Store the elements by row, where the
i-th row and
j-th column is stored in index
NC the number of columns. This applies to a non-symmetric general matrix.
To store a symmetric matrix of size
N you only need
N*(N+1)/2 elements in the array. You can assume that
i<=j such that the array indexes go like this:
k(i,j) = i*N-i*(i+1)/2+j i<=j //above the diagonal
k(i,j) = j*N-j*(j+1)/2+i i>j //below the diagonal
i = 0 .. N-1
j = 0 .. N-1
Example when N=5, the array indexes go like this
| 0 1 2 3 4 |
| 1 5 6 7 8 |
| 2 6 9 10 11 |
| 3 7 10 12 13 |
| 4 8 11 13 14 |
The total elements needed are
5*(5+1)/2 = 15 and thus the indexes go from
i-th diagonal has index
k(i,i) = i*(N+1)-i*(i+1)/2. So the 3rd row (
i=2) has diagonal index
k(2,2) = 2*(5+1)-2*(2+1)/2 = 9.
The last element of the
i-th row has index =
k(i,N) = N*(i+1)-i*(i+1)/2-1. So the last element of the 3rd row is
k(2,4) = 5*(2+1)-2*(2+1)/2-1 = 11.
The last part that you might need is how to go from the array index
k to the row
i and column
j. Again assuming that
i<=j (above the diagonal) the answer is
i(k) = (int)Math.Floor(N+0.5-Math.Sqrt(N*(N+1)-2*k+0.25))
j(k) = k + i*(i+1)/2-N*i
To check the above I run this for
k=0..14 and got the following results:
Which is correct!
To make the copy then just use
Array.Copy() on the elements which is super fast. Also to do operations such as addition and scaling you just need to work on the reduced elements in the array, and not on the full
N*N matrix. Matrix multiplication is a little tricky, but doable. Maybe you can ask another question for this if you want.