Matchstick-Sized Sensor Can Record Your Private Chats Outdoors

wabrandsma sends this story from New Scientist: "A sensor previously used for military operations can now be tuned to secretly locate and record any single conversation on a busy street. [A] Dutch acoustics firm, Microflown Technologies, has developed a matchstick-sized sensor that can pinpoint and record a target's conversations from a distance. Known as an acoustic vector sensor, Microflown's sensor measures the movement of air, disturbed by sound waves, to almost instantly locate where a sound originated. It can then identify the noise and, if required, transmit it live to waiting ears. Security technologist Bruce Schneier says this new capability is unwelcome – particularly given the recent claims about the NSA's success at tapping into our private lives. 'It's not just this one technology that's the problem,' Schneier says. 'It's the mic plus the drones, plus the signal processing, plus voice recognition.'"

a few laws of physics problems here

While the sensor measures the vector direction of sound, it measures the *SUM* of all sounds impinging on that point. With a single point sensor, you can't separate the direction of a particular one.

Now, a reasonably small array of these sensors (maybe as small as 30cm across) might be able to accurately localize the source, in the same way that your brain can tell what direction a sound is coming from with just two ears.

Of course, it will also be confused by multipath and reflections, although if adequately characterized, those could be used for localization as well, since the reflected paths have different spectral properties.

There are LOTS of sensors that are tiny and easily deployed these days, using all sorts of sensing modalities. And processor horsepower and tiny comm to get the signals to the processor are easier to get too.

Governments have always had the technical means to be invasive, they are restrained by common decency and the law of the land. I actually would have more concerns about private industry: they're not subject to most privacy laws (at least in the U.S.): The wiretap laws, for instance, refer only to comms over a system. If you want to set up a big acoustic array at the beach and record everyone's conversations, process it, and sell the product to whoever, that's perfectly legal. Or set that array up out on the pubic street in front of your house, or the thermal imaging camera, or the mmWave wall penetrating radar or whatever.

So, it's those laws and common decency is where the efforts should concentrate.

Welcome technology if

[aNonnyMouseCowered]

...everybody has it. The last thing we need is awesome tech only spies and generals possess (weapons of mass destruction/contamination being a notable exception). So yes, this is unwelcome technology, but since it's already there, we might as well let everybody have it.

Re:Welcome technology if

[Kjella]

No, having the lack of privacy go both ways isn't as good as having privacy. A system where nobody can keep their actions private is a system governed by mob rule, nobody wants to engage in socially unacceptable behavior because they're instantly shunned and those who fail to participate in the shunning are also shunned for condoning it. Nobody will speak out unpopular opinions even if they feel it ought to be said, because those who don't like the message will go after the messenger. All social circles become totally transparent and people will self-censor their associations to avoid social stigma. It's freedom of the "you have freedom of speech and can say what you want, but we'll shoot you afterwards" variety.

Not to mention, it won't work. The powers to be will always find some reason why their conversations must be protected in the name of national security - after you've given up yours in the name of national security, of course. And if you don't like it you've got something to hide and is probably one of the bogeymen we're trying to catch. They can clam up any time they feel like it, while you'll stay stripped bare. Only the truly naive wants to head us in that direction, because <Admiral Ackbar>It's a trap!</Admiral Ackbar> and a pretty obvious one at that.

Re:a few laws of physics problems here

[ATMAvatar]

Governments have always had the technical means to be invasive, they are restrained by common decency and the law of the land.

What governments would those be which are restrained by the law, let alone common decency?

Re:a few laws of physics problems here

I think the coarse hair would block the sound waves on a pubic street, thus rendering the technology useless.

Re:a few laws of physics problems here

[ebno-10db]

Governments have always had the technical means to be invasive, they are restrained by common decency and the law of the land.

They are?

If you want to set up a big acoustic array at the beach

Were I to surveil the beach, I'd be more interested in visual than auditory information. YMMV.

All joking aside, I'm skeptical of the technical claims of superiority, other than small size. That's tempered by my lack of knowledge of acoustics. I think of it in terms of analogies to optics or radar (as a physicist I once knew said, a wave is a wave is a wave). You need an array to locate the direction something is coming from. Roughly speaking the larger the array relative to the wavelength, the more precisely you can determine direction, and the more you can spatially filter that source from other sources. You can do that with small optical sensors (e.g. a camera or your eye) only because of the short wavelength of light. Radar antennas with the same directionality and resolution need to be much larger. At 1kHz (a frequency you definitely need to understand conversation) the wavelength of a sound wave is 343mm. For radio waves that's the wavelength you'd get at 875MHz. You need a fairly big antenna to get decent resolution. That can be accomplished by widely spaced sensors (antenna elements, whatever) and some serious signal processing. I don't see how one of these sensors can have any serious directionality by itself, or having three in the same place pointing at x, y and z directions can do much.

One difference I can think of between electromagnetic radiation and sound waves is that the former are transverse waves and the latter are longitudinal waves. Does that make much of a difference for these purposes?

Re:a few laws of physics problems here

[FatdogHaiku]

... If you want to set up a big acoustic array at the beach and record everyone's conversations, process it, and sell the product to whoever, that's perfectly legal...

Unless you are openly and obviously (to the subjects being recorded) voice recording, most states don't allow the type of action you posit there. At least ONE party from each conversation has to consent to any recording and in 12 states EVERYONE must consent. There are limited "Presumed Consent" exceptions but a public beach would not be one of them. There is a quick review here:
http://www.wingfieldaudio.com/surreptitious-recording.html
Not sure about "through the walls" video/audio recording but I'd bet peeping tom laws would be made to suffice...

Re:a few laws of physics problems here

[Solandri]

While the sensor measures the vector direction of sound, it measures the *SUM* of all sounds impinging on that point. With a single point sensor, you can't separate the direction of a particular one.

That's true for a single snapshot of sound in any given instant. But if you collecting acoustic data over a period of time, transient sounds (noise) average out, and the loud peak (gunshot) or cyclical nature (engine) of certain sounds of interest should ease their extraction, with sufficient processing.

Now, a reasonably small array of these sensors (maybe as small as 30cm across) might be able to accurately localize the source, in the same way that your brain can tell what direction a sound is coming from with just two ears.

That was my impression too (one of my grad school courses was on acoustics and sonar design). That's what they do in submarines - make a great big phased array microphone. But if you follow the link in TFA to the company's site, they have a PDF which gives a bit more info on how their sensors work:

The Microflown sensor is based upon MEMS technology , and uses the temperature difference in the cross section of two extremely sensitive heated wires to determine acoustic particle velocity . Assembling three orthogonally placed Microflown sensors in one single point, a very compact Acoustic Vector Sensor can be produced.

So whereas a phased array sensor works by comparing the arrival times of a wavefront at different locations to determine the direction the wavefront is traveling, it sounds like their gizmo is measuring in 3 dimensions the actual movement of air molecules caused by the sound wave, and deriving the wavefront travel direction from that.

Re:Not the future I want to live in

I don't know, is your daughter's bedroom really private if I can watch her change from mine?

We have laws about these things. Laws used to apply to everyone, and people used to have a reasonable expectation that they would be followed. The government's current position seems to be that we're supposed to reasonably expect that the government will break the laws whenever its convenient for them.

Re:a few laws of physics problems here

[fa2k]

One difference I can think of between electromagnetic radiation and sound waves is that the former are transverse waves and the latter are longitudinal waves. Does that make much of a difference for these purposes?

It's been explained already by Solandri but I'll give it a try. The sensor measures the displacement of the air, not the pressure. The GP post argues that it measures the vector sum of the displacement caused by all sounds, and this is correct. I imagine a small light ball that's magnetically suspended and being pushed around by the air, and the movement of the ball is recorded (this is probably not how it's done, I imagine it would have a highly non-linear frequency response). If there are two sounds from different directions with different frequencies, you could easily tell them apart -- e.g. the ball is moving up and down fast, and left and right slowly. If the sources have the same frequency, or it's just some broadband noise, you can't tell them apart. You could probably do it easily with two vector sensors and relative timing, but the whole point was that you can do it with one sensor in plausible conditions.

As for electromagnetism / sound, you are right that the transverse/longitudinal distinction makes a difference. The air displacement is analogous to the electric field. An RF antenna sort of measures the projection of the electric field onto some given axis, and an omnidirectional antenna measures approximately the absolute value of the electric field. (A mic may measure pressure, not displacement, but these are alternative variables for discribing the same wave). An analogous RF detector to the sound vector sensor would be three small linear antennae pointing in linearly independent directions, measuring the x,y and z components of the electric field as functions of time. The transverse / longitudinal distinction comes in here: the EM waves have an additional degree of freedom, namely polarisation. The E field can point in any direction perpendicular to the direction of propagation. Given the polarisation vector you can thus only constrain the vector to the source to a plane.

Re:a few laws of physics problems here

[ebno-10db]

I just got back from a pleasure trip. I took my mother-in-law to the airport.