You first need to find the *envelope* of your oscillating function (the function that amplitude-modulates your sine). This can be done e.g. by rectifying the signal and then low-pass-filtering, but I choose to do a quick and dirty running maximum. After you found the envelope, there are various ways to fit an exponential function. I again chose a quick&dirty trick to do a first order polyfit to the log of the envelope. The code below works for the simple example you gave, but is might not work if you have an offset, if you choose `n`

wrong, etc. It also won't give the best possible result in case of a noisy measurement.

```
fsamp = 1e5;
tmax = 0.1;
t=0:1/fsamp:tmax;
f = 12e3; %should be smaller than fsamp/2!
tau = 0.0765;
y=sin(2 * pi * f * t) .* exp(-t / tau);
%calculate running maximum
n = 20; %number of points to take max over
nblocks = floor(length(t) / n);
trun = mean(reshape(t(1:n*nblocks), n, nblocks), 1); %n-point mean
envelope = max(reshape(y(1:n*nblocks), n, nblocks), [], 1); %n-point max
%quick and dirty exponential fit, not the proper way in case of noise
p = polyfit(trun, log(envelope), 1);
tau_fit = -1/p(1);
k_fit = exp(p(2));
plot(t, y, trun, envelope, 'or', t, k_fit * exp(-t / tau_fit), '-k')
title(sprintf('tau = %g', tau))
```

Note that with exponential decay, it is more common to define the time-constant `tau = 1 / d`

.

`d`

at a given frequency then what is`y`

? You're missing constraints. Otherwise, your equation can be solved for`d`

with basic algebra. If you have a particular waveform, you could look into the logarithmic decrement method. Otherwise, I'm not sure that this is a Matlab question. – horchler Aug 12 '13 at 17:29