Tutorial: Solution of an NPZD model
This tutorial is about the efficient solution of production-destruction systems (PDS) with a small number of differential equations. We will compare the use of standard arrays and static arrays from StaticArrays.jl and assess their efficiency.
Definition of the production-destruction system
The NPZD model we want to solve was described by Burchard, Deleersnijder and Meister in Application of modified Patankar schemes to stiff biogeochemical models for the water column. The model reads
\[\begin{aligned} N' &= 0.01P + 0.01Z + 0.003D - \frac{NP}{0.01 + N},\\ P' &= \frac{NP}{0.01 + N}- 0.01P - 0.5( 1 - e^{-1.21P^2})Z - 0.05P,\\ Z' &= 0.5(1 - e^{-1.21P^2})Z - 0.01Z - 0.02Z,\\ D' &= 0.05P + 0.02Z - 0.003D, \end{aligned}\]
and we consider the initial conditions $N=8$, $P=2$, $Z=1$ and $D=4$. The time domain of interest is $t\in[0,10]$.
The model can be represented as a conservative PDS with production terms
\[\begin{aligned} p_{12} &= 0.01 P, & p_{13} &= 0.01 Z, & p_{14} &= 0.003 D,\\ p_{21} &= \frac{NP}{0.01 + N}, & p_{32} &= 0.5 (1.0 - e^{-1.21 P^2}) Z,& p_{42} &= 0.05 P,\\ p_{43} &= 0.02 Z, \end{aligned}\]
whereby production terms not listed have the value zero. Since the PDS is conservative, we have $d_{i,j}=p_{j,i}$ and the system is fully determined by the production matrix $(p_{ij})_{i,j=1}^4$.
Solution of the production-destruction system
Now we are ready to define a ConservativePDSProblem and to solve this problem with a method of PositiveIntegrators.jl or OrdinaryDiffEq.jl.
As mentioned above, we will try different approaches to solve this PDS and compare their efficiency. These are
- an out-of-place implementation with standard (dynamic) matrices and vectors,
- an in-place implementation with standard (dynamic) matrices and vectors,
- an out-of-place implementation with static matrices and vectors from StaticArrays.jl.
Standard out-of-place implementation
Here we create a function to compute the production matrix with return type Matrix{Float64}.
using PositiveIntegrators # load ConservativePDSProblem
function prod(u, p, t)
N, P, Z, D = u
p12 = 0.01 * P
p13 = 0.01 * Z
p14 = 0.003 * D
p21 = N / (0.01 + N) * P
p32 = 0.5 * (1.0 - exp(-1.21 * P^2)) * Z
p42 = 0.05 * P
p43 = 0.02 * Z
return [0.0 p12 p13 p14;
p21 0.0 0.0 0.0;
0.0 p32 0.0 0.0;
0.0 p42 p43 0.0]
endThe solution of the NPZD model can now be computed as follows.
u0 = [8.0, 2.0, 1.0, 4.0] # initial values
tspan = (0.0, 10.0) # time domain
prob_oop = ConservativePDSProblem(prod, u0, tspan) # create the PDS
sol_oop = solve(prob_oop, MPRK43I(1.0, 0.5))Plotting the solution shows that the components $N$ and $P$ are in danger of becoming negative.
using Plots
plot(sol_oop; label = ["N" "P" "Z" "D"], xguide = "t")
PositiveIntegrators.jl provides the function isnonnegative (and also isnegative) to check if the solution is actually nonnegative, as expected from an MPRK scheme.
isnonnegative(sol_oop)trueStandard in-place implementation
Next we create an in-place function for the production matrix.
function prod!(PMat, u, p, t)
N, P, Z, D = u
p12 = 0.01 * P
p13 = 0.01 * Z
p14 = 0.003 * D
p21 = N / (0.01 + N) * P
p32 = 0.5 * (1.0 - exp(-1.21 * P^2)) * Z
p42 = 0.05 * P
p43 = 0.02 * Z
fill!(PMat, zero(eltype(PMat)))
PMat[1, 2] = p12
PMat[1, 3] = p13
PMat[1, 4] = p14
PMat[2, 1] = p21
PMat[3, 2] = p32
PMat[4, 2] = p42
PMat[4, 3] = p43
return nothing
endThe solution of the in-place implementation of the NPZD model can now be computed as follows.
prob_ip = ConservativePDSProblem(prod!, u0, tspan)
sol_ip = solve(prob_ip, MPRK43I(1.0, 0.5))plot(sol_ip; label = ["N" "P" "Z" "D"], xguide = "t")
We also check that the in-place and out-of-place solutions are equivalent.
sol_oop.t ≈ sol_ip.t && sol_oop.u ≈ sol_ip.utrueUsing static arrays
For PDS with a small number of differential equations like the NPZD model the use of static arrays will be more efficient. To create a function which computes the production matrix and returns a static matrix, we only need to add the @SMatrix macro.
using StaticArrays
function prod_static(u, p, t)
N, P, Z, D = u
p12 = 0.01 * P
p13 = 0.01 * Z
p14 = 0.003 * D
p21 = N / (0.01 + N) * P
p32 = 0.5 * (1.0 - exp(-1.21 * P^2)) * Z
p42 = 0.05 * P
p43 = 0.02 * Z
return @SMatrix [0.0 p12 p13 p14;
p21 0.0 0.0 0.0;
0.0 p32 0.0 0.0;
0.0 p42 p43 0.0]
endIn addition we also want to use a static vector to hold the initial conditions.
u0_static = @SVector [8.0, 2.0, 1.0, 4.0] # initial values
prob_static = ConservativePDSProblem(prod_static, u0_static, tspan) # create the PDS
sol_static = solve(prob_static, MPRK43I(1.0, 0.5))using Plots
plot(sol_static; label = ["N" "P" "Z" "D"], xguide = "t")
This solution is also nonnegative.
isnonnegative(sol_static)trueThe above implementation of the NPZD model using StaticArrays can also be found in the Example Problems as prob_pds_npzd.
Performance comparison
Finally, we use BenchmarkTools.jl to show the benefit of using static arrays.
using BenchmarkTools
@benchmark solve(prob_oop, MPRK43I(1.0, 0.5))BenchmarkTools.Trial: 2414 samples with 1 evaluation per sample.
Range (min … max): 1.545 ms … 67.734 ms ┊ GC (min … max): 0.00% … 85.82%
Time (median): 1.602 ms ┊ GC (median): 0.00%
Time (mean ± σ): 2.068 ms ± 2.435 ms ┊ GC (mean ± σ): 13.41% ± 13.41%
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1.54 ms Histogram: log(frequency) by time 9.01 ms <
Memory estimate: 2.89 MiB, allocs estimate: 41328.using BenchmarkTools
@benchmark solve(prob_ip, MPRK43I(1.0, 0.5))BenchmarkTools.Trial: 5650 samples with 1 evaluation per sample.
Range (min … max): 749.649 μs … 57.823 ms ┊ GC (min … max): 0.00% … 97.16%
Time (median): 772.000 μs ┊ GC (median): 0.00%
Time (mean ± σ): 882.458 μs ± 1.231 ms ┊ GC (mean ± σ): 5.55% ± 4.90%
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750 μs Histogram: log(frequency) by time 1.02 ms <
Memory estimate: 477.19 KiB, allocs estimate: 6570.@benchmark solve(prob_static, MPRK43I(1.0, 0.5))BenchmarkTools.Trial: 10000 samples with 1 evaluation per sample.
Range (min … max): 274.784 μs … 46.214 ms ┊ GC (min … max): 0.00% … 97.76%
Time (median): 287.608 μs ┊ GC (median): 0.00%
Time (mean ± σ): 337.456 μs ± 716.228 μs ┊ GC (mean ± σ): 6.16% ± 5.29%
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275 μs Histogram: frequency by time 395 μs <
Memory estimate: 251.06 KiB, allocs estimate: 1743.Package versions
These results were obtained using the following versions.
using InteractiveUtils
versioninfo()
println()
using Pkg
Pkg.status(["PositiveIntegrators", "StaticArrays", "LinearSolve", "OrdinaryDiffEq"],
mode=PKGMODE_MANIFEST)Julia Version 1.11.3
Commit d63adeda50d (2025-01-21 19:42 UTC)
Build Info:
Official https://julialang.org/ release
Platform Info:
OS: Linux (x86_64-linux-gnu)
CPU: 4 × AMD EPYC 7763 64-Core Processor
WORD_SIZE: 64
LLVM: libLLVM-16.0.6 (ORCJIT, znver3)
Threads: 1 default, 0 interactive, 1 GC (on 4 virtual cores)
Environment:
JULIA_PKG_SERVER_REGISTRY_PREFERENCE = eager
Status `~/work/PositiveIntegrators.jl/PositiveIntegrators.jl/docs/Manifest.toml`
[7ed4a6bd] LinearSolve v2.38.0
[1dea7af3] OrdinaryDiffEq v6.90.1
[d1b20bf0] PositiveIntegrators v0.2.6 `~/work/PositiveIntegrators.jl/PositiveIntegrators.jl`
[90137ffa] StaticArrays v1.9.11