# Meaning of negative values in audio waveforms

I've been pondering this question lately. I've got this small app I've built, in which I visualize a wav file and give it a wave form (similar to what audacity does).

I've noticed that from some reason there are negative and positive values. Well, I can understand the importance of negative values in sinusoidal waves, where the direction represents the direction of the electric current. But what does negative value represent in music?

• I don't see a reason to vote to close. If questions about game physics are kosher, then so is a question about the physical meaning of a digitized value. Of course, this is probably near the edge of what is "programming related". – RBerteig Sep 4 '09 at 21:14
• I agree. This question may technically be better suited for the electrical engineering overflow community but it's also a fundamental question that many software people have as their backgrounds may not be as involved in EE. Personally, I've been wondering this myself for quite a while, despite reading some fairly sophisticated DSP literature. This question is about interpretation of digitized data, which is extremely relevant to programming. – Joey Carson Dec 4 '13 at 15:28

Sound is fundamentally a pressure wave, made up of "peaks" which are regions of higher pressure and "troughs" which are regions of lower pressure. A microphone responds to the incident pressure wave by taking advantage of some physical material property to measure that pressure over time. Making a recording is the process of sampling those measurements and transcribing them to some media.

A reasonable representation to choose is to call the ambient pressure zero, with higher and lower pressures positive and negative. Another reasonable representation is to take ambient pressure as half-scale, with lower pressures below and higher pressures above half. Other representations are possible, and it isn't even required that the relationship between the incident pressure and the measured value be linear.

Whether a signed or unsigned representation is used is only a matter of history and convention. 16-bit audio is usually represented as signed but 8-bit audio is usually not, for instance.

Historically, the telephone system has used 8 bit unsigned measurements following a non-linear function called either a-law or µ-law. The non-linear representation supports greater dynamic range within the same bit rate than a linear representation.

• so let's see if I got it right. 0 represents no sound whatsoever. So what it the meaning of a negative value? It represents the direction of the amount of sound? Positive value indicates a strengthening sound (say a blast) and a negative value indicates a decrease in the amount of sound? If that's the case why just don't draw a line between the amount of sound in every moment, values always being positive, as long as there's sound. What use is there for negative values then? – vondip Sep 4 '09 at 18:23
• You did not get that right. 0 is a single sample. No single sample can be said to represent any sound or no sound whatsoever. It is only in the frequency of oscillation in the signal that sound can exist. Obviously, a single sample can not represent any oscillation. – recursive Sep 4 '09 at 18:29
• The current value - either positive, zero, or negative - represents no sound at all. It's the variation of the value over time that represents the sound. Look at a loud speaker. The value in a wave form represents the position of the membrane at different points in time. Positive means the membrane moved in one direction (from the equilibrium when the music is off) and negative means the other direction. Absolute smaller values represent small displacements, absolute larger values represent large displacements. – Daniel Brückner Sep 4 '09 at 18:30
• @Daniel Brückner Oh, I thought the values represented the actual position of the membrane, not the displacement (but now that I think about it, it makes sense since the magnet in a speak can only attract/repel it, not put it in a specific position instantly). So what does that do to the speaker if the waveform is for example not centered on 0 (no displacement), is maybe even a flat line of 1 / +100%? – Bart van Heukelom Aug 26 '11 at 21:08
• A flat waveform that is away from zero (either way) would be asking the speaker to hold the cone still against its return spring, which would consume power, heat up the voice coil, and potentially damage the speaker. In practice, this sort of DC offset is removed in the amplifier so that damage to the speaker is prevented. A DC offset is one cause of the click or pop you might hear when you connect or disconnect an audio source, since the sudden jump from one DC level to another does go through that filter. – RBerteig Aug 27 '11 at 0:35

Sound is mechanical energy in the form of pressure variances in an elastic medium. These pressure variances propagate as waves from a vibrating source. Changes in air pressure (air being a propagating medium) can be represented by a WAVEFORM, which is a graphic representation of a sound. In reality, sound waves propagate through the air in LONGITITUDAL WAVES (and not TRANSVERSE WAVES).

The concept of compression and rarefaction comes into picture where in a compression is a period of higher pressure than the ambient pressure(or when the output is 0) and rarefaction is a period wherein the pressure is lower than the ambient pressure. So when the longitudinal wave is incident on the membrane of the microphone/transducer. The compression produces a positive value of amplitude and the rarefaction produces a negative value of the amplitude.

Waveform is flat (Y=0) if there's no sound.

Y axis relates to the pressure difference relative to ambient pressure. Positive Y values indicate compression and negative Y values indicate rarefaction.

Exactly the same ... a wave file just represents a sampled sound wave. And sound waves (as most waves of any type) are sometimes below and sometimes above the equilibrium (in the case of an sound wave the local air pressure is lower or higher then the ambient air pressure) and hence are the samples sometimes negative and sometimes positive.

In the end its just a matter of fixing a equilibrium. A 16 bit sound file has sample values ranging from -32.768 to +32.767. You could just add 32.768 to all sample values and get samples values in the range 0 to 65.535 and you moved the equilibrium (total silence (in absence of a DC offset)) from 0 to 32.768.

The sample values in a sound file can be thought of as the movement of the microphone membrane used to record that sound: the microphone membrane vibrated up (positive) and below (negative) its rest position (zero).

Similarly, to reproduce this sound, the speaker membrane will move ahead (positive) and back (negative) from its rest position (zero). This vibration around a centre position will create sound.

From the WAV format :

8-bit samples are stored as unsigned bytes, ranging from 0 to 255. 16-bit samples are stored as 2's-complement signed integers, ranging from -32768 to 32767.

Negative values comes signed integers.