# Multiplication, sum and Cholesky decomposition of sparse matrices

I'm trying to solve a system of differential equations involving variational inequalities. I'm currently using the LCP solver in LCPsolve.jl. I've profiled my code and found that the bottleneck is in lines 216-219 here. More specifically, the profiler highlights the multiplication and sum in:

``````H = Jk'*Jk + μ*I
``````

where `Jk` is a sparse matrix with size that varies within the `for` loop (but always smaller than 150x150) and

``````typeof(Jk) = SparseMatrixCSC{Float64, Int64}
typeof(μ) = Float64
``````

It also seems that those steps also allocate memory. The other operation highlighted by the profiler is

``````-(cholesky(H)\Jphi)
``````

where

``````typeof(H) = SparseMatrixCSC{Float64, Int64}
typeof(Jphi) = Vector{Float64}
``````

Is there a way to improve the performance and/or memory allocation of those steps? Thank you!

• I think this will be faster and more accurate if you use Qr rather than the normal equations. Feb 24 at 16:09
• Hi Oscar, could you provide more details? I have tried using `qr`. However, I'm not getting the same results when H is a sparse matrix. Here is what I mean: `A = rand(100,100); b = rand(100); x1 = A\b; Q, R = qr(A); x2 = inv(factorize(R))*(Q'*b); isapprox(x1, x2); A = sprand(100,100,0.1); b = rand(100); x1 = A\b; aux = qr(A); x2 = inv(factorize(aux.R))*(aux.Q'*b); isapprox(x1, x2);` In the second case with sparse matrix A, i'm not getting the same result. So I don't know how to implement your suggestion. Feb 24 at 19:14