constreg: Constrained Parametric Regression
In coneproj: Primal or Dual Cone Projections with Routines for Constrained Regression
constreg R Documentation
Constrained Parametric Regression
Description
The least-squares regression model y = X\beta + \varepsilon is considered, where the object is to find \beta to minimize
||y - X\beta||^2, subject to A\beta \ge 0.
Usage
constreg(y, xmat, amat, w = NULL, test = FALSE, nloop = 1e+4)
Arguments
y
A vector of length n.
xmat
A full column-rank design matrix. The column number of xmat must equal the length of \beta.
amat
A constraint matrix. The rows of amat must be irreducible. The column number of amat must equal the length of \beta.
w
An optional nonnegative vector of weights of length n. If w is not given, all weights are taken to equal 1. Otherwise, the minimization of (y - X\beta)'w(y - X\beta) over C is returned. The default is w = NULL.
test
A logical scalar. If test == TRUE, then the p-value for the test H_0:\beta is in V versus H_1:\beta is in C is returned. C is the constraint cone of the form \{\beta: A\beta \ge 0\}, and V is the null space of A. The default is test = FALSE.
nloop
The number of simulations used to get the p-value for the E_{01} test. The default is 1e+4.
Details
The hypothesis test H_0:\beta is in V versus H_1:\beta is in C is an exact one-sided test, and the test statistic is E_{01} = (SSE_0 - SSE_1)/SSE_0, which has a mixture-of-betas distribution when H_0 is true and \varepsilon is a vector following a standard multivariate normal distribution with mean 0. The mixing parameters are found through simulations. The number of simulations used to obtain the mixing distribution parameters for the test is 10,000. Such simulations usually take some time. For the "FEV" data set used as an example in this section, whose sample size is 654, the time to get a p-value is roughly 6 seconds.
The constreg function calls coneA for the cone projection part.
Value
constr.fit
The constrained fit of y given that \beta is in the cone C of the form \{\beta: A\beta \ge 0 \}.
unconstr.fit
The unconstrainted fit, i.e., the least-squares regression of y on the space spanned by X.
pval
The p-value for the hypothesis test H_0:\beta is in V versus H_1:\beta is in C. The constraint cone C has the form \{\beta: A\beta \ge 0 \} and V is the null space of A. If test == TRUE, a p-value is returned. Otherwise, the test is skipped and no p-value is returned.
coefs
The estimated constrained parameters, i.e., the estimation of the vector \beta.
Note
In the 3D plot of the "FEV" example, it is shown that the unconstrained fit increases as "age" increases when "height" is large, but decreases as "age" increases when "height" is small. This does not make sense, since "FEV" should not decrease with respect to "age" given any value of "height". The constrained fit avoids this situation by keeping the fit of "FEV" non-decreasing with respect to "age".
Author(s)
Mary C. Meyer and Xiyue Liao
References
Brunk, H. D. (1958) On the estimation of parameters restricted by inequalities.
The Annals of Mathematical Statistics 29 (2), 437–454.
Raubertas, R. F., C.-I. C. Lee, and E. V. Nordheim (1986) Hypothesis tests for normals
means constrained by linear inequalities. Communications in Statistics - Theory and
Methods 15 (9), 2809–2833.
Meyer, M. C. and J. C. Wang (2012) Improved power of one-sided tests. Statistics and
Probability Letters 82, 1619–1622.
Liao, X. and M. C. Meyer (2014) coneproj: An R package for the primal or dual cone projections with routines for constrained regression. Journal of Statistical Software 61(12), 1–22.
See Also
coneA
Examples
# load the FEV data set
data(FEV)
# extract the variables
y <- FEV$FEV
age <- FEV$age
height <- FEV$height
sex <- FEV$sex
smoke <- FEV$smoke
# scale age and height
scale_age <- (age - min(age)) / (max(age) - min(age))
scale_height <- (height - min(height)) / (max(height) - min(height))
# make xmat
xmat <- cbind(1, scale_age, scale_height, scale_age * scale_height, sex, smoke)
# make the constraint matrix
amat <- matrix(0, 4, 6)
amat[1, 2] <- 1; amat[2, 2] <- 1; amat[2, 4] <- 1
amat[3, 3] <- 1; amat[4, 3] <- 1; amat[4, 4] <- 1
# call constreg to get constrained coefficient estimates
ans1 <- constreg(y, xmat, amat)
bhat1 <- coef(ans1)
# call lm to get unconstrained coefficient estimates
ans2 <- lm(y ~ xmat[,-1])
bhat2 <- coef(ans2)
# create a 3D plot to show the constrained fit and the unconstrained fit
n <- 25
xgrid <- seq(0, 1, by = 1/n)
ygrid <- seq(0, 1, by = 1/n)
x1 <- rep(xgrid, each = length(ygrid))
x2 <- rep(ygrid, length(xgrid))
xinterp <- cbind(x1, x2)
xmatp <- cbind(1, xinterp, x1 * x2, 0, 0)
thint1 <- crossprod(t(xmatp), bhat1)
A1 <- matrix(thint1, length(xgrid), length(ygrid), byrow = TRUE)
thint2 <- crossprod(t(xmatp), bhat2)
A2 <- matrix(thint2, length(xgrid), length(ygrid), byrow = TRUE)
par(mfrow = c(1, 2))
par(mar = c(4, 1, 1, 1))
persp(xgrid, ygrid, A1, xlab = "age", ylab = "height",
zlab = "FEV", theta = -30)
title("Constrained Fit")
par(mar = c(4, 1, 1, 1))
persp(xgrid, ygrid, A2, xlab = "age", ylab = "height",
zlab = "FEV", theta = -30)
title("Unconstrained Fit")
coneproj documentation built on Oct. 15, 2023, 9:06 a.m.
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| constreg | R Documentation |
Constrained Parametric Regression
Description
The least-squares regression model y = X\beta + \varepsilon is considered, where the object is to find \beta to minimize
||y - X\beta||^2, subject to A\beta \ge 0.
Usage
constreg(y, xmat, amat, w = NULL, test = FALSE, nloop = 1e+4)
Arguments
y |
A vector of length |
xmat |
A full column-rank design matrix. The column number of xmat must equal the length of |
amat |
A constraint matrix. The rows of amat must be irreducible. The column number of amat must equal the length of |
w |
An optional nonnegative vector of weights of length |
test |
A logical scalar. If test == TRUE, then the p-value for the test |
nloop |
The number of simulations used to get the p-value for the |
Details
The hypothesis test H_0:\beta is in V versus H_1:\beta is in C is an exact one-sided test, and the test statistic is E_{01} = (SSE_0 - SSE_1)/SSE_0, which has a mixture-of-betas distribution when H_0 is true and \varepsilon is a vector following a standard multivariate normal distribution with mean 0. The mixing parameters are found through simulations. The number of simulations used to obtain the mixing distribution parameters for the test is 10,000. Such simulations usually take some time. For the "FEV" data set used as an example in this section, whose sample size is 654, the time to get a p-value is roughly 6 seconds.
The constreg function calls coneA for the cone projection part.
Value
constr.fit |
The constrained fit of |
unconstr.fit |
The unconstrainted fit, i.e., the least-squares regression of |
pval |
The p-value for the hypothesis test |
coefs |
The estimated constrained parameters, i.e., the estimation of the vector |
Note
In the 3D plot of the "FEV" example, it is shown that the unconstrained fit increases as "age" increases when "height" is large, but decreases as "age" increases when "height" is small. This does not make sense, since "FEV" should not decrease with respect to "age" given any value of "height". The constrained fit avoids this situation by keeping the fit of "FEV" non-decreasing with respect to "age".
Author(s)
Mary C. Meyer and Xiyue Liao
References
Brunk, H. D. (1958) On the estimation of parameters restricted by inequalities. The Annals of Mathematical Statistics 29 (2), 437–454.
Raubertas, R. F., C.-I. C. Lee, and E. V. Nordheim (1986) Hypothesis tests for normals means constrained by linear inequalities. Communications in Statistics - Theory and Methods 15 (9), 2809–2833.
Meyer, M. C. and J. C. Wang (2012) Improved power of one-sided tests. Statistics and Probability Letters 82, 1619–1622.
Liao, X. and M. C. Meyer (2014) coneproj: An R package for the primal or dual cone projections with routines for constrained regression. Journal of Statistical Software 61(12), 1–22.
See Also
coneA
Examples
# load the FEV data set
data(FEV)
# extract the variables
y <- FEV$FEV
age <- FEV$age
height <- FEV$height
sex <- FEV$sex
smoke <- FEV$smoke
# scale age and height
scale_age <- (age - min(age)) / (max(age) - min(age))
scale_height <- (height - min(height)) / (max(height) - min(height))
# make xmat
xmat <- cbind(1, scale_age, scale_height, scale_age * scale_height, sex, smoke)
# make the constraint matrix
amat <- matrix(0, 4, 6)
amat[1, 2] <- 1; amat[2, 2] <- 1; amat[2, 4] <- 1
amat[3, 3] <- 1; amat[4, 3] <- 1; amat[4, 4] <- 1
# call constreg to get constrained coefficient estimates
ans1 <- constreg(y, xmat, amat)
bhat1 <- coef(ans1)
# call lm to get unconstrained coefficient estimates
ans2 <- lm(y ~ xmat[,-1])
bhat2 <- coef(ans2)
# create a 3D plot to show the constrained fit and the unconstrained fit
n <- 25
xgrid <- seq(0, 1, by = 1/n)
ygrid <- seq(0, 1, by = 1/n)
x1 <- rep(xgrid, each = length(ygrid))
x2 <- rep(ygrid, length(xgrid))
xinterp <- cbind(x1, x2)
xmatp <- cbind(1, xinterp, x1 * x2, 0, 0)
thint1 <- crossprod(t(xmatp), bhat1)
A1 <- matrix(thint1, length(xgrid), length(ygrid), byrow = TRUE)
thint2 <- crossprod(t(xmatp), bhat2)
A2 <- matrix(thint2, length(xgrid), length(ygrid), byrow = TRUE)
par(mfrow = c(1, 2))
par(mar = c(4, 1, 1, 1))
persp(xgrid, ygrid, A1, xlab = "age", ylab = "height",
zlab = "FEV", theta = -30)
title("Constrained Fit")
par(mar = c(4, 1, 1, 1))
persp(xgrid, ygrid, A2, xlab = "age", ylab = "height",
zlab = "FEV", theta = -30)
title("Unconstrained Fit")
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