Thin plate spline smoothers are a special case of the isotropic splines discussed in Duchon (1977). A subset of this more
general class can be invoked by terms like s(x,z,bs="ds",m=c(1,.5)
in a gam
model formula.
In the notation of Duchon (1977) m is given by m[1]
(default value 2), while s is given by m[2]
(default value 0).
Duchon's (1977) construction generalizes the usual thin plate spline penalty as follows. The usual TPS penalty is given by the integral of the squared Euclidian norm of a vector of mixed partial mth order derivatives of the function w.r.t. its arguments. Duchon re-expresses this penalty in the Fourier domain, and then weights the squared norm in the integral by the Euclidean norm of the fourier frequencies, raised to the power 2s. s is a user selected constant taking integer values divided by 2. If d is the number of arguments of the smooth, then it is required that -d/2 < s < d/2. To obtain continuous functions we further require that m + s > d/2. If s=0 then the usual thin plate spline is recovered.
The construction is amenable to exactly the low rank approximation method given in Wood (2003) to thin plate splines, with similar
optimality properties, so this approach to low rank smoothing is used here. For large datasets the same subsampling approach as is used in the
tprs
case is employed here to reduce computational costs.
These smoothers allow the use of lower orders of derivative in the penalty than conventional thin plate splines, while still yielding continuous functions. For example, we can set m = 1 and s = d/2 - .5 in order to use first derivative penalization for any d (which has the advantage that the dimension of the null space of unpenalized functions is only d+1).
# S3 method for ds.smooth.spec
smooth.construct(object, data, knots)
# S3 method for duchon.spline
Predict.matrix(object, data)
An object of class "duchon.spline"
. In addition to the usual elements of a
smooth class documented under smooth.construct
, this object will contain:
A record of the shift applied to each covariate in order to center it around zero and avoid any co-linearity problems that might otehrwise occur in the penalty null space basis of the term.
A matrix of the unique covariate combinations for this smooth (the basis is constructed by first stripping out duplicate locations).
The matrix mapping the smoother parameters back to the parameters of a full Duchon spline.
The dimension of the space of functions that have zero wiggliness according to the wiggliness penalty for this term.
a smooth specification object, usually generated by a term s(...,bs="ds",...)
.
a list containing just the data (including any by
variable) required by this term,
with names corresponding to object$term
(and object$by
). The by
variable
is the last element.
a list containing any knots supplied for basis setup --- in same order and with same names as data
.
Can be NULL
Simon N. Wood simon.wood@r-project.org
The default basis dimension for this class is k=M+k.def
where M
is the null space dimension
(dimension of unpenalized function space) and k.def
is 10 for dimension 1, 30 for dimension 2 and 100 for higher dimensions.
This is essentially arbitrary, and should be checked, but as with all penalized regression smoothers, results are statistically
insensitive to the exact choise, provided it is not so small that it forces oversmoothing (the smoother's
degrees of freedom are controlled primarily by its smoothing parameter).
The constructor is not normally called directly, but is rather used internally by gam
.
To use for basis setup it is recommended to use smooth.construct2
.
For these classes the specification object
will contain
information on how to handle large datasets in their xt
field. The default is to randomly
subsample 2000 `knots' from which to produce a reduced rank eigen approximation to the full basis,
if the number of unique predictor variable combinations in excess of 2000. The default can be
modified via the xt
argument to s
. This is supplied as a
list with elements max.knots
and seed
containing a number
to use in place of 2000, and the random number seed to use (either can be
missing). Note that the random sampling will not effect the state of R's RNG.
For these bases knots
has two uses. Firstly, as mentioned already, for large datasets
the calculation of the tp
basis can be time-consuming. The user can retain most of the advantages of the
approach by supplying a reduced set of covariate values from which to obtain the basis -
typically the number of covariate values used will be substantially
smaller than the number of data, and substantially larger than the basis dimension, k
. This approach is
the one taken automatically if the number of unique covariate values (combinations) exceeds max.knots
.
The second possibility is to avoid the eigen-decomposition used to find the spline basis altogether and simply use
the basis implied by the chosen knots: this will happen if the number of knots supplied matches the
basis dimension, k
. For a given basis dimension the second option is
faster, but gives poorer results (and the user must be quite careful in choosing knot locations).
Duchon, J. (1977) Splines minimizing rotation-invariant semi-norms in Solobev spaces. in W. Shemp and K. Zeller (eds) Construction theory of functions of several variables, 85-100, Springer, Berlin.
Wood, S.N. (2003) Thin plate regression splines. J.R.Statist.Soc.B 65(1):95-114
Spherical.Spline
require(mgcv)
eg <- gamSim(2,n=200,scale=.05)
attach(eg)
op <- par(mfrow=c(2,2),mar=c(4,4,1,1))
b0 <- gam(y~s(x,z,bs="ds",m=c(2,0),k=50),data=data) ## tps
b <- gam(y~s(x,z,bs="ds",m=c(1,.5),k=50),data=data) ## first deriv penalty
b1 <- gam(y~s(x,z,bs="ds",m=c(2,.5),k=50),data=data) ## modified 2nd deriv
persp(truth$x,truth$z,truth$f,theta=30) ## truth
vis.gam(b0,theta=30)
vis.gam(b,theta=30)
vis.gam(b1,theta=30)
detach(eg)
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