For example: Here is the adjacency list(undirected), the third column is the weight.

1 2 3
1 3 4
1 4 5
2 3 4
2 5 8
2 4 7

++++++++++++++++++++++

that should be converted to:

``````   1  2  3  4  5

1     0  4  5  0
2  3     4  7  8
3  4  7     0  0
4  0  7  0     0
5  0  8  0  0
``````
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Why isn't the diagonal zero? And if you consider undirected connections, the matrix has to be symmetric. – Fraukje Oct 10 '13 at 12:40
I reformatted your matrix... is that what you were after? Why isn't it symmetrical? – Dan Oct 10 '13 at 12:45

You can use `sparse` matrix. Let `rows` be the first column, `cols` the second, and `s` the weight.

``````A = sparse([rows; cols],[cols; rows],[s; s]);
``````

If you want to see the matrix. use `full()`.

UPDATE:

``````list = [1 2 3
1 3 4
1 4 5
2 3 4
2 5 8
2 4 7];

rows = list(:,1)
cols = list(:,2)
s = list(:,3)
``````

Now, `rows`, `cols` and `s` contains the needed information. Sparse matrices need three vectors. Each row of the two first vectors, `rows` and `cols` is the index of the value given in the same row of `s` (which is the weight).

The sparse command assigns the value `s(k)` to the matrix element `adj_mat(rows(k),cols(k))`.

Since an adjacency matrix is symmetric, `A(row,col) = A(col,row)`. Instead of doing `[rows; cols]`, it is possible to first create the upper triangular matrix, and then add the transposed matrix to complete the symmetric matrix.

``````A = sparse([rows; cols],[cols; rows],[s; s]);
full(A)

A =
0   3   4   5   0
3   0   4   7   8
4   4   0   0   0
5   7   0   0   0
0   8   0   0   0
``````
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could you explain in detail? – Jusleong Oct 10 '13 at 12:41
@user2866942: See updated answer. – Stewie Griffin Oct 20 '13 at 14:38

It's really hard to tell what your'e asking. Is this right?

``````list = [1 2 3
1 3 4
1 4 5
2 3 4
2 5 8
2 4 7];

matrix = zeros(max(max(list(:, 1:2))));  %// Or just zeros(5) if you know you want a 5x5 result

matrix(sub2ind(size(matrix), list(:,1), list(:,2))) = list(:,3);  %// Populate the upper half
matrix = matrix + matrix'  %'// Find the lower half via symmetry

matrix =

0   3   4   5   0
3   0   4   7   8
4   4   0   0   0
5   7   0   0   0
0   8   0   0   0
``````
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