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:**

I made the answer a bit simpler (everything in one line, instead of adding the transposed, and included explanations, as requested:

```
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
```