# Stochastic differential equation with callback in Julia

I'm trying to solve a diffusion problem with reflecting boundaries, using various SDE integrators from DifferentialEquations.jl. I thought I could use the FunctionCallingCallback to handle the boundaries, by reflecting the solution about the domain boundaries after every integrator step.

This is my code

using DifferentialEquations

K0 = 1e-3
K1 = 5e-3
alpha = 0.5

K(z)    = K0 + z*K1*exp(-z*alpha)
dKdz(z) = K1*exp(-alpha*z) - K1*alpha*z*exp(-alpha*z)

a(z,p,t) = dKdz(z)
b(z,p,t) = sqrt(2*K(z))

dt = 0.1
tspan = (0.0,1.0)

z0 = 1.0

prob  = SDEProblem(a,b,z0,tspan)

function reflect(z, p, t, integrator)
bottom = 2.0
if z < 0
# Reflect from surface
z = -z
elseif z > bottom
# Reflect from bottom
z = 2*bottom - z
end
return z
end

cb = FunctionCallingCallback(reflect;
func_everystep = true,
func_start = true,
tdir=1)

sol = solve(prob, EM(), dt = dt, callback = cb)

Edit: After solving my initial problem thanks to the comment by Chris Rackauckas, I modified my reflect function. Now the code runs, but the solution contains negative values, which should have been prevented by reflection about 0 after every step.

Any ideas as to what's going wrong here would be greatly appreciated.

Note by the way that the FunctionCallingCallback example found here contains two different function signatures for the callback function, but I get the same problem with both. It's also not clear to me if the callback should modify the value of z in place, or return the new value.

Edit 2: Based on Chris Rackauckas' answer, and looking at this example, I've modified by reflect function thus:

function reflect(z, t, integrator)
bottom = 2.0
if integrator.u < 0
# Reflect from surface
integrator.u = -integrator.u
elseif integrator.u > bottom
# Reflect from bottom
integrator.u = 2*bottom - integrator.u
end
# Not sure if the return statement is required
return integrator.u
end

Running this with initial condition z0 = -0.1 produces the following output:

retcode: Success
Interpolation: 1st order linear
t: 11-element Array{Float64,1}:
0.0
0.1
0.2
0.30000000000000004
0.4
0.5
0.6
0.7
0.7999999999999999
0.8999999999999999
1.0
u: 11-element Array{Float64,1}:
-0.1
-0.08855333388147717
0.09862543518953905
0.09412012313587219
0.11409372573454478
0.10316400521980074
0.06491042188420941
0.045042097789392624
0.040565317051189105
0.06787136817395374
0.055880083559589955

It seems to me that what's happening here is:

1. The first output value is just z0. I expected the reflection to be applied first, given that I set func_start = true.
2. The second value also being negative indicates two things:
1. The callback was not called prior to the first integrator call.
2. The callback was not called prior to storing the output after the first integrator call.

I would have expected all the values in the output to be positive (i.e., have the callback applied to them before storing the output). Am I doing something wrong, or should I simply adjust my expectations?

• z[z .< 0.0] is going to fail with a BoundsError because you defined z as a Float64, not an array. – Chris Rackauckas Mar 5 at 15:59
• Great, thanks! I was translating a python code where z was an array, but it seems in Julia it's easier to use the MonteCarloProblem approach, so I settled on that but forgot to change the reflect function. I still can't get it to work as I want though (see edits). – Tor Mar 5 at 17:19

The FunctionCallingCallback is a function (u,t,integrator), so I'm not sure how your code didn't error for you. It should be:

using DifferentialEquations

K0 = 1e-3
K1 = 5e-3
alpha = 0.5

K(z)    = K0 + z*K1*exp(-z*alpha)
dKdz(z) = K1*exp(-alpha*z) - K1*alpha*z*exp(-alpha*z)

a(z,p,t) = dKdz(z)
b(z,p,t) = sqrt(2*K(z))

dt = 0.1
tspan = (0.0,1.0)

z0 = 1.0

prob  = SDEProblem(a,b,z0,tspan)

function reflect(z, t, integrator)
bottom = 2.0
if z < 0
# Reflect from surface
z = -z
elseif z > bottom
# Reflect from bottom
z = 2*bottom - z
end
return z
end

cb = FunctionCallingCallback(reflect;
func_everystep = true,
func_start = true,
tdir=1)

sol = solve(prob, EM(), dt = dt, callback = cb)

## Edit

You don't want the function calling callback. Just use the normal callback:

using DifferentialEquations

K0 = 1e-3
K1 = 5e-3
alpha = 0.5

K(z)    = K0 + z*K1*exp(-z*alpha)
dKdz(z) = K1*exp(-alpha*z) - K1*alpha*z*exp(-alpha*z)

a(z,p,t) = dKdz(z)
b(z,p,t) = sqrt(2*K(z))

dt = 0.1
tspan = (0.0,1.0)

z0 = 1.0

prob  = SDEProblem(a,b,z0,tspan)

condition(u,t,integrator) = true
function affect!(integrator)
bottom = 2.0
if integrator.u < 0
# Reflect from surface
integrator.u = -integrator.u
elseif integrator.u > bottom
# Reflect from bottom
integrator.u = 2*bottom - integrator.u
end
end

cb = DiscreteCallback(condition,affect!;save_positions=(false,false))

sol = solve(prob, EM(), dt = dt, callback = cb)
• Ok. The two function signatures in the example linked in my post are func(u,p,t,integrator) and func(t,u,integrator), so I guess neither of those are correct. In any case, this still doesn't work for me. When I run this exact code, but with z0 = -0.1, I get only negative values of z (randomly varying around -0.1) in the solution. I found another example that indicates I need to modify integrator.u instead of z, though. Getting increasingly close to what I'm trying to do. – Tor Mar 5 at 21:31
• Updated original post. – Tor Mar 5 at 22:00
• The new one is the one you want. – Chris Rackauckas Mar 5 at 22:37
• This still doesn't quite do what I expected. With this code, I get an output vector of 21 elements instead of 11, where every time point except 0.0 is repeated. And the two first solution values are still negative when running with z0 = -0.1, which indicates that the callback isn't applied prior to the first integrator call (I can live with that, though). For all the repeated outputs (i.e., all except t = 0.0), the first seems to be the output from the integrator, while the second has the callback applied to it, e.g., at t = 0.3, I get the two solutions -0.0132918... and 0.0132918... – Tor Mar 6 at 7:50
• Oh yes, let me edit to show how to fix that with save positions – Chris Rackauckas Mar 6 at 13:37