predictSurface {fields} | R Documentation |
Evaluates a fitted function or the prediction error as a surface that is suitable for plotting with the image, persp, or contour functions.
Description
Evaluates a a fitted model or the prediction error on a 2-D grid keeping any other variables constant. The resulting object is suitable for use with functions for viewing 3-d surfaces such as image, imagePlot and contour.
Usage
## Default S3 method:
predictSurface(object, grid.list = NULL,
extrap = FALSE, chull.mask = NA, nx = 80, ny = 80,
xy = c(1,2), verbose = FALSE, ...)
## S3 method for class 'fastTps'
predictSurface(object, gridList = NULL,
extrap = FALSE, chull.mask = NA, nx = 80, ny = 80,
xy = c(1,2), verbose = FALSE, ...)
## S3 method for class 'Krig'
predictSurface(object, grid.list = NULL, extrap = FALSE, chull.mask = NA,
nx = 80, ny = 80, xy = c(1, 2), verbose = FALSE, ZGrid = NULL,
drop.Z = FALSE, just.fixed=FALSE, ...)
## S3 method for class 'mKrig'
predictSurface(object, gridList = NULL, grid.list = NULL,
ynew =
NULL, extrap = FALSE, chull.mask = NA, nx = 80, ny =
80, xy = c(1, 2), verbose = FALSE, ZGrid = NULL,
drop.Z = FALSE, just.fixed = FALSE, fast = FALSE,
NNSize = 4, giveWarnings = FALSE, derivative = 0, ...)
mKrigFastPredict(object, gridList, ynew = NULL, derivative = 0, Z =
NULL, drop.Z = FALSE, NNSize = 5, setupObject = NULL,
giveWarnings = TRUE)
## Default S3 method:
predictSurfaceSE(object, grid.list = NULL, extrap = FALSE, chull.mask =
NA, nx = 80, ny = 80, xy = c(1, 2), verbose = FALSE,
ZGrid = NULL, just.fixed = FALSE, ...)
Arguments
object |
An object from fitting a function to data. In fields this is usually a Krig, mKrig, or fastTps object. |
gridList |
A list with as many components as variables describing the surface.
All components should have a single value except the two that give the
grid points for evaluation. If the matrix or data frame has column names,
these must appear in the grid list. See the grid.list help file for more
details. If this is omitted and the fit just depends on two variables the
grid will be made from the ranges of the observed variables.
(See the function |
grid.list |
Alternative to the |
giveWarnings |
If TRUE will warn when more than one observation is in a grid box. |
extrap |
Extrapolation beyond the range of the data. If |
chull.mask |
Whether to restrict the fitted surface to be on a convex hull, NA's are assigned to values outside the convex hull. chull.mask should be a sequence of points defining a convex hull. Default is to form the convex hull from the observations if this argument is missing (and extrap is false). |
nx |
Number of grid points in X axis. |
ny |
Number of grid points in Y axis. |
xy |
A two element vector giving the positions for the "X" and "Y"
variables for the surface. The positions refer to the columns of the x
matrix used to define the multidimensional surface. This argument is
provided in lieu of generating the grid list. If a 4 dimensional surface
is fit to data then |
drop.Z |
If TRUE the fixed part of model depending on covariates is omitted. |
just.fixed |
If TRUE the nonparametric surface is omitted. |
fast |
If TRUE approximate predictions for stationary models are made using the FFT. For large grids( e.g. nx, ny > 200) this can be substantially faster and still accurate to several decimal places. |
NNSize |
Order of nearest neighborhood used for fast prediction. The default, |
setupObject |
The object created explicitly using
|
derivative |
Predict the estimated derivatives of order |
ynew |
New data to use to refit the spatial model. Locations must be the same but if so this is efficient because the matrix decompositions are reused. |
... |
Any other arguments to pass to the predict function associated with the fit object. Some of the usual arguments for several of the fields fitted objects include:
|
ZGrid |
An array or list form of covariates to use for
prediction. This must match the same dimensions from the
If ZGrid is an array then the first two indices are the x and y
locations in the
grid. The third index, if present, indexes the covariates. e.g. For
evaluation on
a 10X15 grid and with 2 covariates. |
Z |
The covariates for the grid unrolled as a matrix. Columns index
the variables and rows index the grid locations. E.g. For
evaluation on a 10X15 grid and with 2 covariates. |
verbose |
If TRUE prints out some imtermediate results for debugging. |
Details
These function evaluate the spatial process or thin plate spline estimates on a regualr grid of points The grid can be specified using the grid.list/ gridList information or just the sizes.
For the standard Krig and mKrig versions the steps are to create a matrix of locations the represent the grid,
call the predict function for the object with these
points and also adding any extra arguments passed in the ... section,
and then reform the results as a surface object (as.surface). To
determine the what parts of the prediction grid are in the convex hull
of the data the function in.poly
is used. The argument
inflation in this function is used to include a small margin around
the outside of the polygon so that point on convex hull are
included. This potentially confusing modification is to prevent
excluding grid points that fall exactly on the ranges of the
data. Also note that as written there is no computational savings for
evaluting only the convex subset compared to the full grid.
For the "fast" option a stationary covariance function and resulting surface estimate is approximated by the covariance kernel restricted to the grid locations. In this way the approximate problem becomes a 2-d convolution. The evaluation of the approximate prediction surface uses a fast Fourier transform to compute the predicted values at the grid locations.
The nearest
neighbor argument NNSize
controls the number of covariance kernels
only evalauted at grid location used
to approximate a covariance function at an off-grid location. We have
found good results with NNSize=5
.
predictSurface.fastTps
is a specific version ( m=2, and k=2) of
Kriging with a compact covariance kernel (Wendland).
that can be much more efficient because it takes advantage of a low
level FORTRAN call to evaluate the covariance function. Use
predictSurface
or predict
for other choices of m and k.
predictSurface.Krig
is designed to also include covariates for the fixed in terms of grids.
predictSurface.mKrig
Similar in function to the Krig prediction function but it more efficient using the mKrig
fit object.
mKrigFastpredict
Although this function might be called at the top is it easier to use through the wrapper, predictSurface.mKrig
and fast=TRUE
.
NOTE: predict.surface
has been depreciated and just prints out
a warning when called.
Value
The usual list components for making image, contour, and perspective plots
(x,y,z) along with labels for the x and y variables. For
predictSurface.derivative
the component z
is a three
dimensional array with values( nx
, ny
, 2 )
See Also
Tps, Krig, predict, grid.list, make.surface.grid, as.surface, surface, in.poly
Examples
data( ozone2)
x<- ozone2$lon.lat
y<- ozone2$y[16,]
obj<- Tps( x,y)
# or try the alternative model:
# obj<- spatialProcess(x,y)
fit<- predictSurface( obj, nx=40, ny=40)
imagePlot( fit)
# predicting a 2d surface holding other variables fixed.
fit<- Tps( BD[,1:4], BD$lnya) # fit surface to data
# evaluate fitted surface for first two
# variables holding other two fixed at median values
out.p<- predictSurface(fit)
surface(out.p, type="C")
#
# plot surface for second and fourth variables
# on specific grid.
glist<- list( KCL=29.77, MgCl2= seq(3,7,,25), KPO4=32.13,
dNTP=seq( 250,1500,,25))
out.p<- predictSurface(fit, glist)
surface(out.p, type="C")
out.p<- predictSurfaceSE(fit, glist)
surface(out.p, type="C")
## a test of the fast prediction algorithm for use with
# mKrig/spatialProcess objects.
## Not run:
data(NorthAmericanRainfall)
x<- cbind(NorthAmericanRainfall$longitude,
NorthAmericanRainfall$latitude)
y<- log10(NorthAmericanRainfall$precip)
mKrigObject<- mKrig( x,log10(y),
lambda=.024,
cov.args= list( aRange= 5.87,
Covariance="Matern",
smoothness=1.0),
sigma2=.157
)
gridList<- list( x = seq(-134, -51, length.out = 100),
y = seq( 23, 57, length.out = 100))
# exact prediction
system.time(
gHat<- predictSurface( mKrigObject, gridList)
)
# aproximate
system.time(
gHat1<- predictSurface( mKrigObject, gridList,
fast = TRUE)
)
# don't worry about the warning ...
# just indicates some observation locations are located
# in the same grid box.
# approximation error omitting the NAs from outside the convex hull
stats( log10(abs(c(gHat$z - gHat1$z))) )
image.plot(gHat$x, gHat$y, (gHat$z - gHat1$z) )
points( x, pch=".", cex=.5)
world( add=TRUE )
## End(Not run)