poly {stats} | R Documentation |
Returns or evaluates orthogonal polynomials of degree 1 to
degree
over the specified set of points x
: these are all
orthogonal to the constant polynomial of degree 0. Alternatively,
evaluate raw polynomials.
poly(x, ..., degree = 1, coefs = NULL, raw = FALSE, simple = FALSE) polym (..., degree = 1, coefs = NULL, raw = FALSE) ## S3 method for class 'poly' predict(object, newdata, ...)
x, newdata |
a numeric vector at which to evaluate the
polynomial. |
degree |
the degree of the polynomial. Must be less than the
number of unique points when |
coefs |
for prediction, coefficients from a previous fit. |
raw |
if true, use raw and not orthogonal polynomials. |
simple |
logical indicating if a simple matrix (with no further
|
object |
an object inheriting from class |
... |
|
Although formally degree
should be named (as it follows
...
), an unnamed second argument of length 1 will be
interpreted as the degree, such that poly(x, 3)
can be used in
formulas.
The orthogonal polynomial is summarized by the coefficients, which can
be used to evaluate it via the three-term recursion given in Kennedy
& Gentle (1980, pp. 343–4), and used in the predict
part of
the code.
poly
using ...
is just a convenience wrapper for
polym
: coef
is ignored. Conversely, if polym
is
called with a single argument in ...
it is a wrapper for
poly
.
For poly
and polym()
(when simple=FALSE
and
coefs=NULL
as per default):
A matrix with rows corresponding to points in x
and columns
corresponding to the degree, with attributes "degree"
specifying
the degrees of the columns and (unless raw = TRUE
)
"coefs"
which contains the centering and normalization
constants used in constructing the orthogonal polynomials and
class c("poly", "matrix")
.
For poly(*, simple=TRUE)
, polym(*, coefs=<non-NULL>)
,
and predict.poly()
: a matrix.
This routine is intended for statistical purposes such as
contr.poly
: it does not attempt to orthogonalize to
machine accuracy.
R Core Team. Keith Jewell (Campden BRI Group, UK) contributed improvements for correct prediction on subsets.
Chambers, J. M. and Hastie, T. J. (1992) Statistical Models in S. Wadsworth & Brooks/Cole.
Kennedy, W. J. Jr and Gentle, J. E. (1980) Statistical Computing Marcel Dekker.
cars
for an example of polynomial regression.
od <- options(digits = 3) # avoid too much visual clutter (z <- poly(1:10, 3)) predict(z, seq(2, 4, 0.5)) zapsmall(poly(seq(4, 6, 0.5), 3, coefs = attr(z, "coefs"))) zm <- zapsmall(polym ( 1:4, c(1, 4:6), degree = 3)) # or just poly(): (z1 <- zapsmall(poly(cbind(1:4, c(1, 4:6)), degree = 3))) ## they are the same : stopifnot(all.equal(zm, z1, tol = 1e-15)) ## poly(<matrix>, df) --- used to fail till July 14 (vive la France!), 2017: m2 <- cbind(1:4, c(1, 4:6)) pm2 <- zapsmall(poly(m2, 3)) # "unnamed degree = 3" stopifnot(all.equal(pm2, zm, tol = 1e-15)) options(od)