secondDeriv: Numeric second derivatives
In tmcd82070/Rdistance: Distance-Sampling Analyses for Density and Abundance Estimation
secondDeriv R Documentation
Numeric second derivatives
Description
Computes numeric second derivatives (hessian) of an
arbitrary multidimensional function at a particular location.
Usage
secondDeriv(x, FUN, eps = 1e-08, ...)
Arguments
x
The location (a vector) where the second derivatives
of FUN are desired.
FUN
An R function for which the second derivatives are
sought.
This must be a function of the form FUN <- function(x, ...)...
where x is a vector of variable parameters to FUN at which
to evaluate the 2nd derivative,
and ... are additional parameters needed to evaluate the function.
FUN must return a single value (scalar), the height of the
surface above x, i.e., FUN evaluated at x.
eps
A vector of small relative
distances to add to x
when evaluating derivatives. This determines the 'dx' of
the numerical derivatives. That is, the function
is evaluated at x, x+dx, and x+2*dx, where
dx = x*eps^0.25, in order to compute the second
derivative.
eps defaults to 1e-8 for all
dimensions which equates to setting dx to one percent
of each x (i.e., by default the function is
evaluate at x, 1.01*x and 1.02*x
to compute the second derivative).
One might want to change eps if the scale
of dimensions in x varies wildly (e.g., kilometers and millimeters),
or if changes between
FUN(x) and FUN(x*1.01) are below machine precision.
If length of eps is less than length of x,
eps is replicated to the length of x.
...
Any arguments passed to FUN.
Details
This function uses the "5-point" numeric second derivative
method advocated in numerous numerical recipe texts. During computation
of the 2nd derivative, FUN must be
capable of being evaluated at numerous locations within a hyper-ellipsoid
with cardinal radii 2*x*(eps)^0.25 = 0.02*x at the
default value of eps.
A handy way to use this function is to call an optimization routine
like nlminb with FUN, then call this function with the
optimized values (solution) and FUN. This will yield the hessian
at the solution and this is can produce a better
estimate of the variance-covariance
matrix than using the hessian returned by some optimization routines.
Some optimization routines return the hessian evaluated
at the next-to-last step of optimization.
An estimate of the variance-covariance matrix, which is used in
Rdistance, is solve(hessian) where hessian is
secondDeriv(<parameter estimates>, <likelihood>).
Examples
func <- function(x){-x*x} # second derivative should be -2
secondDeriv(0,func)
secondDeriv(3,func)
func <- function(x){3 + 5*x^2 + 2*x^3} # second derivative should be 10+12x
secondDeriv(0,func)
secondDeriv(2,func)
func <- function(x){x[1]^2 + 5*x[2]^2} # should be rbind(c(2,0),c(0,10))
secondDeriv(c(1,1),func)
tmcd82070/Rdistance documentation built on April 10, 2024, 10:20 p.m.
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| secondDeriv | R Documentation |
Numeric second derivatives
Description
Computes numeric second derivatives (hessian) of an arbitrary multidimensional function at a particular location.
Usage
secondDeriv(x, FUN, eps = 1e-08, ...)
Arguments
x |
The location (a vector) where the second derivatives
of |
FUN |
An R function for which the second derivatives are
sought.
This must be a function of the form FUN <- function(x, ...)...
where x is a vector of variable parameters to FUN at which
to evaluate the 2nd derivative,
and ... are additional parameters needed to evaluate the function.
FUN must return a single value (scalar), the height of the
surface above |
eps |
A vector of small relative
distances to add to One might want to change |
... |
Any arguments passed to |
Details
This function uses the "5-point" numeric second derivative
method advocated in numerous numerical recipe texts. During computation
of the 2nd derivative, FUN must be
capable of being evaluated at numerous locations within a hyper-ellipsoid
with cardinal radii 2*x*(eps)^0.25 = 0.02*x at the
default value of eps.
A handy way to use this function is to call an optimization routine
like nlminb with FUN, then call this function with the
optimized values (solution) and FUN. This will yield the hessian
at the solution and this is can produce a better
estimate of the variance-covariance
matrix than using the hessian returned by some optimization routines.
Some optimization routines return the hessian evaluated
at the next-to-last step of optimization.
An estimate of the variance-covariance matrix, which is used in
Rdistance, is solve(hessian) where hessian is
secondDeriv(<parameter estimates>, <likelihood>).
Examples
func <- function(x){-x*x} # second derivative should be -2
secondDeriv(0,func)
secondDeriv(3,func)
func <- function(x){3 + 5*x^2 + 2*x^3} # second derivative should be 10+12x
secondDeriv(0,func)
secondDeriv(2,func)
func <- function(x){x[1]^2 + 5*x[2]^2} # should be rbind(c(2,0),c(0,10))
secondDeriv(c(1,1),func)
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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