nelmin: Nelder-Mead Minimization Method
In adagio: Discrete and Global Optimization Routines
neldermead R Documentation
Nelder-Mead Minimization Method
Description
An implementation of the Nelder-Mead algorithm for derivative-free
optimization / function minimization.
Usage
neldermead( fn, x0, ..., adapt = TRUE,
tol = 1e-10, maxfeval = 10000,
step = rep(1.0, length(x0)))
neldermeadb(fn, x0, ..., lower, upper, adapt = TRUE,
tol = 1e-10, maxfeval = 10000,
step = rep(1, length(x0)))
Arguments
fn
nonlinear function to be minimized.
x0
starting point for the iteration.
adapt
logical; adapt to parameter dimension.
tol
terminating limit for the variance of function values;
can be made *very* small, like tol=1e-50.
maxfeval
maximum number of function evaluations.
step
size and shape of initial simplex; relative magnitudes of
its elements should reflect the units of the variables.
...
additional arguments to be passed to the function.
lower, upper
lower and upper bounds.
Details
Also called a ‘simplex’ method for finding the local minimum of a function
of several variables. The method is a pattern search that compares function
values at the vertices of the simplex. The process generates a sequence of
simplices with ever reducing sizes.
The simplex function minimisation procedure due to Nelder and Mead (1965),
as implemented by O'Neill (1971), with subsequent comments by Chambers and
Ertel 1974, Benyon 1976, and Hill 1978. For another elaborate implementation
of Nelder-Mead in R based on Matlab code by Kelley see package ‘dfoptim’.
eldermead can be used up to 20 dimensions (then ‘tol’ and ‘maxfeval’
need to be increased). With adapt=TRUE it applies adaptive
coefficients for the simplicial search, depending on the problem dimension
– see Fuchang and Lixing (2012). This approach especially reduces the
number of function calls.
With upper and/or lower bounds, neldermeadb applies transfinite
to define the function on all of R^n and to retransform the solution to the
bounded domain. Of course, if the optimum is near to the boundary, results
will not be as accurate as when the minimum is in the interior.
Value
List with following components:
xmin
minimum solution found.
fmin
value of f at minimum.
fcount
number of iterations performed.
restarts
number of restarts.
errmess
error message
Note
Original FORTRAN77 version by R O'Neill; MATLAB version by John Burkardt
under LGPL license. Re-implemented in R by Hans W. Borchers.
References
Nelder, J., and R. Mead (1965). A simplex method for function minimization.
Computer Journal, Volume 7, pp. 308-313.
O'Neill, R. (1971). Algorithm AS 47: Function Minimization Using a Simplex
Procedure. Applied Statistics, Volume 20(3), pp. 338-345.
J. C. Lagarias et al. (1998). Convergence properties of the Nelder-Mead
simplex method in low dimensions. SIAM Journal for Optimization, Vol. 9,
No. 1, pp 112-147.
Fuchang Gao and Lixing Han (2012). Implementing the Nelder-Mead simplex
algorithm with adaptive parameters. Computational Optimization and
Applications, Vol. 51, No. 1, pp. 259-277.
See Also
hookejeeves
Examples
## Classical tests as in the article by Nelder and Mead
# Rosenbrock's parabolic valley
rpv <- function(x) 100*(x[2] - x[1]^2)^2 + (1 - x[1])^2
x0 <- c(-2, 1)
neldermead(rpv, x0) # 1 1
# Fletcher and Powell's helic valley
fphv <- function(x)
100*(x[3] - 10*atan2(x[2], x[1])/(2*pi))^2 +
(sqrt(x[1]^2 + x[2]^2) - 1)^2 +x[3]^2
x0 <- c(-1, 0, 0)
neldermead(fphv, x0) # 1 0 0
# Powell's Singular Function (PSF)
psf <- function(x) (x[1] + 10*x[2])^2 + 5*(x[3] - x[4])^2 +
(x[2] - 2*x[3])^4 + 10*(x[1] - x[4])^4
x0 <- c(3, -1, 0, 1)
neldermead(psf, x0) # 0 0 0 0, needs maximum number of function calls
# Bounded version of Nelder-Mead
lower <- c(-Inf, 0, 0)
upper <- c( Inf, 0.5, 1)
x0 <- c(0, 0.1, 0.1)
neldermeadb(fnRosenbrock, c(0, 0.1, 0.1), lower = lower, upper = upper)
# $xmin = c(0.7085595, 0.5000000, 0.2500000)
# $fmin = 0.3353605
## Not run:
# Can run Rosenbrock's function in 30 dimensions in one and a half minutes:
neldermead(fnRosenbrock, rep(0, 30), tol=1e-20, maxfeval=10^7)
# $xmin
# [1] 0.9999998 1.0000004 1.0000000 1.0000001 1.0000000 1.0000001
# [7] 1.0000002 1.0000001 0.9999997 0.9999999 0.9999997 1.0000000
# [13] 0.9999999 0.9999994 0.9999998 0.9999999 0.9999999 0.9999999
# [19] 0.9999999 1.0000001 0.9999998 1.0000000 1.0000003 0.9999999
# [25] 1.0000000 0.9999996 0.9999995 0.9999990 0.9999973 0.9999947
# $fmin
# [1] 5.617352e-10
# $fcount
# [1] 1426085
# elapsed time is 96.008000 seconds
## End(Not run)
adagio documentation built on Oct. 26, 2023, 5:08 p.m.
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| neldermead | R Documentation |
Nelder-Mead Minimization Method
Description
An implementation of the Nelder-Mead algorithm for derivative-free optimization / function minimization.
Usage
neldermead( fn, x0, ..., adapt = TRUE,
tol = 1e-10, maxfeval = 10000,
step = rep(1.0, length(x0)))
neldermeadb(fn, x0, ..., lower, upper, adapt = TRUE,
tol = 1e-10, maxfeval = 10000,
step = rep(1, length(x0)))
Arguments
fn |
nonlinear function to be minimized. |
x0 |
starting point for the iteration. |
adapt |
logical; adapt to parameter dimension. |
tol |
terminating limit for the variance of function values;
can be made *very* small, like |
maxfeval |
maximum number of function evaluations. |
step |
size and shape of initial simplex; relative magnitudes of its elements should reflect the units of the variables. |
... |
additional arguments to be passed to the function. |
lower, upper |
lower and upper bounds. |
Details
Also called a ‘simplex’ method for finding the local minimum of a function of several variables. The method is a pattern search that compares function values at the vertices of the simplex. The process generates a sequence of simplices with ever reducing sizes.
The simplex function minimisation procedure due to Nelder and Mead (1965), as implemented by O'Neill (1971), with subsequent comments by Chambers and Ertel 1974, Benyon 1976, and Hill 1978. For another elaborate implementation of Nelder-Mead in R based on Matlab code by Kelley see package ‘dfoptim’.
eldermead can be used up to 20 dimensions (then ‘tol’ and ‘maxfeval’
need to be increased). With adapt=TRUE it applies adaptive
coefficients for the simplicial search, depending on the problem dimension
– see Fuchang and Lixing (2012). This approach especially reduces the
number of function calls.
With upper and/or lower bounds, neldermeadb applies transfinite
to define the function on all of R^n and to retransform the solution to the
bounded domain. Of course, if the optimum is near to the boundary, results
will not be as accurate as when the minimum is in the interior.
Value
List with following components:
xmin |
minimum solution found. |
fmin |
value of |
fcount |
number of iterations performed. |
restarts |
number of restarts. |
errmess |
error message |
Note
Original FORTRAN77 version by R O'Neill; MATLAB version by John Burkardt under LGPL license. Re-implemented in R by Hans W. Borchers.
References
Nelder, J., and R. Mead (1965). A simplex method for function minimization. Computer Journal, Volume 7, pp. 308-313.
O'Neill, R. (1971). Algorithm AS 47: Function Minimization Using a Simplex Procedure. Applied Statistics, Volume 20(3), pp. 338-345.
J. C. Lagarias et al. (1998). Convergence properties of the Nelder-Mead simplex method in low dimensions. SIAM Journal for Optimization, Vol. 9, No. 1, pp 112-147.
Fuchang Gao and Lixing Han (2012). Implementing the Nelder-Mead simplex algorithm with adaptive parameters. Computational Optimization and Applications, Vol. 51, No. 1, pp. 259-277.
See Also
hookejeeves
Examples
## Classical tests as in the article by Nelder and Mead
# Rosenbrock's parabolic valley
rpv <- function(x) 100*(x[2] - x[1]^2)^2 + (1 - x[1])^2
x0 <- c(-2, 1)
neldermead(rpv, x0) # 1 1
# Fletcher and Powell's helic valley
fphv <- function(x)
100*(x[3] - 10*atan2(x[2], x[1])/(2*pi))^2 +
(sqrt(x[1]^2 + x[2]^2) - 1)^2 +x[3]^2
x0 <- c(-1, 0, 0)
neldermead(fphv, x0) # 1 0 0
# Powell's Singular Function (PSF)
psf <- function(x) (x[1] + 10*x[2])^2 + 5*(x[3] - x[4])^2 +
(x[2] - 2*x[3])^4 + 10*(x[1] - x[4])^4
x0 <- c(3, -1, 0, 1)
neldermead(psf, x0) # 0 0 0 0, needs maximum number of function calls
# Bounded version of Nelder-Mead
lower <- c(-Inf, 0, 0)
upper <- c( Inf, 0.5, 1)
x0 <- c(0, 0.1, 0.1)
neldermeadb(fnRosenbrock, c(0, 0.1, 0.1), lower = lower, upper = upper)
# $xmin = c(0.7085595, 0.5000000, 0.2500000)
# $fmin = 0.3353605
## Not run:
# Can run Rosenbrock's function in 30 dimensions in one and a half minutes:
neldermead(fnRosenbrock, rep(0, 30), tol=1e-20, maxfeval=10^7)
# $xmin
# [1] 0.9999998 1.0000004 1.0000000 1.0000001 1.0000000 1.0000001
# [7] 1.0000002 1.0000001 0.9999997 0.9999999 0.9999997 1.0000000
# [13] 0.9999999 0.9999994 0.9999998 0.9999999 0.9999999 0.9999999
# [19] 0.9999999 1.0000001 0.9999998 1.0000000 1.0000003 0.9999999
# [25] 1.0000000 0.9999996 0.9999995 0.9999990 0.9999973 0.9999947
# $fmin
# [1] 5.617352e-10
# $fcount
# [1] 1426085
# elapsed time is 96.008000 seconds
## End(Not run)
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