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I have a function solving two ODEs and joining the solution which gives a really nice plot in linear scales, but which has a high drop in quality in log scale depending on the parameters I use. In the code below, I plot the solution for two sets of parameters, in which you can see the first set is not smooth, while the second one is kind of okay. If I try to obtain a smoother visualisation using the saveat option in the second ODEs, solclass = solve(probclass,Tsit5(),saveat=0.001), I get an error when plotting the second set: ArgumentError: range step cannot be zero. Is there a way to obtain smooth linear-log other than manually changing the saveat option? Also, I have tried using a few other backends, but they gave an error at ploting the solution.

using DifferentialEquations, Plots, RecursiveArrayTools

function alpha_of_phi!(s2,d,a0,ϕ₀)
    # α in the quantum phase 
    function quantum!(dv,v,p,ϕ)
        s2,d=p
        α = v[1]
        dv[1] = (ϕ*s2*sin(2*d*α)+2*d*sinh(s2*α*ϕ))/(-α*s2*sin(2*d*α)+2*d*cos(2*d*α)+2*d*cosh(s2*α*ϕ))
    end
    # When dα/dϕ = 1, we reach the classical regime, and stop the integration
    condition(v,ϕ,integrator) = (ϕ*s2*sin(2*d*v[1])+2*d*sinh(s2*v[1]*ϕ))/(-v[1]*s2*sin(2*d*v[1])+2*d*cos(2*d*v[1])+2*d*cosh(s2*v[1]*ϕ))==1.0
    affect!(integrator) = terminate!(integrator)
    cb = DiscreteCallback(condition,affect!)
    # Initial Condition at the bounce
    α₀ = [a0]
    classspan = (0,ϕ₀)
    probquant = ODEProblem(quantum!,α₀,classspan,(s2,d))
    solquant = solve(probquant,Tsit5(),callback=cb)

    # α in the classical phase
    function classic!(du,u,p,ϕ)
        αc = u[1]
        dαc = u[2]
        du[1] = dαc
        du[2] = 3*(-dαc^3/sqrt(2)+dαc^2+dαc/sqrt(2)-1)
    end
    # IC retrieved from end of quantum phase
    init = [last(solquant);1.0]
    classspan = (last(solquant.t),ϕ₀)
    probclass = ODEProblem(classic!,init,classspan)
    solclass = solve(probclass,Tsit5())

    # α(ϕ) for ϕ>0
    solu = append!(solquant[1,:],solclass[1,:]) # α
    solt = append!(solquant.t,solclass.t) # ϕ

    # α(ϕ) for ϕ<0
    soloppu = reverse(solu)
    soloppt = -reverse(solt)
    pop!(soloppu)
    pop!(soloppt)

    # Join the two solutions
    soltotu = append!(soloppu,solu)
    soltott = append!(soloppt,solt)
    soltot = DiffEqArray(soltotu,soltott)
end

plot(alpha_of_phi!(10000.0,-0.0009,0.0074847,2.0),yaxis=:log)
plot!(alpha_of_phi!(16.0,-0.1,0.00001,2.0))
```
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  • I believe this question is more suitable for stackoverflow. – Paddy Jun 21 at 18:29
  • I can't answer your question. Do you not have access to the DifferentialEquations plot recipes with DiffEqArray? Have you seen this suggestion? discourse.julialang.org/t/… You may find more focused help on discourse, rather than SO. – PatrickT Jun 24 at 11:18
1

If you were plotting a solution returned by solve directly, then the Plots recipes for DifferentialEquations enable an optional keyword argument for plot entitled plotdensity, which would let you choose the number of points plotted, and thus smoothness, as described in the docs, e.g.:

plot(sol,plotdensity=10000)

However, this keyword appears to require a solution object, rather than a DiffEqArray. Consequently, your best bet will indeed be manually setting saveat. For this approach, saveat = 0.01 would seem to be plenty to obtain fully smooth lines. However, this still gives the "range step cannot be zero" error you describe.

While I have no deep understanding of the system you are solving, an inspection of the results revealed duplicate timesteps in the results for alpha_of_phi!(16.0,-0.1,0.00001,2.0) run without saveat, suggesting that the classical simulation was being run with over a range of no time. In other words, this hints that last(solquant.t) may well be equal to or greater than ϕ₀ with these parameters, resulting in a timespan of zero. If so, this will quite understandably fail when you request to saveat some finite time within that timespan (last(solquant.t), ϕ₀).

Consequently, working on this hypothesis, if we just rewrite your function to check for this condition

using DifferentialEquations, Plots

function alpha_of_phi!(s2,d,a0,ϕ₀)
    # α in the quantum phase
    function quantum!(dv,v,p,ϕ)
       s2,d=p
       α = v[1]
       dv[1] = (ϕ*s2*sin(2*d*α)+2*d*sinh(s2*α*ϕ))/(-α*s2*sin(2*d*α)+2*d*cos(2*d*α)+2*d*cosh(s2*α*ϕ))
    end
    # When dα/dϕ = 1, we reach the classical regime, and stop the integration
    condition(v,ϕ,integrator) = (ϕ*s2*sin(2*d*v[1])+2*d*sinh(s2*v[1]*ϕ))/(-v[1]*s2*sin(2*d*v[1])+2*d*cos(2*d*v[1])+2*d*cosh(s2*v[1]*ϕ))==1.0
    affect!(integrator) = terminate!(integrator)
    cb = DiscreteCallback(condition,affect!)
    # Initial Condition at the bounce
    α₀ = [a0]
    classspan = (0,ϕ₀)
    probquant = ODEProblem(quantum!,α₀,classspan,(s2,d))
    solquant = solve(probquant,Tsit5(),callback=cb,saveat=0.01)

    # α in the classical phase
    function classic!(du,u,p,ϕ)
       αc = u[1]
       dαc = u[2]
       du[1] = dαc
       du[2] = 3*(-dαc^3/sqrt(2)+dαc^2+dαc/sqrt(2)-1)
    end
    if last(solquant.t) < ϕ₀
       # IC retrieved from end of quantum phase
       init = [last(solquant);1.0]
       classspan = (last(solquant.t),ϕ₀)
       probclass = ODEProblem(classic!,init,classspan)
       solclass = solve(probclass,Tsit5(),saveat=0.01)

       # α(ϕ) for ϕ>0
       solu = append!(solquant[1,:],solclass[1,:]) # α
       solt = append!(solquant.t,solclass.t) # ϕ
    else
       solu = solquant[1,:] # α
       solt = solquant.t # ϕ
    end

    # α(ϕ) for ϕ<0
    soloppu = reverse(solu)
    soloppt = -reverse(solt)
    pop!(soloppu)
    pop!(soloppt)

    # Join the two solutions
    soltotu = append!(soloppu,solu)
    soltott = append!(soloppt,solt)
    soltot = DiffEqArray(soltotu,soltott)
end

plot(alpha_of_phi!(10000.0,-0.0009,0.0074847,2.0),yaxis=:log)
plot!(alpha_of_phi!(16.0,-0.1,0.00001,2.0))

then we would seem to be in business! smooth log plot

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