mirror of
https://gitlab.freedesktop.org/gstreamer/gstreamer.git
synced 2024-12-29 19:50:40 +00:00
63 lines
2.5 KiB
Text
63 lines
2.5 KiB
Text
|
|
||
|
This is a snapshot of my current work developing an audio
|
||
|
resampling library. While working on this library, I started
|
||
|
writing lots of general purpose functions that should really
|
||
|
be part of a larger library. Rather than have a constantly
|
||
|
changing library, and since the current code is capable, I
|
||
|
decided to freeze this codebase for use with gstreamer, and
|
||
|
move active development of the code elsewhere.
|
||
|
|
||
|
The algorithm used is based on Shannon's theorem, which says
|
||
|
that you can recreate an input signal from equidistant samples
|
||
|
using a sin(x)/x filter; thus, you can create new samples from
|
||
|
the regenerated input signal. Since sin(x)/x is expensive to
|
||
|
evaluate, an interpolated lookup table is used. Also, a
|
||
|
windowing function (1-x^2)^2 is used, which aids the convergence
|
||
|
of sin(x)/x for lower frequencies at the expense of higher.
|
||
|
|
||
|
There is one tunable parameter, which is the filter length.
|
||
|
Longer filter lengths are obviously slower, but more accurate.
|
||
|
There's not much reason to use a filter length longer than 64,
|
||
|
since other approximations start to dominate. Filter lengths
|
||
|
as short as 8 are audially acceptable, but should not be
|
||
|
considered for serious work.
|
||
|
|
||
|
Performance: A PowerPC G4 at 400 Mhz can resample 2 audio
|
||
|
channels at almost 10x speed with a filter length of 64, without
|
||
|
using Altivec extensions. (My goal was 10x speed, which I almost
|
||
|
reached. Maybe later.)
|
||
|
|
||
|
Limitations: Currently only supports streams in the form of
|
||
|
interleaved signed 16-bit samples.
|
||
|
|
||
|
The test.c program is a simple regression test. It creates a
|
||
|
test input pattern (1 sec at 48 khz) that is a frequency ramp
|
||
|
from 0 to 24000 hz, and then converts it to 44100 hz using a
|
||
|
filter length of 64. It then compares the result to the same
|
||
|
pattern generated at 44100 hz, and outputs the result to the
|
||
|
file "out".
|
||
|
|
||
|
A graph of the correct output should have field 2 and field 4
|
||
|
almost equal (plus/minus 1) up to about sample 40000 (which
|
||
|
corresponds to 20 khz), and then field 2 should be close to 0
|
||
|
above that. Running the test program will print to stdout
|
||
|
something like the following:
|
||
|
|
||
|
time 0.112526
|
||
|
average error 10k=0.4105 22k=639.34
|
||
|
|
||
|
The average error is RMS error over the range [0-10khz] and
|
||
|
[0-22khz], and is expressed in sample values, for an input
|
||
|
amplitude of 16000. Note that RMS errors below 1.0 can't
|
||
|
really be compared, but basically this shows that below
|
||
|
10 khz, the resampler is nearly perfect. Most of the error
|
||
|
is concentrated above 20 khz.
|
||
|
|
||
|
If the average error is significantly larger after modifying
|
||
|
the code, it's probably not good.
|
||
|
|
||
|
|
||
|
|
||
|
dave...
|
||
|
|