Next Wave Of Hard Drive Tech: Perpendicular Recording

angrytuna writes "New serial technologies are set to replace standard SCSI and ATA (Advanced Technology Attachment) interfaces over the next two years, even as hard-disk drive manufacturers prepare for an entirely new form of bit storage. Perpendicular recording will replace longitudinal recording in storage devices, placing bits on end instead of lying them parallel on the disc surface, thus dramatically increasing the possible storage density."

Re:a shame then

[Christopher+Thomas]

a crackdown on file-sharing. If they take that away from us, then whats the point of having that much space?

Legitimate content.

It's easy enough to end up with tens of thousands of photographs on your machine if you're in the habit of carrying a digital camera around. Now, think about what happens when you snap video clips the way you currently snap photographs.

This is already happening. With cameras being integrated into phones, it's growing even more.

Re:Details?

[Gogo+Dodo]

Essentially, as I understand it, with longitudinal recording the poles of the bits are pointed flat on the surface. Imagine a bar magnet. Put the long flat end of the bar on the platter. That's longitudinal recording.

With perpendicular recording the bar magnet would be standing on it's end.

Longitudianl recording is like this:

N--S
------------------- platter

Perpendicular recording is like this:

N
|
S
------------------- platter

Google is your friend...

Re:Details?

[deglr6328]

Goodnight. :-]

Re:Density doubling annually; access speeds lag

[Allen+Varney]

That's assuming current speeds. Well, as data gets more dense, the access speed inherently gets much faster, assuming the RPMs stay constant. If physical size stays the same, random access can't really get too much slower. So what is it that is going to be bad about terabyte disks?

The problem, as Jim Gray outlines it in the ACMQueue article:

"But starting about 1989, disk densities began to double each year. Rather than going slower than Moore's Law, they grew faster. Moore's Law is something like 60 percent a year, and disk densities improved 100 percent per year.

"Today disk-capacity growth continues at this blistering rate, maybe a little slower. But disk access, which is to say, 'Move the disk arm to the right cylinder and rotate the disk to the right block,' has improved about tenfold. The rotation speed has gone up from 3,000 to 15,000 RPM, and the access times have gone from 50 milliseconds down to 5 milliseconds. That's a factor of 10. Bandwidth has improved about 40-fold, from 1 megabyte per second to 40 megabytes per second. Access times are improving about 7 to 10 percent per year. Meanwhile, densities have been improving at 100 percent per year."

There's a lot more about this in the article. Check it out; it's +5 Informative stuff.

Re:How exactly...

[randyest]

Interesting? This clueless and sadly-late attepmpt at a FP is misleading everyone that reads it!. And you mods are to blame -- that's right: YOU!

Grrr, RTFA: there is nothing "3D" about it. It's still a 2-dimensional array of bits on a platter. The density increase comes from standing the little areas of magnetic media on end, instead of laying down. So, a top view of the old scheme would look like:

||||||||
||||||||

The new scheme, from the top:

::::::::
::::::::


In this case 2x density, as the lower one has twice as many dots in the same area as the dashes of the upper. (That is, each dot or dash represents the area of the physical medium used to store one bit by changing its magentic orientation). Get it? No 3-d. No holograms. Just 2-4x density increase by changing the orientation of the bits from parallel to perpendicular (relative to the disk platter surface).

Re:Increased Reliability?

[idiotnot]

You forgot 32-bit, 33 Mhz PCI bus @ ~150M/sec.

Faster hard drives would need a faster bus to operate off. I went looking for a non-server board the other day with PCI-X (for gigE), and couldn't find one in a store.

Drives aren't the only bottlenecks.

Re:Transition from 3.5" to 2.5"?

[zenyu]

HDD manufacturers said they expect to start replacing 3.5in. disk drives with smaller 2.5in. devices in enterprise products sometime within the next year.
Why would they want to do this?

Average Access Time. Ever notice how it hasn't changed much in the last 20 years?
It was like 10-20ms in 1984 and is like 3-9ms now? No matter how fast you spin the disk or how much cache you add you still need to move the head from one side of the platter to the other. With 5" drives it was a little over 2" with 3.5" its a little over 1", with 2.5" drives 0.75" It's also true that if you make it smaller you can spin it faster, but I don't think 15,000 rpm is really hitting the limits of the materials or they would already have made the platers non-uniform in thickness. They could also go to single crystal metals like they do in aeroplane turbine blades (not so expensive to do in quantity.)

OTOH The disparity between bandwidth and access time is already embarrasing enough that I consider partitioning just half the space on my drives to improve access time. There are uses for big slow drives. For instance, things like audio and video if artists ever get their act together and jettison the media conglomerate dead weight they are carrying on their backs. Or for backups.

At this point GBs of hard drive space is like the Mhz thing was with processors. Most consumers just read the density and maybe the dBs and transfer rate, like they used to buy 900Mhz processors and get just 16 MBs of RAM when a 50Mhz Processor with 128MBs of RAM would have been literally thousands of times faster because they were thrashing with too little RAM. Buyers should look at access time, then transfer rate, and then capacity, unless it is for backups or some such tape replacement use. They should partition their drives because real-life filesystems still suck at placing frequently accessed data closely and contiguously for actual access patterns. If people realized this, hard drive manufacturers would do things like have multiple independent heads accessing the same platters, two would be easy, three could probably be done with current technology, and many more could be done with different mechanical linkages (for instance, screews might be slower and less elegant than an arm at moving the heads, but if you could fit fifty heads accessing the platters at once you would probably have better worst and average case access time.) This also would require updating some drivers, but I don't think it would take long considering the performance payoff.

What this MEANS

[TwistedSpring]

If you have no idea what the difference between Longitudinal Recording and Perpendicular Recording might be, and the phrase "stands the bits on end" meant absolutely nothing to you because its an utterly ridiculous way to explain it, here's the lodown. Longitudinal recording is what we use today in everything from cassette tape to hard disks. It works by magnetising tiny sections of the recording medium. You can imagine the magnetised sections as tiny bar magnets laid end-to-end. The read head detects transitions in the direction of the magnetic field.

<- -> <-- -> <- -->

In the above diagram we're looking down at one track on the surface of a platter. Perpendicular recording works differently. The "magnets" or bits are arranged so that the field they emit is perpendicular to the medium, like this:

x . x . x . x .
In the above diagram we're looking down at one track on the surface of a platter 'x' represents a field pointing away from us, '.' is one pointing towards us. This is what it looks like in cross-section (looking in from the edge of the platter):
^ | ^ | ^ | ^ | ^
| v | v | v | v |

In perpendicular recording the read head detects the actual direction of the fields emitted by these bits/magnets, rather than transitions in the field. Perpendicular recording is advantageous because it allows one to use a much smaller surface area on the medium for one bit. Imagine if you laid a line of bricks end-to-end on the ground, you could make the line shorter but taller if you stood each brick on end (so they're laid flat-to-flat), but you've not had to make the bricks any smaller in order to acheive this change in the length of your line.

Most of the above is hopefully right. Anyway it's a better explanation than that site gave.

Re:Increased Reliability?

[Mooncaller]

as harddrives get more and more high-tech, the reliability seems to be taking a big nosedive

Talk about ignorant moderation. Sheesh.

Hard Drives technology is very mature. Every innovation has involved incremental improvments to the same basic tech. So the notion of Hard Drives getting more high tech is false. Second, the reliability of Hard Drives has been steadily increasing in a nearly linear fasion since their introduction in the 60s. There has always been instances of a particular Drive model or model family having difficulties. These are special cases from a statistical point of view. Saying that these models represent the quality of all Hard Drives is like saying that terrorists represents all Irishmen. On top of this, many HD reliability issues are realy HD handeling issues, i.e. originating with the PC manufacturers, not the HD producers. So the second part of the statement is also false, in fact way false.

how will this effect the reliability of future drives?

If you bothered to read the full artical, you would know that one of the hold ups of this new approch is quality concerns. The HD manufacturers will not deploy it untill it is suitable for their high end ( i.e. most reliable) Hard Drive lines.

Re:How exactly...

Well, in my experience, engineers only like to brag about a new technique if it gives a 10x improvement. (Or more.) If you read the article, you would have noticed some numbers:

The "brick wall" in magnetic recording is called the superparamagnetic effect. This is the point at which the recorded data starts to get lost in the thermal noise of the media. (As you approach the superparamagnetic, it becomes statistically likely for recorded bits to sporadically flip states resulting in data corruption.)

For longitudinal recording technology, it is estimated that superparamagnetic will start to become a problem around 100Gbits/square inch recording density. (Current hard drive technology is around 50Gbits/square inch - so they are getting close to the wall.)

Perpendicular recording technology is estimate to scale up to around 1Tbit/square inch.

Now, what did I say about engineers liking to brag about 10x improvements? Well, 1Tbit is about 10x improvement over 100Gbit. How about that! :)

What this means to you: if current hard drives store about 120GB using a recording density of about 50Gbit/square inch, then we can expect perpendicular recording to eventually deliver drives that store about 2.4TB extrapolating up to a 1Tbit/square inch. Even if this technology only works half as good, at least we will eventually have hard drives that store 1TB!

On top of that, the article say they are moving away from 3.5" drives toward 2.5" even for "enterprise" applications. Now, if we get 1TB drives in 2.5" form factor that's going to result in some killer MP3^^err...uncompressed 24bit, 192kHz iPods :)

A temporary solution, a fundamental problem

[ControlFreal]

Although the solution proposed in the article would increase storage capacity by, say, a factor 2 or 4, it still is a temporary solution that does not solve the fundamental problem at hand.

The fundamental problem is the superparamagnetic limit: if you make a magnetic domain (a bit) smaller than a certain size, it becomes thermodynamically unstable. In English, this means that very small bits loose their value after a while. It also means that for the time being, we'll have to use tricks to pack the bits closer together while keeping them large enough to be stable.

It should be noted that perpendicular recording is not the only effort to achieve higher recording densities in the looming shadow of the superparamagnetic limit. Indeed, harddrive manufacturers have seen this problem coming for a number of years now, and have had meeting to discuss possible solutions.

On a brighter note, there seems to be progress in circumventing the superparamagnetic limit: very recent research show promising results for the future.