that leads to it allowss for a higher S/N ratio, too.

It must be nice to be unable to hear the difference between a 320k MP3 and a CD on your "$3000 sound system", because I can hear the difference on the $80 speakers connected to my PC and on my $800 "sound system". I'm not exactly an audiophile. CDs are good enough that I almost never buy vinyl anymore, but part of that comes from the added convenience of the CD. It's playable on portables and in a car, it's easier to carry, and so forth.

But every time I put on some vinyl, even if it's technopop or garage rock, the room warms up.

Re:Incorrect... (Re:Nyquist theorem)

[sec]

No, a square wave is a square wave is a square wave. Sine waves operate on entirely different principles. A true sine wave is the result of a trigeometry identity - sine. They are not an "infinite number of sine waves" rolled into one. All you've done here is a nice graphing trick - just like a good way of representing pi is 22/7.

Try this: Take a 22kHz square wave, and run it through a low-pass filter with a cutoff frequency that's slightly higher -- say, 25kHz. Look at the output on an oscilloscope.

What will you see?

You'll see a somewhat distorted sine wave, that's what you'll see.

If a square wave is in fact made up of a bunch of sine waves, it is easy to explain why this happens. The filter has allowed the fundamental frequency to pass, and has attenuated the higher harmonics. The distortion results from the fact that the filter is not perfect, and will allow some of the first few harmonics to pass.

On the other hand, if indeed a squarewave is something entirely different, how do you explain this result?

In other words, you have just denied a theorem which underlies much of modern signal processing and communications. You better have damn good proof of your position!

You are confusing bits/second with sampling rate. To capture and reproduce a sine wave, you need only sample at double the highest frequency. ie, to capture 22khz or lower, you sample at 44khz. This is the Nyquist Criteria, which I believe may have been mentioned earlier in this thread. The formula is somewhat complex to write out here, so please visit these guys for the formula

No, he's right. If you want to get a reasonably accurate digital representation of a squarewave, you need to sample at a higher rate. Why? In order to capture the higher harmonics present in a squarewave, that's why. If you sample at a high enough rate, you will capture several higher harmonics, which will combine in order to approximate a square wave.

Oh, but you don't seem to accept Fourier's theorem. Well, never mind then.

Re:Lesson in hearing and sampling

[The+Cookie+Monster]

A square wave is a sum of sine waves, likewise with a trianglar wave, any fequencies higher than the nyquist limit needed to build the wave would be lost (though the basic shape would still be there if enough harmonics fit under the limit) but this isn't an issue because sound isn't made up of artificial waves like square waves or triangluar waves, it's made out of sine waves.

Guitar strings, vocal chords, wind whistling through trees - none of these are square waves, square waves are an artificial construct that can't even exist as sound - infinite energy would be required. You're making up a scenario that can't happen then pointing to it and saying 'look, can't be encoded'.

Also, nyquists is a bit more powerful than you suggest in your message, not only can you reproduce a sine wave by sampling at twice the frequency of the original, but you can also reproduce all the sine waves (of any frequency lower or equal) that were contained in the arbitrary wave.

I'm not sure what you were saying about CD and DVD but DVD Audio can store frequencies far higher than anything your stereo will ever be able to reproduce, and far far higher than anything mine will ever be able to reproduce, so I'm happy.

SACD is inherently second-rate

[Sara+Chan]

The Audio Engineering Society held it's 109th conference at the end of last month. One of the papers presented at the conference was

"Why Professional 1-Bit Sigma-Delta Conversion is a Bad Idea", Stanley P. Lipshitz and John Vanderkooy, University of Waterloo

This is a mathematical proof that SACD (i.e. 1-bit sigma-delta conversion) is the wrong approach. It is better to stick with standard sampling technology--though with a greater sampling frequency and more bits/sample than used by CDs (i.e. DVD-Audio). Lipshitz and Vanderkooy are well-respected applied mathematicians.

The paper is available as AES preprint #5188, but at a charge. There is a brief write up about it in Stereophile at http://www.stereophile.com/shownews.cgi?860, which also discusses some related issues.

See also comment #211.

Re:A scientific analysis

[Jeff+DeMaagd]

Walmart doesn't have its own house label does it?

While it is silly to spend $5000 on an audio system, if you can't tell the difference between a $30 sound system and a $100 sound system of the same brand, I'd have to ask you to go to an audiologist. If you still stand on that and you are not trolling, I will tell you right now that there are musicians and audiophiles that do hear better than you do. Those people are more likely to pay more for what they like, and their market is not yours.

For one thing, a $30 system is unlikely to have good or deep bass. I'd have concerns about the reliability and how long it lasts... I try to avoid buying landfill fodder.

The problem with ultra high end stuff is that we don't know how many people would be able to pass a "double blind" test and identify which is more accurate.

I imagine the general populace would probly like the cheaper stuff not totally because of price but because it sounds like what they are used to - less expensive stuff with less attention to accuracy paid to it.

Re:Doesn't DVDA have 24-bit sampling?

[Cuthalion]

It's interesting to notice that audiophiles often focus on vinyl's claimed (but untrue) higher recordable frequencies, but neglect the far more important quantisation errors

What's the dynamic range of vinyl?

This is great and everything...

[tomcrooze]

But almost all of you are talking about how great the audio would be with higher resolution. The question now is: "Can speakers that cost less than $5,000 each reproduce this super-high-fidelity sound?"

Re:This is great and everything...

[idomeneo]

Of course they can, you can get very good quality speakers starting at roughly $300 that will sound noticably better when listening to SACD if you have an interest in quality reproduction. Obviouslly the more revealing the system the more noticable the improvement from SACD becomes but even on modest systems the difference will be noticable.

Re:Please! Most people think (cough) MP3s sound fi

[mr3038]

...will tell you that 128Kbps MP3 is "CD quality". Fact is, it's inferior to Minidisc, to FM radio and--in many respects--analog cassettes.

I'm surely happy I don't own "golden ears". I'm happy with 192kbps (or even 128kbps) MP3s. They are not as good as CDs but good enough. And to my ears those sound better than my Sony(R) Minidisc(tm). FM radio is actually pretty good also (I listen it through cable without antenna problems). IMHO any one of these will beat any analog cassette system.
_________________________

Analog components are the limiting factor

[Goonie]

It's been demonstrated again and again that for everything other than absolute audiophile gear (>$5000US systems, >$500 headphones) the limiting factor isn't the signal coming out of the CD player (unless it's a $50 special), it's the quality of the amplifiers, cables, speakers, and particularly the acoustics of the listening environment.

Get yourself a pair of really good speakers and amplifier and *then* worry about the quality of your CD player.

Re:Analog components are the limiting factor

[Spyky]

Get yourself a pair of really good speakers and amplifier and *then* worry about the quality of your CD player.

EXACTLY.

Then again, if you are even *considering* purchasing a $1500 CD player (SACD player) you better have some damn good speakers and an amplifier :-)

Spyky

What more bit depth really gains you

[QuasEye]

OK, so far as I've seen, nobody's mentioned this, so maybe I should.

Bit-depth - what does it gain you? The answer is, less quantization noise. Whenever you sample something, the accuracy of each sample is a function of how many bits you're using. The difference between the real and the sampled signals, although not truly random, looks a lot like white noise. This is quantization noise. White noise has a frequency spectrum that's flat across the board, and is therefore impossible to filter out, and a Bad Thing. 16 bits gets you a signal to noise ratio of like 96 db. Not bad at all for home audio, but for the master tapes, you'll probably want something better. Less quantization noise is all, repeat, all, that more bit depth gains you.

Frequency response, on the other hand, is determined only by sampling rate. If you sample a signal with frequencies higher than half your sampling rate, they get aliased. That means they will be reproduced as frequencies different from what they started out as - generally a bad thing. Reconstruction (in a practical way) will also add artifacts. Filtering can fix this (theoretically) perfectly, but again practicality stops perfection. Higher sampling rates have the advantage of moving these artifacts higher, where they are more easily filtered, as well as less likely to be heard in the first place.

The thing that worries me about this system (SACD)is that it sacrifices bit depth for sampling rate. The sampling rate related artifacts can be filtered. Quantization noise, however, can't be.

"If I removed everything here that I thought was pointless, there would be like two messages here."

Re:Vinyl

[nathanh]

What quantisation? It's an analog media!

Irrelevant. Quantisation is the accuracy to which you can represent an intensity level. Vinyl has a limitation just like any recording medium.

You measure it indirectly with vinyl, using SNR readings from a single sinusoid.

Re:Upgrade media to new format?

[VAXman]

Since you, and four moderators, are confused, I think a refresher course on the licensing of musical recordings is in order.

A recording does not have one but TWO "copyrights": the composition and the recording.

You may have already paid for a 'royalty' for the composition, but you have not paid for the new recording. The new recording is new and you haven't paid for it already.

If you are still confused, a good way to look at this is modern re-issues of recordings which are now out of copyright. Louis Armstrong's Hot Fives & Sevens are an excellent example. If you have access to an recording of these sides, you have the right to issue them on CD (as manhy companies have done); however, you do not have the right to copy a CD of these reissued recordings. This is because the act of transferring from the original shellac recordings to digital media itself is a copyrightable new work. Likewise, the transition from CD to Sony's new format is also a copyrightable work.

Also note that there is no 'license' for a music recording. The existence of an original recording implies a license (unlike software). If you did indeed have the right to buy the new media for the cost of media, this creates new problems. If you sold your old CD to somebody else, do they have the right to listen it? According to your reasoning, no, because you retain the license and they have the media (but not the license). The only way around this problem is to separate the two, but that would be too confusing for most consumers.

Re:Wrong!

[HKelle]

That's incorrect. If the signal is sampled at twice its highest frenquency, the signal can be reconstructed exactly. This assumes that the samples are recorded precisely without quantization, and that the signal is truly bandlimited.

You can reconstruct a signal sampled at the Nyquist rate ONLY by using sinc interpolation functions. These functions do not have compact support (that is they live on the whole real line) and therefore you can never create them and use them. You use something similar, something close but then you can't reconstruct exacly. The "solution"? Sample at a frequency higher than the Nyquist rate.

Good enough is good enough

[nagora]

CD quality is so good that the vast majority of people simply could not care less that there is something better which requires new equipment.

All this talk about hearing ranges of 20Hz to 20KHz is bollocks: look at the results of testing groups of people aged 20+; very few will get outside the 50Hz to 18Khz range. My girlfriend can't hear over 14KHz!

I'm a bit of a music nut in that CD's do bug me, but it's not the frequency range, it's the dynamic range that I'd like to see extended, particularly for the little classical music that I listen to.

TWW

Re:Yet another psuedo-standard (minidiscs bite)

[linuxlad]

I own a minidisc. I love it. I use to record concerts and use music match to then create mp3 out of them. The quality is PERFECT.

Re:You still can't deny the typographical error.

[AFCArchvile]

He spelled "theorem" as "theorum". That is a blatant spelling error. Any offtopic ramblings on your part are just an attempt at karma whoring.

Re:And yet people can hear the difference...

[toh]

Yup, and there are also a lot of people who fool themselves into believing things for scientific reasons. ;) Confusing the model for the real world, for instance.

Basically I think we're just easily fooled.

Re:You still can't deny the typographical error.

[n+xnezn+juber]

Ah yes I see... how very big of you to correct his spelling mistake. The world needs more educated people like you.

Re:You still can't deny the typographical error.

[AFCArchvile]

However relatively unimportant this correction is, the world still needs more proofreaders. Take a look at the text on the sides of Sony products; you're bound to find at least one spelling mistake or technical specification error.

Let's hope it shows people the problems with mp3..

[SpookyFish]

I only hope that this provides a clear, easy way to prove to "the masses" how much better things can sound at high bitrate.

Just like with HDTV, where the networks want to use high bandwidth channels to broadcast 4+ SDTV signals, I constantly fear that something like 128k MP3 will become "a standard" because it is "good enough".

Re:Please! Most people think (cough) MP3s sound fi

[mindstrm]

Yeah.. that works too. Try combining the two! (I mean, a good stereo, AND good dope, not pink floyd & the dead.)

After posting last night, I dug into the subject a bit.

It turns out that many modern CDs are *very* badly mastered, in that they do not use the dynamic range available to them. They maximize everything to the loudest volume in order to get the loudest radio play. So... as a result, many modern stereos are configured (by the users) to listen to everyday pop music... and unfortunately, if something that has real dynamic range to it is used, you'll just miss most of it.

It's not as simple as you seem to be

[Jay+L]

20-20K is a standard spec range, and allows easy comparison from one mic/speaker to the next. That doesn't mean it doesn't reproduce or transduce frequencies above 20KHz, just that they haven't spec'd out its frequency response there.

Better IS Better

[itzdandy]

Most people wont be able to hear a big difference right off the bat, and in fact, humans do not HEAR much out of the range of current CD-audio, but people can feel the difference without registering a sound. That ultra-clear, ultra-high note wont "sound" but it will make other high notes sound better. Just like 3D visuals, you don't see everything they produce, but what you don't see helps to make what you do see all that much better.

Its just a feeling and i support this new format, its may be a little to high end for most, but costs will fall as the format matures

Re:Better IS Better

[Floody]

Everyone knows that a CD sounds distinguishably better than an MP3 encoded from it (though usually not by much if the MP3 is 128-bit encoded).

Right. 128kb-encoded mp3s sound like garbage. I'm amazed that people find them acceptable. The highs are SO washed out and so much clarity is lost, it's almost painful to listen to 'em.

Re:Better IS Better

[Amoeba+Protozoa]

A good example of this at the other end of the audio frequency spectrum is that you really can't hear notes much lower than 45Hz...however you sure can feel them if they are loud enough; anybody who has woke up to a, "ghetto-blaster," boom-b-boom-b-boom driving through the night knows what I mean. It sort of works in the same way for ultra-high frequencies: the various frequencies bounce around in your ear-canal and create far-out physical harmonies.

-AP

Re:Better IS Better

[roju]

You're totally wrong hear. In testing, it has been proven that CD audio sounds distinguisably better than an mp3 of the same track. I don't know a web site to back it, but if you live in Ontario, pick up this week's Fast Forward section.

Re:Better IS Better

[Dahan]

You're totally wrong hear. In testing, it has been proven that CD audio sounds distinguisably better than an mp3 of the same track.

That's nice, I can tell the difference betweena CD and 128kbit mp3 too, but that's not what the discussion is about. Nobody mentioned anything about mp3.

Re:Better IS Better

[DankNinja]

People can secondarily hear some frequency ranges above 20KHz, up to the 100's. It is a resonance effect in the skull that is the main cause.

Re: 22050Hz

[toh]

Ok, I have to respond to at least one of the posts in this vein, so it may as well be this one.

Finally, most people can't hear above 20kHz, especially those people who are incessantly blasting their ears out with loud music.

This is one of a set of often-quoted assumptions - that we know human beings can only hear tones between 20Hz-20kHz, that their ears respond to a dynamic range of 120dB, etc. Now I'd love to think that my social science education and psych degree gives me some deep insight into sensation and perception - indeed, I spent an entire term's class studying nothing but hearing - but how do you think those figures were arrived at? Here's how: a bunch of psychologists thought up the best experimental tests they could, and sat a bunch of young white north americans down in the 1960s. After playing some noxious noisy sine waves and having the poor stressed underpaid psych 100 students press buttons when they could/couldn't hear them, someone wrote up some conclusions. End of story (any apparent bitterness here from a former psych 100 student with ringing ears is entirely coincidental ;).

Now ignoring the usual issues of sample size and between-subject composition, all these many repeated exercises have really proved is the extent of cleverness that have so far been reached in the theory and experimentation of sensation testing. Is a JND a useful measure of anything? Is the representation of sound as additive Fourier sinusoids sufficient to model the way our hearing actually performs? No one really knows, because no one really has all that great an idea yet how the ear and the incredible cortical processing behind it even manages to work at all. When you measure anything in an experimental setting, you are measuring the experiment as much as the subject. You can't do anything about this but be humble in what you assert based on those results - and that means resisting the urge to trumpet how we know humans can't detect a 30kHz sound. In fact they can, without even going into weirder things like how that 30kHz tone might affect the cortical processing of other noises you're listening to at the same time. Pesky humans have shown again and again that the limits on sensation depend on the type of test you use, and we're nowhere near the point where we could make grand pronouncements. We haven't thought up anywhere near enough clever tests yet.

So that's experimentation, now on to theoretical bias (phew). My own feeling is that the current engineering perspectives on sound and signal theory have led us in some interesting and really useful directions, but they've also excluded other directions and other assumptions we ought to be looking at as well. We don't really know how we hear in the real world, and it's folly to think that we can then know how our own mysterious equipment interacts with the innards of a CD player. Even if Nyquist were real-world truth instead of merely a model, brick-wall filters would be fictional. As it is you've got both the theoretical bias and the real-world engineering constraints to deal with. That doesn't mean I don't like CDs, or SACDs, or DVD-audio, but I do recognise that no sound can ever be recreated through a digital representation. They're all merely worthwhile compromises so I can listen to tunes in my living room without having to actually invite Shirley Manson over. Because she always eats all the snacks.

This is just stupid.

[jcr]

There's no way anyone is going to be able to hear the difference between a 64x oversampled stream, and a 16-bit, 44.1 Khz stream in a double-blind test.

That business about needing to preserve 50Khz+ components in their old analog tapes is a CROCK. It's called *noise*, guys. Show me a single human being who claims he can hear up to 50 Khz, and I'll show you a self-deluded idiot.

-jcr

Re:This is just stupid.

[photon317]

I agree with you in principle, but I also argue that reproducing sounds beyond human hearing is a valid pursuit for the following reasons (some more serious than others, but all "valid"):

• Harmonics above human hearing (let's just say above 44khz for argument's sake) still contribute to the human-hearable sound. A multitude of out-of-range harmonics still interefere with the in-range sounds, altering them (cancellation, multiplication) in ways that humans can hear. One might argue that this can occur virtually before encoding at human-hearable levels. This is true if you're encoding with all 3D environmental effect included, designed to be listened to on headphones. If you're playing stereo sound out of speakers, bouncing off of walls, it still matters to reproduce what you can and let it bounce around and interfere.
• Not all listeners are human. Some people have fun getting their dogs to sing along to music, for example. The reasons certain dogs seem to repetitively pick certain songs might just be because of certain frequencies that humans can't hear on the recording.
• Historical Preservation. Someone in the year 2200 might be interested in Musical History, and may use these recordings not only for listening pleasure, but also for scientific study into our recording methods. He might even be trying to construct a then-extinct physical music instrument (say a saxophone) from listening to it's harmonic characteristics in a recording. The beyond-hearing harmoics wuold be excessively valuable to him.
• We may soon (some would say 10 years, some would say 100... who knows) have biologically or electronically altered hearing available to the masses as an "upgrade", allowing us to perceive previously out-of-range frequencies

Don't forget that most artists today record at CD rates (16/44.1) on DAT because they know they're shooting for a CD. Therefore even the master has no better fidelity. If we raise the bar for the CD, we raise the bar for the original as well.

Re:This is just stupid.

[Big+Ol'+Troll]

I will agree that 4 sample points are enough if you are dealing with a sine wave... but what if the original signal is a triangle wave. For both the sine signal I'd mentioned earlier and the triangle wave there are four samples per cycle. If the signal was sampled at peak and zero crossing, how can a DSP tell the difference between these two signals. I'd say it can't.

Re:This is just stupid.

[trauma]

It's not about preserving audible signal, it's about being able to design antialiasing filters that don't chop off audible frequencies and introduce a lot of group delay/phase problems in order to eliminate all frequencies above 1/2 the sampling rate. Higher sampling rate = maneuvering room.

The marketing folks, however, think the general public would rather hear about preserving those ultra-cool bitchen super high frequencies. And they are right.

Re:This is just stupid.

[h4x0r-3l337]

Actually, Tesla apparently did some experiments with extremely loud ultrasound, and found that humans can in fact hear way beyond 20kHz, as long as the signal is strong enough.

Re:This is just stupid.

[Big+Ol'+Troll]

There is a way when you are talking discrete samples. What do you think a 11.025 KHz sine wave looks like when sampled at 44.1Khz. I'll give you a hint, each cycle has four samples. With this number of samples it is possible to miss the peaks and the waveform is not sinusoidal. Can you hear the difference between a sine, triangle, and square wave? I think most people can.

Someone correct me if I'm wrong, but don't most CD players upsample to smooth out the decoded signal? This is why some people spend a lot of money single disc CD player. (This is not me!!!) Your player has to make some kind of a guess at what the original signal looked like and reproduce it. Sony is removing some of the guesswork. From what I've read, SACD beats the pants off of all but the best CD players. But then again, Sony's original CD player is said to be a piece of garbage, so let's see what happens.

I'm pretty optimistic about what is possible. Unfortunately, I'm pessimistic about people's willingness to change. Most people buy there audio equipment based on features like does it have a cool looking remote or can I do some weird DSP stuff (which only is tried once or twice.) The average consumer has been brainwashed to think CD's are the greatest and the best that audio can be.

Re:Someone who can't bear 96khz

[plunge]

Maybe he just has sand in his ears. Somehow, I think this post sounds more coherent on a first read than it actually is on close analysis.

Re:No catch; it's consistent with open source phil

[jms]

The encouraging thing about this article is that Sony is actually spending money to preserve their audio tape library, as opposed to the motion picture industry, which deliberately destroyed their silent movie archives, allowed their nitrate archives to molder to dust, and sat by as their Eastman color libraries faded away.

Re:Yet another psuedo-standard (minidiscs bite)

[Enigma2175]

Yes, they provide digital outputs on full size units, but that is not what I want. If I wanted to lug the full size deck around, I might as well just take a computer and get full PCM audio rather than the compressed audio that a minidisc offers. You say "The portable ones don't - the reason being fairly obvious (why would you need a digital output for a walkman-type application ?)." I explained the real world reason in my post above. I don't want to lug around a full-size deck, I wanted something that was ultra portable. Before I got the MD I would lug a laptop to the show and record with it. It was good (I could get more than 2 tracks as well), but I didn't like having to deal with the extra crap. I got the MD for convienence, but I am disappointed with the output options.
When you say This is nothing to do with the question of software piracy you're right, because software is not involved, but it is very much a question of music piracy. There are certainly a number of reasons to have digital outputs on a portable player, but there are few reasons not to include them. There is also the SCMS to deal with. A little quote from a MD FAQ:
SCMS stands for "Serial Copy Management System" and is the way copies of digital music are regulated in the consumer market. It is information that is added to the stream of data that contains the music when one makes a digital copy (a "clone"). When making an analog copy only the music is transferred so there is no SCMS, and copying is totally unrestricted.
Now, this is not hard to get around, and "professional" decks allow you to manipulate this feature, but not all struggling bands can afford to spend thousands of dollars on a minidisc deck to do a little recording. I have no intention of copying pre-recorded MDs, so the SCMS does not really affect me, but I included the info to make the point that the industry is VERY concerned about piracy and are doing everything they can to stop it, including not allowing digital output from portable recorders.

Enigma .sigless


Enigma

Re:Doesn't DVDA have 24-bit sampling?

[svirre]

16 bit sampling is likely also above and beyond what's detectable error by human ears. (When properly dithered that is, but that goes for any other resolution as well)

At 16 bit you got 96 dB dynamic range which for a normal room means you must have peak levels at 126 (ish) dBspl, (which translates to immidiate loss of hearing). to raise the lsb above the noise floor.

The human hearing got a dynamic range at about 40dB (But has a slowly adjustable bias).

Re:What's with Sony's fetish for making new format

[bigdavex]

If they goal was simply to make better audio available, they would be releasing regular DVDs without video tracks. 5.1 24-bit 96khz. No, instead they want you to buy a whole new machine that essentially does they same thing, except is broken by disabling the digital output!

I totally agree with your point here. DVD-Audio will be a tough sell.

In the tradition of geekdom and Usenet, I will point out a minor problem with your numbers:
(24 bits)*(96kHz)*(5 channels) = 11.5 Mbits / sec
1x DVD speed delivers only 10 Mbits / sec. Therefore, a 24 bit, 96kHz, 5.1 channel disc wouldn't be legal DVD-Video.

What's with Sony's fetish for making new formats?

[Dr_Bones]

Ok, so, Betamax, Minidiscs, Memory Sticks, SACD. What's the deal with striking out on their own? How many times will they come up with a good format, only to have it ignored? Why do they continue to bother?

Re:Incorrect... (Re:Nyquist theorem)

[kb]

Sorry, but this whole post is like complete BS.

- The Fourier theorem says (and imho proves) that every periodic signal consists of an arbitrary or even infinite number of sine waves. So a square wave actually IS a composition of the base tone and all odd harmonics.

- Typically, when humans grow older, the upper end of their listening range goes from about 20KHz to 12KHz at worst. I know enough 20-year-olds which aren't able to hear a PAL TV's beeping (at 15625Hz) anymore.

- Harmonics aren't sine waves BELOW the base tone, but actually ABOVE them, at 2x, 3x, 4x etc the frequency.

- The nyquist theorem is correct in a certain way, but it's neglecting the fact that from frequencies at samplerate/10 up, there is enough aliasing to severely disturb the signal. Go try sample a 22051Hz sine wave with 44100Hz.

- What's that complete nonsense with 32bit/sec? A CD player reads at 176400bytes/sec (2x44100x16bit). With 16bit resolution, the quantisation error and thus the SNR is at about -96dB. Go look up what "dB" means next time, please.

- it's interesting that you first claim everybody knows what "digital" means and then compare digital signal transmission with your oh-so-cool car stereo. Digital audio signals are transmitted with about 2-3 MBit and can even pass some 10 metres of simple cinch audio cable without any loss. Flipped bits are very improbable and timing jitters are completely neglectable, as they get flattened out by the receiver's internal clock (if the equipment is good, that is). The only situation in which jitters are important is mixing of arbitrary digital audio signals which all have their own clock source - and normally, this does not happen outside studios.

So, better do some research next time or ask the people you refer to all the time before throwing around words and expressions you obviously do not understand.

Thanks,
kb

Re:No catch; it's consistent with open source phil

[g_mcbay]

I don't follow your reasoning. By your definition, pretty much every thing every corporation does is consistent with Open Source philosophy.

Observe: Bill Gates had an itch (getting lots and lots of money), scratched it and produced many valuable products (as well as many other pieces of crap products) as a side-effect.

Re:Incorrect... (Re:Nyquist theorem)

[h4x0r-3l337]

Most of these frequencies would be filtered out prior to any kind of processing (digital or analog).

They are filtered out because the signal is going to be processed with limited equipment. If the equipment were better, the signal would not need to be filtered (as much).

Nyquists theorem is fine if you're dealing with low frequencies or frequencies that are a divisor of the sampling rate, but if you have high frequencies that are not a divisor of the sampling rate (i.e. 44100 for CD), you are going to introduce aliasing distortion. Granted, most of the artefacts are beyond the range of normal hearing, but not all of them. This is where highger sampling rates become useful.

SACD vs DVD-A: Fight!

[Wag]

Can someone please explain what the real differences are (other than the storage medium)between the two formats?

As I understand it, the big selling point of DVD-A is 5.1 surround. Now, I'm all for the higher sampling rates, but I don't really understand where the need is for 5.1 audio. I think most folks are just happy with good sounding 2 channel stereo and don't want to bother with surround speakers and such. So many folks have jumped onto the DVD format already I just don't see DVD-A ever catching on.

What are the selling points for SACD other than the higher sampling rates? They don't seem to be pushing 5.1 surround.

Re:SACD vs DVD-A: Fight!

[fnj]

When stereo was young (and I was fairly young :-), I thought the concept was misguided. I would rather put limited funds into one good audio channel than two mediocre ones. In due course, I came around, of course. I became a bit more well off, electronics got a lot cheaper, and I could not deny that stereo was a richer listening experience.

But I think 5.1 is a bit different. There are many of us without the room and the layout to install a decent 5.1 system at home. All that wiring, not the least! And unless you sit in the one ideal spot within the layout, you are kidding yourself about the effect. And we find ourselves in places (work, travel) where 5.1 is completely impractical. I think 5.1 is a complete waste and I wouldn't even think of investing in it.

Who knows, I may come around again, after the curve :-) But I tend to think not.

Re:SACD vs DVD-A: Fight!

[Yardley]

According to the article, DVD audio has an average sampling frequency of 96 Khz and can go as high as 192 Khz. It uses a 24-bit word length. (Regular CD is 44.1 Khz with 16-bit word length.) On the other hand, Sony Audio CD uses a sampling frequency of 2.82 Mhz (which is 64 times more than regular CD) but only has a 1-bit word length (from my reading of the article). So, the Sony format holds only around 4 times the info of a regular CD.

By my calculations, at the average DVD sampling rate, Sony holds one-quarter more info than DVD audio (D = 0.8 * S). But at the maximum sampling rate of DVD, Sony holds one-third less info than DVD (D = 1.5 * S).

Seeing as the Sony proprietary players cost a couple grand and DVD audio players cost a couple hundred, I'm inclined to go with DVD for my future audio needs and forsake the Sony format.

--

Re:SACD vs DVD-A: Fight!

[Andy+Dodd]

You can hear the difference between 2-channel and 5.1 surround. You can hear a BIG difference.

But you can mathematically prove that you can't hear the difference between 44.1 KHz/16 bits and something "better". (Note, as mentioned before, there are some slight exceptions... The mathematics that say 44.1 KHz is enough assume a perfect low-pass filter with no phase-shifting and an infinite slope dropoff. Using a somewhat higher sampling rate allows you to use a less-perfect LPF.) But above 96 KHz, you need not bother... 96 gives PLENTY of headroom for the filter designers.

So this SACD format is going to die unless Sony pushes it with HEAVY marketing. But DVD-A has more people backing it with cheaper (but better!) equipment.

Re:Incorrect... (Re:Nyquist theorem)

[DeeKayWon]

?

Oversampling pads the signal with zeros between the samples in order to approximate impulse sampling more closely. The result is that less of the noise power falls within the range of the output lowpass filter than with flat-top sampling and the SNR goes up a bit.

Re:Lesson in hearing and sampling

[The+Cookie+Monster]

Problem is that anything other than a sine wave has higher order components

OK, a different way of putting it

There is nothing other than sine waves. Sine waves are the only kind of [sound] wave that are transmitted by the medium (normally air). We don't build sound out of sine waves because it seemed like a good idea at the time, we build sound out of sine waves because that's the only thing sound is made of - not square waves or triangular waves

Next time you're in the bath, try and make a square wave, or a triangular wave (without using sine waves) :)

The only way a near-square wave could exist is as a sum of sines, and the point at which its sine components are no longer audible is the point where you no longer store them.

Likewise, we don't hear square waves or triangluar waves, the do-hickies in our ears oscillate to sine waves, so we only hear the sine compenents of square waves etc.

Nyquists still holds.

Re:And yet people can hear the difference...

[Johnny+Vector]

There are a lot of people in this world who can hear the difference and suggest that the CD format is severely limited in terms of it's frequency range.

Course, they're just fooling themselves. In any careful blind listening test, with decent quality components in working order, under realistic listening conditions, nobody can hear the difference between the source tape and a CD copy, and anybody can hear the difference between source tape and a vinyl copy.

You are free to state that you like the sound of LPs better, but it is undeniable that the reason is that vinyl is changing the sound. I prefer to hear what the producer intended. If he wants to add modulation noise, channel-to-channel phase noise, and high-frequency rolloff, that's his choice. I just don't want the storage medium to add any.

Note: it is possible to hear differences between CD players when listening to low-level digitally-generated test signals with the volume turned way up. But:

1. Those differences disappear when listening to actual recorded music.
2. The differences are in the implementation of the D/A section of the players; the signal recorded on the disc is the same.

compatibility

[Kyobu]

Half the point of SACDs is that they're backwards-compatible, right? Wrong. According to my boss at the record label where I worked over the summer, some of the SACDs we distributed were not backwards-compatible. As far as I know, there's no way to know before you plop the disc in your player whether it'll work on your old-school CD player, either.

Re:compatibility

[DeeKayWon]

Current SACDs aren't backwards compatible. future ones will using two layers: the lower layer will contain the DSD data, and a normal CD player's layer will pass through that to read the CD layer above.

Re:compatibility

[kaphka]

future ones will using two layers: the lower layer will contain the DSD data, and a normal CD player's layer will pass through that to read the CD layer above.

Of course, you can do that with DVDs too. Although I don't know if anyone has attempted it yet.

Beat to the punch

[m0nkeyb0y]

Sorry sony, but DVD-A has already got you beat. If DVD-A disks will play on existing DVD-V players, which are already very well established, then the format will have instant acceptance. Also, the already existing audio CD format and DVD are as much of Compact Disc based media as most people are willing to accept. People are now waiting for something smaller and better. Size is the new frontier to break in terms of consumer entertaiment media. Course, I really can't tell if what I just said made any sense at all cuz I'm kinda drunk now. I'm a college student, what do you want from me.

Re:Beat to the punch

[Detritus]

I thought DVD Audio had been put on hold while they worked on an "improved" copy protection scheme.

Re:Beat to the punch

[Ian+Schmidt]

Actually, DVD Audio discs won't play on existing DVD Video players. DVD-A was slated to use a varient of CSS ("CSS-2") for copy protection, but DeCSS put the kibosh on that. DVD-Audio as now shipping uses a new and supposedly improved encryption scheme (but still nonstandard and closed, so it's probably crackable). Think RIAA's having a fit now that we can make perfect rips of 44.1k/16-bit CDs? Hah! That's nothing :)

Anyway, most DVD-Audio players coming out now are also DVD-Video (thank god), but older DVD-V (and computer DVD-ROM drives) won't be able to read DVD-A discs.

Re:Beat to the punch

[otis+wildflower]

but older DVD-V (and computer DVD-ROM drives) won't be able to read DVD-A discs.

Well, unless Sony ships me a new 200-DVD changer w/DVDA (not the band ;) for free I won't bother with the new format..

btw, if Sony was smart, they'd charge current CD prices for the SACDs and let people have the lower quality MP3 versions for free as come-ons..

Or, they can just keep milking suckas. I guess _that's_ the smarter move. For now.

Your Working Boy,

Re:Beat to the punch

[IntlHarvester]

btw, if Sony was smart, they'd charge current CD prices for the SACDs and let people have the lower quality MP3 versions for free as come-ons..

Bingo -- one of the big marketing imperatives of SACD or DVD-A is to move physical disks "up market", with computer audio formats like MP3 nipping at CD quality levels. (And I know MP3 isn't CD-quality yet, but it's still pretty much in the first or second generation of adoption. As bandwith increases, so will the sample rates, and the quality.)
--

Re:Beat to the punch

[Apotsy]

It's finally out now. I saw a review recently (sorry, can't find the link) of the first DVD-A player. It "only" costs about US$3,000. Not to worry, though. Within a year or two, DVD-A decoding will be one of those "me-too" features that comes on every DVD player. And the sheer number of DVD players being sold will all but guarantee its sucess.

The cool thing about DVD-A is that it has two modes, 5.1 (24 bit, 96 kHz) and 2-channel (24 bit, 192 kHz). In the review I read the author stated that he was worried he wouldn't be able to tell the difference between it and regular CDs, but he was stunned at the increase in quality. I can't wait to hear it myself.

Sure wish I could find that link...

Re:Incorrect... (Re:Nyquist theorem)

[msobkow]

I have an issue with your last paragraph. The problem with vinyl isn't the dynamics, but the flakiness and cost of the setup. Take a Sota Star Saphire turntable with an SME IV arm and a Koetsu Black cartridge. When tweaked and "dialed in" the sound stage, imaging, and sibilance of cymbals and brass puts you "there" in the audience.

Unfortunately, it is only "dialed in" for that side of the album you set it for. As soon as you flip the record or change to another one, you need to tweak the setup process again to get that glorious sound. At 10-20 minutes per setup, you end up spending more time tweaking the setup than listening to music.

Does it sound better than even the latest CD players? You bet! But the front end described above use to run about $10-20,000 CDN (depending how you shopped around), and CDs don't require all the fiddling.

Personally I doubt any human will hear a true difference between a top-quality SACD and ADVD format media. They will probably hear a difference between the quality of the line amps (IC vs discrete), power supplies (seperate digital/analog vs single), and quality of the DACs involved.

Personally I'm going to hold off for a year to see which format takes hold in the market, then do some shopping. Either way, I can't wait to have albums that have snares, cymbals, and brass again instead of sounding like I have cotton in my ears.

Re:What's with Sony's fetish for making new format

[fnj]

You have a valid point. Innovative is good. There are several technically-innovative market-failures for each technically-innovative market-success. Praise the innovators, for they are the ones willing to take chances, and it is through their efforts that improvements are made.

The real question is how Sony can be so economically successful when they have to write off so many of these innovations that flunk the market test.

Re: 22050Hz

[FonkiE]

even if a mic would pick up sound above 22kHz - a special one - there is distortion. the higher the frequencies the more distortion.

but now you can record it :-)

higher bit depth is a positive thing, but then again *who* really hears the difference, even the equipment which plays that is too expensive ...

Re:General Niftiness :)

[habaneroburger]

This is all BS. The most important reason why a lot of professional audio gear uses higher bit depths than 16 bits and higher sampling rates than 44.1/48 kHz is so that the equipment makers can convince people to spend a lot of money upgrading their old equipment to newer and ostensibly better stuff. It may come in useful if you're going to be recording something with a lot of dynamic range, as it will leave you a lot of headroom to handle transients in the music so you can record low without being afraid that the input is going to clip (very ugly in the digital domain), but for the final mix, even 16 bits is overkill.

The whole scam about getting people to buy better equipment applies not just to the makers of pro audio gear, but to folks like Sony trying to convince suckers to shell out big bucks for a "better" CD player. If you're listening to music on a $65,000 pair of Wilson Grand SLAMMs, driven by some Martin-Logan class A amps, all in a specially-designed acoustically perfect listening room, and you're listening to chamber music recorded in an anechoic chamber which Schoeps mics, godlike preamps, and godlike A/D, and your ears are 30 years old or younger and you live and die by what your stereo sounds like, then maybe you can talk to me about 24 bits or 96 kHz sampling rates, but if not all of the above are true, forget it. The existing CD standard is way better than everything else in the audio chain, from performer to listener, for 99.9% of the audio equipment, performers, recording engineers, listeners, and types of music (Britney Spears in 24/96?) in existence.

I'm not just blowin' smoke here. I do mobile audio recording professionally (Earthworks mics, Earthworks pre, Apogee A/D, record straight to stereo DAT -- see my URL), and it's standard practice for me to record things 3-6 dB lower than peak to leave breathing room, and in post-processing, design the sound to use no more than 30-40 dB of dynamic range nearly all the time (as making a recording with more dynamic range than that makes it very difficult to listen to unless you're in a very quiet room over high-end headphones). I'm only using a fraction of what lil' ol' CD is capable of, but anything more would just capture room rumble and people's breathing in that much more detail.

If you believe that current audio is somehow shortchanging you from hearing that ineffable "something" that will make your music sound better, then give up the fake science in Sony's product descriptions, save your money on fancy CD players, and go out and buy some better speakers than those Radio Shacks that your brother Jim gave you when he went off to college.

-----

Re:Wadia is out of business

[Chris+Johnson]

Eh, there's lots of other companies doing that. Wadia was certainly not the only one. You just won't find the products at Radio Shack ;) and I daresay you won't find them cheap even now- I just looked on eBay and the prices I was seeing were $200, $500 and $1500 in US dollars.

Um.

[Chris+Johnson]

Leaving aside the bit depth (I keep trying to explain that it's not about maximum contrast but the quantization inherent in _linear_ reduction of a continuous range to discrete increments)...

What the _hell_ do you think I have for mains, Yamaha NS-10s? The _only_ way to get remotely serious performance is either to spend loads of money or educate yourself extensively and rebuild/custom build _everything_.

There is a hard limit to the low frequency extension available from ported enclosures: that's why my speakers have variovents. There's another hard limit on how much acoustic power you can produce with a given cone size within the linear excursion limits of the voice coil (_not_ the suspension physical limit, but keeping the voice coil within the magnet gap). That's why my speakers run 12/10/8/6.5 drivers in a series/parallel configuration as if they were a guitar speaker cab- all the drivers contribute to the piston area for subsonic content. There's a softer limit to enclosure size- I don't feel like running an active EQ system like the very clever Bag End 'ELF' system, so that's why my cabs are four feet tall, over three feet deep and as much as 15 inches wide. They'd make damn good stage bass cabinets, though they're not really designed for those wattages. That fixes the lowest frequency at... let me put it this way. I own synthesizers. I can _put_ subsonic tones through my full system, and stuff will be falling over. There's a limit to how much acoustic pressure even that much cone area can produce, but it's not giving up at 20hz, that's for damn sure.

The other extreme? Composite drivers using piezo elements to handle the extreme highs. (no, not a whizzer cone with a clunky piezo disc glued onto the back and flopping around in a plastic housing). This type of element is easily capable of extreme frequency content- this is what they use to make ultrasonic devices, piezos. I have inverted aluminum domes on these which are so light and delicate you could damage one by blowing hard at it. To top all this off these are effectively HORN LOADED- not in an extreme fashion but the waveguide is definitely reminiscent of an exponential horn, and that means LOUD. The supersonic acoustic power these can produce is not subtle- it will give you a nasty headache very quickly if there's a lot of supersonic ringiness or grunge in the signal.

I don't know _where_ these people are coming from, but there seems to be an infinite supply. All I can say is- I hope you folks are my competition for sound engineering work, because the more fervently you insist that none of that high endy stuff even matters, the less use you will be at a task like mastering. This stuff is not hypothetical: there is practical application provided you work in the business. Ability to monitor a signal over an audio range substantially beyond 20-20K means better ability to control the sound balance and integrate the various instruments into a coherent whole, never mind that in certain areas like bass there are whole subcultures (car audio!) dedicated to showing off the ability to push this limit (by the same token, electrostatic speaker fans are declaring their interest in pushing the opposite limit).

Indeed I think about bandwidth and- S/N ratio is a rotten way to express this, let's call it _linearity_. However, the system _will_ happily go above 20K- and the linearity is considerably in excess of 16-bit quantization. And so is my digital source- I swear by Alesis 20-bit 48K ADAT. The highs could be better but the linearity is really quite good and I'm not dead certain a full 24 bits is necessary. However, the difference between 20 bit and 16 bit is major- and the difference between 44.1 and 48K is minor but every little bit helps. I was testing some new tweeter design changes on Frank Zappa's "One Size Fits All" album- the Kerry McNab-engineered Zappa albums push the high end _hard_ and the mikes turn a really large amount of the 40% supersonic content of cymbals into voltage. Playing this back with the new tweeter configuration really drove home how much we've lost: that album is very good at reproducing the natural supersonic balance of the sounds it contains, and a CD cannot contain even distorted versions of this acoustic content- the LP tends to distort it but the CD throws it away completely. So, again- 44.1K (really significantly below 22K) isn't enough. 16 bits aren't enough either.

I want something smaller than 5"

[drinkypoo]

The problem with CD for me isn't the quality; It's good enough(tm) for my purposes, which is to rock out in the car, or very occasionally in the comfort of my own home. Ironically, I have only one device in the car which plays CDs (the changer on my Kenwood, which is admittedly all I need) and about nine devices in my home which I own (besides those belonging to my housemate) which will play them.

Anyway, CDs need to get smaller and more reliable. It's too easy to destroy a CD; They break, scratch (on both sides!) and warp if you get them hot enough. A teensy little scratch can, if it's in the right (wrong) place, completely ruin the quality of the recording.

Minidisc obviously isn't the answer; It's a lossy compression (MPEG-based.) But I'd really like something with a form factor similar to minidisc, preferrably with recordable and re-recordable counterparts at varying costs. Really, if minidisc only had somewhat higher quality (granted, it's already better than a mp3 player, at least the small ones) it would be nearly ideal.

I could go for something with more than 80 minutes, too.

Re:What's with Sony's fetish for making new format

[bigdavex]

Yes, but using 2:1 or 2.5:1 lossless compression is so easy, that halves the data rate. I'm not sure what compression Meridian Lossless Compressions achieves, but I'm pretty sure it exceeds 2.5:1.

OK, and MLP is part of the DVD-Audio specification, not the DVD-Video specification. My point is that the DVD-Video specification doesn't allow 24/96 5.1 channel audio. Today's mainstream players won't play it. What's your point?

Re:Wrong(was Re:It's not as simple as you seem to

[Jay+L]

Ah! That's a different argument, then. I'm not arguing about whether reproducing >20KHz is important, as I don't know nearly enough about signal processing. I do know that I can hear a pure 21KHz tone on my monitors (Genelec 1030a), but I realize I'm in the minority there.

I was merely responding to the statement that nothing reproduces above 20KHz. FWIW, here's the reply from Neumann. Looks like they handle the upper frequencies decently, at least on some mics, but just don't bother to spec them. Of course, he's talking about the KM184 (a small-condenser mic, and my next toy, in KM100 form), not the U89i.

(I tried to e-mail this to you but you didn't publish your address.. perhaps you'll see this anyway here.)

---------------------------------

Dear Mr. Levitt,
Along to the standard for microphones (IEC 60268-4) the 'Frequency Range' that you will find within the Technical Data just gives the frequency
'band' within the manufacturer is willing to show or to define any specific values i.e. a frequency graph showing an amplitude response. That does not mean that microphones will not 'hear' signals below of 20 Hz or above 20.000 Hz.

At low frequencies you may extrapolate the frequency response shown in the data. Since it is not easy to measure the low frequency response along the standard exactly you should not trust the figures given by many companies.

Let's have a look into the figure of KM 184 as an example: You will find a low frequency roll off of about 5 dB @ 50 Hz and 12 dB @ 20 Hz. This is the free field frequency response along the o.m. standard. It is to the law of physics. Many companies whould like to make you believe that their microphones would be more flat within this frequency range. TEST IT.

But sorry for going astray: you actually are asking for the high frequency response.
The frequency response above 20.000 Hz depends of the type of microphone. Normally you also may extrapolate the response given if you can realize any specific tendency. For the KM184 again as an example the -3dB point is at 25 kHz. (That means: The use of any steep cut off filter with 20 kHz
boundary frequency would still affect the transient response of the microphone!)

With best regards
Georg Neumann GmbH, Berlin
i.V. Stephan Peus
(Director of Development)

Re:Nyquist really has little to do with it

[mcg1969]

I'm sure I'll lose karma for being so nitpicky, but... if there's more noise than signal, the signal-to-noise ratio will be between 0 and 1. Not negative.

Signal to noise ratios are normally expressed in decibels, which are logarithmic scale. Whenever there is more noise than signal, the SNR will be negative. Indeed, on the non-logarithmic scale it will be between 0 and 1, but nobody ever talks about SNR in that way.

Re:Lesson in hearing and sampling

[Big+Ol'+Troll]

I agree, nyquist does hold. What I'm arguing is that if you have a triangle wave of a certain frequency, the harmonics needed to create that triangle wave are at higher frequencies than the original (a harmonic is F * 2^N where F is frequency and N is a positive harmonic number.) So out 11.025 KHz will have harmonics at 22.05 KHz, 44.1KHz, 88.1KHz, 176.2KHz, and so on. The higher the sampling rate, the more harmonics stored.

Now, whether your ears can tell the difference between an 11.025KHz triangle and sine wave is another difference. There may be something to do with the power level which is easily corrected unless amplitude also matters. But I'm only guessing hear.

Got me there ;)

[Chris+Johnson]

In one sense you got me there: a wave at 14.7K with a 22K filter is exactly a sine wave. I'll retract anything I said about it not being one- I spoke too quick, I was mistaken.

I _will_ note that the wave is phase shifted compared to the original source- in fact when I talk about intermodulation distortion what's happening is that the wave gets phase shifted forward and back very rapidly.

I would _suggest_ that a wave which is phase shifted against other sounds is not the _same_ wave that is sampled. It can be _a_ sine wave but if it's not in the same phase as the source (compared to other music data) is it the same wave?

It's possible that given 4X oversampling Nyquist is as near to correct as necessary. Certainly if you're not concerned with phase but only the presence of frequency components 2X Nyquist is basically right. I draw the line at saying it is theoretically perfect- I'd say it could be a very good approximation. I don't understand why so many people arguing for Nyquist take on a positively religious tone, demanding the acceptance of articles of faith. 'Theoretically perfect' is a very strong statement, and the context (such as 'bandlimited, and ignoring phase and time information completely') needs to be clarified or people take it to mean 'therefore CDs are perfect reproducers of sound': which is not accepted by any competent sound engineer today, since again 'perfect' is a very strong term.

Re:Got me there ;)

[Dahan]

Well, Nyquist's theorem isn't an article of faith if you've seen it and the proof :) While math does have a few axioms that you do have to take on faith, everything else has a proof... no further faith needed :) And only conditions are for the input signal to be bandlimited and the reconstruction filter to be ideal... ignoring phase and time is not part of the requirements. In the theoretical world of math, you can make a filter that has zero phase distortion... only problem is you need to know the signal from -infinity to +infinity, i.e., before the beginning of time to after the universe ends :) All real world filters do introduce some phase shift, which I acknowledged in my post. However, it's possible to design filters that have a pretty much constant group delay--ones that just end up delaying all frequencies of the signal by the same amount.

Signal processing engineers know the importance of phase shifts, know what filters do to the phase, and know how to compensate... I think modems are a pretty good demonstration of that--even old 2400bps modems use something known as Quadrature Amplitude Modulation to encode 4 bits of data in a single "symbol". Both the phase of the signal wrt. the carrier, and its amplitude determine the bits that are being sent across the line. Faster modems do something similar, with fancier signal processing to squeeze more bits in; accurately preserving/determining the phase shift becomes even more important.

CDs definitely aren't perfect reproducers of sound, but what is? Not SACD, not LPs, not DVD-A, not 8 tracks; I wouldn't apply "perfect" to any real world method of sound reproduction... But I'm just trying to combat the misconception that some folks have (including you, I believe :) that the whole theory behind CDs and digital sampling is flawed and introduces serious defects in the sound right off the bat.

Anyways, to get this back on topic, the bottom line for me personally is that CDs are good enough, and I'm not gonna pay a premium for better sound reproduction for frequencies at the edge of my hearing. I can see why Sony wanted this though, and I do think that folks who record/mix/etc... music could use better than CD quality (but don't y'all have that already? I got the impression from other articles here that converting to 16 bit/44.1k for CD was typically the last step in the process, and that intermediate steps were done with more bits and samples).

If it isn't backwards compatible it isn't worth it

[elomire]

That goes for SACD and DVD-A. I have a nice DVD drive in my computer and if neither of them are able to play on it then they won't be purchased. They just aren't that much better. MP3 will reign supreme for me, until another codec can come around that will make music smaller and sound as nice. I don't want to have to keep millions of CDs/DVDs around, that's why I turned to MP3. DVD-A will be a dead duck if it's not compatible with current DVD drives. SACD is just a bad idea, both are really. These people need to focus on .mp3 or a codec like it, that is where the future is.

Re:What's with Sony's fetish for making new format

[fnj]

Not to take away from your other examples, but minidiscs are quite successful in Japan and in some other parts of the world. North America is a very important market, but no longer the only market that counts - not for quite a while now.

As for striking out on their own and not sticking with established standards - er - Microsoft has been rather successful in the market doing the same thing :-)

New media = keep revenue stream??

[misterplow]

I have an eerie feeling about this. Its the same eerie feeling I get when I read about how avidly Sony is promoting its Memory Stick media for various digital media applications.

A recent comment from a Sony spokesperson recently with regard to the Napster, etc. battle struck a not with me. The question that was raised was something like 'are you trying to stop Napster because the activity there is inherently or morally wrong, or are you just looking out for your pocketbook?'.

The spokesperson was very honest and frank (thank you) about Sony's motivation to stop Napster-assisted mp3 trading. To paraphrase, "We will stop at nothing to bring this [illegal music sharing] to an end. We will even reinvent (and market) new media which digital music is stored on in order to guarantee our revenue stream"

While there may be great technical merrits to this new CD format, is this not an obvious case of Sony once again reinventing/marketing 'revolutionary' new media?? Not that I don't like the sound quality of MDs, etc. but I just don't like where this new CD format could go. In other words, could this be a benign first step in order to once again put a deathgrip on SW/HW interaction (and allow access, for a fee, of course).

Love 'em or hate 'em, you gotta give high marks to their business strategists.

Re:New media = keep revenue stream??

[mindstrm]

In short, no. Nothign ends up that way.
Others make MD players. The one thing that kept MD players from saturating the market was price... too expensive at first. More reasonable now, but not flexible enough given the current age. (I have a player, but never use it; I don't like not having direct access to copy my MDs)

HOw can one blame sony for this? Did they *hurt* you by inventing a new technology and then making it expensive? No.. you didn't have it in the first place.

I mean, I hate corporatism (to coin katz) (I can't believe I did that) as much as anyone, but Sony is just not one of the companies that I think of as 'evil'.
I think some of their stuff is too expensive.. but that's their loss.

I'm amazed how so many Americans find the fact that Napster is being sued to outrageous... hell, you Americans sue each other like there's no tomorrow!

What do you mean 'once again reinventing'? How is this bad? So they come out with a new CD format that's proprietary and must be licensed from sony.. how is this going to hurt you?

Re:Please! Most people think (cough) MP3s sound fi

[sheldon]

First off MP3's sound like crap...

As far as how to sell this to the mass market. I think the DVD spec provides a means to really add value to the music disc.

The disc could contain pictures, live video, it could even be recorded in 5 channel.

That's what I suspect we'll see.

It's basically like the CD-Extra format, only better.

Subwoofer candy

[Chris+Johnson]

Actually, one of the neat things about CDs and digital sound in general is that it allows for totally-flat-to-0-hz low frequencies. This is actually a very big deal- stereo equipment tends to develop a sort of thick boomy quality around the low cutoff frequency (not just bass reflex speakers, even amplifiers show this effect a little bit). One of the primary achilles' heels of the LP playback format is that you're at the mercy of the tonearm resonances and cannot even attempt to track anything like fractional hz- if you do, the needle just skips ;) it takes quite unusual design to build tonearms that will be compliant at fractional hz but not flabby wobbly things at say 20-30 hz.

It is _very_ nice that digital allows low frequencies down to 0 hz. I will never knock even CD sound quality for the ability to convey extremely low sounds- the only limitation is the analog stages that drive your stereo. I produce sonograms of my recordings sometimes, and they easily produce frequency information at 9 hz and lower (I refuse to use bass drum sounds that can't be made to have substantial subsonic content :) ). CD can easily encode _substantially_ below 20 hz. There's basically no limit. The format is flat to 0 hz.

Incorrect... (Re:Nyquist theorem)

[Naysayer]

Sounds of up to half the sampling rate can be reproduced *exactly* by (ideal) audio equipment.
This is what the Nyquist theorem says. The thing you are saying about square waves is a misunderstanding on your part.

The frequencies we are talking about are all sine waves. So the shape to be reconstructed is predetermined and known clearly. There is no "interpolation". You may be familiar with the Fourier transform, which takes advantage of the fact that all sounds can be represented as compositions of sine waves.

All that said, I think that the idea of higher fidelity is a good one. Because there are two things that happen on CDs as they stand now:

(1) Companding
(2) Quantization

A brief and kinda-misleading explanation of "companding" is that the bottom hundred or so Hertz of music on a CD is chopped out. This is under the theory that the human ear can't hear this stuff, but lots of people say they can. And even if you can't consciously notice these tones in isolation, it's not much of a step to believe that they contribute to the "richness" of a sound when mixed in.

Quantization is another matter. Say you have 44,100 samples per second stored on a CD. Each of those samples represents the intensity of the sound at each point in time. That intensity is a real number (an analog value) and it's being stored as an integer (a digital value). In mapping from the analog to the digital value, you lose precision (think of rounding a float to an
int). The more bits you have to represent each value, the less distorted the sound is. Think
of the difference between 16-bit truecolor and 24-bit truecolor when viewing photographs and whatnot.

I think added resolution on disc-based music would be really nice. Whether it comes through audio DVD, or a different CD format, though, I don't really care. I think that DVD would be nicer for obvious reasons of storage capacity.

-J.

Re:Incorrect... (Re:Nyquist theorem)

[onyxruby]

Actually, a square wave at Xhz consists of an infinite number of sin waves One of which has the frequency X, and the others having frequencies 3X 5X 7X and so on

No, a square wave is a square wave is a square wave. Sine waves operate on entirely different principles. A true sine wave is the result of a trigeometry identity - sine. They are not an "infinite number of sine waves" rolled into one. All you've done here is a nice graphing trick - just like a good way of representing pi is 22/7.

People can hear frequencies up to something in the 20Khz range...

No, typically only young children can hear into the 20khz range. Most adults aged 21 or older are only capable of hearing to about 18.5 - 19.5Khz.

...that means they can hear the components of a signal whose frequencies are lower than that.

Yes, they're called harmonics, and since the human ear cannot hear beyond about 20khz, it doesn't matter if an instrument has a fundamental frequency higher than that, as the ear is picking up the harmonics at 1/2, 1/4, 1/8th, etc of that original frequency. That is what your equipment needs to be able to reproduce, not the fundamental.

So yeas, to represent a square wave at 22Khz fairly well you'd need to sample at atleast 100Khz, preferably 200Khz.

You are confusing bits/second with sampling rate. To capture and reproduce a sine wave, you need only sample at double the highest frequency. ie, to capture 22khz or lower, you sample at 44khz. This is the Nyquist Criteria, which I believe may have been mentioned earlier in this thread. The formula is somewhat complex to write out here, so please visit these guys for the formula.

Now, I suspect you were talking about the bits/second, so I'd like to get into that for a minute, since this is likely where the large numbers came from. A CD-ROM typically encodes at 32 bits/second, per channel. The thing is, whenever you convert from analog to digital, you do lose a finite amount of information. This is expressed as a "quantization error". It can be up to +/- 0.5 dB between the original signal, and the real signal. The smaller the quantization error, the better the digital signal represents the original (analog) signal. This isn't important to go into, beyond to understand that too low of a bitrate means a greater error rate - the signal will be skewed, even if the sampling rate is sufficiently high.

Most "audiophiles" are idiots.

Most "audiophiles" tend to educate themselves on what all of what I just said means. They know about signal degregation, they know about harmonic distortion, intermodulation distortion, etc. Why? Because that is their hobby - and like any good hobbiest they're going to read up on the issue. This is in sharp contrast to people who merely want something that goes thump-thump to impress their friends. Those people are merely interested in music - but hardly an enthusiast. The number of parallels between car audiophiles and computer geeks is uncanny, having been pigeonholed by others as both, I can safely say this. They take their hobby/craft/profession just as seriously as /.'r that looked for a 300A from the Brazil fab.

For instance most audiophiles do not understand what the term "digital" means.

Excuse me? Everybody who doesn't live under a rock knows what digital means - little ones and zeros, little bits of data. With all the hype about the internet and e-commerce, the idea that someone might NOT have heard the word "digital" in today's world is preposterous.

It's entirely pointless spending money on more expensive and "better" cables and pickup-assemblies to read and transmit the ones and zeroes.

So can I get away with using CAT3 wiring when I need to use CAT5 wiring in my network? This aside, had you any experience in the installation of audio systems, you would know that as soon as it leaves the head (the thing you put the CD in), it is an analog signal. At this point, Shannon's Law takes over and signal strength and attentuation become supremely important. Also, because it is an electrical signal - digital or analog, it is suseptible to interference. I take it you haven't ever competed in IASCA or IDBL then. Let me make a case in point about my own experience with high end car audio.

I have a setup that uses 1000 watts of power, drawing 83.3 amps on 4 ga wire capable of handling 85 amps. First point, cabling is critical to be able to handle your load, from one end to another.

My head unit than takes the signal and puts it out through several pre-outs. This signal is than passed from the head unit to the amplifiers. The amplifiers do their bit and than send the signal to the speakers. At the power levels I am running at (1000 watts), any weak point in the system would invariably become an immediate issue. I had at one point, cheap $45 cables running from the deck to the amplifiers, and the amount of /noise/ in the system was absolutely unacceptable. I /fixed/ the problem after replacing the cabling with much higher quality cabling.

1st, A heavy duty cable makes a world of difference, and can be detected in a heartbeat. Do you think a lowend cable can ever take the place of a quality componenet? Think about it, would you use a cheap cable for your brand new ultra 160 raid 5 array? Are you going to run generic cat 5 for your network backbone? Why on earth do you think that audio issues are going to be any fundamentally different than computer issues. A cable is a cable, and quality makes a difference regardless of the application it used for! A cheap cable is more prone to attenuation and distortion at higher frequencies, regardless of what it is used for.

A better cable provides additional ground, which means much better shielding and allows a signal to go through with less distortion.

Purchasing high quality speakers and not using high quality speaker wire nullifies your investment in high quality speakers.

While I certainly don't dispute there are people who just want something loud that goes thump, these are the people that tend to get put in their place if the actually enter a competition.

Now if you really want to press your point that cabling does not make a difference, let me suggest another slashdot like forum for you. The friendly people over at SoundDomain.com will be more than happy to discuss all those little details with you.

Re:Incorrect... (Re:Nyquist theorem)

[jovlinger]

I love those markers. And then they start talking about jitter and shelling out loads of money for a great transport (read CD-ROM player). I guess it all stems from a basic misunderstanding of the nature of bit-dom, and the fact that a one bit cannot be of better quality than another.

Re:Incorrect... (Re:Nyquist theorem)

[YKnot]

The superstition that certain audiophiles' attitude to audio equipment is based on is crucial in the analogue domain: It is the driving force for ever better equipment which, by lack of objective means to measure quality, would otherwise always produce the feeling of not getting a "good enough sound". Digital absoluteness doesn't allow for superstition. If you don't trust it, you can measure bit-error-rates, calculate signal to noise ratios and generally make objective statements about the quality of the equipment. Until the signal finally leaves the digital world. That's why audiophiles are turned to when it comes to lossy compression: All of a sudden, the drive for (unachievable) perfect signal reproduction is the only hope to get a good enough result, because there is no truly objective way of measuring quality.

Re:Incorrect... (Re:Nyquist theorem)

[YKnot]

The point was that as long as ones end up as ones and zeros end up as zeros on the other side of the cable, there is no need for a better cable. The example of cd-pickups and cabling is excellent. There is absolutely no point in putting a better cable or a better pickup-mechanism into a cd-player if the ordinary one achieves bit-error-rates which are uncritical to the error-correction. C't, a german computer and technology magazine, tested how well audio cds are read by various CD-ROM drives. The drives which were not susceptible to frame jitter read the discs flawlessly, meaning 0 errors. That would not be improved by throwing more money in the form of more expensive cables at it. A perfect result can not be improved. It is this fact which some audiophiles fail to acknowledge because they are so used to their world, where there is no such thing as a perfect result.

Re:Incorrect... (Re:Nyquist theorem)

[h4x0r-3l337]

Sounds of up to half the sampling rate can be reproduced *exactly* by (ideal) audio equipment. This is what the Nyquist theorem says. The thing you are saying about square waves is a misunderstanding on your part.

I think the misunderstanding is on your part. A square wave of 22050 can NOT be reproduced by even the most ideal audio equipment. This is what the original poster (and indeed most other people when talking about practical applications such as CD audio) was talking about. Close to the Nyquist limit you're basically limited to reproducing sinewaves, however there is no quarantee that the original waveform was a sinewave. This is why higher sampling rates (and I mean substantially higher, not lame-ass 96kHz) is important for accurate reproduction of the original signal.

Re:Incorrect... (Re:Nyquist theorem)

[Naysayer]

Okay okay....

When we say "You can reproduce frequencies of up to 22050 Hz", we are talking about sine waves. The "square wave of 22050 Hz" that you are talking about is pretty much irrelevant. A 22050 square wave contains frequencies that are *much* higher than 22kHz. Most of these frequencies would be filtered out prior to any kind of processing (digital or analog).

So in a sense you're confusing the discussion. A square wave, in terms of the signal processing we're talking about, is not a pure "wave" any more than is the sound of someone coughing up a lung. You must first decompose the sound into its component frequencies before you can discuss signal processing and make any sense.

Trying to think in terms of a square wave, at all, puts you in the wrong position to think about this (unless you're talking about the Haar wavelet but that is a different subject entirely).

Re:Incorrect... (Re:Nyquist theorem)

[Woodmeister]

In theory......

Truth is, one of the unfortunate byproducts of digital sampling is something called 'aliasing' of frequencies above fN. Think this: a sound byte is sampled at 44100 Hz. The Nyquist is 22050 Hz. A 21000 Hz sine wave will be reproduced alright, but another 24000 Hz sin wave (22050 + 150 Hz) will show up as 21000 (22050 - 150 Hz) in the digital sample upon playback. So when music is digitized, some fancy low-pass filters are required on the input to prevent this aliasing effect.

Now, one of the problems with filters is that 'perfect' filters are somewhat imposible. Even good low-pass filters which must exhibit near -20dB at fN, roll-off about -3dB at fN-10%.

So the whole point of this is that frequencies near the Nyquist must have already been attenuated or discolorization of frequencies above 12kHz or so will occur.

That's why I swear by good vinyl. A good needle/cartridge and amp can give impressive 30kHz results! Ironically, most people can't really hear this anyway, but most audiophiles will agree it makes for a crisp,full sound that sounds dynamic, as opposed to digital, which sounds cold or flat in comparison. Not that records have the best signal/noise ratio stats ;-)
--

Re:Incorrect... (Re:Nyquist theorem)

[nathanh]

Truth is, one of the unfortunate byproducts of digital sampling is something called 'aliasing' of frequencies above fN. Think this: a sound byte is sampled at 44100 Hz. The Nyquist is 22050 Hz. A 21000 Hz sine wave will be reproduced alright, but another 24000 Hz sin wave (22050 + 150 Hz) will show up as 21000 (22050 - 150 Hz) in the digital sample upon playback.

Wrong. It will alias to 24000 - 22050 = 1950Hz.

So when music is digitized, some fancy low-pass filters are required on the input to prevent this aliasing effect.

This is correct. Low-pass filters are used before sampling to prevent aliasing.

Now, one of the problems with filters is that 'perfect' filters are somewhat imposible. Even good low-pass filters which must exhibit near -20dB at fN, roll-off about -3dB at fN-10%.

Also correct.

So the whole point of this is that frequencies near the Nyquist must have already been attenuated or discolorization of frequencies above 12kHz or so will occur.

And suddenly wrong again. You have a source signal x(t) which is comprised of nothing but sine waves. This is Fourier's discovery. You low-pass the signal at 20kHz. You now only have sine waves with frequencies under 20kHz.

The discolouration occurs only above 20kHz. But, we know that most people can't hear those frequencies anyway, and certainly most people's speakers have trouble doing better than -3dB at anything over 18kHz anyway. So it's hardly any loss at all to throw away the sine waves over 20kHz. You Won't Hear Them Anyway.

That's why I swear by good vinyl. A good needle/cartridge and amp can give impressive 30kHz results! Ironically, most people can't really hear this anyway, but most audiophiles will agree it makes for a crisp,full sound that sounds dynamic, as opposed to digital, which sounds cold or flat in comparison. Not that records have the best signal/noise ratio stats ;-)

Most audiophiles are full of shit. The weight of a physical needle restricts it's dynamics to well under 18kHz and the granularity of vinyl produces a maximum SNR resolution of 70dB. Laser tracking record players on platinum originals I'll wager would be better than CD, but people who prefer vinyl are fooling themselves.

Re:Incorrect... (Re:Nyquist theorem)

[ChadN]

Exactly, this is really all about filtering. Building a nice, zero-phase filter, with good cutoff properties, in the analog domain, is difficult. This was the rational for oversampling and pulse-width modulation, which allows one to use a much simpler filter in the analog domain.

Basically, we can get very fast and precise timing out of crystals, and less precise voltage regulation out of traditional D/A design (well, at least for the mass market). By using a super high sampling frequency, and less bits per sample, one can exploit this asymmetry and get better sound from cheaper (in theory) components.

Re:Incorrect... (Re:Nyquist theorem)

[nathanh]

I think the misunderstanding is on your part.

No, the previous poster is entirely correct.

A square wave of 22050 can NOT be reproduced by even the most ideal audio equipment.

Sure. This is because a square wave at 22050 Hz contains frequencies above 22050 Hz.

A square wave contains a single sine wave at the square wave frequency and many harmonics at integer multiples of that frequency. When you sample a square wave you're actually sampling AN INFINITE number of sine waves. These harmonics are well beyond the ability of your ear to hear.

Now at least some of the harmonics of a square wave will have a frequency higher than half your sampling rate. So if you naively sampled a 22050 Hz square wave at 44100 Hz, of course you would corrupt the signal. This is why a recording studio will low-pass the source before sampling at approximately 22050 Hz. It removes the harmonics you'd never hear anyway.

Close to the Nyquist limit you're basically limited to reproducing sinewaves, however there is no quarantee that the original waveform was a sinewave.

All signals are composed of sine waves. Nyquist says nothing about square waves because a square wave is just a collection of sine waves. The Nyquist theorem lets you reproduce sine waves perfectly up to half the sampling rate. This nonsense about "but I applied a square wave and Nyquist was wrong" is totally stupid. What you've actually done is sampled several sine waves, most of them at frequencies well above half the sampling rate, then found that they got badly aliased.

Saying this is means you're "limited to reproducing sine waves" is just nonsense. There is no other signal except a sine wave. The Nyqust limit is entirely correct.

This is why higher sampling rates (and I mean substantially higher, not lame-ass 96kHz) is important for accurate reproduction of the original signal

For accurate reproduction, yes. But you won't be able to hear that accurate reproduction!

Let's get something straight: when it's said people can hear up to 22kHz tones, that is a sine wave at 22kHz. If you try and listen to a 22kHz square wave then you will ONLY HEAR the first harmonic at 22kHz. All the other harmonics will be beyond your range of hearing.

There is no need to sample higher than 96kHz for audio purposes. There's no real need to sample much higher than 50kHz, despite some of the absolute nonsense that people claim. The standard of sampling at 96kHz is absolute over kill for human ears.

Re:Incorrect... (Re:Nyquist theorem)

[gallir]

If you try and listen to a 22kHz square wave then you will ONLY HEAR the first harmonic at 22kHz.

Furthermore there isn't exist any physical devices able to reproduce square signals. Just physics: mass, inertia, acceleration...

--ricardo

Re:General Niftiness :)

[Johnny+Vector]

Wow. Where to start...

16 bits isn't enough. That's _really_ obvious at this point- no professional works in 16 bits except for the final CD output.

And the reason is... Because real-world signals have a lot more dynamic range than we can fit on the final output. Stick your ear into the bell of a trumpet or 2 inches under a snare drum and tell me how much hearing you have left after an hour. Yet you find microphones there all the time. When recording digitally, it's critical not to exceed the peak amplitude -- digital clipping is obvious and nasty. So you leave plenty of room at the top for extra-loud sounds, and adjust the volume when mixing it down. That means you want more than 16 bits to get 16 bits of resolution in the final product.

even if you mix with ideal noiseless coloration-less electronics

ARGH!! Digital mixing is addition. There's no noise or coloration to be added. If you want to add some, you have to add it on purpose.

44.1K isn't enough either.

Actually, this may be true. Some studies have shown pretty convincingly that a few people can detect the presence of tones close to 30 kHz. Whether such tones exist at detectable levels in actual music isn't clear. But the science does allow the possibility that a 60 or 70 kHz sample rate may be necessary. However...

High end amplifier designers go to great lengths to get their pass-bands up into the megahertz

Utter nonsense. Deliberately extending your passband that high would not only seriously compromise performance at audio frequencies, but it would make your amp incredibly sensitive to RF interference.

The neat thing about the bit rate is that it's effectively infinite bit rate

Not at all. What they describe is delta-sigma modulation, the same thing used in nearly all CD players today. From what I can tell, their scheme is simply a higher bit-rate delta-sigma system with the storage medium containing the 1-bit stream. There is absolutely nothing new about any of this.

There doesn't need to be _any_ brickwall filter on the output

Precisely. And this is in fact the very reason that delta-sigma modulation is used on commercial CD players (and most of the A/D converters used in the industry, as well). Again, the difference here (AFAICT) is that the 1-bit stream is what gets stored, rather than resampling to the 44.1/16 CD standard.

the potential slew rate of this technology is just astronomical

This has absolutely nothing to do with slew rate. Nothing at all. And slew rate has little to do with how loud something sounds. It is true that absurdly powerful amplifiers can sound better than smaller amps with otherwise equal specs. And you almost have it right; the reason is that the peaks require a lot more power than the average, and if you turn up the volume, the smaller amp can't produce the peak power needed for the transients. The result is clipping, which is audible.

However, again this has nothing to do with the storage medium. Remember, modern CDs are almost all recorded and played back using delta-sigma modulation. Sony's plan is to simply skip the current step where the bitstream is reorganized to 16 bits at 44.1 kHz. This allows them to choose a bit rate with a higher dynamic range and cutoff frequency. I leave the arguments about the need for those to other postings.

Wrong(was Re:It's not as simple as you seem to be)

[jbf]

Wrong; look at the specs of a Shure SM58 (50 to 15,000; http://www.shure.com/sm58.html) and the Earthworks T30K (+/-1dB 9-25k; +1/-3dB to 30kHz; http://www.earthwks.com/tc30spec.html)

Also please see Event's PS5 semipro active monitors: off at most 3dB 52Hz-19kHz (http://www.event1.com/product/ps_spec.htm)

It's decidely not true that you look at the flatness from 20-20k as a "standard spec range." People build and optimize for 20-20k because that's what people in the know buy. I'd pay no extra money for +/-1dB 20-50k than I would for +/-1dB 60-20k were I to use a mic as a vocal mic, for example.

I build real systems for real people, who put their money where my mouth is. How about you?

A few links...

[DeeKayWon]

http://www.mpeglabs.com/dvd/dvdaud io/ sacd.htm

http://www.sonymusic.com/sacd/

http://www.superaudio-cd.com/

Something that doesn't gush like a press release

Another more objective link

It appears they're using a dual layer method for backwards compatibility. The details about copy protection methods are vague, but they do mention visible and invisible watermarks aimed against both pirates and counterfeiters. But I can't seem to find a decent explanation of how the encoding DSD encoding scheme works.

Re:And yet people can hear the difference...

[fnj]

Perhaps you would be so good to cite a single controlled, blind, comparative listening test with qualified and impartial supervision.

Until then, such claims are merely unsupported opinion to which the sublimely ignorant holder is perfectly entitled.

Aha, someone who's heard of Wadia ;)

[Chris+Johnson]

Good recommendation :)

There's a good analogy for the dynamic range of CDs. It is computer monitor displays. People who are content with 16 bits in their audio because it covers a range of silent to really loud should _also_ be content to always use 'thousands' of colors on their monitors- because that covers the same range of black to white as 'millions' does.

Of course, people will not be content with this, because 'thousands' produces subtle banding and a perceptible degradation of the picture in ways that are clearly understood. In the same way, 16 bit digital audio produces a thinning and drying of the sonic texture that is the audio equivalent of banding- for the same reason, which is linear dynamic encoding of an analog source that will virtually never be _exactly_ equal to the 16 bit truncation of its resolution.

20 or 24 bit is near as dammit: it's way harder to notice any adverse effects. The Sony format is particularly interesting as it has the potential, sometime in the future, of being handled without recourse to PCM encoding (though, distressingly, it seems that the current incarnations do make use of such a stage- hopefully a really impressive one like 128K cutoff and 32 bit or something equally flash). What that would mean is that there would be no specific bit depth it would be comparable to- saying '8 bit' or '16 bit' or '24 bit' w.r.t PCM is saying 'Here is the maximum signal displacement, from -Xv to Xv. I will now chop the area between into equal parts and quantize whatever the _real_ voltage is to the nearest level I can encode.' In this sense, PCM is never accurate at all- it's very unlikely that at a given moment, the voltage really exactly matches the encoding, because the encoding might be 1.0256 volts and the real voltage was 1.02562854647823862349823474634672348 volts.

Again, it's the same issue as monitor color trueness at 'thousands' of colors. The ironic thing is, with well recorded music the hottest peaks are _really_ hot: 99.9% of a piece of music might be less than half the available dynamic area used for encoding. The encoding is linear, so that is _wasting_ half the bits. A sort of Gaussian distribution might have been a better idea, but it's too late to worry about that now :)

Of course if you make music horrible enough sonically with brutal overcompression, most of it will take up the full dynamic range of the format. It's a pity that this sounds atrocious, as it's the only way to really make use of linear encoding :)

go easy on me...

[Voltage_Gate]

But I want my dog to be able to hear what I can't, and interpret what he hears through the love and companionship that he gives us. That's why I'm getting AC/DC's "Big Balls" as soon as it comes out in this new format. And I vote...

The discussing is diverging.

[mindstrm]

You are both correct.

Re:General Niftiness :)

[phliar]

16 bits isn't enough.

Bullshit!

44.1K isn't enough either.

Bullshite!

If I were to sneak into a recording studio and insert a 20 kHz low-pass filter and inject white noise at -90dB, would anyone notice?

No.

And that's the sort of thing you should think about. Not mythical triangle and square waves (which instruments produce those?) but what's the bandwidth and the S/N ratio of the whole system? From mikes to master tapes to mixers to your home amps and speakers. All this put end-to-end, what is the bandwidth and S/N ratio? That's all. Once you have that, you know what is the lowest sampling frequency you can use, and the lowest resolution you can use.

Hint: the system has a bandwidth of less than 20 kHz and an S/N ratio of less than 70 dB.

*ahem*

[Chris+Johnson]

It's CD AUDIO. You don't get to pick the lowpass frequency. It has to be 22.05K.

I don't understand how you manage to turn the idea of a 14700 sine into a 918.75Hz tone, but so much the worse for you: the 14700 (ironically) does have the second harmonic obliterated by the 22.05K lowpass. When you start talking about 918 hz tones you shoot yourself in the foot- you don't _get_ a 919 hz filter in CD audio, and the modulations are going to still be there. They won't be as nasty as a stepped sampled wave but you've got quite a few harmonics that will remain after lowpass filtering at 22.05K (even the compromised realworld version). Some of the modulation you see _will_ survive this.

It's flatly incredible how many armchair audio theoreticians won't even go as far as you have, insightfully, gone, in seeing that the results of the sampling process are modulated. Phase differences do matter, but even if they did not, the degree of modulation of the sampled wave is mathematically provable unless you get to do a _specific_ lowpass filter on it. If you count obvious changes in phase, the amount of change is provable even when you do ideal lowpass filtering on it.

Yes, math is grand ;)

Re:What SACD is all about and why DVD audio is bet

[Johnny+Vector]

My god, a posting from someone who actually knows what he's talking about! What is /. coming to? Nevertheless...

The Sony SACD skips the decimation and interpolation stage. It stores the noise-shaped bitstream directly on the disc. The beauty of this idea is in its simplicity: it performs much less transformations on the sigma-delta signal and therefore should offer inherently higher fidelity and wider bandwidth.

Just to be clear, the conversion to 44.1/16 doesn't add any noise or distortion, it just places an upper limit on the quality of the final product. Sony's scheme leaves that limit higher than that of CD's. Whether it's better than 96/24 isn't immediately obvious.

If sigma-delta converters were available 20 years ago when the CD was invented they would probably have chosen this method for its simplicity.

You got that right. And note also that delta-sigma converters were understood then, they just weren't feasible with the digital technology available. Also, please, it's "delta-sigma", not "sigma-delta" (see Note 1 in Oversampling for the curious the furious, and the damned). Which by the way is a nice review of oversampling, and I recommend it to nearly everyone else who has posted something in this discussion.

So is DVD-audio is actually better? Your point about tape bias signals gives the edge to SACD, though as you point out it doesn't apply to home listeners, only archivists. And DVD-audio is an existing standard. In which case I suppose it wins by default. As far as audible differences, there aren't going to be any, so that leaves only the lack of surround capability as the difference. Okay, so there you have it. 96 kHz is enough, 24 bits is way more than enough, but 2 channels is not enough. DVD-audio wins.

Re:Please! Most people think (cough) MP3s sound fi

[talonyx]

Well, MP3's sound fine to me. I listen to variable bitrate ones that I rip myself, usually, with max bitrate at around 320.

And I can't tell the difference between that and the CD on my $3000 sound system...

On 128kbps ones, sure. But 192 and higher, most people really _can't_ tell.
The only people who say they can tell are, as far as I see it, aloof audiophiles who are scared shitless that they aren't really getting their money's worth. These are the same people that cling to vinyl and say it's better than a CD.

Sorry, no. Sure, it might theoretically have a higher frequency response, but the human ear can only hear from 20 to 20000 Hz, which requires precisely CD quality sound. CD also allows for a little lower than that for big ol' subs.

So there's no point in going up to 100kHz audible range, because NOBODY EXCEPT MY CAT AND THE NEIGHBOUR'S YAPPING LITTLE DOG are going to get any advantage from it.

And my cat doesn't like Paul van Dyk anyways.

Re:Please! Most people think (cough) MP3s sound fi

[mindstrm]

The reason that people tend to think that mp3 is 'cd quality' is due to two things.

1) The majority of mp3 afficiandos are listening to pop music (or former pop music). To get the effect of this music, a really high quality setup is not required (may times because they have only listened to the CDs on crappy headphones or a mediocre stereo). So to them, the mp3 sounds perhaps slightly different, but not really any worse, and completely listenable. I know the first time I heard Pink Floyd: The Wall on a *nice* stereo (hand built & tuned amp, nice speakers..).. I was amazed. I could not *BELIEVE* what I heard.

2) people use 'cd quality' to mean 'acceptable quality for me to listen to without pops and hisses'. You are entirely correct. They don't mean it's the same quality is a CD recording; they mean they couldn't care if it is or not.

And if any of them really loved symphony... you'd see that difference right away.

HF stats

[Chris+Johnson]

Regarding 'hardly any loss to whom'- it would be more accurate to ask, throwing away >20K is hardly any loss to _what_?

• Human voice sibilance is maybe 6% over 20K.
• A cymbal crash is as much as _40%_ over 20K.
• Keys jingling is _60%_ over 20K.

I (big surprise ;) ) agree with Paul here: I am surprised that people will claim that throwing away more than half the sound information from a sound will be hardly any loss! This is not some piddling little 1% frequency content we're talking about here- plenty of very common sounds both in real life and in music have as much over-20K content as under, and some are _mostly_ over 20K. That's scientifically proven, and an interesting study it was too- thanks to the slashdotter who posted it :)

Somewhat related to the Nyquil theorem?

[Anne+Marie]

The Nyquil theorem states that 72 minutes is as long as any individual can listen to a single cd before experiencing levels of boredom similar to the soporific effects of Nyquil (in the words of Dennis Leary, "Nyquil, Nyquil, Nyquil! We love you! You giant fucking 'Q'"). I fear Sony may have a tough road ahead on marketing extended cds; they're running up against a law of nature on this one.

(note)

[Chris+Johnson]

Note: the harmonic distortion content to the 918.75hz sine wave is not going to be continuous. It is going to be rapidly cyclical as it's the product of interaction with the sampling rate- each harmonic's strength will oscillate between zero and whatever the maximum is (a fraction of a percent?) depending on the phase of the tone relative to the sampling rate. This effect will be considerably more obvious at higher frequencies but will still be present at 918hz. The harmonic distortion is never a continuous amount, but is invariably a rapid cycling between zero and the maximum amount.

What about dynamic range though?

[ironman8250]

If you read the article you'd realize the system is not sampling quantitative values at 2+Mhz... what it does is the same as the switching powersupply in your PC does. It is switching a line-out voltage @2Mhz and then low-pass filtering the result at around 50khz. It is an interesting system. I'm curious why they didn't quote the dynamic range they can acheive..? This *IS* one area sorely lacking in audio recording. 24bit is decent, but 16bit doesn't quite provide enough range for demanding recordings. I'm guessing the bitstream system will yield significantly higher dynamic range.

Good post!

[Chris+Johnson]

Here's an additional point on your side- cables have a quality known as capacitance (also inductance but let's focus on the capacitance). Using a bad cable with your high powered amplifiers and speakers could lead to a situation where the cable is interacting with the tweeters and producing a dip in the impedance in the high frequencies. The result is acutely unpleasant grating highs as the amplifier's presented with a nasty impedance dip, possibly in a range where it's at risk of oscillating.

Cables are _hugely_ important. It's not because of magic- it's because of capacitance, resistance, inductance and the way amplifiers interact with these qualities. You could easily have an amplifier and speaker combination where, with one set of cables, all was well, but with another set the amplifier would oscillate to feedback blowing up the amp! That is about as real as you could ask for. Normal cables are less prone to be _that_ bad, but there's still a great deal of difference in different cables. Again, it's not primarily the cable itself but the way it interacts with the transducer and especially the amplifier.

I think in order to understand this properly, you'd kind of have to have enough technical background to know that speakers' impedance drops sharply at the driver's resonance... without granting some facts like that, it's impossible to even begin to explain to otherwise smart people what's happening. 'But I put a voltage through and it was there on the other side of the wire!' is not evidence that a wire will perform under demanding dynamic conditions- or hooked up to a borderline-unstable amplifier. And competitive high end car audio is very much about borderline-unstable amplifiers due to the very low impedances :) interestingly, stadium sound reinforcement uses similar principles. You might have a stadium-sized PA with an amplifier that puts out one watt... and God knows how many amps, through a speaker network that is 0.00000000001 ohms. The rules change when you start to deal with jobs that big...

Re:Good post!

[n+xnezn+juber]

Just about the only thing you need to worry about with cables is to match impedance. Effects of resistance and capacitance of the cable are the least of your problems if you have a SWR >> 1. With a properly matched cable, impedance within the operating frequency is virtually constant.

Proofreading, damnit!

[AFCArchvile]

"Even if I like the idea of ultra-fidelity, my faith in the Nyquist theorum..."

That's theorem, and don't you forget it!

Re:Proofreading, damnit!

[n+xnezn+juber]

Don't you forget the difference between theorem and theory!

Theory: hypothesis assumed for the sake of argument or investigation b : an unproved assumption : CONJECTURE c : a body of theorems presenting a concise systematic view of a subject

Theorem: an idea accepted or proposed as a demonstrable truth often as a part of a general theory : PROPOSITION

A theorem is PROVEN based on the validity of axioms. Like a+0 = a is an axiom of mathematics. Therefore my theorem of 3+0 = 3 is PROVEN by substituting 3 for a in the axiom... 3+0 = 3 is not a theory.

Again, theorems are proven to hold true if axioms hold true (like a*0=0 or a*1=a). Theories are hypothesis supported by evidence but not proven. Nyquist's Theorem is a Theorem. BTW what is your educational background? Just wondering...

MP3s DO sound fine.

[anonymous+cowerd]

So here's the ugly truth. The MP3 revolution seems to have proven that most people have tin ears...

No, what the MP3 revolution shows is that almost all music fans value the content more than the technical reproduction. In the same way I'd prefer a worn paperback Nabokov to a shiny-new hardbound Stephen King, I'd rather, by a factor of a thousand at least, listen to a scratchy cassette copy of "Tim" on my Walkman than the latest Brittney Spears (sp.?) blasting out through the best stereo system you've ever seen or heard in your life. If you're not a Replacements fan, or if you are, God help you, a B.S. fan, go ahead and substitute in the above sentence the names of your faves ad lib.

Yours WDK - WKiernan@concentric.net

You're my favorite thing!

Waste of technology

[cyrixone]

Most amplifiers and speakers simply cannot handle a wider spectrum than 20Hz to 20kHz. Who cares anyway? Maybe my dog. Don't even get me started about more bits for more dynamic range... I'd like to see a dynamic range COMPRESSOR! Yes, I am SICK AND TIRED of not being able to hear dialog when watching a movie, but when things start blowing up onscreen, the walls shake and the neighbors think we're being bombed. If you're going to get into frequences that go unreproduced, look low... Most people do not have the size woofers required to accurately produce the bass present in most music. :) Remember, Joe sixpack still watches movies on a VHS 2-head VCR connected to his TV via cheap coax from the VCR's RF modulator... the audio comes out of a 3" speaker in the TV. And he thinks he's got it so good. :)

pickin' nits

[anonymous+cowerd]

A square wave of 22050 can NOT be reproduced by even the most ideal audio equipment.

In fact, all the energy in the cosmos can't reproduce any square wave perfectly, because the leading edge of an ideal square wave is perfectly vertical, requiring an infinite acceleration at the speaker cone.

Fussily yours WDK - WKiernan@concentric.net

How do you process 1-bit audio?

[MobyDisk]

Let me ask a question from a coder's standpoint: how do I write code to perform operations on a high-frequency 1-bit sample? I can write code to lowpass, highpass, bass boost, mix, compress... 16-bit audio easily. But what happens when I have to write my .S3M player to do these effects on a 1-bit sample? Even if the format is technically superior, I think it may be too hard for the amateur to work with for it to be useful.

22050Hz

[jbf]

More frequency range isn't going to be recorded, played, or heard by anyone.

First of all, things above 22kHz aren't picked up by ordinary mics... Even the ultra-high-end Neumann U87Ai only claims 20-20kHz frequency response (http://www.neumann.com/mics/u87ai.htm)

Secondly, most speakers won't crank out those high frequencies without a severe falloff in response: the high-end Genelec 1038A triamped monitor gets you 33-20k Hz (-3dB). (http://www.genelec.com/products/1038a/1038a.htm)

Finally, most people can't hear above 20kHz, especially those people who are incessantly blasting their ears out with loud music.

The best reason for Super CD (or DVD or whatever) is higher bit depth, NOT higher sampling rate; going from 16/44.1 (CD quality) to 24/44.1 takes just 50% more space, for nontrivially better quality, while going from 16/44.1 to 16/88.2 brings minimal benefit at a 100% space penalty.

Re: 22050Hz

[bbrantley]

First of all, things above 22kHz aren't picked up by ordinary mics... Even the ultra-high-end Neumann U87Ai only claims 20-20kHz frequency response (http://www.neumann.com/mics/u87ai.htm)

Far from true. The mikes used in this paper, "There's life above 20 KHz!", certainly were capable of this.

Secondly, most speakers won't crank out those high frequencies without a severe falloff in response: the high-end Genelec 1038A triamped monitor gets you 33-20k Hz (-3dB). (http://www.genelec.com/products/1038a/1038a.htm)

Also not true. Unless there is a low-pass filter to prevent sending higher-frequency signal to the tweeters, most amplifiers, speaker wire, and drivers will gladly play sounds upwards of 100KHz. Whether it is necessarily FLAT is another story, as most people don't optimize (or even measure) flatness above 20k.

The best reason for Super CD (or DVD or whatever) is higher bit depth, NOT higher sampling rate; going from 16/44.1 (CD quality) to 24/44.1 takes just 50% more space, for nontrivially better quality, while going from 16/44.1 to 16/88.2 brings minimal benefit at a 100% space penalty.

This is probably true, except that "minimal" may be too harsh a term. Have YOU ever done a careful comparison between a 16/44.1 recording and a 16/88.2 recording? (I have!) On a somewhat-related note, it is remarkably interesting what effect a more accurate clock signal has on the quality of a 44.1KHz recording. The human ear can distinguish playback when the timing of these samples being played back varies by as little as 10^-10 seconds!

The reality is that the human ear's ability to differentiate is remarkably more subtle and complex than the market (and marketeers) would have you believe.

Re: 22050Hz

[mcg1969]

The best reason for Super CD (or DVD or whatever) is higher bit depth, NOT higher sampling rate; going from 16/44.1 (CD quality) to 24/44.1 takes just 50% more space, for nontrivially better quality, while going from 16/44.1 to 16/88.2 brings minimal benefit at a 100% space penalty.

Actually, the SACD is only 2.82Mbps per channel, which is exactly four times the rate of a normal CD. Plus, I think it uses a lossless compression method to achieve about a 2:1 compression rate, brining it down to 1.41Mbps. That's not much of a space penalty.

And frankly, since it's on a DVD-capacity disc, who cares if it takes a bit more space? In fact, an SACD can store a 2-channel AND a 6-channel version of the same 74-minute session that is stored on it's 16bit/44.1kHz CD layer.

Re: 22050Hz

[/dev/kev]

The article says that they want to archive some analog stuff with frequencies "well above" 50kHz. That humans can't hear these frequencies is of diminishing concern when you're archiving, since you just want the best quality analog to digital transition.

I'm not sure how this justifies a 2.82MHz sampling rate, but it does justify sampling rates above 44.1kHz and even 100kHz.

Re: 22050Hz

[jbf]

You're assuming two things: perfect filters and infinite bit depth. As I argued in my previous post, higher bit depth is a Good Thing. Better filters are left as an exercise to the high-end CD player manufacturers.

Wrong!

[gargle]

Nyquist's theorem does not imply, however, that the representation of the maximum [or near maximum] frequencies will be highly accurate as far as the shape of the wave form is concerned.

That's incorrect. If the signal is sampled at twice its highest frenquency, the signal can be reconstructed exactly. This assumes that the samples are recorded precisely without quantization, and that the signal is truly bandlimited.

This is why higher sampling frequencies ARE relevent to higher audio fidelity. Higher bit resolutions are arguable though...

No. Higher sampling frequencies allow you to get away with fewer number of bits per sample, and this usually simplifies the electronics. e.g. With delta sigma modulation, the signal is sampled with 1 bit per sample at a very high sampling rate. The bit sample essentially encodes the change between successive samples., i.e. an increase or decrease, and if the sampling rate is high enough, the original signal can be reconstructed from this information fairly accurately.

Re:Wrong!

[Zoyd]

gargle wrote:
No. Higher sampling frequencies allow you to get away with fewer number of bits per sample, and this usually simplifies the electronics. e.g. With delta sigma modulation, the signal is sampled with 1 bit per sample at a very high sampling rate.

This is what Sharp's new 1-bit digital amplifier does (coincidentally, a piece of equipment that would be necessary to hear the quality of the subject of this /. article).

Most folks here probably haven't heard of 1-bit amplifiers, but almost everyone reading this will own one in 10 years.

Re:Wrong!

[Dahan]

Most folks here probably haven't heard of 1-bit amplifiers, but almost everyone reading this will own one in 10 years.

While I hadn't heard of 1-bit amplifiers, the Sony Discman I bought in 1993 uses 1-bit delta sigma DACs...

Re:What SACD is all about and why DVD audio is bet

[Frankus]

So when will we see megahertz Class D amplifiers that turn the bitstream directly into high power output?

i.e.:

MHz Bitstream -> Big bucks, high power, high frequency power switching -> Low pass filter -> Speakers

Better yet, how 'bout:

MHz Bitstream -> Big bucks, high power, high frequency power switching -> High power, high frequency transducers (piezo?) -> Accoustic LPF

No catch; it's consistent with open source phil.

[Anne+Marie]

Whatever you may think of Sony's conduct in general, this particular product is entirely consistent with the open-source philosophy that we all cherish. From the article:

The company was faced with archiving some 300,000 pre-1960 analog recordings. Unlike fine wine, analog does not age well with time; after about thirty years, recording tape becomes brittle and disintegrates. Preserving these analog masters by creating digital copies is of paramount importance. But the limitations of digital sound proved a hindrance.

Sony had an itch (archiving their own recordings), scratched it, and produced a valuable product as a side-effect. We should support them for it.

CD not good enough?

[Kyd_A]

I was under this impression...

Re:Someone who can't bear 96khz

[Rares+Marian]

Ok so the sig works.

Re:Wrong(was Re:It's not as simple as you seem to

[Jay+L]

The fact that some manufacturers post specs that cast them in a better light (Shure SM-58? Narrow response? Shocking!) or that some go the extra mile to get or measure flatness up to 30KHz (cool!) doesn't mean anything. Have you asked Neumann if their mic actually stops reproducing at 20K?

Re:Wadia is out of business

[idomeneo]

Too bad Wadia just went out of business. You might be able to find some Wadia gear quite cheap though.

DVD-Audio discs will not play in existing players

[idomeneo]

DVD Audio is a new and incompatible format and will not play in existing DVD players. However, the first discs coming from Warner will have a dolby digital layer on the disc along with the DVD-Audio layer that will allow them to play in DVD-Video players. If you do this though you are not listening to DVD-Audio and do not get the increased fidelity. The same applies to SACD, hybrid SACDs have a CD layer and an SACD layer and play just fine in regular CD players. But again when you do this you do not get increased fidelity.

Re:Hybrid SACD discs are backwards compatible

[idomeneo]

Dual layer hybrid SACD discs can be played in regular CD and DVD players with no problem. You do not get improved sound but you can still play the disc. But if you think MP3 is good enough then don't bother with SACD you won't see the benefit. Also have you heard SACD? If not then how can you even begin to judge whether it is or is not that much better?

Upgrade media to new format?

[knarf]

Well, another day, another media format. Of course, the media companies will happily sell me their products. But I already have Radiohead's 'OK Computer' on CD, so I already paid the license fees. I want to 'upgrade' that CD to the format-du-jour, and am willing to pay the production costs and a little something to make it worthwile for the industry to keep on developing new products. I do NOT want to pay royalties again, since I already did. And since I have always been told that those compact discs are so expensive because of the license fees, this upgrade should be quite cheap, am I right? I mean, I only OWN the piece of plastic, which is cheap. It is the license fee which drives up the price (or so 'they' say). So, just let me upgrade my piece of plastic then...

No, unfortunately I am wrong. But I should be right...

Re:Upgrade media to new format?

[Forrestina]

if i had mod points, i'd use em here.

-------

Super CD just isn't the right name....

[ledbetter]

why don't they just call it BetaCD?

Bah..

[adrox]

After Sony's ridiculously restricting and inconvenient software on the memory stick walkman "MP3 players" (although they don't really play MP3s I really don't think I'll be buying into their new music format. I'm sure it'll have some sort of ultra inconvenient copyright restrictions.

Although I have to admit I wouldn't buy a discman from any company. Seems like it's one of the few areas where they still do it right.

Re:Wrong(was Re:It's not as simple as you seem to

[jbf]

Nothing can be flat to 20k and not reproduce 20001Hz (as people have mentioned about brickwall filters) However, if there were a legitimate reason for people (who build real systems, instead of waxing philosophic on manufacturer spec sheets) to capture >20kHz at least to master, don't you think the high-end equipment manufacturers would strive to get flatness out as far as they can?

Someone who can't bear 96khz

[Rares+Marian]

A friend of mine can't bear CDs. They sound like sand in his ears to him. It's not the sample that's important. Music is about change and motion or even lack of it but never about the sample. While Digital records samples like snaphsots people listen to melodies. Or even lack of. Hmm gives me ideas...

Just a simple question...

[HobophobE]

What impact (if any) would result if audio only dvds won out over other standards (like this one)? Will it cause any trouble like regular DVDs have (eg. regional encoding, not able to copy ala DeCSS case)?

-HobophobE

Re:Nyquist rate, yeah, but...

[The+Cookie+Monster]

I doubt very much he was advocating CD Audio

The Nyquist limit for DVD Audio is 96Khz, DVD Audio also has the flexibility of being able to go from 96khz - 192khz (thats a lower bitrate than SACD up to a much higher one) depedending on the quality vs quantity requirements of the media - and you can buy movies on them.

But what does it SOUND like?

[flux4]

I suppose all this technical talk is appropriate for where we are, but before the battle escalates further -- shouldn't some of you actually take a listen? This is not about numbers. Us humans hear in analogue. As a somewhat dramatic friend once said, "specifications... will never tell you how the violin actually sounds." And he was right.

I had the opportunity to listen to the first Sony SACD player to arrive in my province, when it passed through Vancouver on a Canadian tour. While wandering around at a high-end shop I heard this incredible Jazz music; following the sound through a fairly indiscrete door I entered a listening room that's generally off limits, and there it was, playing softly away. There were no salespeople about, so for a good half hour I just played with the thing.

And, how was the music? It was.... right there. Live, transparent. All the good words. I have heard many expensive CD players in the $50 to $100,000 CDN range, coupled with some fairly kick-ass speakers, and this stuff could not compare. I don't even *like* Jazz, and there I was, absolutely enthraled.

One thing -- the speakers I listened to weren't by Sony. For whatever reason, Sony speakers have always been incredibly bad. If you listen to an SACD player, don't even bother if it's paired with their speakers.

At any rate. From Sony's point of view, the SACD format was invented to make digital sound more like vinyl -- brand new virgin vinyl, with none of the nasty drawbacks. CDs cannot compete. Nor can DVD-A, but that's another flame war.

The SACD-1 player has already been given the highest quality rating by every audio magazine I've been able to find. These are ratings that generally go to CD players (or turntables!) worth about 20 times more than the unit is going for.

This format rocks. It will also be compatible with CD players (you can play a hybrid SACD disc on a regular CD player, and you can play CDs on a SACD player... and they sound damn good). As for the price -- a player cost $5000 US last year, so this year's $1200 bodes well. Remember how expensive CD players were when they *first* came out? Anyone?

If you can't go and hear a SACD player any time soon, grab a copy of Stereophile from your library or zine stand -- each issue has good SACD coverage and real reviews. Also, if no one's mentioned this link, here's the Sony SACD Info page.

And yes, you self-titled nerds: the technical whitepaper is there too.

-Joseph

Good ideas

[Fervent]

Personally, I think upping the sample rate is a good idea. I've long heard arguments from audio proponents that 44K was simply not enough to sample high-quality tracks.

Calls to question, however, what will we do about all the CD's already burned at this rate (that is, if the standard gets acknowledged)? Will we be seeing Super CD's in the future with warnings on the back "Due to the fact that this CD was recorded in conventional format, you may experience small pops and scratches that are a known limitation of this original format" (much like they say with CD's created from old records).

Also, does DAT produce any better recordings? Does DAT even sample the same way a CD does?

Single Blind Test Results

[clare-ents]

Ok, I've done a single blind test (i.e. the person recording the results also knew the setup) so this isn't 100% accurate.

I took 5 friends who were interested in audio and all have reasonable high end stereos and worry about cable quality.

I then compared their opinions on a favourite track of theirs, once sent pure, once sent with a 50Hz high pass filter and 0.5dB louder.

The louder test won hands down.

Similar tests showed that the louder signal almost always won, even applying small amounts of compression and EQ almost randomly to the sound.

The reason that high end speaker cable sounds better is that it has a lower impedance and is slightly louder than the cheaper cable.

This is why I believe that most audiophiles understand nothing of what they talk [not to mention the profound belief from one hifi magazine that putting your cd's in the fridge improved the sound quality].

Great! Just what we needed!

[Abwehr]

Oh, joy. Just what the world needs: another multimedia storage format. Another lump of hardware with too little compatible content. Another blizzard of competing user apps to further confuse our multimedia file type associations. Another set of hardware resource conflicts. And for what??? Maybe I'll buy one to keep my 8-track and Beta-Max company.

Re:Lesson in hearing and sampling

[Big+Ol'+Troll]

True, you cannot "hear" anything above 20kHz, but a recent Stereophile Magazine article has mentioned that some of the upper frequencies are somehow sensed. They mention that it is those upper frequencies that add reality to sound. The example they gave is along the lines that even an untrained listener is capable of differentiating between someone playing a trumpet down the hall and a recording. After listening to much stereo equipment I can tell you there is something missing in today's recordings.

Also, think about this for a second. A standard CD has a sample rate of 44.1KHz. If you are playing a 11.025KHz signal, there are 4 samples per cycle. This will hardly matches the appearance of the original signal. There are many waveforms and people are capable of differentiating between saw, sine, and square waves to name a few. On top of that, a single sine wave is seldom played by itself. There are often multiple waves played (different instruments and instruments more complex than a sine wave generator.)

I am one of those people who is not satisfied with typical consumer audio equipment. There is more to audio gear than simply outputing digital samples at two times the upper limit of "audible" sound.

Nyquist really has little to do with it

[mcg1969]

The SACD has a sampling rate of 2.82 MHz. This means that theoretically you could accurately (AD/DA converters and such aside) reproduce the frequencies up to 1.41 MHz (1410000 Hz).

Sorry, SACD is a lot more complex than a simple application of Nyquist can handle. The key to SACD's high fidelity is all in the quantization theory.

Yes, an SACD has a sample rate of 2.82MHz, but that's with one bit per sample (per channel). Yep, that's right---a single bit per sample. In fact, the signal-to-noise ratio on a SACD is very likely negative--there is more noise than signal.

Now before you blow your top with how absurd that sounds, let's clarify one thing: the SACD format jumps through serious technical hoops to insure that the vast majority of that noise is in the completely inaudible range. And, the vast majority of the signal is, of course, within the audible range. The technique is, not surprisingly, called "noise shaping".

So once you limit your measurements to, say, 0-20kHz, you're back to where you would hope: the astronomical dynamic range and signal-to-noise ratio of a high-fidelity audio format. (In fact, SACD is designed to provide ultra-low noise and 120dB of dynamic range all the way out to 100kHz, from what I understand.)

For those of you who remember, or perhaps own, CD players with "1-bit D/A"s, you're using a similar version of this technology. The difference is that the SACD recording process can decide at the mastering stage how to get down to 1 bit per sample, and that's a much better place to make that decision.

Copying W3C's naming scheme?

[yerricde]

DVD-A was slated to use a varient of CSS ("CSS-2") for copy protection

Let's see... W3C releases CSS (Cascading Style Sheets). DVDCCA and MPAA release CSS (Content Scrambling System).

Then W3C releases CSS2, with positioning. DVDCCA and RIAA release their own CSS2.

Trademark dilution? ;-)

Lesson in hearing and sampling

[blakestah]

First, although it is often quoted that people hear sounds up to 20 kHz, they don't. Most people hear up to about 15 kHz. Typical listeners lose 5 dB in threshold between 5 and 10 kHz, and another 10 dB between 10 and 15 kHz. The thresholds are so high around 15 kHz that you cannot ever hear such frequencies with normal sound equipment. For almost any recordings knocking off all frequencies above 12 kHz won't change perception during playback.

Second, almost all speakers drop off severely above 20 kHz. There is no easy way to play such sounds unless you get a speaker designed to keep gophers away (they, like many mammals, hear above 20 kHz).

Third, you cannot reconstruct accurately sound frequencies above 10 kHz with standard CD encoding anyway. 16bit sampling is simply not enough. I've spent some time reverse engineering 20 millisecond sound samples, and I can tell you from experience that with limited sampling bits you are better off doubling the Nyquist. And the Nyquist theorem doesn't guarantee such reconstruction anyway with 16 bit sampling.

SONY is pulling a marketing ploy - redesigning sound recordings to try to give people a little extra - well, I'll tell you what, I'll bring my dog along. At least he has a chance of hearing the differences. Because I sure don't.

Re:Lesson in hearing and sampling

[cot]

The weakest link in the typical reproduction chain is the speakers.

A major reason that you can likely tell the difference between a live trumpet player and a recording, even down the hall, is the failure of the recording process to accurately capture the acoustics at the performance combined with the coloration of the listening environment and the speakers.

Another huge factor with those types of live instruments is dynamic range, something which will be addressed with higher bit depth formats.

Re:Lesson in hearing and sampling

[Peter+H.S.]

I think your are right about, that most people, me included, can't hear much above 15kHz.
But that is not the whole story; the problem as I remember it, is, that the _filtering_ required to cut of the frequencies above eg. 20kHz, may have a large influence, on the sound and frequencies below.
So it should be better to shoot the cut-off point, as far as possible, into the upper spectrum part.

The price qouted; 2500$ for a 1st generation SACD player, isn't bad considering what a 1st gen. Phillips cd-player (Model 102?) costed in the start 80'ies. And those cd-players were clearly inferior, compared to any decent analog record-player. But a lot of people bought them anyway.

Re:Lesson in hearing and sampling

[DeeKayWon]

What probably more important os that there' no scientific evidence that people can hear frequencies above 15-16kHz in the presence of other sounds. That's why so many MP3 encoders lowpass filter at 16kHz when encoding at 128kbps; why include those frequencies if they're below the masking threshold?

Re:No catch; it's consistent with open source phil

[Anne+Marie]

BSD scratched Linus's itch just as well (and without great additional effort) so why didn't he just use that? Because he wanted to try a new approach. Same principle.

And yet people can hear the difference...

[sheldon]

There are a lot of people in this world who can hear the difference and suggest that the CD format is severely limited in terms of it's frequency range.

It's not as simple as you claim.

Re:And yet people can hear the difference...

There are a lot of people who fool themselves into believing certain things for nonscientific reasons.

Duration estimate

[yerricde]

DSD is a single bit recording format

Which is identical to the format the PC Speaker accepts.

CD's are a single bit recording format

No. CDs are sampled at 44.1 KHz, 16 bits per channel.

The big question in my mind is what sort of recording time do they have? The sampling rate is 2.82 MHz

And the data rate is 2.82e6 samples/sec * 1 bit/channel * 2 channels/sample * 1 byte/8 bits = 705 KBytes/sec, which makes (assuming DVD data density of 4.7 GB/side) 1 hour and 51 minutes of play time.

Another product in search of a market

[fm6]

The article seems to be saying that consumer application of this technology is an afterthought. Sony developed this technology so their huge (and expensive) library of recordings wouldn't disappear in a puff of magnetic dust. Having done that, they're now trying to sell it as a consumer technology, on the assumption that people will throw away their CD players and plunk down big bucks for a slight improvement in sound quality. Meanwhile, the coming thing is MP3 -- a format that actually discards information.

You know, Sony seems to have a real problem grasping the concept of standdard formats. Witness the Betamax, 8MM video, and now the Memory Stick. What's really weird/ironic is that they're partnering with Phillips, a company famous for giving away the analog audio cassette patent -- and driving out a lot of competing formats in the process.

The above link is broken because Slashdot insists on munging the following url:
http://www.ieee.org/organizations/history_center/o ral_histories/transcripts/drabek.html

__________

Stereophile magazine? Are you kidding?

[jcr]

Aren't these the same pinheads who had a run-in with Bob Carver a few years ago?

Carver offered to tune the transfer function of one of his M400 amps to match the most expensive frou-frou tube amp the Stereophile morons could muster, and they couldn't tell the difference in a double blind test. After admitting as much in one issue of their magazine, they reneged in the next issue, after they realized that their market is the kind of jackasses who would spend fifty grand on a turntable with a fluid transmission.

That magazine is all about snob appeal, and has nothing whatsoever to do with science.

-jcr
(I've got a set of speaker cables on e-bay, for the very low reserve price of just two grand, each!)

Old recordings...

[joto]

Well, they usually keep a master, so it's not like they typically create CD's from LP's today, but from the master tape (or a direct copy of it).

So in the future, they will not typically create SACD/DVD's from CD's but from the original master. The master is usually recorded in much better format on multitrack recorders.

Actually, it needs to be better, since you have to mix the channels later, to get it down to one stereo-track. But it's probably not very common with 64 times oversampling on master tapes today, so there will always be a difference between new and old recordings...

However, most people will probably not notice it, and so the record companies will not "announce it" either. I can't see the point either.

DAT's can have up to 48kHz sampling frequency, compared to the fixed 44kHz on CD's. This should leave a little bit more room for the very highest frequencies the human ear can hear, but unless your hearing is very good you will never notice. Both DAT's and CD's use 16 bits, so except for the sampling rate they should sound pretty similar.

General Niftiness :)

[Chris+Johnson]

I _hope_ this becomes common technology- there are some extraordinarily important things about it. A little background:

• 16 bits isn't enough. That's _really_ obvious at this point- no professional works in 16 bits except for the final CD output. Mix busses have to be many times that in the digital domain, but even if you mix with ideal noiseless coloration-less electronics there's a really big difference between monitoring an undigitised feed of the signal with monitoring the 16 bit output.
• 44.1K isn't enough either. This is not primarily due to people being able to hear beyond 20K (though you can sense such sounds to some extent- why do you think smashing glass or dropped plates make you jump? Viciously loud supersonic transients), it's due to the brick-wall filters required. High end amplifier designers go to great lengths to get their pass-bands up into the megahertz (and nobody claims humans hear that!) because cutting off lower causes interactions across the entire frequency band. Cutting off at 22K is just ridiculous.

Now, how does the Sony approach compare? The neat thing about the bit rate is that it's effectively infinite bit rate- it's not a finite set of voltage levels but just one bit very fast tracing a voltage level that could be anywhere. This is substantially beyond even 24 bit- a major, major advance. That's gonna be very noticable.

As for frequency, there is a surprise in store here. It may or may not be competitive with advanced PCM encoding at say 96K- but two very, very important points:

• There doesn't need to be _any_ brickwall filter on the output- provided a circuit can be made to output this stuff that doesn't merely calculate it as a super-PCM-encoding and D/A converter. If the format can feed a sort of very high frequency analog synthesiser, no filter is needed- which is critical, because...
• ...the potential slew rate of this technology is just astronomical. I hope the power supply of the players is up to it- if not there will be some very effective power supply mods waiting to be done, such as backing up the power supply with MIT Multicaps (a film cap that can produce very very high instantaneous voltage). Basically, if you fed this technology a big square wave, it might not be able to turn the corners of the wave instantly, but the vertical parts of the wave would be _vertical_- no brick-wall-filtered system can get anywhere close to this.

We're talking absurdly high transient peak voltages here: this is why high end audiophiles use absurdly heavy cables and absurdly powerful amplifiers, to let those peaks through. It doesn't hurt the speakers: this isn't RMS or even 'peak' wattage, the spikes are of such short duration that you can feed speakers many times the maximum 'peak' voltage if it's only for a microsecond, and high end systems do just that.

Where do you find such peaks? Easy- The Who ;) seriously, The Who is a _good_ example, but symphony orchestras are also good for this. The capacity for this type of extreme and essentially 'inaudible' (too brief!) transient translates to the ability to produce the _sensation_ of loudness- for instance, you could easily make many systems play 'Live At Leeds' and sound loud and bright and kind of grating and ear-splitting, but with this technology it would be less grating but more _electrifying_ and the impact would be like having the living people right there playing at you, not just a bunch of very loud sounds. Alternately, you could play big orchestra crescendos and the resulting sound would be _huge_, not just loud but as big as a live performance.

It's really not hard to make stuff sound 'loud', but making it _feel_ loud is something else. If you don't have that, the loudness ends up being just a grating, thin surface, which is actually a very good description of the sound of most pop recordings these days :) the irony is that this technology is coming around just when the recording industry's pushing sounds that are substantially worse than even CD audio can produce...

Bottom line: I want one. Specifically, I want this to _master_ to. I have quite a bit of stuff that loses about 2/3 of its potential when made into 44/16 (eight tracks of 48/20 output analog and mixed with passive resistance mixing will tend to do that- I once figured the rough equivalent resolution was about a 64 bit mix bus, possibly higher) Maybe I should try to wheedle Sony out of a recorder ;)

Doesn't DVDA have 24-bit sampling?

[rakslice]

"Higher resolution is what is actually needed [...]"

Wasn't the DVD Audio standard going to move to 24 bit sampling as well?

Re:Doesn't DVDA have 24-bit sampling?

[nathanh]

Wasn't the DVD Audio standard going to move to 24 bit sampling as well?

Yes, and it is a good thing. 16-bit samples are good but not great. 24-bit samples are getting well past the great and into the "more than we'll ever need" stage.

Smaller samples produce quantisation errors. The noise produced by quantisation errors is difficult to remove. 24-bit samples make these errors basically irrelevant.

It's interesting to notice that audiophiles often focus on vinyl's claimed (but untrue) higher recordable frequencies, but neglect the far more important quantisation errors.

CD has quantisation errors approximately 2 orders of magnitude smaller than vinyl (-26db).

What was the system again...?

[Gorimek]

Maybe I'm tired, but I didn't get how it works. It's 2822 kHz of how many bits? I get the impression that it's just one bit somehow.

So... Can anyone clarify?

Re:Nyquist rate, yeah, but...

[The+Cookie+Monster]

I replied a little hastily before...

The thing about the Nyquist limit is we know DVD Audio can store everything up to 96Khz, this is not the case with Sony's new system.

Look at the differences, Sony's system can store a 2.8Mhz signal, but can only store that signal at the quietest volume it's capable of - so who cares you ask (nobody can hear that high), well, the point is that the higher the frequency, the less volume this system can store it at (right up to that extreme of 2.8Mhz at quietest possible volume). And it can't store a square wave at all (not that we'll have speakers that can accurately reproduce a square wave, tho that would be cool - as a weapon or something).

Basically, yeah, it's got the high frequencies, but with Nyquists limit on a DVD we know we get everything. This system relies on it's failings being to subtle for us to notice.

Re:What's with Sony's fetish for making new format

[SpookyFish]

My theory on this: Sony's expense to promote new technologies is relatively minimal compared to many companies. They are the electronics industry equivalent to an Intel or Microsoft, in that they have a strong current user base, incredible distribution network, and an established technology base. Fortunately, they don't have the same ability to "dictate" what people use.

This makes it a cost-efficient thing to push a system that, in a best-case scenario "wins" and in a worst-case scenario establishes a following that leads to further purchases by happy users. It also leads them to develop many technologies and processes that *will* be used someday, even if it is adapted to fit someone else's form factor.

Sure this strategy makes them $$$$, but makes good sense in other ways. Their researchers are able to develop something "their way" without having to fight with standards committies and delay after delay as specs get hammered out, and that keeps those people happy & pushing the envelope.

---
my .02 and worth less

Re:Let's hope it shows people the problems with mp

[jCaT]

Unfortunately it's not gonna be the same with audio- people _just_dont_hear_the_difference_. You're not going to be able to sell someone a super high definition sound system like HDTV; pretty much anyone can look at an HDTV and say "wow, that looks great." Once they get cheap, they'll be flying off the shelves.

However in the rarified world of audio, you can't draw much of a parallel. Most of the listening public are sheep; to them the stock stereo in their honda civic is more than they could ever want, and they can't hear the glaring deficiencies with it. What difference would SCD make for them? Absolutely nothing. _That_ is why 128kbit mp3's are so common.

An illustration:

I was encoding some radio commercials into mp3's at work a while ago so people could e-mail them around. I was going from a studio copy on a burned cd; it was probably taken right off the DAT's. I encoded it at 160kbit, and then again at 48kbit mono and played both for a bunch of people at work on decent stereos and they couldn't tell the difference. To me, the low bitrate one sounded like ass, but they were perfectly happy with the 48kbit one.

This is why you hear the word "audiophile" a lot more than "videophile."

:)

[glowingspleen]

"2000-10-14 03:58:33 New Super Audio CD is out (articles,news) (rejected) "

No comment...

Anyway, it will take a lot to make people switch over. VHS->DVD was feasable because of the quality and the total change in viewing ability. SCD on the other hand...I need a little more than "more bits in your music" before I race out to buy all of my CDs over again.

Similar note - 16 bits is all you need.

[Andy+Dodd]

If you do the math, you'll see that the maximum error you obtain with 16-bit sampling is all you need given that line-out signals are 3 volts peak-peak. I don't remember the exact voltage, and I'm too tired to re-work it now. (3 volts divided by 2^16...) But the maximum error of a 16-bit sampled signal is FAR lower than the minimum electrical noise added by even the best super-high quality amplifiers with gold-plated speaker wire contacts and the like. The mathematics behind that are far simpler than the mathematics behind the Nyquist theorem. (While I knew the NT to be true in the past, I finally saw a proof/derivation of it in my Signals and Systems lecture last week - cool stuff.)

Re:Stereophile magazine? Are you kidding?

[Big+Ol'+Troll]

I'm not sure about the who speaker cable thing. I've recently bought a new pair of cables to smooth out a receiver I have and do notice a difference (even a girlfriend who is an anti-audiophile could hear the diffrence.) However, the cables are MIT terminator's which have passive components in them which may be filtering somethings out. MIT claims they are correcting for phase changes across various freqs. Who knows? All I know is my ears don't bleed when using these cables.

I do have to ask you though, can you hear the difference between a square and sine wave?

Nyquist theorem: looks great on paper...

[forty-2]

as stated before, @ the highest sampling rate, you get a square wave (or triangle or sine with half-assed interpolation) In addition to this, tests were conducted that showed humans can tell the difference between a sine & triangle wave @ 15khz...we're talking about at least the second harmonic here...30khz. I'm all for cranking up that sampling rate!

How about this..

[rent]

New digital audio 'standard formats' come out every day. Once a new digital format comes out, it forces the user to throw away the old equipment in favor of new equipment that can support the new format.

The problem is that it doesn't make sence to throw away an older standard just because the older standard has a lower sampling rate!

How about if someone would invent a standard that allows us to change the sample rate / word length at any time we like?

Vibrating bones

[floki]

In my physics class I've learned that it's exactly those high frequencies the human ear can't hear that make the sound more vivid and rich. Our teacher told us that they aren't percepted by the ear itself but by the bones next to the ear. This seems to somehow stimulate the ear's nerves, just in a different way. The effect of vibrating bones of the head is for example used by the Aboriginees when they play the didgeridoo for meditation.

HDCD, SACD, what else now?

[Antonio+M.]

It semms that the run to audio coding bits is just started.
The original CDs are coded on 16 bits so they don't reproduce sound armonics placed to our ear limits.
The HDCD standard (that exists right now from almost 2 years and is widely implemented - my avino system reads HDCD and CD) is coded on 20 bit capturing armonics that most of us will never appreciate (the human ear conventionally catches signals extending from 20Hz to almost 20 kHz).
Now we have SACD coded on 24 bits reproducing armonics beyond our earing band.
Is it necessary?
I wonder when someone other will produce 32 bits audio CDs claiming it as a new standard.

Re:Yet another psuedo-standard (minidiscs bite)

[Enigma2175]

I have problems with the minidisc. The problem is they don't have any digital outputs, not because it is a technical problem, it is because the industry thinks it will cut down on piracy and wouldn't support the standard with digital outputs. What this boils down to is I can't use my minidisc for the purpose that I bought it (recording live performances by a band for which I mix audio). In addition, it doesn't work with my fancy sound card, because the card only has digital inputs and outputs. I can take a digital signal out of my computer into the minidisc, but if I want to record a show on the MD, I have to transfer it into the computer through an analog sound card, compromising my audio quality with a DA->AD->DA conversion. This new standard sounds like it might be a little better in the digital arena. Since it supports the current CD format, we can use the players we already have to extract digital data from the disc. However, I don't understand why we need a new format, CDs hold quite a bit of data, and as soon as DVD-RWs come down in price I think we will be moving in that direction. Although the new tech is exciting, I don't think it will fly in the face of the technololgies that we already use.

Enigma
.sigless


Enigma

A visual aid

[Dahan]

Can't you _see_ this?? Doesn't your math acknowledge this? These are not only measurable distortions but the problem is still present even _completely_ in the theoretical realm.

Sure, I can see it... my math acknowledges it, takes it into account, and works perfectly. Sometimes math isn't intuitively obvious, even though it all works out in the end.

Here, look at some pictures I made... they're kinda quick and dirty, but they should get the point across:

• 14700Hz
• 14600Hz

For the 14700Hz picture, I plotted a 14700Hz sine wave, then marked the sample points in red. Then, in the next picture down, I plot the square wave signal made by the samples. As you say, it's not symmetrical, even though the original sine wave was. Now, I write the samples out to a file, and load it into Goldwave, a sound editing tool (I picked Goldwave because I'm vaguely familiar with it, and know that it does filtering). The third picture is how the sample looks in Goldwave. For visual purposes, and because Goldwave only works on digitally sampled files, the file loaded into Goldwave actually has each sample repeated 16 times, so it'd actually be a 918.75Hz tone if played back at a 44100Hz sampling rate. This doesn't invalidate my point though; remember that in the real world, pictures 2, 3, and 4 are analog signals, without any sampling rate. Now, I tell Goldwave to do a low pass filter, with a cutoff frequency of 919Hz. Voilà, I get a nice symmetrical sine wave back.

The 14600Hz picture is the same, and yes, the square wave does look like it's been modulated. But do a lowpass filter on it, and it's all fixed

Ain't math grand? :)

What a coincidence ;)

[Chris+Johnson]

Funny you should say that- I just posted a relentlessly technical analysis of exactly why this is potentially a killer technology, and here you are with a perfect analogy ;)

The difference between this and CD audio _is_ quite comparable with the difference between DVD and VHS- except there is no change that I can see in listening behavior- it's all audio quality. I'd check it out- if I don't miss my guess the difference will drop your jaw. It's not a question of 'all of a sudden the high frequencies are X times louder, thanks Sony': the frequency ranges may not seem any different. However, the technology has the capacity to produce an extended range with _no_ filter ringing of any sort, plus effectively infinite bit depth (I'd be _very_ interested to know exactly how they are doing playback- is it essentially an analog circuit steered by the digital data?). The result will be this: the sound will be bigger, lusher, more vivid yet warmer at the same time. It'll be like a 35mm film photograph compared with a generic digital camera- the 'liquid' quality should come across even on very cheesy speakers, to some extent, but of course the finer the equipment the better. Actually, if you played it over those Klipsch Promedias the differences should be particularly striking- the Klipsch use a sort of horn loading on the sats for both the woofer and tweeter, and this will maximise the increased transient dynamics. Those are relatively affordable computer/multimedia speakers and some Slashdotters probably have them- the acoustic power output they have are what will show off this new format, there will be some very hot peaks in the signal, felt more than heard.

Again, VHS to DVD is a pretty good analogy for what this format would do, and the frequency range is not the most significant factor- effective bit depth is important but the capacity for slew rate and lack of HF ringing from lowpass filters are really the killer aspects. It _will_ come across even on humble speakers (actually the rock bottom cheapness ones may be better than feature-laden mid-level crud w. 7 band equalisers). I want one, but only if I can record to it, as I don't care in the slightest what Sony artists are doing lately. :)

Deja Vu all over again...

[KFury]

Now that DVD-Audio is finally hammered out (dear god why did it take so long???) they come out with this, thinking that somehow it could catch on as a mainstream standard.

Kind of reminds me of DCC back in '92. It's a format built around half-backward compatability (you need new equipment, but at least it can read your old media too), touting enhancements over the media it seeks to replace, while admitting that only audiophiles will be able to hear the difference, and that media will cost more.

Really, truly? I think nowadays the primary motivation behind any new audio media format is to inhibit rampant replication. do you have a Super-CD burner? Will they sell one?

the article describes the tech as if the advancements in sampling were directly tied to the 'advancements' in media. There's no reason this data format couldn't be stored on a DVD, except that DVD-RAM players are becoming too readily available for Sony Music's liking.

Kevin Fox