# Improve plots quality in log scale in Julia

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
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))
$$```$$
``````
• 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

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
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!