# Extracting orthogonal polynomial coefficients from R's poly() function?

R's `poly()` function produces orthogonal polynomials for data fitting. However, I would like to use the results of the regression outside of R (say in C++), and there doesn't seem to be a way to get the coefficients for each orthogonal polynomial.

Note 1: I don't mean the regression coefficients, but the coefficients of the orthogonal polynomials themselves), e.g. the `p_i(x)` in

``````y = a0 + a1*p_1(x) + a2*p_2(x) + ...
``````

Note 2: I know `poly(x, n, raw=T)` forces poly to return non-orthogonal polynomials, but I want to regress against orthogonal polynomials, so that's what I'm looking for.

The polynomials are defined recursively using the `alpha` and `norm2` coefficients of the `poly` object you've created. Let's look at an example:

``````z <- poly(1:10, 3)
attributes(z)\$coefs
# \$alpha
# [1] 5.5 5.5 5.5
# \$norm2
# [1]    1.0   10.0   82.5  528.0 3088.8
``````

For notation, let's call `a_d` the element in index `d` of `alpha` and let's call `n_d` the element in index `d` of `norm2`. `F_d(x)` will be the orthogonal polynomial of degree `d` that is generated. For some base cases we have:

``````F_0(x) = 1 / sqrt(n_2)
F_1(x) = (x-a_1) / sqrt(n_3)
``````

The rest of the polynomials are recursively defined:

``````F_d(x) = [(x-a_d) * sqrt(n_{d+1}) * F_{d-1}(x) - n_{d+1} / sqrt(n_d) * F_{d-2}(x)] / sqrt(n_{d+2})
``````

To confirm with `x=2.1`:

``````x <- 2.1
predict(z, newdata=x)
#               1         2         3
# [1,] -0.3743277 0.1440493 0.1890351
# ...

a <- attributes(z)\$coefs\$alpha
n <- attributes(z)\$coefs\$norm2
f0 <- 1 / sqrt(n[2])
(f1 <- (x-a[1]) / sqrt(n[3]))
# [1] -0.3743277
(f2 <- ((x-a[2]) * sqrt(n[3]) * f1 - n[3] / sqrt(n[2]) * f0) / sqrt(n[4]))
# [1] 0.1440493
(f3 <- ((x-a[3]) * sqrt(n[4]) * f2 - n[4] / sqrt(n[3]) * f1) / sqrt(n[5]))
# [1] 0.1890351
``````

The most compact way to export your polynomials to your C++ code would probably be to export `attributes(z)\$coefs\$alpha` and `attributes(z)\$coefs\$norm2` and then use the recursive formula in C++ to evaluate your polynomials.

• Excellent -- this is exactly what I was looking for. In the poly() documentation, mention was made of the 3-term recursion expression in Kennedy & Gentle 1980, but having left academia, I no longer have free access to journal publications, plus I thought there probably ought to be an easy way to do this in R. Thanks. – Gilead Nov 4 '14 at 14:07
• @Gilead yeah I saw that reference as well, but honestly I found it easier to just read the source code (lines 110-124) to figure it out. – josliber Nov 4 '14 at 16:20
• If anyone needs a C# implentation of this, which is particular well suited due to it's first-class function capabilties, it's detailed here: solores-software.net/post/… – zola25 May 2 at 13:25

Note 1: I don't mean the regression coefficients, but the coefficients of the orthogonal polynomials themselves), e.g. the `p_i(x)` in

``````y = a0 + a1*p_1(x) + a2*p_2(x) + ...
``````

As josliber mentions, the functions are constructed recursively and the most compact way of representing them is with the norms and "alpha" coefficients used by R. A C++ version using (Rcpp)Armadillo can look something like

``````// [[Rcpp::depends(RcppArmadillo)]]

namespace polycpp {
class poly_basis {
void scale_basis(arma::mat &X) const {
if(X.n_cols > 0)
X.each_row() /=
arma::sqrt(norm2.subvec(1L, norm2.n_elem - 1L)).t();
}

public:
arma::vec const alpha, norm2;

poly_basis(arma::vec const &alpha, arma::vec const &norm2):
alpha(alpha), norm2(norm2) {
for(size_t i = 0; i < norm2.size(); ++i)
if(norm2[i] <= 0.)
throw std::invalid_argument("invalid norm2");
if(alpha.n_elem + 2L != norm2.n_elem)
throw std::invalid_argument("invalid alpha");
}

/**
behaves like poly(x, degree). The orthogonal polynomial is returned by
reference.
*/
static poly_basis get_poly_basis
(arma::vec x, size_t const degree, arma::mat &X){
size_t const n = x.n_elem,
nc = degree + 1L;
double const x_bar = arma::mean(x);
x -= x_bar;
arma::mat XX(n, nc);
XX.col(0).ones();
for(size_t d = 1L; d < nc; d++){
double       * xx_new = XX.colptr(d);
double const * xx_old = XX.colptr(d - 1);
for(size_t i = 0; i < n; ++i, ++xx_new, ++xx_old)
*xx_new = *xx_old * x[i];
}

arma::mat R;
/* TODO: can be done smarter by calling LAPACK or LINPACK directly */
if(!arma::qr_econ(X, R, XX))
throw std::runtime_error("QR decomposition failed");

for(size_t c = 0; c < nc; ++c)
X.col(c) *= R.at(c, c);

arma::vec norm2(nc + 1L),
alpha(nc - 1L);
norm2[0] = 1.;
for(size_t c = 0; c < nc; ++c){
double z_sq(0),
x_z_sq(0);
double const *X_i = X.colptr(c);
for(size_t i = 0; i < n; ++i, ++X_i){
double const z_sq_i = *X_i * *X_i;
z_sq += z_sq_i;
if(c < degree)
x_z_sq += x[i] * z_sq_i;
}
norm2[c + 1] = z_sq;
if(c < degree)
alpha[c] = x_z_sq / z_sq + x_bar;
}

poly_basis out(alpha, norm2);
out.scale_basis(X);
return out;
}

/** behaves like predict(<poly>, newdata). */
arma::mat operator()(arma::vec const &x) const {
size_t const n = x.n_elem;
arma::mat out(n, alpha.n_elem + 1L);
out.col(0).ones();
if(alpha.n_elem > 0L){
out.col(1) = x;
out.col(1) -= alpha[0];
for(size_t c = 1; c < alpha.n_elem; c++){
double       * x_new  = out.colptr(c + 1L);
double const * x_prev = out.colptr(c),
* x_old  = out.colptr(c - 1L),
* x_i    = x.memptr();
double const fac = norm2[c + 1L] / norm2[c];
for(size_t i = 0; i < n; ++i, ++x_new, ++x_prev, ++x_old, ++x_i)
*x_new = (*x_i - alpha[c]) * *x_prev - fac * *x_old;
}
}

scale_basis(out);
return out;
}
};
} // namespace polycpp

// export the functions to R to show that we get the same
using namespace polycpp;
using namespace Rcpp;

// [[Rcpp::export(rng = false)]]
List my_poly(arma::vec const &x, unsigned const degree){
arma::mat out;
auto basis = poly_basis::get_poly_basis(x, degree, out);
return List::create(
Named("X") = out,
Named("norm2") = basis.norm2,
Named("alpha") = basis.alpha);
}

// [[Rcpp::export(rng = false)]]
arma::mat my_poly_predict(arma::vec const &x, arma::vec const &alpha,
arma::vec const &norm2){
poly_basis basis(alpha, norm2);
return basis(x);
}
``````

We can easily get rid of the Armadillo dependence if needed. I verify below that we get the same as the R function

``````set.seed(1L)
x <- rnorm(100)
Rp <- poly(x, degree = 4L)
Cp <- my_poly(x, 4L)

all.equal(unclass(Rp), Cp\$X[, -1L], check.attributes = FALSE)
#R> [1] TRUE
all.equal(attr(Rp, "coefs"),
lapply(Cp[c("alpha", "norm2")], drop))
#R> [1] TRUE

z <- rnorm(20)
Rpred <- predict(Rp, z)
Cpred <- my_poly_predict(z, Cp\$alpha, Cp\$norm2)
all.equal(Rpred, Cpred[, -1], check.attributes = FALSE)
#R> [1] TRUE
all.equal(Cp\$X, my_poly_predict(x, Cp\$alpha, Cp\$norm2))
#R> [1] TRUE
``````

A nice bonus, although it likely does not matter in practice, is that the new functions are faster

``````options(digits = 3)
microbenchmark::microbenchmark(
R = poly(x, degree = 4L), cpp = my_poly(x, 4L))
#R> Unit: microseconds
#R> expr    min     lq  mean median    uq   max neval
#R>    R 118.93 123.63 135.4  126.1 129.0 469.1   100
#R>  cpp   7.22   7.97  11.3   10.9  11.7  89.4   100
microbenchmark::microbenchmark(
R = predict(Rp, z), cpp = my_poly_predict(z, Cp\$alpha, Cp\$norm2))
#R> Unit: microseconds
#R> expr  min    lq  mean median    uq   max neval
#R>    R 18.6 19.20 20.50  19.43 19.89 92.86   100
#R>  cpp  1.2  1.39  1.92   1.98  2.23  8.85   100
``````