Try making your output a vector, where the first element is the state that you are interested in (`y`

), and the second element is its derivative with respect to time (`dy/dt`

); so `y0 = [0;0];`

or whatever your starting conditions are. Then make a separate file for your ODE, let's call it "myFcn":

```
function dydt = myFcn(~, y, M1, P, M2, E, current) % the ~ is because we are not explicitly dependent on tspan
% Initialize the d/dt vector of our states, y
dydt = zeros(size(y));
% Update the d/dt vector of our states
dydt(1) = y(2); % because (d/dt)y(1) = y(2) = dydt
dydt(2) = current/P - (M1/P)*sin(y) + (M2/P)*sin(y+E); % your update equation
```

Now just replace your handle and `ode45`

call in the above with:

```
f = @(y, M1, P, M2, E, current(k))myFunc(y, M1, P, M2, E, current(k));
[t{k}, y{k}] = ode45(f, tspan, y0);
```

Your output will then be the vector `y`

that will give your "position" state `y(1)`

and "velocity" state `y(2)`

. These will be stored in your cell array as before.

## Edit:

Updated code to include `current(k)`

, remaining consistent with OP's code.