do_ldet: Spatial regression model Jacobian computations

Description

These functions are made available in the package namespace for other developers, and are not intended for users. They provide a shared infrastructure for setting up data for Jacobian computation, and then for caclulating the Jacobian, either exactly or approximately, in maximum likelihood fitting of spatial regression models. The techniques used are the exact eigenvalue, Cholesky decompositions (Matrix, spam), and LU ones, with Chebyshev and Monte Carlo approximations; moments use the methods due to Martin and Smirnov/Anselin.

Usage

do_ldet(coef, env, which=1)
jacobianSetup(method, env, con, pre_eig=NULL, trs=NULL, interval=NULL, which=1)
cheb_setup(env, q=5, which=1)
mcdet_setup(env, p=16, m=30, which=1)
eigen_setup(env, which=1)
eigen_pre_setup(env, pre_eig, which=1)
spam_setup(env, pivot="MMD", which=1)
spam_update_setup(env, in_coef=0.1, pivot="MMD", which=1)
Matrix_setup(env, Imult, super=as.logical(NA), which=1)
Matrix_J_setup(env, super=FALSE, which=1)
LU_setup(env, which=1)
LU_prepermutate_setup(env, coef=0.1, order=FALSE, which=1)
moments_setup(env, trs=NULL, m, p, type="MC", correct=TRUE, trunc=TRUE, eq7=TRUE, which=1)
SE_classic_setup(env, SE_method="LU", p=16, m=30, nrho=200, interpn=2000,
 interval=c(-1,0.999), SElndet=NULL, which=1)
SE_whichMin_setup(env, SE_method="LU", p=16, m=30, nrho=200, interpn=2000,
 interval=c(-1,0.999), SElndet=NULL, which=1)
SE_interp_setup(env, SE_method="LU", p=16, m=30, nrho=200,
 interval=c(-1,0.999), which=1)
can.be.simmed(listw)

Value

do_ldet returns the value of the Jacobian for the calculation method recorded in the environment argument, and for the Monte Carlo approximation, returns a measure of the spread of the approximation as an “sd” attribute; the remaining functions modify the environment in place as a side effect and return nothing.

Arguments

coef: spatial coefficient value
env: environment containing pre-computed objects, fixed after assignment in setup functions
which: default 1; if 2, use second listw object
method: string value, used by jacobianSetup to choose method
con: control list passed from model fitting function and parsed in jacobianSetup to set environment variables for method-specific setup
pre_eig: pre-computed eigenvalues of length n
q: Chebyshev approximation order; default in calling spdep functions is 5, here it cannot be missing and does not have a default
p: Monte Carlo approximation number of random normal variables; default calling spdep functions is 16, here it cannot be missing and does not have a default
m: Monte Carlo approximation number of series terms; default in calling spdep functions is 30, here it cannot be missing and does not have a default; m serves the same purpose in the moments method
pivot: default “MMD”, may also be “RCM” for Cholesky decompisition using spam
in_coef: fill-in initiation coefficient value, default 0.1
Imult: see Cholesky; numeric scalar which defaults to zero. The matrix that is decomposed is A+m*I where m is the value of Imult and I is the identity matrix of order ncol(A). Default in calling spdep functions is 2, here it cannot be missing and does not have a default, but is rescaled for binary weights matrices in proportion to the maximim row sum in those calling functions
super: see Cholesky; logical scalar indicating is a supernodal decomposition should be created. The alternative is a simplicial decomposition. Default in calling spdep functions is FALSE for “Matrix_J” and as.logical(NA) for “Matrix”. Setting it to NA leaves the choice to a CHOLMOD-internal heuristic
order: default FALSE; used in LU_prepermutate, note warnings given for lu method
trs: A numeric vector of m traces, as from trW
type: moments trace type, see trW
correct: default TRUE: use Smirnov correction term, see trW
trunc: default TRUE: truncate Smirnov correction term, see trW
eq7: default TRUE; use equation 7 in Smirnov and Anselin (2009), if FALSE no unit root correction
SE_method: default “LU”, alternatively “MC”; underlying lndet method to use for generating SE toolbox emulation grid
nrho: default 200, number of lndet values in first stage SE toolbox emulation grid
interval: default c(-1,0.999) if interval argument NULL, bounds for SE toolbox emulation grid
interpn: default 2000, number of lndet values to interpolate in second stage SE toolbox emulation grid
SElndet: default NULL, used to pass a pre-computed two-column matrix of coefficient values and corresponding interpolated lndet values
listw: a spatial weights object

Author

Roger Bivand Roger.Bivand@nhh.no

Details

Since environments are containers in the R workspace passed by reference rather than by value, they are useful for passing objects to functions called in numerical optimisation, here for the maximum likelihood estimation of spatial regression models. This technique can save a little time on each function call, balanced against the need to access the objects in the environment inside the function. The environment should contain a family string object either “SAR”, “CAR” or “SMA” (used in do_ldet to choose spatial moving average in spautolm, and these specific objects before calling the set-up functions:

eigen

Classical Ord eigenvalue computations - either:

listw: A listw spatial weights object
can.sim: logical scalar: can the spatial weights be made symmetric by similarity
verbose: logical scalar: legacy report print control, for historical reasons only

or:

pre_eig: pre-computed eigenvalues

and assigns to the environment:

eig: a vector of eigenvalues
eig.range: the search interval for the spatial coefficient
method: string: “eigen”

Matrix

Sparse matrix pre-computed Cholesky decomposition with fast updating:

listw: A listw spatial weights object

can.sim

logical scalar: can the spatial weights be made symmetric by similarity

and assigns to the environment:

csrw: sparse spatial weights matrix
nW: negative sparse spatial weights matrix
pChol: a “CHMfactor” from factorising csrw with Cholesky
nChol: a “CHMfactor” from factorising nW with Cholesky
method: string: “Matrix”

Matrix_J

Standard Cholesky decomposition without updating:

listw: A listw spatial weights object

can.sim

logical scalar: can the spatial weights be made symmetric by similarity

number of spatial objects

and assigns to the environment:

csrw: sparse spatial weights matrix
I: sparse identity matrix
super: the value of the super argument
method: string: “Matrix_J”

spam

Standard Cholesky decomposition without updating:

listw: A listw spatial weights object

can.sim

logical scalar: can the spatial weights be made symmetric by similarity

number of spatial objects

and assigns to the environment:

csrw: sparse spatial weights matrix
I: sparse identity matrix
pivot: string --- pivot method
method: string: “spam”

spam_update

Pre-computed Cholesky decomposition with updating:

listw: A listw spatial weights object

can.sim

logical scalar: can the spatial weights be made symmetric by similarity

number of spatial objects

and assigns to the environment:

csrw: sparse spatial weights matrix
I: sparse identity matrix
csrwchol: A Cholesky decomposition for updating
method: string: “spam”

Standard LU decomposition without updating:

listw: A listw spatial weights object

number of spatial objects

and assigns to the environment:

W: sparse spatial weights matrix
I: sparse identity matrix
method: string: “LU”

LU_prepermutate

Standard LU decomposition with updating (pre-computed fill-reducing permutation):

listw: A listw spatial weights object

number of spatial objects

and assigns to the environment:

W: sparse spatial weights matrix
lu_order: order argument to lu
pq: 2-column matrix for row and column permutation for fill-reduction
I: sparse identity matrix
method: string: “LU”

Monte Carlo approximation:

listw: A listw spatial weights object

and assigns to the environment:

clx: list of Monte Carlo approximation terms (the first two simulated traces are replaced by their analytical equivalents)
W: sparse spatial weights matrix
method: string: “MC”

cheb

Chebyshev approximation:

listw: A listw spatial weights object

and assigns to the environment:

trT: vector of Chebyshev approximation terms
W: sparse spatial weights matrix
method: string: “Chebyshev”

moments

moments approximation:

listw: A listw spatial weights object

can.sim

logical scalar: can the spatial weights be made symmetric by similarity

and assigns to the environment:

trs: vector of traces, possibly approximated
q12: integer vector of length 2, unit roots terms, ignored until 0.5-52
eq7: logical scalar: use equation 7
correct: logical scalar: use Smirnov correction term
trunc: logical scalar: truncate Smirnov correction term
method: string: “moments”

SE_classic

listw: A listw spatial weights object

number of spatial objects

and assigns to the environment:

detval: two column matrix of lndet grid values
method: string: “SE_classic”
SE_method: string: “LU” or “MC”

SE_whichMin

listw: A listw spatial weights object

number of spatial objects

and assigns to the environment:

detval: two column matrix of lndet grid values
method: string: “SE_whichMin”
SE_method: string: “LU” or “MC”

SE_interp

listw: A listw spatial weights object

number of spatial objects

and assigns to the environment:

fit: fitted spline object from which to predict lndet values
method: string: “SE_interp”
SE_method: string: “LU” or “MC”

Some set-up functions may also assign similar to the environment if the weights were made symmetric by similarity.

Three set-up functions emulate the behaviour of the Spatial Econometrics toolbox (March 2010) maximum likelihood lndet grid performance. The toolbox lndet functions compute a smaller number of lndet values for a grid of coefficient values (spacing 0.01), and then interpolate to a finer grid of values (spacing 0.001). “SE_classic”, which is an implementation of the SE toolbox code, for example in f_sar.m, appears to have selected a row in the grid matrix one below the correct row when the candidate coefficient value was between 0.005 and 0.01-fuzz, always rounding the row index down. A possible alternative is to choose the index that is closest to the candidate coefficient value (“SE_whichMin”). Another alternative is to fit a spline model to the first stage coarser grid, and pass this fitted model to the log likelihood function to make a point prediction using the candidate coefficient value, rather than finding the grid index (“SE_interp”).

References

LeSage J and RK Pace (2009) Introduction to Spatial Econometrics. CRC Press, Boca Raton, pp. 77--110.

Bivand, R. S., Hauke, J., and Kossowski, T. (2013). Computing the Jacobian in Gaussian spatial autoregressive models: An illustrated comparison of available methods. Geographical Analysis, 45(2), 150-179.

Examples

Run this code

data(boston, package="spData")
#require("spdep", quietly=TRUE)
lw <- spdep::nb2listw(boston.soi)
can.sim <- can.be.simmed(lw)
env <- new.env(parent=globalenv())
assign("listw", lw, envir=env)
assign("can.sim", can.sim, envir=env)
assign("similar", FALSE, envir=env)
assign("verbose", FALSE, envir=env)
assign("family", "SAR", envir=env)
eigen_setup(env)
get("similar", envir=env)
do_ldet(0.5, env)
rm(env)
env <- new.env(parent=globalenv())
assign("listw", lw, envir=env)
assign("can.sim", can.sim, envir=env)
assign("similar", FALSE, envir=env)
assign("verbose", FALSE, envir=env)
assign("family", "SAR", envir=env)
assign("n", length(boston.soi), envir=env)
eigen_pre_setup(env, pre_eig=eigenw(similar.listw(lw)))
do_ldet(0.5, env)
rm(env)
env <- new.env(parent=globalenv())
assign("listw", lw, envir=env)
assign("can.sim", can.sim, envir=env)
assign("similar", FALSE, envir=env)
assign("family", "SAR", envir=env)
assign("n", length(boston.soi), envir=env)
Matrix_setup(env, Imult=2, super=FALSE)
get("similar", envir=env)
do_ldet(0.5, env)
rm(env)
env <- new.env(parent=globalenv())
assign("listw", lw, envir=env)
assign("n", length(boston.soi), envir=env)
assign("can.sim", can.sim, envir=env)
assign("similar", FALSE, envir=env)
assign("family", "SAR", envir=env)
spam_setup(env)
get("similar", envir=env)
do_ldet(0.5, env)
rm(env)
env <- new.env(parent=globalenv())
assign("listw", lw, envir=env)
assign("n", length(boston.soi), envir=env)
assign("similar", FALSE, envir=env)
assign("family", "SAR", envir=env)
LU_setup(env)
get("similar", envir=env)
do_ldet(0.5, env)
rm(env)
env <- new.env(parent=globalenv())
assign("listw", lw, envir=env)
assign("n", length(boston.soi), envir=env)
assign("similar", FALSE, envir=env)
assign("family", "SAR", envir=env)
LU_prepermutate_setup(env)
get("similar", envir=env)
do_ldet(0.5, env)
rm(env)
env <- new.env(parent=globalenv())
assign("listw", lw, envir=env)
assign("similar", FALSE, envir=env)
assign("family", "SAR", envir=env)
cheb_setup(env, q=5)
get("similar", envir=env)
do_ldet(0.5, env)
rm(env)
env <- new.env(parent=globalenv())
assign("listw", lw, envir=env)
assign("n", length(boston.soi), envir=env)
assign("similar", FALSE, envir=env)
assign("family", "SAR", envir=env)
set.seed(12345)
mcdet_setup(env, p=16, m=30)
get("similar", envir=env)
do_ldet(0.5, env)
rm(env)

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Description

Usage

Value

Arguments

Author

Details

References

See Also

Examples