# How to read corresponding value at specified time in DiscreteCallback?

Similar to this question, I am trying to solve this ODE with a time-dependent input parameter. It consists of a series of discrete callbacks. At certain times, a parameter is changed (not a state!). Times and values are stored in a `nx2 Array`. But I can't get the `affect` function to find the corresponding parameter value at the specified time. In the given examples, the value assigned to `u[1]` is usually constant. Consider this MWE (with a very Matlab-like approach), which works correctly without the callback:

``````using DifferentialEquations
using Plots

function odm2prod(dx, x, params, t)
k_1, f_1, V_liq, X_in, Y_in, q_in = params

rho_1 = k_1*x[1]
q_prod = 0.52*f_1*x[1]
# Differential Equations
dx[1] = q_in/V_liq*(X_in - x[1]) - rho_1
dx[2] = q_in/V_liq*(Y_in - x[2])
end

x0      = [3.15, 1.5]
tspan   = (0.0, 7.0)
params  = [0.22, 43, 155, 249, 58, 0]
prob    = ODEProblem(odm2prod, x0, tspan, params)

input   = [1.0 60; 1.1 0; 2.0 60; 2.3 0; 4.0 430; 4.05 0]
dosetimes = input[:,1]
function affect!(integrator)
ind_t = findall(integrator.t == dosetimes)
integrator.p[6] = input[ind_t, 2]
end
cb = PresetTimeCallback(dosetimes, affect!)
sol = solve(prob, Tsit5(), callback=cb, saveat=1/12)

plot(sol, vars=[1, 2])
``````

It does not work. The error originates at line 22, since comparing a vector to a scalar seems not to be defined in Julia, or there is a special syntax I am unaware of.

I know that it is possible to use time-dependent parameters in Julia, but I suppose that would only work for continuous functions, not discrete changes!? I haven taken a look at the help for `interpolate`, but I am not sure how to use it for my specific case.

Could someone tell me how to get this to work, please? Should probably need just a few lines of code. Also, I do not necessarily want `dosetimes` as part of `sol.t`, unless they coincide.

You are using `findall` wrong, the documentation says

`findall(f::Function, A)`

Return a vector `I` of the indices or keys of `A` where `f(A[I])` returns `true`.

Then you have to take into account that the result of a search for "all" is a list. As you expect it to only have one element, use the first one only

``````function affect!(integrator)
ind_t = findall(t -> t==integrator.t, dosetimes)
integrator.p[6] = input[ind_t[1], 2]
end
``````

and you get the plot

• Actually, I wanted to mimic Matlab's `ismember` function with Julia's `findall`. But then, I should have placed the arguments vice-versa... Anyway, your solutions works. An alternative would be to use Interpolations.jl, but the necessary option for `previous` interpolation is still pending. Feb 21, 2020 at 20:58
• I was surprised to see this work even when the first `PresetTimeCallback` happens at the initial time point, e.g. `tspan[1]`. I am working on a problem where `PresetTimeCallback` modifies the state and not a parameter. In that case, the callback does not get triggered at the initial time point. Any idea why this would make a difference? Jul 2, 2020 at 15:05
• Anyway, if it helps someone: in the 2nd case where `affect!` modifies a state, e.g. `integrator.u[1] += input[ind_t[1], 2]` a workaround could consist of two steps: a) use `PresetTimeCallback(dosetimes, affect!, initialize = (c,u,t,integrator) -> affect!(integrator))` (as mentioned in github.com/SciML/DifferentialEquations.jl/issues/…). and b) modify `affect!` in order to check `if (integrator.t in dosetimes)`, as otherwise `findall` might throw an error. Jul 2, 2020 at 15:08
• Hi @fabern, didn't have a look here for some time now. I was coding my first steps in Julia, to see if I could change to it permanently. But this jump feature is an essential aspect in the kind of modeling I do, so I need a really solid solution for it. It seems that Pumas would be an interesting alternative, since their `DosageRegimen` very much resembles the kind of feed I use. I will give it a try eventually. Aug 3, 2020 at 13:13