Let A and B be square matrices (both stored column-wise) in R^{nxn} with B an Upper Triangular matrix. Write the MATLAB algorithm that gives C = A x B. Here's my algorithm function C = scalarMultRegUpper(A,B) [n,n] = size(A); [n,n]=size(B); C=zeros(n,n); for j=1:n for k=1:n for i=1:n C(i,j)=C(i,j) + B(k,j)*A(i,k); end end end Now, I'm asked to modify my algorithm to perform vector operations by eliminating the inner most for loop. How to do that? How will the algorithm change?

Modify an algorithm to perform vector operations by eliminating the...

Ameer Hamza on 19 Sep 2020

What is the relevance of B being an Upper Triangular matrix? You are using the naive algorithm of matrix multiplication. I think you are expected to use a more efficient version for the upper triangular matrix B. Also, vectorizing these loops can simply be replaced with

C = A*B;

Vladimir Sovkov on 19 Sep 2020

The most fundamental and beatuful thing about Matlab (matrix laboratory) is that it supports matrix operations, so you can compute that product in just one line of code: C = A*B;

Pascale Bou Chahine on 19 Sep 2020

Exactly Ameer, what is the more efficient version to exploit the special structure of B, being triangular? What would the algorithm be?

Ameer Hamza on 19 Sep 2020

I am not sure what is an optimal algorithm for this case. It seems like a home problem. Have you studied something similar?

Pascale Bou Chahine on 19 Sep 2020

No, but how can I modify my algorithm to show the special property of B?

Vladimir Sovkov on 19 Sep 2020

Edited: Vladimir Sovkov on 19 Sep 2020

If B is upper triangular, then B(k,j)=0 for k>(n+1-j) if the diagonal elements are nonzero (if they are zero, it is k>(n-j)). Hence in your code, you can restrict the k-loop to

for k=1:(n+1-j)

However anyway, C=A*B will work faster.

When working with big matrices having many zero elementss, using the sparse matrix format can be efficient, but I do not think it is justified for the triangular matrices; you can try it.

Pascale Bou Chahine on 19 Sep 2020

I tried running the algorithm with the modified k-loop as you suggested, and tried it for A = [3 2; 1 2], and B = [2 4; 0 4], and I got C = [6 12, 2 4]. However, C should be [6 20, 2 12]. What's the issue?

Pascale Bou Chahine on 19 Sep 2020

And what if both matrices, A and B, are upper triangular, how would this change my code?

Vladimir Sovkov on 19 Sep 2020

I implied that the upper triangular is the matrix of the form

, while in your undestanding (maybe, more common) it is

. This makes the things even easier:

for k=1:j

Rather obvious, isn't it?

Pascale Bou Chahine on 19 Sep 2020

Oh okay, thank you. And what would the algorithm be if both matrices were upper triangular (in my understanding)?

Vladimir Sovkov on 20 Sep 2020

Analogously. Analyze which elements of A are zero with every fixed k and exlude them from the loop over i. The product of upper triangular matrices is the upper triangular matrix.

Modify an algorithm to perform vector operations by eliminating the inner most for loop

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Modify an algorithm to perform vector operations by eliminating the inner most for loop

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