| testcoef.sxenv {Renvlp} | R Documentation |
Hypothesis test of the coefficients of the scaled predictor envelope model
Description
This function tests the null hypothesis L * beta * R = A versus the alternative hypothesis L * beta * R ~= A, where beta is estimated under the scaled predictor envelope model.
Usage
testcoef.sxenv(m, L, R, A)
Arguments
m |
A list containing estimators and other statistics inherited from scale.xenv. |
L |
The matrix multiplied to beta on the left. It is a d1 by p matrix, while d1 is less than or equal to p. |
R |
The matrix multiplied to beta on the right. It is an r by d2 matrix, while d2 is less than or equal to r. |
A |
The matrix on the right hand side of the equation. It is a d1 by d2 matrix. |
Note that inputs L, R and A must be matrices, if not, use as.matrix to convert them.
Details
This function tests for hypothesis H0: L beta R = A, versus Ha: L beta R != A. The beta is estimated by the scaled envelope model in the predictor space. If L = Ip, R = Ir and A = 0, then the test is equivalent to the standard F test on if beta = 0. The test statistic used is vec(L beta R - A) hatSigma^-1 vec(L beta R - A)^T, where beta is the envelope estimator and hatSigma is the estimated asymptotic covariance of vec(L beta R - A). The reference distribution is chi-squared distribution with degrees of freedom d1 * d2.
Value
The output is a list that contains following components.
chisqStatistic |
The test statistic. |
dof |
The degrees of freedom of the reference chi-squared distribution. |
pValue |
p-value of the test. |
covMatrix |
The covariance matrix of vec(L beta R). |
Examples
data(sales)
Y <- sales[, 1:3]
X <- sales[, 4:7]
R <- rep(1, 4)
u <- u.sxenv(X, Y, R)
u
m <- sxenv(X, Y, 2, R)
L <- diag(4)
R <- as.matrix(c(1, 0, 0))
A <- matrix(0, 4, 1)
test.res <- testcoef.sxenv(m, L, R, A)
test.res