How to 'break' a Gaussian pulse into discrete parts in Matlab

Question

I need to break down a continuous Gaussian pulse into 50 discrete parts so I can use each of the 50 individual amplitudes in calculations. Here is what I've tried:

% Gauss pulse discretisation
tg = 20*10^(-3);         % pulse duration [sec]
B1 = 1;                  % max amplitude [muT]
t  = -tg/2:tg/50:tg/2;   % sampling times
sd = 0.25;               % pulse standard deviation
% pulse shape
p  = B1*exp(-((t-tg/2).^2)/(2*sd.^2));
plot(t,p);

However, the plot looks nothing like a Gaussian pulse of 20ms in duration! Is there a problem with how the sampling time is defined? For example if the sampling time is defined as

t  = -1:tg/50:1

then the pulse does look like a Gaussian but it is broken down in 5001 parts. Could someone please point me in the right direction?

what do you mean by "breaking down to discrete parts"? You mean representing it as a discrete signal in the time domain? — Itamar Katz, Nov 29 '15 at 07:18
For example, the 20 ms Gaussian shaped pulse to be discretised into 20 separate 1 ms rectangular pulses, each with a variable amplitude and no delay between them. — Fotaras, Nov 29 '15 at 14:48

score 0 · Accepted Answer · answered Nov 29 '15 at 20:00

In order for your Gaussian to look like a Gaussian when you plot it, you need to make sure that you: (1) sample it around it's center, (2) your sampling interval is much smaller than the standard deviation (SD), and (3) you sample at least 2 or 3 SDs to each side, so you can see the decay. So in your example, since the Gaussian is centered around tg\2, and since your SD is sd = 0.25 (btw the SD sets the pulse duration, not tg), extend the sampling interval, using the SD as a measure (and not tg), and move it so it is centered around the mean. It is easier to do all this using linspace:

t = linspace(-3*sd, 3*sd, 50) + tg\2;

If you further want a 20msec pulse duration, make sd in the order of 20msec, and not tg. Also note that "duration" is really a matter of definition for a Gaussian, as it extends to +- infinity. You have to define something like "pulse duration is from -2 SDs to +2 SDs", which means the effective pulse duration is defined according to how much the tail decayed.

% Gauss pulse discretisation
tg = 0;         % pulse center [sec]
B1 = 1;         % max amplitude [muT]
sd = .5*20*10^(-3);% half the pulse duration (msec)
t  = tg/2 + linspace(-3*sd,3*sd,50);  
% pulse shape
p  = B1*exp(-((t-tg/2).^2)/(2*sd.^2));
plot(t,p,'.-');

Right. So the **sd** sets the duration. It makes sense now. Thanks for the clear explanation. — Fotaras, Nov 29 '15 at 21:53

How to 'break' a Gaussian pulse into discrete parts in Matlab

1 Answers1