Fourier Series Example Script: Difference between revisions
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===Sampled Fourier Series=== |
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This is a script that plots a few terms of the Fourier series of a square wave and then plots some samples of it in red *'s. You can copy this and paste it into your editor and run it from octave or just paste it into an octave window to see the plot. |
This is a script that plots a few terms of the Fourier series of a square wave and then plots some samples of it in red *'s. You can copy this and paste it into your editor and run it from octave or just paste it into an octave window to see the plot. |
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legend('Five Terms','Five Terms Sampled') |
legend('Five Terms','Five Terms Sampled') |
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print("squarewave.png","-dpng") % Prints the plot to a png file called squarewave.png |
print("squarewave.png","-dpng") % Prints the plot to a png file called squarewave.png |
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===Fourier Series Solution for Sinusoidal Steady State Response of a Low Pass Filter=== |
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This goes with the [http://people.wallawalla.edu/~Rob.Frohne/ClassNotes/ENGR351/2010f/Background/index.php class notes for October 1, 2010.] |
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clf; |
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t=0:.01:10; |
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T=pi; |
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R=2; |
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C=1; |
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M=101; |
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vin=0; |
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current =0; |
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for n=1:2:M, |
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vin = vin+1./(n.*pi).*(3.*sin(pi.*n./2)-sin(3.*n.*pi./2)).*cos(2.*pi.*n.*t./T); |
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current = current+1./(sqrt(R.^2+1./((2.*pi.*n./T).^2*C.^2))).*1./(n.*pi).*(3.*sin(pi.*n./2)-sin(3.*n.*pi./2)).*cos(2.*pi.*n.*t. /T-atan2(-1,2*pi*n/T*R*C)); |
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end |
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vout=vin-R.*current; |
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plot(t,vin,'b-',t,vout) |
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title('Fourier Series Representation of a Square Wave') |
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xlabel('time (seconds)') |
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ylabel('Function') |
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grid on; |
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axis([0,10,-2,2]) |
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legend('Input Voltage','Output Voltage') |
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print("LowPass.png","-dpng") % Prints the plot to a png file called squarewave.png |
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The output produces a nice plot. |
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Revision as of 17:50, 6 October 2010
Sampled Fourier Series
This is a script that plots a few terms of the Fourier series of a square wave and then plots some samples of it in red *'s. You can copy this and paste it into your editor and run it from octave or just paste it into an octave window to see the plot.
% This script plots a Fourier Series for a Square Wave
clf;
t=0:.01:10;
T=2.5
M=50
sum1=0;
for m=1:2:M,
sum1 = sum1+4/m/pi*sin(m*pi/2)*cos(2*pi*m*t/T);
end
plot(t,sum1,'b-',t(1:10:end),sum1(1:10:end),'r*')
title('Fourier Series Representation of a Square Wave')
xlabel('time (seconds)')
ylabel('Function')
grid on;
axis([0,10,-2,2])
legend('Five Terms','Five Terms Sampled')
print("squarewave.png","-dpng") % Prints the plot to a png file called squarewave.png
Fourier Series Solution for Sinusoidal Steady State Response of a Low Pass Filter
This goes with the class notes for October 1, 2010.
clf;
t=0:.01:10;
T=pi;
R=2;
C=1;
M=101;
vin=0;
current =0;
for n=1:2:M,
vin = vin+1./(n.*pi).*(3.*sin(pi.*n./2)-sin(3.*n.*pi./2)).*cos(2.*pi.*n.*t./T);
current = current+1./(sqrt(R.^2+1./((2.*pi.*n./T).^2*C.^2))).*1./(n.*pi).*(3.*sin(pi.*n./2)-sin(3.*n.*pi./2)).*cos(2.*pi.*n.*t. /T-atan2(-1,2*pi*n/T*R*C));
end
vout=vin-R.*current;
plot(t,vin,'b-',t,vout)
title('Fourier Series Representation of a Square Wave')
xlabel('time (seconds)')
ylabel('Function')
grid on;
axis([0,10,-2,2])
legend('Input Voltage','Output Voltage')
print("LowPass.png","-dpng") % Prints the plot to a png file called squarewave.png
The output produces a nice plot.