/usr/share/octave/packages/signal-1.3.0/specgram.m is in octave-signal 1.3.0-1.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198 199 200 201 202 203 204 205 206 207 208 209 210 211 212 213 214 215 216 217 218 219 220 | ## Copyright (C) 1999-2001 Paul Kienzle <pkienzle@users.sf.net>
##
## This program is free software; you can redistribute it and/or modify it under
## the terms of the GNU General Public License as published by the Free Software
## Foundation; either version 3 of the License, or (at your option) any later
## version.
##
## This program is distributed in the hope that it will be useful, but WITHOUT
## ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
## FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more
## details.
##
## You should have received a copy of the GNU General Public License along with
## this program; if not, see <http://www.gnu.org/licenses/>.
## -*- texinfo -*-
## @deftypefn {Function File} {} specgram (@var{x})
## @deftypefnx {Function File} {} specgram (@var{x}, @var{n})
## @deftypefnx {Function File} {} specgram (@var{x}, @var{n}, @var{Fs})
## @deftypefnx {Function File} {} specgram (@var{x}, @var{n}, @var{Fs}, @var{window})
## @deftypefnx {Function File} {} specgram (@var{x}, @var{n}, @var{Fs}, @var{window}, @var{overlap})
## @deftypefnx {Function File} {[@var{S}, @var{f}, @var{t}] =} specgram (@dots{})
##
## Generate a spectrogram for the signal @var{x}. The signal is chopped into
## overlapping segments of length @var{n}, and each segment is windowed and
## transformed into the frequency domain using the FFT. The default segment
## size is 256. If @var{fs} is given, it specifies the sampling rate of the
## input signal. The argument @var{window} specifies an alternate window to
## apply rather than the default of @code{hanning (@var{n})}. The argument
## @var{overlap} specifies the number of samples overlap between successive
## segments of the input signal. The default overlap is
## @code{length (@var{window})/2}.
##
## If no output arguments are given, the spectrogram is displayed. Otherwise,
## @var{S} is the complex output of the FFT, one row per slice, @var{f} is the
## frequency indices corresponding to the rows of @var{S}, and @var{t} is the
## time indices corresponding to the columns of @var{S}.
##
## Example:
## @example
## @group
## x = chirp([0:0.001:2],0,2,500); # freq. sweep from 0-500 over 2 sec.
## Fs=1000; # sampled every 0.001 sec so rate is 1 kHz
## step=ceil(20*Fs/1000); # one spectral slice every 20 ms
## window=ceil(100*Fs/1000); # 100 ms data window
## specgram(x, 2^nextpow2(window), Fs, window, window-step);
##
## ## Speech spectrogram
## [x, Fs] = auload(file_in_loadpath("sample.wav")); # audio file
## step = fix(5*Fs/1000); # one spectral slice every 5 ms
## window = fix(40*Fs/1000); # 40 ms data window
## fftn = 2^nextpow2(window); # next highest power of 2
## [S, f, t] = specgram(x, fftn, Fs, window, window-step);
## S = abs(S(2:fftn*4000/Fs,:)); # magnitude in range 0<f<=4000 Hz.
## S = S/max(S(:)); # normalize magnitude so that max is 0 dB.
## S = max(S, 10^(-40/10)); # clip below -40 dB.
## S = min(S, 10^(-3/10)); # clip above -3 dB.
## imagesc(t, f, flipud(log(S))); # display in log scale
## @end group
## @end example
##
## The choice of window defines the time-frequency resolution. In
## speech for example, a wide window shows more harmonic detail while a
## narrow window averages over the harmonic detail and shows more
## formant structure. The shape of the window is not so critical so long
## as it goes gradually to zero on the ends.
##
## Step size (which is window length minus overlap) controls the
## horizontal scale of the spectrogram. Decrease it to stretch, or
## increase it to compress. Increasing step size will reduce time
## resolution, but decreasing it will not improve it much beyond the
## limits imposed by the window size (you do gain a little bit,
## depending on the shape of your window, as the peak of the window
## slides over peaks in the signal energy). The range 1-5 msec is good
## for speech.
##
## FFT length controls the vertical scale. Selecting an FFT length
## greater than the window length does not add any information to the
## spectrum, but it is a good way to interpolate between frequency
## points which can make for prettier spectrograms.
##
## After you have generated the spectral slices, there are a number of
## decisions for displaying them. First the phase information is
## discarded and the energy normalized:
##
## S = abs(S); S = S/max(S(:));
##
## Then the dynamic range of the signal is chosen. Since information in
## speech is well above the noise floor, it makes sense to eliminate any
## dynamic range at the bottom end. This is done by taking the max of
## the magnitude and some minimum energy such as minE=-40dB. Similarly,
## there is not much information in the very top of the range, so
## clipping to a maximum energy such as maxE=-3dB makes sense:
##
## S = max(S, 10^(minE/10)); S = min(S, 10^(maxE/10));
##
## The frequency range of the FFT is from 0 to the Nyquist frequency of
## one half the sampling rate. If the signal of interest is band
## limited, you do not need to display the entire frequency range. In
## speech for example, most of the signal is below 4 kHz, so there is no
## reason to display up to the Nyquist frequency of 10 kHz for a 20 kHz
## sampling rate. In this case you will want to keep only the first 40%
## of the rows of the returned S and f. More generally, to display the
## frequency range [minF, maxF], you could use the following row index:
##
## idx = (f >= minF & f <= maxF);
##
## Then there is the choice of colormap. A brightness varying colormap
## such as copper or bone gives good shape to the ridges and valleys. A
## hue varying colormap such as jet or hsv gives an indication of the
## steepness of the slopes. The final spectrogram is displayed in log
## energy scale and by convention has low frequencies on the bottom of
## the image:
##
## imagesc(t, f, flipud(log(S(idx,:))));
## @end deftypefn
function [S_r, f_r, t_r] = specgram(x, n = min(256, length(x)), Fs = 2, window = hanning(n), overlap = ceil(length(window)/2))
if nargin < 1 || nargin > 5
print_usage;
## make sure x is a vector
elseif columns(x) != 1 && rows(x) != 1
error ("specgram data must be a vector");
endif
if columns(x) != 1, x = x'; endif
## if only the window length is given, generate hanning window
if length(window) == 1, window = hanning(window); endif
## should be extended to accept a vector of frequencies at which to
## evaluate the fourier transform (via filterbank or chirp
## z-transform)
if length(n)>1,
error("specgram doesn't handle frequency vectors yet");
endif
## compute window offsets
win_size = length(window);
if (win_size > n)
n = win_size;
warning ("specgram fft size adjusted to %d", n);
endif
step = win_size - overlap;
## build matrix of windowed data slices
offset = [ 1 : step : length(x)-win_size ];
S = zeros (n, length(offset));
for i=1:length(offset)
S(1:win_size, i) = x(offset(i):offset(i)+win_size-1) .* window;
endfor
## compute fourier transform
S = fft (S);
## extract the positive frequency components
if rem(n,2)==1
ret_n = (n+1)/2;
else
ret_n = n/2;
endif
S = S(1:ret_n, :);
f = [0:ret_n-1]*Fs/n;
t = offset/Fs;
if nargout==0
imagesc(t, f, 20*log10(abs(S)));
set (gca (), "ydir", "normal");
xlabel ("Time")
ylabel ("Frequency")
endif
if nargout>0, S_r = S; endif
if nargout>1, f_r = f; endif
if nargout>2, t_r = t; endif
endfunction
%!shared S,f,t,x
%! Fs=1000;
%! x = chirp([0:1/Fs:2],0,2,500); # freq. sweep from 0-500 over 2 sec.
%! step=ceil(20*Fs/1000); # one spectral slice every 20 ms
%! window=ceil(100*Fs/1000); # 100 ms data window
%! [S, f, t] = specgram(x);
%! ## test of returned shape
%!assert (rows(S), 128)
%!assert (columns(f), rows(S))
%!assert (columns(t), columns(S))
%!test [S, f, t] = specgram(x');
%!assert (rows(S), 128)
%!assert (columns(f), rows(S));
%!assert (columns(t), columns(S));
%!error (isempty(specgram([])));
%!error (isempty(specgram([1, 2 ; 3, 4])));
%!error (specgram)
%!demo
%! Fs=1000;
%! x = chirp([0:1/Fs:2],0,2,500); # freq. sweep from 0-500 over 2 sec.
%! step=ceil(20*Fs/1000); # one spectral slice every 20 ms
%! window=ceil(100*Fs/1000); # 100 ms data window
%!
%! ## test of automatic plot
%! [S, f, t] = specgram(x);
%! specgram(x, 2^nextpow2(window), Fs, window, window-step);
%!#demo # FIXME: Enable once we have an audio file to demo
%! ## Speech spectrogram
%! [x, Fs] = auload(file_in_loadpath("sample.wav")); # audio file
%! step = fix(5*Fs/1000); # one spectral slice every 5 ms
%! window = fix(40*Fs/1000); # 40 ms data window
%! fftn = 2^nextpow2(window); # next highest power of 2
%! [S, f, t] = specgram(x, fftn, Fs, window, window-step);
%! S = abs(S(2:fftn*4000/Fs,:)); # magnitude in range 0<f<=4000 Hz.
%! S = S/max(max(S)); # normalize magnitude so that max is 0 dB.
%! S = max(S, 10^(-40/10)); # clip below -40 dB.
%! S = min(S, 10^(-3/10)); # clip above -3 dB.
%! imagesc(flipud(20*log10(S)));
%!
%! % The image contains a spectrogram of 'sample.wav'
|