How to convert the X & Y value in a matrix format?

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Asyran Abdullah on 26 Sep 2018

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Commented: Asyran Abdullah on 26 Sep 2018

Hi, Given X and Y as follow:

area_length = 100;
area_width = area_length ;
x = round((area_length - 1) * (rand - 0) / (1 - 0) + 1); 
y = round((area_width - 1) * (rand - 0) / (1 - 0) + 1);

How to convert the X & Y value into matrix format? Because i want to add a weights for make i possible to perform a shortest path.

x= ;
y= ;
weights = rand ;%-ok
G = graph(x,y,weights); 
plot(G,'EdgeLabel',G.Edges.Weight);

Thanks for your help

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KSSV on 26 Sep 2018

YOu need to have those points to get the shortest path........do you have those points?

Asyran Abdullah on 26 Sep 2018

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Yes, this is the point:

x = round((area_length - 1) * (rand - 0) / (1 - 0) + 1); 
y = round((area_width - 1) * (rand - 0) / (1 - 0) + 1);

x&y show the coordinate of each nodes, and the value will repeatedly change. However i don't know how to change the value into matrix in order to find a shortest path.

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Answer 1

Walter Roberson on 26 Sep 2018

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Edited: Walter Roberson on 26 Sep 2018

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Your x and y calculated like the above define the coordinates of a single point. To do shortest path, you need multiple points.

I suggest,

N = 50;    %nodes
cutoff = 25;
area_length = 100;
area_width = area_length ;
x = round((area_length - 1) * (rand(N,1) - 0) / (1 - 0) + 1); 
y = round((area_width - 1) * (rand(N,1) - 0) / (1 - 0) + 1);   
A = squareform( pdist([x, y]) );
A(A > cutoff) = 0;
%and do any other tweaking for the A matrix
G = digraph(A);
plot(G, 'XData', x, 'YData', y);

and you can do shortest path calculations on G

With the above code, you could also use G = graph(A) to create undirected graphs, but if you do so then you would not be able to have asymmetric distance matrix. In the real world, there are cases where the transmit and receive path might not be the same.

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Asyran Abdullah on 26 Sep 2018

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Thanks Sir, it works!

N =  45;    %nodes
cutoff = 25;
area_length = 100;
area_width = area_length ;
x = round((area_length - 1) * (rand(N,1) - 0) / (1 - 0) + 1); 
y = round((area_width - 1) * (rand(N,1) - 0) / (1 - 0) + 1);   
A = squareform( pdist([x, y]) );
A(A > cutoff) = 0;
%and do any other tweaking for the A matrix
G =  graph(A ); 
G.Edges.W3 = randi(10, numedges(G) , 1); %laluan
G.Edges.Weight = G.Edges.W3; %weight
h = plot(G, 'XData', x, 'YData', y, 'EdgeLabel',G.Edges.Weight);
axis square;  
grid on 
G = rmedge(G, 1:numnodes(G), 1:numnodes(G)); 
 title('Finding Shortest Path on Random Node'); 
 path = shortestpath(G,1,45);
 highlight(h,path,'NodeColor','g','EdgeColor','g')