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https://github.com/watanabe-j/qfratio

R package for moments and distributions of ratios of quadratic forms
https://github.com/watanabe-j/qfratio

quadratic-forms r r-package rcpp rcppeigen zonal-polynomials

Last synced: 4 months ago
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R package for moments and distributions of ratios of quadratic forms

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README 

          
---

output: github_document

bibliography: vignettes/bibliography.bib

link-citations: TRUE

csl: vignettes/cran_style.csl

---



```{r, include = FALSE}

knitr::opts_chunk$set(

  collapse = TRUE,

  comment = "#>",

  fig.path = "man/figures/README-",

  out.width = "100%"

)

```

```{r setup, include = FALSE}

require(qfratio)

set.seed(64501)

```



# qfratio: R Package for Moments and Distributions of Ratios of Quadratic Forms



[![R-CMD-check](https://github.com/watanabe-j/qfratio/actions/workflows/R-CMD-check.yaml/badge.svg)](https://github.com/watanabe-j/qfratio/actions/workflows/R-CMD-check.yaml)



This package provides functions to evaluate moments of ratios

(and products) of quadratic forms in normal variables, specifically using

recursive algorithms developed by @BaoKan2013 and @HillierEtAl2014.

Generating functions for these moments are closely related to the

top-order zonal and invariant polynomials of matrix arguments.

It also provides some functions to evaluate distribution and density

functions of simple ratios of quadratic forms in normal variables

using several methods from @Imhof1961, @Hillier2001,

@Forchini2002[@Forchini2005], @ButlerPaolella2008, and @BrodaPaolella2009.



There exist a couple of `Matlab` programs developed by Raymond Kan

(available from ) for evaluating the

moments, but this `R` package is an independent project (not a fork or

translation) and has different functionalities, including evaluation of

moments of multiple ratios of a particular form and scaling to avoid numerical

overflow.

This has originally been developed for a biological application,

specifically for evaluating average evolvability measures in

evolutionary quantitative genetics [@Watanabe2023cevo], but can be used

for a broader class of statistics.



## Installation



***WARNING*** Installation size of this package can be very large

(>100 MB on Linux and macOS; ~3 MB on Windows with a recent version (`>= 4.2`)

of `Rtools`), as it involves lots of `RcppEigen` functions.



### From CRAN (stable version)

```{r eval = FALSE}

install.packages("qfratio")

```



### From GitHub (development version)

```{r eval = FALSE}

## Install devtools first:

# install.packages("devtools")



## Recommended installation (pandoc required):

devtools::install_github("watanabe-j/qfratio", dependencies = TRUE, build_vignettes = TRUE)



## Minimal installation:

# devtools::install_github("watanabe-j/qfratio")

```



### Dependencies



    Imports: Rcpp, MASS, stats

    LinkingTo: Rcpp, RcppEigen

    Suggests: mvtnorm, CompQuadForm, graphics, testthat (>= 3.0.0),

              knitr, rmarkdown



If installing from source, you also need [`pandoc`](https://pandoc.org) for

correctly building the vignette.

For `pandoc < 2.11`, `pandoc-citeproc` is required as well.

(Never mind if you use `RStudio`, which appears to have them bundled.)



## Examples



This package has two major functionalities: evaluating moments and

distribution function of ratios of quadratic forms in normal variables.



### Moments



This functionality concerns evaluation of the following moments:

$\mathrm{E} \left( \left( \mathbf{x}^T \mathbf{A} \mathbf{x} \right)^p /

\left( \mathbf{x}^T \mathbf{B} \mathbf{x} \right)^q \right)$ and

$\mathrm{E} \left( \left( \mathbf{x}^T \mathbf{A} \mathbf{x} \right)^p /

\left( \mathbf{x}^T \mathbf{B} \mathbf{x} \right)^q

\left( \mathbf{x}^T \mathbf{D} \mathbf{x} \right)^r \right)$,

where $\mathbf{x} \sim N_n \left(\boldsymbol{\mu}, \boldsymbol{\Sigma}\right)$.



These quantities are evaluated by `qfrm(A, B, p, q, ...)` and

`qfmrm(A, B, D, p, q, r, ...)`.

Because they are evaluated as partial sums of infinite series

[@Smith1989; @Smith1993; @BaoKan2013; @HillierEtAl2009; @HillierEtAl2014],

the evaluation results come with an error bound (where available), and

a `plot` method is defined for inspecting numerical convergence.

```{r, examples}

## Simple matrices

nv <- 4

A <- diag(1:nv)

B <- diag(sqrt(nv:1))



## Expectation of (x^T A x)^2 / (x^T x)^2 where x ~ N(0, I)

qfrm(A, p = 2)



## Compare with Monte Carlo mean

mean(rqfr(1000, A = A, p = 2))



## Expectation of (x^T A x)^1/2 / (x^T x)^1/2

(mom_A0.5 <- qfrm(A, p = 1/2))



## Monte Carlo mean

mean(rqfr(1000, A = A, p = 1/2))



plot(mom_A0.5)



## Expectation of (x^T x) / (x^T A^-1 x)

##   = "average conditional evolvability"

(avr_cevoA <- qfrm(diag(nv), solve(A)))



mean(rqfr(1000, A = diag(nv), B = solve(A), p = 1))

plot(avr_cevoA)



## Expectation of (x^T x)^2 / (x^T A x) (x^T A^-1 x)

##   = "average autonomy"

(avr_autoA <- qfmrm(diag(nv), A, solve(A), p = 2, q = 1, r = 1))



mean(rqfmr(1000, A = diag(nv), B = A, D = solve(A), p = 2, q = 1, r = 1))

plot(avr_autoA)



## Expectation of (x^T A B x) / ((x^T A^2 x) (x^T B^2 x))^1/2

##   = "average response correlation"

## whose Monte Carlo evaluation is called the "random skewers" analysis,

## while this is essentially an analytic solution (with slight truncation error)

(avr_rcorA <- qfmrm(crossprod(A, B), crossprod(A), crossprod(B),

                    p = 1, q = 1/2, r = 1/2))



mean(rqfmr(1000, A = crossprod(A, B), B = crossprod(A), D = crossprod(B),

           p = 1, q = 1/2, r = 1/2))

plot(avr_rcorA)



## More complex (but arbitrary) example

## Expectation of (x^T A x)^2 / (x^T B x)^3 where x ~ N(mu, Sigma)

mu <- 1:nv / nv

Sigma <- diag(runif(nv) * 3)

(mom_A2B3 <- qfrm(A, B, p = 2, q = 3, mu = mu, Sigma = Sigma,

                  m = 500, use_cpp = TRUE))

plot(mom_A2B3)

```



### Distributions



This functionality concerns evaluation of the (cumulative) distribution

function, probability density, and quantiles of

$\left( \mathbf{x}^T \mathbf{A} \mathbf{x} /

        \mathbf{x}^T \mathbf{B} \mathbf{x} \right) ^ p$,

where $\mathbf{x} \sim N_n \left(\boldsymbol{\mu}, \boldsymbol{\Sigma}\right)$.



These are implemented in `pqfr(quantile, A, B, p, ...)`,

`dqfr(quantile, A, B, p, ...)`, and `qqfr(probability, A, B, p, ...)`,

 whose usage mimics that of regular distribution-related functions.

```{r, examples_distr}

## Example parameters

nv <- 4

A <- diag(1:nv)

B <- diag(sqrt(nv:1))

mu <- 1:nv * 0.2

quantiles <- 0:nv + 0.5



## Distribution function and density of

## (x^T A x) / (x^T B x) where x ~ N(0, I)

pqfr(quantiles, A, B)

dqfr(quantiles, A, B)



## 95, 99, and 99.9 percentiles of the same

qqfr(c(0.05, 0.01, 0.001), A, B, lower.tail = FALSE)



## Comparing profiles

qseq <- seq.int(1 / sqrt(nv) - 0.2, nv + 0.2, length.out = 100)



## Generate p-value sequences for

## (x^T A x) / (x^T B x) where x ~ N(0, I) vs

## (x^T A x) / (x^T B x) where x ~ N(mu, I)

pseq_central <- pqfr(qseq, A, B)

pseq_noncent <- pqfr(qseq, A, B, mu = mu)



## Graphical comparison

plot(qseq, type = "n", xlim = c(1 / sqrt(nv), nv), ylim = c(0, 1),

     xlab = "q", ylab = "F(q)")

lines(qseq, pseq_central, col = "royalblue4", lty = 1)

lines(qseq, pseq_noncent, col = "tomato", lty = 2)

legend("topleft", legend = c("central", "noncentral"),

       col = c("royalblue4", "tomato"), lty = 1:2)



## Generate density sequences for

## (x^T A x) / (x^T B x) where x ~ N(0, I) vs

## (x^T A x) / (x^T B x) where x ~ N(mu, I)

dseq_central <- dqfr(qseq, A, B)

dseq_noncent <- dqfr(qseq, A, B, mu = mu)



## Graphical comparison

plot(qseq, type = "n", xlim = c(1 / sqrt(nv), nv), ylim = c(0, 0.7),

     xlab = "q", ylab = "f(q)")

lines(qseq, dseq_central, col = "royalblue4", lty = 1)

lines(qseq, dseq_noncent, col = "tomato", lty = 2)

legend("topright", legend = c("central", "noncentral"),

       col = c("royalblue4", "tomato"), lty = 1:2)

```



## Copyright notice



This package bundles selected `C` codes and part of `config.ac` from the

[GNU Scientific Library](https://www.gnu.org/software/gsl/),

whose copyright belongs to the original authors.

See `DESCRIPTION` and individual code files in `src/gsl` for details.

The redistribution complies with the GNU General Public License version 3.



## References