**You said you are using Octave 3.2.4, the latest now is 3.6.2, significantly outdated.**
ftp://ftp.gnu.org/gnu/octave/

**You said you are using signal package 1.0.11, the latest is 1.1.3, a little outdated.**
http://octave.sourceforge.net/signal/index.html

Whenever dealing with why functions won't work right, always grab the latest and greatest versions.

**Have you read the official octave documentation for the signal package function specgram?**

http://octave.sourceforge.net/signal/function/specgram.html

**And after you did that, have you run some of the demonstrations for specgram? Do they work for you?**

http://octave.sourceforge.net/signal/function/specgram.html

**Below is the source for specgram in octave, it contains comments on how it works. It may shed some light on how it is to be used correctly:**

```
## Copyright (C) 2000 Paul Kienzle
##
## This program is free software and may be used for any purpose. This
## copyright notice must be maintained. Paul Kienzle is not responsible
## for the consequences of using this software.
## usage: [S, f, t] = spectrogram(x, Fs, window, step, maxF, shape, minE)
##
## Generate a spectrogram for the signal. This chops the signal into
## overlapping slices, windows each slice and applies a Fourier
## transform to determine the frequency components at that slice.
##
## x: signal to analyse
## Fs: sampling rate for the signal
## window: analysis window length (default 30 msec)
## step: time between windows, start to start (default 5 ms)
## maxF: maximum frequency to display (default 4000 Hz)
## Alternatively, use [maxF, nF], where nF is the minimum
## of frequency points to display. If nF is greater than
## what it would normally be for the given window size and
## maximum displayed frequency, the FFT is zero-padded until
## it at least nF points are displayed on the y axis.
## shape: window analysis function (default 'hanning')
## Shape is any function which takes an integer n and returns
## a vector of length n. If shape contains %d and ends with
## ')', as for example '(1:%d)' or 'kaiser(%d,0.5)' do, then
## %d is replaced with the desired window length, and the
## expression is evaluated.
## minE: noise floor (default -40dB)
## Any value less than the noise floor is clipped before the
## spectrogram is displayed. This limits the dynamic range
## that your spectrogram must accomodate. Alternatively,
## use [minE, maxE], where maxE is the clipping ceiling, also
## in decibels.
##
## Return values
## S is the spectrogram in S with linear magnitude normalized to 1.
## f is the frequency indices corresponding to the rows of S.
## t is the time indices corresponding to the columns of S.
## If no return value is requested, the spectrogram is displayed instead.
##
## Global variables
## spectrogram_{window,step,maxF,nF,shape,minE,maxE} can override
## the default values with your own.
##
## To make a good spectrogram, generating spectral slices is only half
## the problem. Before you generate them, you must first choose your
## window size, step size and FFT size. A wide window shows more
## harmonic detail, a narrow window shows more formant structure. This
## defines your time-frequency resolution. Step size controls the
## horizontal scale of the spectrogram. Decrease it to stretch, or
## increase it to compress. Certainly, 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. Finally, FFT length controls the vertical scale, with
## larger values stretching the frequency range. Clearly, padding with
## zeros does not add any information to the spectrum, but it is a
## cheap, easy and good way to interpolate between frequency points, and
## can make for prettier spectrograms.
##
## After you have generated the spectral slices, there are a number of
## decisions for displaying them. Firstly, the entire frequency range
## does not need to be displayed. The frequency range of the FFT is
## determined by sampling rate. If most of your signal is below 4 kHz
## (in speech for example), there is no reason to display up to the
## Nyquist frequency of 10 kHz for a 20 kHz sampling rate. Next, there
## is the dynamic range of the signal. Since the 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 normalized magnitude and some lower limit such as -40 dB.
## Similarly, there is not much information in the very top of the
## range, so clipping to -3 dB makes sense there. Finally, 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.
## TODO: Accept vector of frequencies at which to sample the signal.
## TODO: Consider accepting maxF (values > 0), shape (value is string)
## TODO: and dynamic range (values <= 0) in any order.
## TODO: Consider defaulting step and maxF so that the spectrogram is
## TODO: an appropriate size for the screen (eg, 600x100).
## TODO: Consider drawing in frequency/time grid;
## TODO: (necessary with automatic sizing as suggested above)
## TODO: Consider using step vs. [nT, nF] rather than maxF vs [maxF, nF]
## TODO: Figure out why exist() is so slow: 50 ms vs 1 ms for lookup.
function [S_r, f_r, t_r] = spectrogram(x, Fs, window, step, maxF, shape, minE)
global spectrogram_window=30;
global spectrogram_step=5;
global spectrogram_maxF=4000;
global spectrogram_shape="hanning";
global spectrogram_minE=-40;
global spectrogram_maxE=0;
global spectrogram_nF=[];
if nargin < 2 || nargin > 7
usage ("[S, f, t] = spectrogram(x, fs, window, step, maxF, shape, minE)");
end
if nargin<3 || isempty(window),
window=spectrogram_window;
endif
if nargin<4 || isempty(step),
step=spectrogram_step;
endif
if nargin<5 || isempty(maxF),
maxF=spectrogram_maxF;
endif
if nargin<6 || isempty(shape),
shape=spectrogram_shape;
endif
if nargin<7 || isempty(minE),
minE=spectrogram_minE;
endif
if any(minE>0)
error ("spectrogram clipping range must use values less than 0 dB");
endif
if length(minE)>1,
maxE=minE(2);
minE=minE(1);
else
maxE = spectrogram_maxE;
endif
if length(maxF)>1,
min_nF=maxF(2);
maxF=maxF(1);
else
min_nF=spectrogram_nF;
endif
## make sure x is a column vector
if size(x,2) != 1 && size(x,1) != 1
error ("spectrogram data must be a vector");
end
if size(x,2) != 1, x = x'; end
if (maxF>Fs/2)
## warning("spectrogram: cannot display frequencies greater than Fs/2");
maxF = Fs/2;
endif
step_n = fix(step*Fs/1000); # one spectral slice every step ms
## generate window from duration and shape function name
win_n = fix(window*Fs/1000);
if shape(length(shape)) == ')'
shape = sprintf(shape, win_n);
else
shape = sprintf("%s(%d)", shape, win_n);
endif
win_vec = eval(strcat(shape,";"));
if size(win_vec,2) != 1, win_vec = win_vec'; endif
if size(win_vec,2) != 1 || size(win_vec,1) != win_n,
error("spectrogram %s did not return a window of length %d", \
shape, win_n);
endif
## FFT length from size of window and number of freq. pts requested
fft_n = 2^nextpow2(win_n); # next highest power of 2
dF = Fs/fft_n; # freq. step with current fft_n
nF = ceil(maxF(1)/dF); # freq. pts with current fft_n,maxF
if !isempty(min_nF) # make sure there are at least n freq. pts
if min_nF > nF, # if not enough
dF = maxF/min_nF; # figure out what freq. step we need
fft_n = 2^nextpow2(Fs/dF); # figure out what fft_n this requires
dF = Fs/fft_n; # freq. step with new fft_n
nF = ceil(maxF/dF); # freq. pts with new fft_n,maxF
endif
endif
## build matrix of windowed data slices
offset = 1:step_n:length(x)-win_n;
S = zeros (fft_n, length(offset));
for i=1:length(offset)
S(1:win_n, i) = x(offset(i):offset(i)+win_n-1) .* win_vec;
endfor
## compute fourier transform
S = fft (S);
S = abs(S(1:nF,:)); # select the desired frequencies
S = S/max(S(:)); # normalize magnitude so that max is 0 dB.
S = max(S, 10^(minE/10)); # clip below minF dB.
S = min(S, 10^(maxE/10)); # clip above maxF dB.
f = [0:nF-1]*Fs/fft_n;
t = offset/Fs;
if nargout==0
imagesc(f,t,20*log10(flipud(S)));
else
S_r = S;
f_r = f;
t_r = t;
endif
endfunction
```

**specgram Input:**

```
usage: [S [, f [, t]]] = specgram(x [, n [, Fs [, window [, overlap]]]])
x: vector of samples
n: size of fourier transform window, or [] for default=256
Fs: sample rate, or [] for default=2 Hz
window:shape of the fourier transform window, or [] for default=hanning(n)
Note:window length can be specified instead, in which case window=hanning(length)
overlap:overlap with previous window, or [] for default=length(window)/2
```

**specgram Output:**

```
S is complex output of the FFT, one row per slice
f is the frequency indices corresponding to the rows of S.
t is the time indices corresponding to the columns of S.
```