Suppose in matlab the following:
[t, x, te, xe, ie] = ode15s(@myfunc, [tStart tFinal], x0, odeset('Events', @events));
1a) The function
events is called only after a successful step of the solver. Is this true?
1b) Just after the solver has made a successful step, is it possible that the last call of
myfunc not be the call that lead to the successful step?
1c) If the
events function contains multiple terminal events and upon a successful step it is detected that two of them (not just one) have occured, what would be the behavior of the solver?
myfunc contains the following code
if (check(x) > 2) dx(3) = x(1)*x(2); else dx(3) = x(2)^2; end
check is some function of
One way to solve this problem is not use an events function. In my experience the ode solver can solve such problems that way.
The other way to solve this problem is use an events function to locate
check(x) - 2 == 0, one terminal event for
direction = 1 and another one for
direction = -1. After the solver stops on either of the events a global variable eg
myvar is set appropriately to distinguish between the two events, and then the simulation continues from where it stopped. In that case the code in
myfunc will be
if (myvar == 1) dx(3) = x(1)*x(2); else dx(3) = x(2)^2; end
Both way yield correct results in simple cases. However I am trying to solve a very complex problem (additional events than the above and discontinous right-hand parts of the differential equations that are proven to be solvable at some cases) and I am trying to find out if the first way would yield different results than the second one.
One might tell that the ode would either fail to return a solution before
tFinal or return a correct solution, but due to the discontinuity of the right-hand part the solver might not return a solution while a solution exists.
So in some sense, the question is: what is the practical-theoretical difference between using the first way and the second way?