Skip to content
  • 0 Votes
    1 Posts
    47 Views
    No one has replied
  • 0 Votes
    13 Posts
    3k Views
    R

    After a few months of searching for an definitive answer to this topic, I've reached the conclusion that my original assumption would be correct. This page describes how to determine the midpoint of a standard PCM audio signal:

    https://gist.github.com/endolith/e8597a58bcd11a6462f33fa8eb75c43d

    For example an 8-bit signed PCM signal has these ranges:

    Min: -128
    Max: 128
    Midpoint: 0

    As to why the signal I'm getting from my soundcard sits at -128 when there is no sound, I'm going to assume that this is related to a driver problem or could be that this particular piece of hardware does not follow the PCM standard.

    Converting to the logarithmic scale in my understanding is not related to this issue because you should be able to normalize the signal in time-domain even though eventually you will most likely need to convert it to the log scale if you are doing anything in the frequency domain (e.g. FFT).

    If anyone has any input, please feel free to add it.

  • 0 Votes
    5 Posts
    643 Views
    R

    Thank you for your help, I've probably identified the problem - one of the input parameters was a char (8 bit). I've tried to fix it using the following code to reformat it so that it can be used properly for 16 bit but I keep getting the same problem

    /* Function with char as one of the parameters - qint64 XYSeriesIODevice::writeData(const char *data, qint64 maxSize) - same as in the Qt audio example**/ int bitsPerSample = 16; int bytesPerSample = (bitsPerSample / BITS_IN_BYTE); int signalLength = (strlen(data) ) / numChannels / bytesPerSample; short* signal = (short*)malloc(sizeof(short) * signalLength); for(int i = 0; i < signalLength; i++){ int index = i * numChannels * bytesPerSample; memcpy(&signal[i], &data[index], sizeof(short)); }

    Any suggestions?

  • 0 Votes
    2 Posts
    2k Views
    raven-worxR

    @Punit
    see the Spectrum example