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AUDIO-RESAMPLER

Audio Resampling Engine & Command-Line Tool

Copyright (c) 2022 David Bryant.

All Rights Reserved.

Distributed under the BSD Software License.

What is this?

This is a simple audio resampler, written entirely in C and specifically targeting embedded systems. It provides fine control over both the CPU load and memory footprint so it can be easily adapted to a wide range of hardware (e.g., ESP32 to high-end ARM). It is also well suited for ASRC (asynchronous sample rate converter) applications because it provides a function to query the exact phase position of the resampler (which is required in the feedback loop of an ASRC).

The package includes a command-line program (ART) to experiment with the resampler and serve as example code for the engine API. The resampling and filtering code works with only 32-bit float audio data, however the command-line program includes examples of how to convert to and from integer audio samples, including the use of highpass TPDF dither and 1st-order noise shaping.

ART works with Microsoft WAV files and includes four quality presets that set the number and size of the sinc filters and serve as a starting point for experimentation:

Preset Number of sinc filters Number of taps per filter RAM use (stereo)
-1 16 16 3.4 Kbytes
-2 64 64 25.3 Kbytes
-3 256 256 293 Kbytes
-4 1024 1024 4244 Kbytes

Preset -3 is the default and is a reasonable compromise for high-quality resampling on a PC. Presets -1 and -2 are more suited for realtime use on embedded systems and -4 represents the highest quality available for this tool.

Infinite Wave has a very useful site comparing the audio performance of various sample rate converters and now includes this resampler utilizing presets -2, -3, and -4. Here's the comparison of ART preset -2 and preset -4, and you can scroll through to many other converters to see that ART is competetive in quality with virtually anything out there.

ART supports integer samples from 4-bits to 24-bits, as well as 32-bit floating-point samples. Any number of channels are supported. Normally the output bitdepth is set to the same as the input file, however this can be forced to one of the other supported bitdepths with the -o option.

Both the resampling and filter engines are endian-safe and the command-line program is endian-aware (although, of course, WAV files are always little-endian).

Technical Description

The resampler uses windowed sinc interpolation filters. A configurable number of filters are generated on initialization representing subdivisions of the unit circle. Normally, the output sample value is calculated by convolving the input samples (the required history is stored in the resampler) with the two sinc filters on either side of the desired phase angle, and then linear interpolating to get the precise result. If it is known that there will always be an exact sinc filter (or there's enough room for many filters) then the interpolation can be skipped and only the nearest sinc filter is used (controlled with the -n option in the CLI).

The sinc filters are generated with either Hann or Blackman-Harris (4 term) windowing functions. The Blackman-Harris is usually the best choice (and the default in the CLI) because it has very good stopband (side-lobe) rejection. However, in some situations (e.g., short filters) the Hann window might be better because it has a sharper transition (this is controlled in the CLI with the -b and -h options).

For upsampling or simple resampling operations the sinc filters preserve the original waveform (i.e., they are purely interpolative). However, for downsampling applications this is not sufficient because aliasing occurs if content at the old sampling rate moves above the Nyquist frequency of the new sampling rate. For these cases the sinc filters are constructed with an implicit lowpass, and this lowpass frequency is optimized for the length of the interpolation filters (i.e., longer filters allow the lowpass to be closer to the Nyquist frequency). This is also available for upsampling if desired to eliminate frequencies close to the Nyquist frequency of the input and reduce aliasing further at the expense of some HF loss (e.g., it might be desirable to set a lowpass of 20 kHz when resampling up from 44.1 kHz even though it's not strictly required). The lowpass option is enabled with the -l option in the CLI).

It is sometimes desirable to reduce aliasing further with lowpass filters either before downsampling or after upsampling as this can be more efficient than increasing the length of the sinc filters. This is enabled with the -p option in the CLI and implements a cascaded pair of 2nd-order biquads. Note that unlike the sinc filters, these filters are not linear-phase and will introduce group delay.

Building

To build the command-line tool (ART) on Linux or OS-X:

$ gcc -Ofast art.c resampler.c biquad.c -lm -o art

The "help" display from the command-line app:

 Usage:     ART [-options] infile.wav outfile.wav

 Options:  -1|2|3|4    = quality presets, default = 3
           -r<Hz>      = resample to specified rate
           -g<dB>      = apply gain (default = 0 dB)
           -s<degrees> = add specified phase shift (+/-360 degrees)
           -l<Hz>      = specify alternate lowpass frequency
           -f<num>     = number of sinc filters (2-1024)
           -t<num>     = number of sinc taps (4-1024, multiples of 4)
           -o<bits>    = change output file bitdepth (4-24 or 32)
           -n          = use nearest filter (don't interpolate)
           -b          = Blackman-Harris windowing (best stopband)
           -h          = Hann windowing (fastest transition)
           -p          = pre/post filtering (cascaded biquads)
           -q          = quiet mode (display errors only)
           -v          = verbose (display lots of info)
           -y          = overwrite outfile if it exists

 Web:       Visit www.github.com/dbry/audio-resampler for latest version and info

Caveats

  • The resampling engine is a single C file, with another C file for the biquad filters. Don't expect the quality and performance of more advanced libraries, but also don't expect much difficulty integrating it. The simplicity and flexibility of this code might make it appealing for many applications, especially on limited-resource systems.
  • In the command-line program, unknown RIFF chunk types are correctly parsed on input files, but are not passed to the output file, and pipes are not supported.
  • The command-line program is not very restrictive about the option parameters, so it's very easy to get bad results or even crashes with crazy input.