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I would like to solve two ODE first order on microcontroller. It has to be evaluated every 100ms

x'=-k_{1}\cdot (x-x_{ref})\cdot e^{-b\cdot ((x-x_{obs})^{2}+(y-y_{obs})^{2})}
y'=-k_{1}\cdot (y-y_{ref})\cdot e^{-b\cdot ((x-x_{obs})^{2}+(y-y_{obs})^{2})}

Basically i thought of using euler integration (Runge-Kute I)


I expect error to be < 0.001. How do i determine how many iterations i should run until i hit that error rate ?

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1 Answer 1

up vote 2 down vote accepted

I guess that x and y, as well as x_{ref}, y_{ref}, x_{obs}, y_{obs} are time dependent. This limits the number of ODE solver you can use. So it can be only the Euler method and a Runge-Kutta method of 2 order (I forgot the name), which evaluate the r.h.s of you ODE only at the time points x(t), x(t+dT)´,x(t+2dT)`,...

You can use classical step size control with these two methods. That is you make one with step with the Euler method and one step with the RK-II method. The difference between these two steps is an indicator for the error and can be used for classical step size control. Have a look at the Numerical Recipes for more details.

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Only x and y are time dependant. Those others are constant values. I will try with RK-2. What i dont understand is following: im using calculated x and y every 100ms, at that point in time i set constants x_ref, x_obs. So every 100ms i set boundary for ODE as x(0) = previous cycle value ? and run the ODE for dT=0.1 ? –  Gossamer Mar 10 '13 at 11:22
Sure, that is absolutely common. In principle the Runge-Kutta methods work iteratively and map a give x(t) to a x(t+dT). This one is then mapped to x(t+2dT) and so... –  headmyshoulder Mar 10 '13 at 13:06
I tried Euler method in Matlab and it gives good enough result. So i will go with Euler implementation on microcontroller. Thanks for the tips. –  Gossamer Mar 12 '13 at 7:58

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