I indicate matrices by capital letters, and vectors by small letters.
I need to solve the following system of linear inequalities for vector
min(rv - (u + Av), v - s) = 0
0 is a vector of zeros.
r is a scalar,
s are vectors, and
A is a matrix.
z = v-s,
B=rI - A,
q=-u + Bs, I can rewrite the previous problem as a linear complementarity problem and hope to use an LCP solver, for example from
LCP(M, z): min(Bz+q, z) = 0
or, in matrix notation:
z'(Bz+q) = 0 z >= 0 Bz + q >= 0
The problem is that my system of equations is huge. To create
- Create four matrices
- And stack them together as
A = scipy.sparse.bmat([[A11, A12], [A21, A22]])
- (This also means that
Ais not symmetric, and hence some efficient translations into
QPproblems won't work)
openopt.LCP apparently cannot deal with sparse matrices: When I ran this, my computer crashed. Generally,
A.todense() will lead to a memory error. Similarly,
compecon-python is not able to solve
LCP problems with sparse matrices.
LCP implementations are fit for this problem?
I really did not think sample data was required for a general "which tools to solve LCP" question were required, but anyways, here we go
from numpy.random import rand from scipy import sparse n = 3000 r = 0.03 A = sparse.diags([-rand(n)], ) s = rand(n,).reshape((-1, 1)) u = rand(n,).reshape((-1, 1)) B = sparse.eye(n)*r - A q = -u + B.dot(s) q.shape Out: (3000, 1) B Out: <3000x3000 sparse matrix of type '<class 'numpy.float64'>' with 3000 stored elements in Compressed Sparse Row format>
Some more pointers:
openopt.LCPcrashes with my matrices, I assume it converts the matrices to dense before continuing
compecon-pythonoutright fails with some error, it apparently requires dense matrices and has no fallback for sparsity
Bis not positive semi-definite, so I cannot rephrase the linear complementarity problem (LCP) as a convex quadratic problem (QP)
- All QP sparse solvers from this exposition require the problem to be convex, which mine is not
- In Julia, PATHSolver can solve my problem (given a license). However, there are problems calling it from Python with PyJulia (my issue report here)
- Also Matlab has an LCP solver that apparently can handle sparse matrices, but there implementation is even more wacky (and I really do not want to fallback on Matlab for this)