Mark's Homework 15
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Problem
Make a MATLAB script to do four times oversampling and a filter so as to eliminate as much as possible the effect of the D/A converter that follows the interpolation filter.
MATLAB Script
%Author: Mark Priddy %Homework #15 MATLAB script %Description: Demonstrates oversampling and cancelling of the effects of the D/A converter clear all; close all; %Number of sample points for our original signal N = 20; %Time, in seconds, to extend our original signal. We then sample this signal N times tmax=2; %Number of oversampling points oversampling = 4; %Calculations T=tmax/N; t=0:T:(N-1)*T; %This is our signal to over sample x=sin(2*pi*t)+sin(2*pi*2*t)+sin(2*pi*5*t); %The following three lines is our oversampling/interpolating filter N1=(oversampling-1)*N; X=fft(x); X1 = (N1+N)/N*[X(1:N/2), zeros(1, N1), X(N/2+1:N)]; %This preserves our interpolated signal for graphing later on x2= ifft(X1); % %This is to cancel out the effects of the D/A Converter % %sT is how many times we are going to sample our pulse p(t) sT = T*oversampling; %This is how wide our pulse has to be when we oversample stmax = oversampling*T; %This is the total number of sampling points for sampling p(t) sN = stmax/sT; t = 0:sT:stmax-sT; %This is p(t), the pulse of the D/A converter, sampled at our oversampling rate p = u(t+1e-9) - u(t-T/(2*oversampling)) + u(t - (oversampling*T-T/(2*oversampling))); %P(f) is calculated: P = fft(p); %Take 1/P(f) so we cancel the effects of the D/A converter (which is P(f)) iP = 1./P; %Element multiply our interpolating filter with our D/A converter effect canceller filter X1 = X1 .* iP; x1 = ifft(X1); % %Graphs % %Figure 1 plots the original signal and our interpolated signal (with D/A converter effects cancelled.) figure(1) t1 = 0:N/(N+N1)*T:(N-1/(N1+N))*T; t=0:T:(N-1)*T; plot(t1, x1, 'bo', t, x, 'r-o', t1, x2, 'g-'); legend('Interpolated signal with D/A effects cancelled', 'Original sampled signal', 'Interpolated oversampled signal') xlabel('Time (s)'); ylabel('Amplitude'); %Figure 2 plots just our interpolated signal, but this time with lines connecting each point. figure(2) plot(t1, x1, 'b-'); title('Interpolated oversampled signal'); xlabel('Time (s)'); ylabel('Amplitude'); %Figure 3 plots the frequency response of our original sampled signal. figure(3) f = -1/(2*T):1/(N*T):1/(2*T)-1/(N*T); plot(f,abs(fftshift(X))) title('Frequency response of the origianl signal'); xlabel('Frequency (Hz)'); ylabel('Amplitude');
To run this script, you'll also need another script, called "u.m" with the following contained inside. This must be located in the same folder as the main script above.
function [out] = u(t) out=(1+sign(t))./2; end
I couldn't find MATLAB's step function, so I created my own.
Graphs