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numdiff
numerical gradient estimation
Calling Sequence
g=numdiff(fun,x [,dx])
Arguments
- fun
an external, Scilab function or list. See below for calling sequence, see also external for details about external functions.
- x
vector, the argument of the function
fun
- dx
vector, the finite difference step. Default value is
dx=sqrt(%eps)*(1+1d-3*abs(x))
- g
vector, the estimated gradient
Description
given a function fun(x)
from
R^n
to R^p
computes the matrix
g
such as
g(i,j) = (df_i)/(dx_j)
using finite difference methods. Uses an order 1 formula.
Without parameters, the function fun calling sequence is
y=fun(x)
, and numdiff can be called as
g=numdiff(fun,x)
. Else the function fun calling
sequence must be y=fun(x,param_1,pararm_2,..,param_q)
.
If parameters param_1,param_2,..param_q
exist then
numdiff
can be called as follow
g=numdiff(list(fun,param_1,param_2,..param_q),x)
.
See the derivative with respect to numerical accuracy issues and comparison between the two algorithms.
Examples
// example 1 (without parameters) // myfun is a function from R^2 to R : (x(1),x(2)) |--> myfun(x) function f=myfun(x) f=x(1)*x(1)+x(1)*x(2) endfunction x=[5 8] g=numdiff(myfun,x) // The exact gradient (i.e derivate belong x(1) :first component and derivate belong x(2): second component) is exact=[2*x(1)+x(2) x(1)] //example 2 (with parameters) // myfun is a function from R to R: x(1) |--> myfun(x) // myfun contains 3 parameters, a, b, c function f=myfun(x, a, b, c) f=(x+a)^c+b endfunction a=3; b=4; c=2; x=1 g2=numdiff(list(myfun,a,b,c),x) // The exact gradient, i.e derivate belong x(1), is : exact2=c*(x+a)^(c-1)
See Also
<< lsqrsolve | Optimisation et Simulation | optim >> |