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As per following the inital thread make efficient the copy of symmetric matrix in c-sharp from cMinor.

I would be quite interesting with some inputs in how to build a symmetric square matrix multiplication with one line vector and one column vector by using an array implementation of the matrix, instead of the classical

long s = 0;
List<double> columnVector = new List<double>(N); 
List<double> lineVector = new List<double>(N); 
//- init. vectors and symmetric square matrix m

for (int i=0; i < N; i++)
{
    for(int j=0; j < N; j++){
        s += lineVector[i] * columnVector[j] * m[i,j];
    }
}

Thanks for your input !

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3 Answers 3

up vote 3 down vote accepted

The line vector times symmetric matrix equals to the transpose of the matrix times the column vector. So only the column vector case needs to be considered.

Originally the i-th element of y=A*x is defined as

y[i] = SUM( A[i,j]*x[j], j=0..N-1 )

but since A is symmetric, the sum be split into sums, one below the diagonal and the other above

y[i] = SUM( A[i,j]*x[j], j=0..i-1) + SUM( A[i,j]*x[j], j=i..N-1 )

From the other posting the matrix index is

A[i,j] = A[i*N-i*(i+1)/2+j]  // j>=i
A[i,j] = A[j*N-j*(j+1)/2+i]  // j< i

For a N×N symmetric matrix A = new double[N*(N+1)/2];

In C# code the above is:

int k;
for(int i=0; i<N; i++)
{
    // start sum with zero
    y[i]=0;
    // below diagonal
    k=i;
    for(int j=0; j<=i-1; j++)
    {                    
        y[i]+=A[k]*x[j];
        k+=N-j-1;
    }
    // above diagonal
    k=i*N-i*(i+1)/2+i;
    for(int j=i; j<=N-1; j++)
    {
        y[i]+=A[k]*x[j];
        k++;
    }
}

Example for you to try:

| -7  -6  -5  -4  -3 | | -2 |   | 10 |
| -6  -2  -1   0   1 | | -1 |   | 16 |
| -5  -1   2   3   4 | |  0 | = | 22 |
| -4   0   3   5   6 | |  1 |   | 25 |
| -3   1   4   6   7 | |  7 |   | 25 |

To get the quadratic form do a dot product with the multiplication result vector x·A·y = Dot(x,A*y)

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Thanks for this pretty detailed answer and for providing the code, I have learned a lot in few lines. –  Sebastien Thuilliez May 24 '12 at 9:46
    
Just a small confirmation on my understanding. In this particular case using a square symmetric matrix we can consider both vector as column vectors (that we can name x & x'). Meaning that if I want to have multiplication result for both vectors, I can do it in one go by using for "below diagonal" code as y[i]+=A[k]*x[j]*x'[j]; and so on for "above diagonal". Am I correct ?! –  Sebastien Thuilliez May 24 '12 at 9:55
    
Well you wouldn't consider both x and x' in the same operation. So the statement y[i]+=A[k]*x[j]*x'[j] is not valid. Maybe you need to include an example in the original posting on what you are trying to do. Typically you do something like scalar = x'*A*x. –  ja72 May 24 '12 at 15:50
    
Consider also that the product of two symmetric matrices is not symmetric. –  ja72 May 24 '12 at 18:28
    
Thanks for the update –  Sebastien Thuilliez May 25 '12 at 6:59
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You could make matrix multiplication pretty fast with unsafe code. I have blogged about it.

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Correct. If the goal is speed, unsafe is the way to go. If the object is reduced size, then the reduced element approach referenced in OP is the way to go. –  ja72 May 23 '12 at 16:57
    
+1 for the unsafe approach and for the blog link. Thanks. –  Sebastien Thuilliez May 24 '12 at 9:46
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Making matrix multiplication as fast as possible is easy: Use a well-known library. Insane amounts of performance work has gone into such libraries. You cannot compete with that.

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