Ads Below The Title

ADC and DAC using MATLAB

         Here we add some Gaussian noise to the input sine wave and then will will convert that to digital signal. This digital signal sampled data will be used in Modelsim. In the modelsim we develop moving average filter using VHDL, this will filters the sampled data and writes into another file. Using the new updated sampled data we will regenerate the Analog signal.
 
                  

%ADC & DAC
clear all;
close all;
clc;
fs=500000;
% taking sampling frequency as 500kHz
fm=10000;
% input signal frequency 10kHz
t=1:200;     % displaying 200 samples
x=5*cos(2*pi*(fm/fs)*t);
%input sinusoidal signal
z=awgn(x,1);
% adding white Gaussian noise to the input signal with S/N=1
h=1:1000;
plot(t,x,'g','LineWidth',2);
% plotting input signal
hold on;
plot(t,z,'r','linewidth',1.5);
% plotting noisy signal
hold on;
stem(t,z);
hold on;     
Vd=-5:0.0390625:5; % step size =0.0390625, when n=8 bits
for i=1:256  
Vdelta(i)=(Vd(i)+Vd(i+1))/2;
% Quantization levels
end

 i=0:255;
binary= dec2bin(i);
% decimal to binary conversion
% Quantization of input signal

for i=1:200
    for j=1:256
        if(z(i)< Vd(1))
            z(i) = Vdelta(1);
        end
        if (z(i) > Vd(257))
            z(i) = Vdelta(256);
        end
        if(z(i) <= Vd(j+1) && z(i) >= Vd(j))
            z(i) = Vdelta(j);
        end
    end
end

% Encoding the Quantized data
for i=1:200
    for j=1:256
        if (z(i)==Vdelta(j))
            B_data(i,1:8) = binary(j,1:8);
        end
    end
end
% representing binary data in decimal
figure
for i=1:200
 B(i)=bin2dec(B_data(i,1:8));    
end


% First solution; writing Encoded data into ADC.txt file. The we will perfom
% Moving average filter operation in VHDL
f = fopen('ADC.txt', 'w');
for n = 1:200
    fprintf(f, '%s\n', B_data(n,1:8));
end
fclose(f);
subplot(221);
plot(x);
title('original sinwave','fontsize',12);
xlabel('--->time in 2us');
ylabel('--->amplitude in volts');
subplot(222);
plot(z);
title('noise signal','fontsize',12);
xlabel('--->time in 2us');
ylabel('--->amplitude in volts');
% After the moving avg filter the filtered data has been written to vhdl_out.txt file
f=fopen('vhdl_out.txt','r');
A = fscanf(f,'%g',[1 inf]);
fclose(f);

subplot(224)
plot(B)
title('signal with white gaussian noise','fontsize',12);
xlabel('--->time in 2us');
ylabel('--->amplitude in decimal');
%Digital to Analog conversion
for i=1:192
    for j=1:256
      if(A(i)== j )
          outpt(i)=Vdelta(j);
      end
    end
end

subplot(223);
plot(outpt);
title('filtered sine wave sinewave output','fontsize',12);
xlabel('--->time in 2us');
ylabel('--->amplitude in decimal');

RESULT: 
Output data files 

ADC and DAC using MATLAB ADC and DAC using MATLAB       Reviewed by haru on April 03, 2013 Rating: 5

No comments

Ads Inter Below The Post
Image Link [https://lh3.googleusercontent.com/-wlvSkBWGUW0/AAAAAAAAAAI/AAAAAAAAAxU/6FpWSjn-h2o/s120-c/photo.jpg] Author Name [Sora Templates] Author Description [Lorem Ipsum is simply dummy text of the printing and typesetting industry. Lorem Ipsum has been the industry's standard] Facebook Username [#] Twitter Username [#] GPlus Username [#] Pinterest Username [#] Instagram Username [#]