Audio Signal Filtering - Rhea

Audio Signal Filtering

Background

• Audio signals in the digital world are simply 1-D signals that contain the values of the sampled sound v/s an index, say k.
• Consider the diaphragm on a microphone, that vibrates every time a sound impinges on it.
• The vibration is converted to an electrical signal by a transducer, which then relays the "analog" signal to an A/D converter.
• Finally, the A/D converter samples the analog signal, and makes it a train of samples; each box of the train contains a value.
• This value corresponds to the digital representation of the electrical signal that resulted from the vibration.
• For example, say the diaphragm vibrated 0.2mm, resulting in a generated voltage of 0.2mV (these values are completely arbitrary).
• If the A/D converter designated 0V to x00 and 10mV to xFF, then the resolution of designating values to the samples would be 10/255 mV or .04mV. Thus, 0.2 mV would be x05.
• This value would be stored in the digital sound file, against a time index corresponding to when the A/D received this sample.
• Since this page focuses on Audio Signal filtering, those interested in the basics of Audio Processing can go to the references on the following wiki:
• http://en.wikipedia.org/wiki/Digital_audio

Motivation

• This page took a long time to figure out. Mainly because, for images and sine waves, it's easy to find some that aren't copyrighted.
• For images you just use your pet dog's best photograph, and for sine waves, you write a line in MATLAB.
• But for audio signals, almost every recorded sound is copyrighted in some way or the other, and to avoid being sued for copyright infringement, I had to find sounds to play with, and publish online, that weren't "owned", so to speak.
• Fortunately, however, animals don't take you to court for stealing their sounds, so that's just what I did.
• On this page, I experiment with two animal sounds; the first is a high-frequency bird pitch, while the second is a low-frequency bear rumble.

The Song-Bird Experiment

• So, let's begin with the song-bird. Click on the link to here the sound >>Media:song_bird.wav
• In the following figure, you can see what the sound looks like both in the time domain, and the frequency domain.

• As expected, most of the energy of the signal, in this case the bird's voice,