If you were to write a program that takes microphone input, reverses it (sets it out of phase by making 1's 0's and 0's 1's), and plays it back out of the speakers, could that cancel out sound? Wave physics says if crests align with troughs, destructive interference occurs, so can that be utilized here to achieve a lessened noise if not canceled out "completely." I can imagine that this wouldn't work due to either complication in reversing the audio, or even because it takes too long to reverse and play back, so that the sound wave has passed. If i had to associate a language to do this in it would have to be either c++ or java (I'm at least competent in both).

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    Not with PCs and in software. The latency is too high and your inverse waves will be too late to cancel out anything. Noise cancelling headphones that use this exist but they do that afaik in hardware because it needs to be super fast. – zapl Nov 18 '15 at 23:46
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    As @zapl has said, latency is generally a key issue. You can do it in "software" though using something like an FPGA. – ajshort Nov 18 '15 at 23:47
  • yeah i thought that would be the case, i just wanted to be sure – Jean Valjean Nov 18 '15 at 23:48
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    @zapl - you also need to take into account the distance between the microphone and speakers, and their relative position with respect to the original sound. If the microphone is closer to the original sound than the speakers, you can use the speed of sound to your advantage, If (for example) you were able to process with a 20ms latency - you would need a 7m gap between the microphone and speakers - and it would be possible. (although the latency would have to be constant for this to be useful) – Harry Harrison Nov 19 '15 at 0:19

Yes it will cancel out sound. That's more or less how Surround Sound works: by subtracting the left/right channels, playing that in the 3rd speaker, and inverting the samples, playing those out of the 4th you get interesting spatial effects.

Also you wouldn't simply want to toggle all bits, you'd get noise; instead you want to negate.

With a small sample buffer you'd be fast enough to cancel out waves of certain frequencies. When these attack and decay, you'll be lagging, but as long as the wave sustains you can effectively cancel it out.

With bigger sample buffers, obviously the delay increases, since it takes longer to fill the buffer with samples. The size of the buffer determines how often a device interrupt occurs where the program would copy the input samples to an output buffer while applying an operation to them.

Typically recordings are made at 44.1kHz, meaning that many samples per second. If you set the buffer to say 256 samples, you would get notified 44100/256 times a second that there are 256 samples to be processed.

At 256 samples you'd lag behind 256/44100 = 0.0058 seconds or 5.8 milliseconds. Sound travels at around 340 m/s, so the sound wave would have moved 1.97 meters (340 * 5.8ms). This wavelength corresponds with the frequency 172 Hz (44100/256). That means that you can only effectively cancel out frequencies that have a lower frequency than that, because those of a higher frequency 'move' more than once during 5.8ms and are thus above the maximum 'sample rate', if you will.

For 64 samples, the frequency would be 44100/64 = 689 Hz. And, this is the maximum frequency! That means you could cancel out bass and the base frequency of the human voice, but not the harmonics.

A typical OS has it's clock frequency set to either 500, 1000, or 2000 Hz, meaning at best you could use a sample buffer of around two to three samples, giving you a maximum frequency of 500, 1000, or 2000 Hz. Telephones usually have a maximum frequency of about 3500 Hz.

You could get the system clock up to around 32kHz, and poll an ADC directly to reach such frequencies. However, you'd probably need to solder one to your LPT and run a custom OS, which means Java is out of the question, or use a pre-fab real-time embedded system that runs Java (see the comment by @zapl for links).

One thing I forgot to mention, is that you will need to take into account the position of the sound source, the microphone, and the speaker. Ideally all 3 are in the same place, so there is no delay. But this is almost never the case, which means you'd get an interference pattern: there will be spots in the room where the sound is cancelled, inbetween spots where it is not.


You cannot do this in software, with c++, or even assembly - the latency of just mirroring the the output on the speakers would be more than 6 ms on most computers. Even if you had a latency of only 0.1 ms, the resulting sound (assuming it is perfectly mixed) would at best sound like it was sampled at 10kHz (not very good).

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