Register to reply 
Why do we get oscillations in Euler's method of integration and what i 
Share this thread: 
#1
Jul814, 10:00 AM

P: 2

When using Euler's method of integration, applied on a stochastic differential eq. :
For example  given d/dt v=−γvΔt+sqrt(ϵ⋅Δt)Γ(t) we loop over v[n+1]=v[n]−γv[n]Δt+sqrt(ϵ⋅Δt)Γn. (where −γv[n] is a force term, can be any force and Γn is some gaussian distributed random variable. ) . Then if we choose Δt not small enough, we eventually get (if we run over long times, meaning many repeated iterations) that the solutions become "unstable and oscillations appear around the analytic solution, with amplitude becoming larger and larger with time" (~ collected from many different sources I found on the internet that mention the problem but don't discuss it in depth). Why are these actual OSCILLATIONS, and not simply random fluctuations? What is the period of these oscillations? 


#2
Jul814, 10:33 AM

P: 442




#3
Jul814, 10:54 AM

HW Helper
Thanks
P: 946

y' = ky[/tex] with [itex]k > 0[/itex] and [itex]y(0) = 1[/itex]. This can be solved analytically: [tex]y(t) = e^{kt}.[/tex] Note that [itex]y \to 0[/itex] as [itex]t \to \infty[/itex]. Applying Euler's method with step size [itex]h > 0[/itex] we obtain [tex] y_{n+1} = y_n  hky_n = y_n(1  hk)[/tex] which again can be solved analytically: [tex] y_n = (1  hk)^n. [/tex] Thus the error at time [itex]t = nh[/itex] is given by [tex] \epsilon_n = y(nh)  y_n = e^{nhk}  (1  hk)^n. [/tex] If [itex]hk > 2[/itex] then [itex]1  hk < 1[/itex], so that [tex] \epsilon_n = e^{nhk}  (1)^n1  hk^n.[/tex] Thus, since [itex]1  hk > 1[/itex] and [itex]e^{nhk} < 1[/itex], we see that [itex]\epsilon_n \to \infty[/itex] and that [itex]\epsilon_n[/itex] is alternatively positive and negative (which is what "oscillates" means in this context). 


#4
Jul814, 11:03 AM

P: 2

Why do we get oscillations in Euler's method of integration and what i
1) I see why it oscillates with a frequency of 1 step, (1)^n, so this means you normalized the step size to be Er=1? 2) Silly question perhaps, but can this be written in the form of a sine() than? 


Register to reply 
Related Discussions  
Integrating Euler's equations for rigid body dynamics with Euler's Method  Differential Equations  0  
Euler's method  Calculus & Beyond Homework  2  
Euler methond and the improved Euler method  Differential Equations  4  
Differential equations, euler's method and bisection method  Calculus & Beyond Homework  3  
Euler's Method  Differential Equations  3 