Consider a set of points arranged on a grid of size N-by-M. I am trying to build the adjacency matrix such that neighboring points are connected.

For example, in a 3x3 grid with a graph:

``````1-2-3
| | |
4-5-6
| | |
7-8-9
``````

We should have the corresponding adjacency matrix:

``````+---+------------------------------------------------------+
|   |   1     2     3     4     5     6     7     8     9  |
+---+------------------------------------------------------+
| 1 |   0     1     0     1     0     0     0     0     0  |
| 2 |   1     0     1     0     1     0     0     0     0  |
| 3 |   0     1     0     0     0     1     0     0     0  |
| 4 |   1     0     0     0     1     0     1     0     0  |
| 5 |   0     1     0     1     0     1     0     1     0  |
| 6 |   0     0     1     0     1     0     0     0     1  |
| 7 |   0     0     0     1     0     0     0     1     0  |
| 8 |   0     0     0     0     1     0     1     0     1  |
| 9 |   0     0     0     0     0     1     0     1     0  |
+---+------------------------------------------------------+
``````

As a bonus, the solution should work for both 4- and 8-connected neighboring points, that is:

``````   o             o  o  o
o  X  o   vs.    o  X  o
o             o  o  o
``````

This the code that I have so far:

``````N = 3; M = 3;

for i=1:N
for j=1:M
k = sub2ind([N M],i,j);
if i>1
ii=i-1; jj=j;
end
if i<N
ii=i+1; jj=j;
end
if j>1
ii=i; jj=j-1;
end
if j<M
ii=i; jj=j+1;
end
end
end
``````

How can this improved to avoid all the looping?

-
no this is no homework. My ultimate goal is to plot these points and draw lines between connected points as a graph. The interesting thing is that these points don't have to stay located on the grid.. –  Dave Jul 18 '10 at 23:11

If you notice, there is a distinct pattern to the adjacency matrices you are creating. Specifically, they are symmetric and banded. You can take advantage of this fact to easily create your matrices using the DIAG function (or the SPDIAGS function if you want to make a sparse matrix). Here is how you can create the adjacency matrix for each case, using your sample matrix above as an example:

4-connected neighbors

``````mat = [1 2 3; 4 5 6; 7 8 9];              %# Sample matrix
[r,c] = size(mat);                        %# Get the matrix size
diagVec1 = repmat([ones(c-1,1); 0],r,1);  %# Make the first diagonal vector
%#   (for horizontal connections)
diagVec1 = diagVec1(1:end-1);             %# Remove the last value
diagVec2 = ones(c*(r-1),1);               %# Make the second diagonal vector
%#   (for vertical connections)
diag(diagVec2,c);
%#   copy of itself to make it
%#   symmetric
``````

And you'll get the following matrix:

``````adj =

0     1     0     1     0     0     0     0     0
1     0     1     0     1     0     0     0     0
0     1     0     0     0     1     0     0     0
1     0     0     0     1     0     1     0     0
0     1     0     1     0     1     0     1     0
0     0     1     0     1     0     0     0     1
0     0     0     1     0     0     0     1     0
0     0     0     0     1     0     1     0     1
0     0     0     0     0     1     0     1     0
``````

8-connected neighbors

``````mat = [1 2 3; 4 5 6; 7 8 9];              %# Sample matrix
[r,c] = size(mat);                        %# Get the matrix size
diagVec1 = repmat([ones(c-1,1); 0],r,1);  %# Make the first diagonal vector
%#   (for horizontal connections)
diagVec1 = diagVec1(1:end-1);             %# Remove the last value
diagVec2 = [0; diagVec1(1:(c*(r-1)))];    %# Make the second diagonal vector
%#   (for anti-diagonal connections)
diagVec3 = ones(c*(r-1),1);               %# Make the third diagonal vector
%#   (for vertical connections)
diagVec4 = diagVec2(2:end-1);             %# Make the fourth diagonal vector
%#   (for diagonal connections)
diag(diagVec2,c-1)+...
diag(diagVec3,c)+...
diag(diagVec4,c+1);
%#   copy of itself to make it
%#   symmetric
``````

And you'll get the following matrix:

``````adj =

0     1     0     1     1     0     0     0     0
1     0     1     1     1     1     0     0     0
0     1     0     0     1     1     0     0     0
1     1     0     0     1     0     1     1     0
1     1     1     1     0     1     1     1     1
0     1     1     0     1     0     0     1     1
0     0     0     1     1     0     0     1     0
0     0     0     1     1     1     1     0     1
0     0     0     0     1     1     0     1     0
``````
-
I know there was a pattern I wasn't seeing, thank you –  Dave Jul 20 '10 at 1:37

Just for fun, here's a solution to construct the adjacency matrix by computing the distance between all pairs of points on the grid (not the most efficient way obviously)

``````N = 3; M = 3;                  %# grid size
CONNECTED = 8;                 %# 4-/8- connected points

%# which distance function
if CONNECTED == 4,     distFunc = 'cityblock';
elseif CONNECTED == 8, distFunc = 'chebychev'; end

[X Y] = meshgrid(1:N,1:M);
X = X(:); Y = Y(:);
adj = squareform( pdist([X Y], distFunc) == 1 );
``````

And here's some code to visualize the adjacency matrix and the graph of connected points:

``````%# plot adjacency matrix

%# plot connected points on grid
[xx yy] = gplot(adj, [X Y]);
subplot(122), plot(xx, yy, 'ks-', 'MarkerFaceColor','r')
axis([0 N+1 0 M+1])
[X Y] = meshgrid(1:N,1:M);
X = reshape(X',[],1) + 0.1; Y = reshape(Y',[],1) + 0.1;
text(X, Y(end:-1:1), cellstr(num2str((1:N*M)')) )
``````

-
+1 thats a clever way to build the matrix –  Dave Jul 20 '10 at 1:38

Your current code doesn't seem so bad. One way or another you need to iterate over all neighbor pairs. If you really need to optimize the code, I would suggest:

• loop over node indices i, where `1 <= i <= (N*M)`
• don't use sub2ind() for efficiency, the neighbors of node i are simpy `[i-M, i+1, i+M, i-1]` in clockwise order

Notice that to get all neighbor pairs of nodes:

• you only have to compute the "right" neighbors (i.e. horizontal edges) for nodes `i % M != 0` (since Matlab isn't 0-based but 1-based)
• you only have to compute "above" neighbors (i.e. vertical edges) for nodes `i > M`
• there is a similar rule for diagonal edges

This would leed to a single loop (but same number of N*M iterations), doesn't call sub2ind(), and has only two if statements in the loop.

-
thanks for the suggestions, I see that @jalexiou implemented most of them.. –  Dave Jul 20 '10 at 1:42
No problem. I see that jalexiou updated his post, the code he posted is IMHO the most readable and intuitive code of all the current posted solutions (although it can still be optimized a bit more). For instance Gnovice's solution exemplifies why i hate Matlab :p. O well, in Matlab it's probably more efficient. Good luck! –  catchmeifyoutry Jul 20 '10 at 10:08

I just found this question when searching for the same problem. However, none of the provided solutions worked for me because of the problem size which required the use of sparse matrix types. Here is my solution which works on large scale instances:

``````function W = getAdjacencyMatrix(I)

[m, n] = size(I);

I_size = m*n;

% 1-off diagonal elements
V = repmat([ones(m-1,1); 0],n, 1);
V = V(1:end-1); % remove last zero

% n-off diagonal elements
U = ones(m*(n-1), 1);

% get the upper triangular part of the matrix
W = sparse(1:(I_size-1),    2:I_size, V, I_size, I_size)...
+ sparse(1:(I_size-m),(m+1):I_size, U, I_size, I_size);

% finally make W symmetric
W = W + W';
``````
-

Just came across this question. I have a nice working m-function (link: `sparse_adj_matrix.m`) that is quite general.

It can handle 4-connect grid (radius 1 according to L1 norm), 8-connect grid (radius 1 according to L_infty norm).
It can also support 3D (and arbitrarily higher domensional grids).
The function can also connect nodes further than radius = 1.

Here's the signiture of the function:

``````
% Construct sparse adjacency matrix (provides ii and jj indices into the
% matrix)
%
% Usage:
%   [ii jj] = sparse_adj_matrix(sz, r, p)
%
% inputs:
%   sz - grid size (determine the number of variables n=prod(sz), and the
%        geometry/dimensionality)
%   r  - the radius around each point for which edges are formed
%   p  - in what p-norm to measure the r-ball, can be 1,2 or 'inf'
%
% outputs
%   ii, jj - linear indices into adjacency matrix (for each pair (m,n)
%   there is also the pair (n,m))
%
% How to construct the adjacency matrix?
% >> A = sparse(ii, jj, ones(1,numel(ii)), prod(sz), prod(sz));
%
%
% Example:
% >> [ii jj] = sparse_adj_matrix([10 20], 1, inf);
% construct indices for 200x200 adjacency matrix for 8-connect graph over a
% grid of 10x20 nodes.
% To visualize the graph:
% >> [r c]=ndgrid(1:10,1:20);
% >> A = sparse(ii, jj, 1, 200, 200);;
% >> gplot(A, [r(:) c(:)]);
``````
-
Shai, imagine I've a binary image (`100x200`) and I would like to obtain the valid 8-adjacencies only for the white pixels (`foreground`), i.e. in some cases some of the 8-neighbors of `(i,j)` are not valid since they might belong to background. I would like to obtain only the ones in the foreground. How could I build such an adjacency matrix using your `sparse_adj_matrix` script? –  Tin Apr 2 '14 at 13:38
An example of the binary image/ mask image is available in the following link: imgur.com/Wb432Sc –  Tin Apr 2 '14 at 14:14
@Tin once you have the indices of the pairs `ii` and `jj` you can select (using logical indexing) only the indices that belongs to white pixels. –  Shai Apr 3 '14 at 7:54
Thanks @Shai! I solved the issue :-) –  Tin Apr 3 '14 at 8:39

For each node in the graph add a connection to the right and one downwards. Check that you don't overreach your grid. Consider the following function that builds the adjacency matrix.

``````function  adj = AdjMatrixLattice4( N, M )
MN = M*N;

% number nodes as such
%  [1]---[2]-- .. --[M]
%   |     |          |
% [M+1]-[M+2]- .. -[2*M]
%   :     :          :
%   []    []   ..  [M*N]

for i=1:N
for j=1:N
A = M*(i-1)+j;          %Node # for (i,j) node
if(j<N)
B = M*(i-1)+j+1;    %Node # for node to the right
end
if(i<M)
B = M*i+j;          %Node # for node below
end
end
end
end
``````

Example as above `AdjMatrixLattice4(3,3)=`

`````` 0     1     0     1     0     0     0     0     0
1     0     1     0     1     0     0     0     0
0     1     0     0     0     1     0     0     0
1     0     0     0     1     0     1     0     0
0     1     0     1     0     1     0     1     0
0     0     1     0     1     0     0     0     1
0     0     0     1     0     0     0     1     0
0     0     0     0     1     0     1     0     1
0     0     0     0     0     1     0     1     0
``````
-
You are missing the point, I'm looking for a solution that will work for any values of N and M (grid size). I used 3x3 only as an example. –  Dave Jul 19 '10 at 2:52
I guess I missed that you wanted a fully connected graph. So now what is needed is a function to generate the connections vector based on a grid size. Actually two functions, one for the 4 connection scheme and one for the 8 connection scheme. See above for answer with 4 connections. –  ja72 Jul 19 '10 at 15:27
The 8-node scenario is more complicated because you have to decide if the connections can cross each other or not. –  ja72 Jul 19 '10 at 16:52

protected by ShaiOct 10 '13 at 12:09

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