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Title kind of says it all and it seems straightforward, but I am having difficulties.

I would like to create a sine wave that decays in frequency exponentially at a power that I input. I have tried a bunch of different things and I either get gibberish, or what I believe is called an acoustic beat?

Gibberish example

In this example the array multiplier goes from 1->4. When I plot cos(70000000*t) and cos(4*70000000*t) both plots look fine, but the plot in the code below just looks like noise.

t = 1:.0000000004:1.0000004;
multiplier = linspace(1,2,1001).^-2;
reference_signal = cos(700000000*t.*multiplier);

Beat Example

t = 1:.0000000004:1.0000004;
mult = linspace(1,3,1001);

Does anyone have any thoughts on how I might create an array that represents a sinewave that is smoothly decaying in frequency exponentially?

Many Thanks

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It seems like changing my t value from t = 1:.0000000004:1.0000004; to t = 0:.0000000004:0.0000004; fixed it for me – PumpkinPie Apr 13 '14 at 4:08

2 Answers 2

up vote 2 down vote accepted

I think your problem is one of sampling - your sampling frequency is too low for the signal you are trying to represent.

I suggest that you debug by explicitly computing

freq = 7E8/(2*pi);
t = 1 + linspace(0, 4E-7, 1001);
multiplier = linspace(1,2,1001).^2;
omega_t = 2*pi*freq*t.*multiplier;
d_omega_t = diff(omega_t);

If d_omega_t becomes greater than pi, you know you have an aliasing problem- you need at least two points per cycle to reproduce a waveform faithfully (Nyquist theorem). This can be solved by using a higher sampling frequency (more points), or a lower frequency.

As it is, your multipliers of 1 and 4 look OK because the aliasing that is going on is constant - so you don't notice it is a problem.


I just ran the above with and without the +1 in the time variable - and it makes a big difference. The delta between two adjacent values is

2*pi*freq*(1 + t(n) - t(n-1)) * (mult(n) - mult(n-1))
2*pi*freq*(mult(n) - mult(n-1) + (t(n)-t(n-1)) * (mult(n)-mult(n-1))

This is a very large value because 2*pi*freq*(multi(n)-mult(n-1)) is a very large value.

When you leave out the +1 and do

t = linspace(0, 4E-7, 1001);
multiplier = linspace(1,2,1001).^-2;

things behave themselves as expected - the plot ends up looking like:

enter image description here

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+1 I was just typing a comment about insufficient sampling – Luis Mendo Apr 13 '14 at 3:35
So I believe I am sampling at 2.5 GHz, and the signal I am trying to create should start at 700 MHz and decay to say 300 MHz. So at worst I should be sampling at 3-4 more then the wave I am trying to create? – PumpkinPie Apr 13 '14 at 3:42
See my updated answer - the delta in the value is much larger than you think because of the +1 you have in the time variable. It took me a minute to convince myself that this made a very big difference. – Floris Apr 13 '14 at 4:05
Thanks for your help! Ahhhh, im still trying to understand whats happening but thanks for your insight, I got it to work better by dropping my start time to t = 0 – PumpkinPie Apr 13 '14 at 4:09
t = 0:0.0001:2*pi;
l = linspace(1,4,numel(t)).^2;
s = sin(t.*l);
figure,plot(t,fliplr(s)),axis tight

Produces the plot:

enter image description here

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Thanks, for some reason just changing my starting time value seemed to do the trick for me. – PumpkinPie Apr 13 '14 at 4:09
That is great to hear! – RDizzl3 Apr 13 '14 at 4:11

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