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#
# Copyright 2007-2020 by the individuals mentioned in the source code history
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
#The quadratic fitfunction in this model has a solution on a parameter boundary, a zero-gradient point outside the feasible space, and a
#Hessian matrix that is nowhere PD. OpenMx should warn about status code 5 (non-convex Hessian), but the optimizers themselves should be
#more-or-less satisfied if they reach the analytically correct solution.
library(OpenMx)
library(testthat)
mxOption(key="feasibility tolerance", value = .00001)
startvals <- c(-5.1, 2.9)
plan <- omxDefaultComputePlan()
plan$steps <- list(plan$steps$GD)
#plan$steps[[1]]$verbose <- 1L
m1 <- mxModel(
"BukinN2",
mxMatrix(type="Full",nrow=1,ncol=1,free=T,values=startvals[1],labels="x1",lbound=-15,ubound=-5,name="X1"),
mxMatrix(type="Full",nrow=1,ncol=1,free=T,values=startvals[2],labels="x2",lbound=-3,ubound=3,name="X2"),
mxAlgebra( 100*( (X2^2) - 0.01*(X1^2) + 1) + 0.01*(X1+10)^2,
name="BukinN2Func"),
#Interestingly, given an analytic gradient to NPSOL and SLSQP makes them FAIL to find the correct solution...
mxAlgebra(cbind(-1.98*X1 + 0.2, 200*X2), name="grad", dimnames=list(NULL,c("x1","x2"))),
mxFitFunctionAlgebra(algebra="BukinN2Func")#,gradient="grad")
)
m1 <- mxRun(m1)
summary(m1)
m1$output$gradient
omxCheckCloseEnough(coef(m1), c(-15,0), 0.1)
omxCheckCloseEnough(m1$output$fit, -124.7500, 5e-5)
omxCheckCloseEnough(m1$output$gradient[1],29.9,0.01)
omxCheckEquals(m1$output$status$code,5)
m2 <- mxModel(
"BukinN2",
plan,
mxMatrix(type="Full",nrow=1,ncol=1,free=T,values=startvals[1],labels="x1",lbound=-15,ubound=-5,name="X1"),
mxMatrix(type="Full",nrow=1,ncol=1,free=T,values=startvals[2],labels="x2",lbound=-3,ubound=3,name="X2"),
mxAlgebra( 100*( (X2^2) - 0.01*(X1^2) + 1) + 0.01*(X1+10)^2,
name="BukinN2Func"),
#Interestingly, given an analytic gradient to NPSOL and SLSQP makes them FAIL to find the correct solution...
mxAlgebra(cbind(-1.98*X1 + 0.2, 200*X2), name="grad", dimnames=list(NULL,c("x1","x2"))),
mxFitFunctionAlgebra(algebra="BukinN2Func")#,gradient="grad")
)
m2 <- mxRun(m2)
summary(m2)
m2$output$gradient
omxCheckCloseEnough(coef(m2), c(-15,0), 0.1)
omxCheckCloseEnough(m2$output$fit, -124.7500, 5e-5)
omxCheckTrue(m2$output$status$code %in% c(0,1))
#All 3 optimizers appear robust to redundant INequality constraints, even with infeasible start values:
startvals <- c(-4.9, 3.1)
m3 <- mxModel(
"BukinN2",
plan,
mxMatrix(type="Full",nrow=1,ncol=1,free=T,values=startvals[1],labels="x1",name="X1"),
mxMatrix(type="Full",nrow=1,ncol=1,free=T,values=startvals[2],labels="x2",name="X2"),
mxConstraint(X1 > -15, name="l1"),
mxConstraint(2*X1 > -30, name="redundant"),
mxConstraint(X1 < -5, name="u1"),
mxConstraint(X2 > -3, name="l2"),
mxConstraint(X2 < 3, name="u2"),
mxAlgebra( 100*( (X2^2) - 0.01*(X1^2) + 1) + 0.01*(X1+10)^2,
name="BukinN2Func"),
mxAlgebra(cbind(-1.98*X1 + 0.2, 200*X2), name="grad", dimnames=list(NULL,c("x1","X2"))),
mxFitFunctionAlgebra(algebra="BukinN2Func",gradient="grad")
)
expect_error(mxRun(m3), "'BukinN2.fitfunction' has a derivative entry for unrecognized parameter 'X2'")
colnames(m3$grad) <- c("x1","x2")
m3 <- mxRun(m3)
m3 <- mxRun(m3)
summary(m3)
omxCheckCloseEnough(coef(m3), c(-15,0), 0.1)
omxCheckCloseEnough(m3$output$fit, -124.7501, .0002)
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