# whats a good way to represent a waveform within a certain height range

I'm happily drawing waveforms to screen from pcm data. I have a problem where occassionally the waveforms height will exceed the height of the display area height.

How can I ensure that the waveform plotting data will never exceed a determined height without having to rip through the entire set of pcm data and normalizing from the maximum value found?

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using a normalized representation is exactly what you would do.

you could cheat and pre-calculate max values for a given range, if that's a constraint offered by the implementation.

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I have no problem whatever with cheating :) Could you offer me a simple example? – dubbeat Feb 1 '11 at 13:41
@dubbeat sure, here's one example - you'll probably have to adapt something more appropriate for your implementation -- for how your app presents the waveform. if you want a fast/cheat normalization scheme, you could: 1) determine the number of samples you will display 2) take that number and find the max absolute value for each subdivision of the signal 3) save the max values in an array 4) use the max values to offset the amplitude of the values you're displaying. if you're displaying portions of these slices, use the max of the two -- but then not every draw will be perfectly normalized. – justin Feb 1 '11 at 14:27
No need to cheat. I would "normalize" with the maximum possible audio level, e.g. 16bit-audio: 32768 = 1.0. Then - when plotting - scale that to the pixel height. x[n] = SampleValue[n] * PixelHeight; – AudioDroid Feb 3 '11 at 14:46

Unfortunately, there is no good way to discover the actual maximum of a signal without going through sample by sample and finding it.

If you know the number of bits in the PCM samples, you can assume the scaling will be bounded by [`-2^(bits-1), 2^(bits-1)-1]`. That will be the absolute highest and lowest the signal can go. However, this is the most pessimistic scaling - if you have a 16-bit signal that never goes outside the range `[-1024,1024]`, for instance, you're giving up a lot of display area (as well as ADC dynamic range, but that's another story).

If you are willing to dynamically scale the signal, you can simply make the graph scale bigger each time your signal would get clipped. A more sophisticated approach would be to upscale as necessary, but then slowly relax the max scale downwards over time. A good way to relax the max scale is exponential decay, like multiply the max scale by .98 (or some other number < 1) on each iteration.

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