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I've got at State System, with "forced" inputs at bounds. My SS equation is: zp = A*z * B. (A is a square matrix, and B colunm)

If B is a step (along the time of experience), there is no problem, because I can use

  tevent = 2;
  tmax= 5*tevent;

  n =100;
  dT = n/tmax;
  t = linspace(0,tmax,n);
  u0 = 1 * ones(size(z'));
  B = zeros(nz,n);
  B(1,1)= utop(1)';
  A = eye(nz,nz);


and SS is:

  function zp = SS(t,z)
          global A B
          zp = A*z + B;

My problem is when I applied a slop, So B will be time dependent.

  utop_init= 20;
  utop_final = 50;
  utop(tevent * dT)=utop_final;

  for k = 2: tevent*dT -1
      utop(k) = utop(k-1) +(( utop(tevent * dT) - utop(1))/(tevent * dT));

  for k = (tevent * dT) +1 :(tmax*dT)
      utop(k) = utop(k-1);

  global A B
  B = zeros(nz,1);
  B(1,1:n) = utop(:)';
  A = eye(nz,nz);

I wrote a new equation (to trying to solve), the problem, but I can't adjust "time step", and I don't get a u with 22x100 (which is the objective).

  for k = 2 : n

SolveSS has the code:

function [ u ] = solveSS( t,k,u0)

  tspan = [t(k-1) t(k)];

  [t,u] = ode15s(@SS,tspan,u0);

      function zp = SS(t,z)
          global A B
          zp = A*z + B(:,k-1);


I hope that you can help!

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1 Answer 1

You should define a function B that is continuously varying with t and pass it as a function handle. This way you will allow the ODE solver to adjust time steps efficiently (your use of ode15s, a stiff ODE solver, suggests that variable time stepping is even more crucial)

The form of your code will be something like this:

function [ u ] = solveSS( t,k,u0)

    tspan = [t(k-1) t(k)];

    [t,u] = ode15s(@SS,tspan,u0,@B);

        function y = B(x)
            %% insert B calculation

        function zp = SS(t,z,B)
            global A
            zp = A*z + B(t);

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thanks for answering @jonnat . I understood what you said, but I didn't get it how to code, but I'm trying. –  marco Jan 27 '12 at 20:47
@marco, the B function will simply be the ramp dependent on x. For example, the body of B could be y=(x-tinit)/(tfinal-tinit) * (Bmax-Bmin) + Bmin –  jonnat Jan 28 '12 at 1:10
I passed my week looking to this problem, I think I need a brake to understand clearly what I can do. B is a matrix with "ramp" at first (and probably at last line). B has the size, nz x size(t). @jonnat I think your "way" can be right, but I need to codify and verify. Thank you for patiente and time ! –  marco Jan 28 '12 at 11:13
If B is a matrix, how can I determine the ramp effect? Can I stick B with size nz x 1, and vary the B(1,1) and B(nz,1) through the time? Sorry @jonnat ,but it is an important work, I'm obcessed :) –  marco Jan 28 '12 at 20:28
If you really need to represent B as a matrix you can do that. But it's important to understand that essentially you want B to be dependent on time, and using ode15s you can't expect the SS function to be evaluated in regular time intervals. If you want to pass B as a matrix (nrows = # of states in your model, ncols = number of time points in which B is evaluated) to SS, you will have to interpolate the columns of B to arbitrary points in time. –  jonnat Jan 29 '12 at 15:06

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