Efficient use of Choleski decomposition in R

Question

This question is related to this one and this one

I have two full rank matrices A₁, A₂ each of dimension p x p and a p-vector y.

These matrices are closely related in the sense that matrix A₂ is a rank one update of matrix A₁.

I'm interested in the vector

β₂ | (β₁, y, A₁, A₂, A₁^-1})

where

β₂ = (A₂' A₂)^-1(A₂'y)

and

β₁ = (A₁' A₁)^-1(A₁' y)

Now, in a previous question here I have been advised to estimate β₂ by the Choleski approach since the Choleski decomposition is easy to update using R functions such as chud() in package SamplerCompare.

Below are two functions to solve linear systems in R, the first one uses the solve() function and the second one the Choleski approach (the second one I can efficiently update).

fx01 <- function(ll,A,y) chol2inv(chol(crossprod(A))) %*% crossprod(A,y)

fx03 <- function(ll,A,y) solve(A,y)

p <- 5
A <- matrix(rnorm(p^2),p,p)
y <- rnorm(p)

system.time(lapply(1:1000,fx01,A=A,y=y))
system.time(lapply(1:1000,fx03,A=A,y=y))

My question is: for p small, both functions seems to be comparable (actually fx01 is even faster). But as I increase p, fx01 becomes increasingly slower so that for p = 100, fx03 is three times as fast as fx01.

What is causing the performance deterioration of fx01 and can it be improved/solved (maybe my implementation of the Choleski is too naive? Shouldn't I be using functions of the Choleski constellation such as backsolve, and if yes, how?

1. A %*% B is the R lingo for matrix multiplication of A by B.
2. crossprod(A,B) is the R lingo for A' B (ie transpose of A matrix multiplying the matrix/vector B).
3. solve(A,b) solves for x the linear system A x=b.
4. chol(A) is the Choleski decomposition of a PSD matrix A.
5. chol2inv computes (X' X)^-1 from the (R part) of the QR decomposition of X.

Answer 1

Your 'fx01' implementation is, as you mentioned, somewhat naive and is performing far more work than the 'fx03' approach. In linear algebra (my apologies for the main StackOverflow not supporting LaTeX!), 'fx01' performs:

• B := A' A in roughly n^3 flops.
• L := chol(B) in roughly 1/3 n^3 flops.
• L := inv(L) in roughly 1/3 n^3 flops.
• B := L' L in roughly 1/3 n^3 flops.
• z := A y in roughly 2n^2 flops.
• x := B z in roughly 2n^2 flops.

Thus, the cost looks very similar to 2n^3 + 4n^2, whereas your 'fx03' approach uses the default 'solve' routine, which likely performs an LU decomposition with partial pivoting (2/3 n^3 flops) and two triangle solves (plus pivoting) in 2n^2 flops. Your 'fx01' approach therefore performs three times as much work asymptotically, and this amazingly agrees with your experimental results. Note that if A was real symmetric or complex Hermitian, that an LDL^T or LDL' factorization and solve would only require half as much work.

With that said, I think that you should replace your Cholesky update of A' A with a more stable QR update of A, as I just answered in your previous question. A QR decomposition costs roughly 4/3 n^3 flops and a rank-one update to a QR decomposition is only O(n^2), so this approach only makes sense for general A when there is more than just one related solve that is simply a rank-one modification.