This question is related to this one and this one

I have two full rank matrices **A _{1}, A_{2}** each
of dimension p x p and a p-vector y.

These matrices are closely related in the sense that
matrix **A _{2}** is a rank one update of matrix

**A**.

_{1}I'm interested in the vector

β

_{2}| (β_{1}, y,A,_{1}A,_{2}A_{1}^{-1}})

where

β

_{2}= (A'_{2}A)_{2}^{-1}(A'y)_{2}

and

β

_{1}= (A'_{1}A)_{1}^{-1}(A' y)_{1}

Now, in a previous question here I have been advised
to estimate β_{2} 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?

`A %*% B`

is the R lingo for matrix multiplication of A by B.`crossprod(A,B)`

is the R lingo for**A**'**B**(ie transpose of A matrix multiplying the matrix/vector B).`solve(A,b)`

solves for x the linear system**A**x=b.`chol(A)`

is the Choleski decomposition of a PSD matrix**A**.`chol2inv`

computes (**X**'**X**)^{-1}from the (R part) of the QR decomposition of**X**.