问题
I'm trying to figure out how to solve a system of ODEs inside a subsystem in a Simulink model. Basically, each call to this subsystem, which happens at each tick of the simulation clock (fixed-step), entails solving the ODEs. So there's like a different "clock" for the subsystem.
I have an M-file that implements the function for the system of ODEs. Currently, I have a MATLAB Function block for that. It needs a lot of parameters that I can get from the base workspace (via evalin and using coder.extrinsic('evalin') at the beginning). But I'm not allowed to define function_handle objects or inner functions to parameterize the function that is used by ode*. I think that if I'm able to solve the ODEs in this block, I'll have solved my problem. But those restrictions are "ruining" it.
I'd appreciate if you have any ideas of how to accomplish this. I welcome different approaches.
Thank you.
EDIT
A simple example is given below. It attempts to solve the van der Pol equation by changing the mu parameter randomly. This is the main idea I have at the moment, which doesn't work because of the problems mentioned above.
This is the main model with the subsystem:
This is the subsystem:
This is the MATLAB Function block implementation (note that there's an error in the @ symbol, since defining function_handle objects isn't allowed):
回答1:
Just use the MATLAB Function block as a wrapper. Put the bulk of your code into a "standard" MATLAB function (i.e. one callable from MATLAB, not the MATLAB Function block) and call that function (after defining it as coder.extrinsic) from the MATLAB Function block.
回答2:
This will be a bit more complex than Phil Goddard's solution. The advantage is that it will allow you to generate standalone code, if necessary, whereas extrinsic functions are not compatible with standalone code generation.
The functions ode23 and ode45 are supported for code generation as of MATLAB R2014b so this applies if your MATLAB release is at least that new. Supposing so, the main limitation you are seeing is that anonymous functions are not supported for code generation.
Simulate Anonymous Function Parameters with Persistent Variables
However, these parameterized anonymous functions can be simulated using a normal function with a persistent. To simulate your function with the parameter mu, make a MATLAB file odefcn.m:
function x = odefcn(t,y)
%#codegen
persistent mu;
if isempty(mu)
% Adjust based on actual size, type and complexity
mu = 0;
end
if ischar(t) && strcmp(t,'set')
% Syntax to set parameter
mu = y;
else
x = [y(2); mu*(1-y(1)^2)*y(2)-y(1)];
end
Then in the MATLAB Function Block, use:
function y = fcn(mu)
%#codegen
% Set parameter
odefcn('set',mu);
% Solve ODE
[~,Y] = ode45(@odefcn,[0, 20], [2; 0]);
y = Y(end,1);
That should work both for simulation and for code generation. You can just add more arguments to odefcn if you need more parameters.
来源:https://stackoverflow.com/questions/32250794/solving-odes-inside-a-subsystem-in-simulink