How to I compute partial derivatives of a function

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Mat Hunt
Mat Hunt el 11 de Ag. de 2016
Comentada: John D'Errico el 12 de Ag. de 2016
Suppose I have a function z=z(x,y), how do I numerically (not symbolically) compute the partial derivatives?
I know of the function gradient(f,dx) which computes general derivatives in one dimension, but what is I want to compute the function:
\frac{\partial^{4}z}{\partial x^{4}}+\frac{\partial^{2}z}{\partial y^{2}}
for example? So I would need to compute them separately. I would rather not do a finite difference solution as that would be a faff. Is there a way of using the gradient function at all?

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Respuestas (2)

Torsten
Torsten el 12 de Ag. de 2016
Compute the derivatives symbolically using "diff" and turn the result in a function handle using "matlabFunction".
Best wishes
Torsten.
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Mat Hunt
Mat Hunt el 12 de Ag. de 2016
No, mixed derivatives are not required this time, but I need to calculate a sixth order derivative in x and a second order derivative in y.
If I arrange Z as a meshgrid, I can look at doing gradient on separate rows and columns I suppose.
Torsten
Torsten el 12 de Ag. de 2016
Yes, exactly, you will have to loop over the rows or columns of the z-matrix.
Best wishes
Torsten.

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John D'Errico
John D'Errico el 12 de Ag. de 2016
High order partials can be difficult to estimate numerically, and to do so with full precision.
The tool derivest (found on the file exchange) can do a decent job though.
http://www.mathworks.com/matlabcentral/fileexchange/13490-adaptive-robust-numerical-differentiation
Consider this example function:
z = @(x,y) exp(-(x+2*y).^2);
z(-1,1)
ans =
0.36788
I'll define the variables x0 and y0 so that you can see how to use it. So we want to compute the 4 order partials around the point (x0,y0).
x0 = -1;
y0 = 1;
[dzdx4,ex] = derivest(@(x) z(x,y0),x0,'deriv',4)
dzdx4 =
-7.3576
ex =
3.4866e-08
[dzdy4,ey] = derivest(@(y) z(x0,y),y0,'deriv',4)
dzdy4 =
-117.72
ey =
1.7325e-06
The second returned argument is an error estimate that indicates how well it thinks it did the job. So I am getting roughly 8 significant digits of precision in each direction.
I did them separately before to see the error estimates also.
In one line do this:
D = derivest(@(x) z(x,y0),x0,'deriv',4) + ...
derivest(@(y) z(x0,y),y0,'deriv',4)
D =
-125.08
  2 comentarios
Mat Hunt
Mat Hunt el 12 de Ag. de 2016
Hi John,
I am solving a PDE using the Newton method, so my function isn't symbolic, it's just a series of numbers (for ease I am considering writing the matrix as a vector), so I can't write it as a function as it's technically a variable. So I don't know if I can write it as function handle.
John D'Errico
John D'Errico el 12 de Ag. de 2016
I NEVER said the problem needed to be symbolic, did I? In the example I showed, nothing was symbolic, just a function, z(x,y), as you said that you had. But you never said that all you really have is a series of numbers. Should I have known that? Oh, well. No. You cannot use derivest.
If you have no more than a list of numbers, then you need to generally need to use a finite difference approximation. Or you can use finite elements. There are lots of classic ways to solve PDES. Books of them, even.

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