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I am trying to implement a routine in mathematica/matlab for a stochastic process. Any code written here is for mathematica, but if someone can help me with encoding this in matlab (if they're more familiar with that) then that would be fine as well. However, mathematica is the priority if possible.

I will state what I want to get after going over the equations first.

The following is the Ito stochastic Process that I am interested in (where z(t)=[x(t),y(t)]:

enter image description here

with the following quantities:

enter image description here

We also have the following (from now I will type x(t),y(t) as x,y):

enter image description here

where, enter image description here is the first exit time and GT(x) is a smooth function of x (please see at the end)

Goal: I want to get Q0 in terms of x and enter image description here only.

=============================================================================== To find the first exit time enter image description here maybe the following can be used (courtesy of b.gatessucks). Please note that the following is a mathematica code.


enter image description here

const[x_, y_] := And[10^-8 <= y <= 10^-3, 0.9*(Uc) <= a1*x^2/2 - a3*x^4/4 <= 1.1*(Uc)]

x0 = 0.1;   (* starting point for x[t] *) y0 = 0.1; (* starting point for y[t] *)

proc = ItoProcess[  {\[DifferentialD]x[t] == y[t] \[DifferentialD]t,   \[DifferentialD]y[t] == (-G*y[t] - (a1*x[t] - a3*x[t]^3) - eps*b3b*y[t]^3) \[DifferentialD]t + Sqrt[2*eps*G] \[DifferentialD]w[t]},    {t, x[t], y[t], Boole[const[x[t], y[t]]]},   {{x, y}, {x0, y0}}, {t, 0}, w \[Distributed] WienerProcess[]]

Exit time is found:

sim = RandomFunction[proc, {0, 1, 0.001}];
First@Select[sim[[2, 1, 1]], #[[4]] == 0 &]

that outputs {t, x[t], y[t], Boole[const[x[t], y[t]]]}

I need to be able to use the above code to find the exit time and then use it in Q0. The above snippet to find exit time produces non zero times for properly chosen enter image description here.


Numerical Task that needs to be set up to find Q0(x):

--> We start from the integral term in this expression. First find enter image description here's for many initial conditions (say 100 for now -- i.e., 100 exit times) starting from inside the domain (maybe by using the snippet already mentioned in this post). Now the integral enter image description here can be evaluated for each of the 100 exit times as functions of x and enter image description here.

--> Now, the expectation of the integral in Q0 is a sample average (by Law of Large Numbers) of all the 100 integrals evaluated before. Thus, Q0 can be found and it should only be a function of x and enter image description here.


My issues:

  1. The code above for the exit time only seems to produce non-zero exit times for appropriately chosen initial conditions. If someone can elucidate as to how to pick the appropriate enter image description here such that there will be sufficient exit time being produced then that would be appreciative. I really want to keep my constraints as specified above in const[x_, y_], but if there seems to be no hope in finding tractable results then I wouldn't mind relaxing it.

  2. The code below for GT(x) results in singularities -- I received error message from DSolve regarding indeterminate expressions....both b0[xc] and DrhoDy[xc] become indeterminate and so the DSolve gives problems when using the initial condition GT[xc] as it becomes indeterminate as well...any way around this matter would be gladly appreciated.

  3. Finally, I really need someone's help in evaluating the 100 integrals in mathematica efficiently (since the terms are huge) for each of the exit times found previously and taking the expectation. I am not sure as to how to find the exit times properly.

================================================================================ To find GT(x):

b1b = 0.9; b3b = .8; a1b = 0.1; a3b = 0.2; G = (1/0.1^2)*
  b1b; a1 = (1/.1^2)*a1b; a3 = (1/.1^2)*a3b; xc = Sqrt[a1/a3]; Uc = 
 a1*xc^2/2 - a3*xc^4/4; L = (G + Sqrt[G^2 + 4*(-(a1 - 3*a3*xc^2))])/2;
y[x_] := (x *a1 - x^3*a3)/(G + L)

b0[x_] := (y[
      x]*(a1*x \[Minus] 
       a3*x ^3)*(1 \[Minus] (a1 \[Minus] 3*a3*x ^2)) \[Minus] 
    G*y[x]*(a1 \[Minus] 3*a3*x ^2)) /(y[
      x] ^2 + (\[Minus]G*y[x] + a1*x \[Minus] a3*x ^3) ^2)

DrhoDy [x_] := 
 Sqrt[y[x]^ 2 /(y[x] ^2 + (\[Minus]G*y[x] + a1*x \[Minus] a3*x ^3) ^2)]

linearequation = 
  y[x]*GT '[x] + b0[x]*GT[x] == G*DrhoDy [x]^2 *GT[x]^ 3;

GT[x] = 
 DSolve[{linearequation, GT[xc] == Sqrt[b0[xc]/( G*DrhoDy [xc]^2 )]}, 
  GT, x]


enter image description here

that satisfies the Initial Condition:

enter image description here


enter image description here


enter image description here

share|improve this question
@OlegKomarov can you please look at this now? hope this is ok. thank you! –  user2468702 Aug 14 '13 at 4:34
@HighPerformanceMark can you please look at this? thank you! –  user2468702 Aug 14 '13 at 4:35
This is quite a long story with questions about Math, Mathematica and Matlab. Please try to chop it up. Ask math questions on math SE, mathetmatica questions on mathematica SE, and isolate the other programming questions (or questions about matlab) and ask them here. Make sure the programming questions contain an easy reproducible example if possible. –  Dennis Jaheruddin Oct 3 '13 at 9:39

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