When I look at the
waveform of a vocal recording, it looks lop-sided, with the waveform
going further above the zero-crossing point than it goes below it. It
sounds fine, though, so what’s happening here?
This
is a naturally occurring asymmetrical waveform, built from the linear
sum of a cosine fundamental and its first four harmonics (created in
Adobe Audition).
In this image we can see that as the waveform amplitude decays, it settles on the zero line (red). There is no DC offset.
This
simple sine wave has a DC offset, which raises the centre of the sine
wave well above the zero line. As the waveform amplitude decays, it
remains well above the zero line.
This
is the typical phase response of a ‘phase rotator’, which can be used
to impose symmetry on asymmetrical waveforms by adjusting the phase
relationships between fundamentals and harmonics. An increasing negative
phase shift is applied progressively as the signal frequency increases,
with the highest frequencies being shifted a full 360 degrees relative
to the lowest frequencies.
Bruno D’Cunha, via email
SOS
Technical Editor Hugh Robjohns replies: This kind of asymmetrical
waveform is quite natural and normal, and is particularly common on
recordings of speech and vocals, brass instruments, and sometimes also
closely miked strings. A lot of percussive sounds are also strikingly
asymmetrical, of course.
In the ‘BC’ era
(Before Computers) we didn’t look at waveforms, we just listened to
them, and this kind of asymmetry was generally inaudible and didn’t
bother us, although some people are sensitive to absolute polarity, and
can actually tell if an asymmetrical waveform is inverted. Waveform
asymmetry has been known about for a very long time, and in the few
areas where it can be an issue (such as in broadcast processing),
technology has long been in place to deal with it. However, since the
prevalence of the DAW and its ubiquitous waveform display, a lot of
people have become aware of it and asked the same question.
This
asymmetry is due mainly to two things, the first being the relative
phase relationships between the fundamental and different harmonic
components in a harmonically complex signal. In combining different
frequency signals with differing phase relationships, the result is
often a distinctly asymmetrical waveform, and that waveform asymmetry
often changes and evolves over time, too. That’s just what happens when
complex related signals are superimposed.
The
other element involved in this is that many acoustic sources inherently
have a ‘positive air pressure bias’ because of the way the sound is
generated. To talk or sing, we have to breathe out, and to play
a trumpet, we have to blow air through the tubing. So, in these
examples, there is inherently more energy available for the compression
side of the sound wave than there is for the rarefaction side, and that
can also contribute to an asymmetrical waveform.
Confusingly
— and erroneously — this natural waveform asymmetry is often attributed
to a ‘DC offset’, but that’s not the case at all. A DC offset is
a specific fault condition where the varying AC audio signal voltage is
offset by a constant DC voltage, and the ‘tell-tale’ is that, although
the waveform might look asymmetrical, a decaying signal waveform settles
away (offset) from the centre zero-line.
DC
offsets are virtually unheard-of these days, but can occur in hardware
analogue electronics under fault conditions. In the digital world, very
early multi-bit A-D converters sometimes suffered a problem in the
quantiser that essentially resulted in encoding a fixed-level shift or
offset onto the audio sample values — the digital equivalent of an
analogue DC offset.
However, a DC offset can be
very easily corrected by passing the audio through a high-pass filter
tuned to a low frequency (typically 10Hz or lower). It is important to
correct DC offsets when they do occur, because editing between an audio
clip with a DC offset and one without results in a loud thump or plop at
the edit point, which is not good!
In contrast,
natural waveform asymmetry cannot be ‘corrected’ with a high-pass
filter, and a rather more complicated solution is required called
a ‘phase rotator’. Generally, there is no need to ‘correct’ a naturally
asymmetrical signal, but occasionally the asymmetry can restrict how
much the signal can be amplified because the stronger half of the
waveform will reach the clip level before the weaker side. By using
a phase rotator process to alter the harmonic phase relationships,
a more balanced symmetry can be established, allowing slightly more gain
to be applied before both sides reach the clipping level at the same
amplitude. Asymmetrical waveforms can also sometimes confuse the
side-chain level-detection circuitry (or algorithms) of some
compressors, resulting in less effective compression than might be
expected.
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