www.slide4math.com

 

This is my version of explanation. I would suggest you to come up with your own explanation. The best way would be for you to try explain this to somebody else in your own words.

 

Following is my version of explanation, but this is just an example. You may come up with a better version.

 

 

 

Convolution - Differentiator

 

Convolution would be the one of the most important operations in engineering math. If you don't have any prior study and understanding on how Convolution works, it would not be easy to make sense out of it. For those who is not familiar with Convolution, I would suggest you to go through my descriptive note here.

 

 

 

 

 

Followings are the code that I wrote in Octave to creates all the plots shown in this page. You may copy these code and play with these codes. Change variables and try yourself until you get your own intuitive understanding.

 

< Code 1 >

 

x = [0 0.4 0.0 0.4 0.0];

 

sf = 20; % samples per bit

 

p_x = x;

 

if sf > 1

   for i = 2:sf

     p_x= [p_x ; x];

   end

   p_x = reshape(p_x,[],1);

 

end

 

a = 0.9;

t = 0:10;

k = 0.3;

chan = [0 1 -1 0 0 0 0 0 0 0 0 ];

 

cs = 31;

 

hFig = figure(1,'Position',[300 300 700 600]);

 

subplot(4,2,1);

stem(p_x,'MarkerFaceColor',[0 0 1],'color','blue');

axis([1 length(p_x) -1.0 1.0]);

title("data");

box on;

set(gca,'xticklabel',[]);

set(gca,'yticklabel',[]);

set(gca,'xtick',[]);

set(gca,'ytick',[]);

 

subplot(4,2,2);

stem(chan,'MarkerFaceColor',[1 0 0],'MarkerEdgeColor',[1 0 0],'color','red');

axis([1 length(p_x) -1.0 1.0]);

title("kernel");

box on;

set(gca,'xticklabel',[]);

set(gca,'yticklabel',[]);

set(gca,'xtick',[]);

set(gca,'ytick',[]);

 

subplot(4,2,[3 8]);

hold on;

s = p_x;

for i = 0:100

    if i < length(p_x)

       line([i i],[5 5+s(i+1)],'color','blue');

       plot(i,5+s(i+1),'bo');

    end;   

end;

line([-40 140],[5 5],'color','green');

 

k = flip(chan);

ks = length(k);

 

for i = 0:100

    if i < length(k)

       line([i-ks+cs i-ks+cs],[3 3+k(i+1)],'color','red');

       plot(i-ks+cs,3+k(i+1),'ro');

    end;   

end;  

line([-40 140],[3 3],'color','green');

 

y = conv(p_x(1:min([length(p_x) cs])),chan(1:min([length(chan) cs])));

y = y(1:cs);

for i = 0:200

    if i < length(y)

       line([i i],[1 1+y(i+1)],'color','black');

       plot(i,1+y(i+1),'ko');

    end;   

end;

line([-40 140],[1 1],'color','green');

 

rdx = min(cs,length(k));

rdy = 3.0;

rx = cs-rdx;

ry = 2.9;

rectangle('Position',[rx ry rdx rdy]);

 

line([cs cs],[1 1+y(end)],'color','red','LineWidth',3, 'Marker','o');

line([cs cs],[1 1+2],'color','red','LineWidth',0.5);

 

hold off;

axis([-50 150 0 6]);

tStr = sprintf("step = %d",cs);

title(tStr);

box on;

set(gca,'xticklabel',[]);

set(gca,'yticklabel',[]);

set(gca,'xtick',[]);

set(gca,'ytick',[]);