1. Digital Audio
Introduction
In the late 1960’s Dr. Thomas Stockham began to experiment with digital tape recording using analogue to
digital converters. By 1975 most professional audio studios began to start using digital tape recording. [1] [2]
Before digital audio was created, all recording, editing and storing music was done from analogue audio.
This experiment will help me discover why digital has taken over from analogue. By using Adobe Audition I
can experiment with digital audio in more depth and get an understanding about aspects of digital audio such
as its file size and sound quality.
It was important for me to research to see how digital audio is created from an analogue signal, as well as
how digital audio can be converted back to an analogue signal.
Experiment
Analogue to Digital Conversion (ADC)
An analogue to digital converter is a device which can convert an analogue input into digital form. This is
done by converting the analogue voltage into a digital number known as binary. [3]
The waveform below is an example of an analogue signal. Analogue signals are continuously variable unlike
a digital signal.
http://micromachine.stanford.edu/~hopcroft/Research/resonator_images/sin_mov1.gif
By using Adobe Audition I can create a waveform similar to the image above. To convert the analogue wave
to a digital wave, it needs to have sample points taken. These are done by measuring the amplitude of the
waveform at regular intervals every second. The number of samples taken each second is known as the
sample rate.
Sample Rate
The diagram below shows a waveform I created in audition.
2. The dots on the waveform are the samples being taken. The wave I created had the sample rate of 44100Hz
which means 44100 samples are taken each second. This sample rate is that of a standard CD.
The reason for this is that the sample rate of a CD has to be larger than about 40 kHz. This is because it
needs to be double the maximum analogue frequency which is around 20 kHz. This theory was found out by
Harry Nyquist and is therefore known as the Nyquist sampling theorem [4]
By halving the sample rate of my waveform in Audition I can see this halves the number of sample points
taken. To see what this does to the sound quality, I opened up a sample in Audition and changed the sample
rate each time and wrote what happened in the table below.
Sample Rate (Hz) Effect on test sample
48000 Sounds the same
44100 Original sample rate, so no change
22050 The sample sounds more muffled
11025 Very muffled, losing high frequencies
6000 Very poor sound, no high frequencies at all
This confirmed my assumption that the lower the sample rate the poorer the sound quality. Changing the
sample rate to as low as 6000Hz made a huge difference as it sounded like there were no high frequencies
at all. An interesting discovery was when increasing the sample rate the quality stays the same. This is
because there’s no longer the original analogue wave to sample from and increasing the number of the
samples on the digital wave just keeps the wave the same.
Bit Depth
The values that are taken from the sample rate are stored as binary numbers. Binary is a code read by
computers and is made up of 0’s and 1’s. [5] More numbers can be created by having more than one bit.
Having 2 bit’s will allow 4 possible outcomes 00, 01, 10, 11.
The number of bits determine bit depth, the larger the number of bits the bigger the bit depth. Bit depth
rounds each sample point taken to a binary number. Therefore a higher bit depth produces a more accurate
wave.
The following diagram shows the bit depth of a waveform. You can see that the bit depth is 2 bit as there are
4 possible values. Each sample taken has to be rounded to the nearest binary number. This digital waveform
is a very bad conversion. The bit depth needs to be much higher to get a more accurate representation of the
analogue wave.
http://www.pgmusic.com/images/wave6.gif
The results of this poor conversion would be quantization noise.
“Due to this rounding off, the raw value mis-states the actual signal by a slight amount; the error introduced
by the digitization is called quantization error, and is sometimes referred to as quantization noise” [6]
3. I did an experiment to find the difference in sound quality by lowering the bit depth and to see if I could hear
quantization noise for myself. I took the same piece of audio I used for the sample rate experiment and
change its bit depth.
Bit Depth Effect on test sample
32 No difference
16 Original bit depth, so no change
8 Fuzzy
4 Fuzzy – Lots of hissing noise
As in the previous experiment increasing the variable (in this case bit depth) had no effect on the sound
quality; this is because the wave itself is not being changed. Lowering the bit depth had a much more
noticeable adverse effect on the sound quality than changing the sample rate did. A big hissing noise
drowned out the audio sample, and as I found out from my research this was quantization noise. One thing
that can help cover quantization noise is dithering. This is done by adding random noise to the digital signal.
[7]
File Size
When saving a file it is obvious that to get the best sound quality you need a high sample rate and a high bit
depth but saving this would result in a large file size.
To see how sample rate and bit depth effect file size I saved an audio file in Adobe Audition and each time
saved it at a different bit depth or sample rate. Below is my results table.
Sample Rate (Hz) Bit Depth File Size
44100 16 1.24MB
44100 8 636KB
44100 32 2.48MB
22050 16 636KB
11025 16 318KB
6000 8 86.5KB
From this experiment I found that halving the sample rate halves the file size. This is also the case when
halving the bit depth.
Choosing which sample rate and bit depth depends on what I would want to do with the file. When saving an
audio mix down it would be best to save the highest quality available but if I had a quick mix down I wanted
to attach in an email or send over the internet it would be best to save it as a smaller file.
Digital to Analogue Conversion (DAC)
Getting digital audio back to analogue works in the opposite way converting analogue to digital did. A digital
to analogue converter takes digital samples and outputs them as analogue. The nyquist theorem states that
as long as the sampling rate is more than double the highest frequency in the original audio sample then the
output will be an exact of the original signal [4]
Conclusion
This experiment has helped me gain a better understanding of why digital audio is now more commonly used
the analogue. I found how an analogue signal is converted to digital audio and how sample rate and bit depth
affects the accuracy.
What I learnt was very useful if I wish to work as a studio engineer or producer as it taught me about storing
data. Larger files have a higher sound quality but take up more memory, so it's a compromise I would have
to bare in mind in the future.
The experiment has also given me an idea of what sample rate and bit depth to save my audio as and which
sound quality is appropriate for different uses.
4. References
1. About.com, The History of Digital Music [Online]
Available at: http://mp3.about.com/gi/dynamic/offsite.htm?
zi=1/XJ/Ya&sdn=mp3&zu=http://www.aes.org/aeshc/docs/audio.history.timeline.html
[Accessed 1 December 2008].
2. University of San Diego, Thomas Stockham and Digital Audio Recording [Online]
Available at: http://history.sandiego.edu/gen/recording/stockham.html
[Accessed 1 December 2008].
3. Hardware secrets, How Analog-to-Digital Converter (ADC) Works [Online]
Available at: http://www.hardwaresecrets.com/article/317
[Accessed 1 December 2008].
4. Columbia University, Explanation of 44.1 kHz CD sampling rate
Available at: http://www.cs.columbia.edu/~hgs/audio/44.1.html
[Accessed 1 December 2008].
5. CIO-Midmarket, What is binary?
Available at: http://searchcio-midmarket.techtarget.com/sDefinition/0,,sid183_gci211661,00.html
[Accessed 1 December 2008].
6. University of Chicago, Noise, Dynamic Range and Bit Depth in Digital SLRs
Available at: http://theory.uchicago.edu/~ejm/pix/20d/tests/noise/#quanterror
[Accessed 1 December 2008].
7. Ear Level, Dither
Available at: http://www.earlevel.com/Digital%20Audio/Dither.html
[Accessed 1 December 2008].