is there a way in python to generate a continuous series of beeps in increasing amplitude and export it into a WAV file?
I've based this on the answer to the previous question and added a lot of comments. Hopefully this makes it clear. You'll probably want to introduce a for loop to control the number of beeps and the increasing volume.
#!/usr/bin/python # based on : www.daniweb.com/code/snippet263775.html import math import wave import struct # Audio will contain a long list of samples (i.e. floating point numbers describing the # waveform). If you were working with a very long sound you'd want to stream this to # disk instead of buffering it all in memory list this. But most sounds will fit in # memory. audio =  sample_rate = 44100.0 def append_silence(duration_milliseconds=500): """ Adding silence is easy - we add zeros to the end of our array """ num_samples = duration_milliseconds * (sample_rate / 1000.0) for x in range(int(num_samples)): audio.append(0.0) return def append_sinewave( freq=440.0, duration_milliseconds=500, volume=1.0): """ The sine wave generated here is the standard beep. If you want something more aggresive you could try a square or saw tooth waveform. Though there are some rather complicated issues with making high quality square and sawtooth waves... which we won't address here :) """ global audio # using global variables isn't cool. num_samples = duration_milliseconds * (sample_rate / 1000.0) for x in range(int(num_samples)): audio.append(volume * math.sin(2 * math.pi * freq * ( x / sample_rate ))) return def save_wav(file_name): # Open up a wav file wav_file=wave.open(file_name,"w") # wav params nchannels = 1 sampwidth = 2 # 44100 is the industry standard sample rate - CD quality. If you need to # save on file size you can adjust it downwards. The stanard for low quality # is 8000 or 8kHz. nframes = len(audio) comptype = "NONE" compname = "not compressed" wav_file.setparams((nchannels, sampwidth, sample_rate, nframes, comptype, compname)) # WAV files here are using short, 16 bit, signed integers for the # sample size. So we multiply the floating point data we have by 32767, the # maximum value for a short integer. NOTE: It is theortically possible to # use the floating point -1.0 to 1.0 data directly in a WAV file but not # obvious how to do that using the wave module in python. for sample in audio: wav_file.writeframes(struct.pack('h', int( sample * 32767.0 ))) wav_file.close() return append_sinewave(volume=0.25) append_silence() append_sinewave(volume=0.5) append_silence() append_sinewave() save_wav("output.wav")