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implement order_of_accuracy (#71)
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* remove debug code

* implement order_of_accuracy

* set version to v0.1.29

* use order_of_accuracy in tutorials

* format

* iterate over rooted tree iterators in order_of_accuracy and add more tests
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ranocha authored Aug 16, 2022
1 parent 44788e5 commit 0335ad4
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2 changes: 1 addition & 1 deletion Project.toml
Original file line number Diff line number Diff line change
@@ -1,7 +1,7 @@
name = "BSeries"
uuid = "ebb8d67c-85b4-416c-b05f-5f409e808f32"
authors = ["Hendrik Ranocha <[email protected]> and contributors"]
version = "0.1.28"
version = "0.1.29"

[deps]
Latexify = "23fbe1c1-3f47-55db-b15f-69d7ec21a316"
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13 changes: 12 additions & 1 deletion docs/src/tutorials/bseries_basics.md
Original file line number Diff line number Diff line change
Expand Up @@ -82,9 +82,20 @@ latexify(coeffs4-coeffs_ex, cdot=false)
This confirms that the method is of 4th order, since all terms involving
smaller powers of $h$ vanish exactly. We don't see the $h^6$ and higher
order terms since we only generated the truncated B-series up to 5th order.
We can also obtain the order of accuracy awithout comparing the coefficients
to the exact solution manually:

For the 2nd-order method, we get:
```@example bseries-basics
order_of_accuracy(coeffs4)
```

For the 2nd-order method, we get

```@example bseries-basics
order_of_accuracy(coeffs2)
```

with the following leading error terms:

```@example bseries-basics
latexify(coeffs2-coeffs_ex, cdot=false)
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26 changes: 25 additions & 1 deletion docs/src/tutorials/bseries_creation.md
Original file line number Diff line number Diff line change
Expand Up @@ -38,6 +38,10 @@ We can check that the classical Runge-Kutta method is indeed fourth-order accura
series - ExactSolution(series)
```

```@example ex:RK4
order_of_accuracy(series)
```


## B-series for additive Runge-Kutta methods

Expand Down Expand Up @@ -75,6 +79,10 @@ the exact solution.
series - ExactSolution(series)
```

```@example ex:SV
order_of_accuracy(series)
```


### References

Expand Down Expand Up @@ -136,6 +144,10 @@ the B-series of the exact solution, truncated at the same order.
series - ExactSolution(series)
```

```@example ex:AVF
order_of_accuracy(series)
```

### References

- Robert I. McLachlan, G. Reinout W. Quispel, and Nicolas Robidoux.
Expand Down Expand Up @@ -182,7 +194,7 @@ series_a = bseries(rk_a, 6)
Note that this method is fourth-order accurate:

```@example ex:compose
series_a - ExactSolution(series_a)
order_of_accuracy(series_a)
```

Next, we set up the starting procedure (method "b" in Butcher's paper):
Expand All @@ -198,6 +210,10 @@ rk_b = RungeKuttaMethod(A, b)
series_b = bseries(rk_b, 6)
```

```@example ex:compose
order_of_accuracy(series_b)
```

Note that this method is only third-order accurate - as is the finishing
procedure given by

Expand All @@ -212,6 +228,10 @@ rk_c = RungeKuttaMethod(A, b)
series_c = bseries(rk_c, 6)
```

```@example ex:compose
order_of_accuracy(series_c)
```

Finally, we can compose the three methods to obtain

```@example ex:compose
Expand All @@ -221,6 +241,10 @@ series = compose(series_b, series_a, series_c, normalize_stepsize = true)
Note that this composition has to be read from left to right. Finally, we check
that the resulting `series` is indeed fifth-order accurate:

```@example ex:compose
order_of_accuracy(series)
```

```@example ex:compose
series - ExactSolution(series)
```
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51 changes: 50 additions & 1 deletion src/BSeries.jl
Original file line number Diff line number Diff line change
Expand Up @@ -19,6 +19,8 @@ using Latexify: Latexify, LaTeXString

export TruncatedBSeries, ExactSolution

export order_of_accuracy

export bseries, substitute, compose, evaluate

export modified_equation, modifying_integrator
Expand Down Expand Up @@ -120,6 +122,8 @@ end
The maximal `order` of a rooted tree with non-vanishing coefficient in the
truncated B-series `series`.
See also [`order_of_accuracy`](@ref).
"""
RootedTrees.order(series::TruncatedBSeries) = order(series.coef.keys[end])

Expand Down Expand Up @@ -187,6 +191,16 @@ for op in (:*, :\)
end
end

# Return a function returning an iterator over all rooted trees used as
# keys for the B-series when given an order of the trees.
function _iterator_type(::TruncatedBSeries{<:RootedTree})
return RootedTreeIterator
end

function _iterator_type(::TruncatedBSeries{<:BicoloredRootedTree})
return BicoloredRootedTreeIterator
end

"""
ExactSolution{V}()
Expand Down Expand Up @@ -274,7 +288,6 @@ for op in (:+, :-)
V = promote_type(valtype(series1), valtype(series2))
series_result = TruncatedBSeries{T, V}()
for (key, val1, val2) in zip(series_keys, values(series1), values(series2))
@info "op" key val1 val2
series_result[key] = ($op)(val1, val2)
end

Expand All @@ -296,6 +309,42 @@ for op in (:+, :-)
end
end

# investigate properties of B-series
"""
order_of_accuracy(series; kwargs...)
Determine the order of accuracy of the B-series `series`. By default, the
comparison with the coefficients of the exact solution is performed using
`isequal`. If keyword arguments such as absolute/relative tolerances `atol`/`rtol`
are given or floating point numbers are used, the comparison is perfomed using
`isapprox` and the keyword arguments `kwargs...` are forwarded.
See also [`order`](@ref), [`ExactSolution`](@ref).
"""
function order_of_accuracy(series::TruncatedBSeries; kwargs...)
if isempty(kwargs) && !(valtype(series) <: AbstractFloat)
compare = isequal
else
compare = (a, b) -> isapprox(a, b; kwargs...)
end

exact = ExactSolution{valtype(series)}()
iterator = _iterator_type(series)

for o in 0:order(series)
# Iterate over all rooted trees used as keys in `series`
# of a given order `o`.
for t in iterator(o)
if compare(series[t], exact[t]) == false
return order(t) - 1
end
end
end

return order(series)
end

# construct B-series
"""
bseries(f::Function, order, iterator_type=RootedTreeIterator)
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39 changes: 39 additions & 0 deletions test/runtests.jl
Original file line number Diff line number Diff line change
Expand Up @@ -128,6 +128,39 @@ using Aqua: Aqua
@test mapreduce(iszero, &, values(diff))
end # @testset "vector space interface"

@testset "order_of_accuracy" begin
@testset "RK4, rational coefficients" begin
# classical fourth-order Runge-Kutta method
A = [0 0 0 0;
1//2 0 0 0;
0 1//2 0 0;
0 0 1 0]
b = [1 // 6, 1 // 3, 1 // 3, 1 // 6]
rk = RungeKuttaMethod(A, b)
series = bseries(rk, 5)
@test @inferred(order_of_accuracy(series)) == 4

series = bseries(rk, 3)
@test @inferred(order_of_accuracy(series)) == 3
end

@testset "RK4, floating point coefficients" begin
# classical fourth-order Runge-Kutta method
A = [0 0 0 0;
1/2 0 0 0;
0 1/2 0 0;
0 0 1 0]
b = [1 / 6, 1 / 3, 1 / 3, 1 / 6]
rk = RungeKuttaMethod(A, b)
series = bseries(rk, 5)
@test @inferred(order_of_accuracy(series)) == 4
@test @inferred(order_of_accuracy(series; atol = 10 * eps())) == 4

series = bseries(rk, 3)
@test @inferred(order_of_accuracy(series)) == 3
end
end

@testset "substitute" begin
Symbolics.@variables a1 a2 a31 a32
a = OrderedDict{RootedTrees.RootedTree{Int, Vector{Int}}, Symbolics.Num}(rootedtree(Int[]) => 1,
Expand Down Expand Up @@ -1104,6 +1137,7 @@ using Aqua: Aqua

diff = series - ExactSolution(series)
@test mapreduce(abs last, +, diff) == 1 // 12
@test @inferred(order_of_accuracy(series)) == 2
end

@testset "Runge-Kutta methods interface" begin
Expand All @@ -1119,11 +1153,13 @@ using Aqua: Aqua
series_integrator = @inferred bseries(rk, 4)
series_exact = @inferred ExactSolution(series_integrator)
@test mapreduce(==, &, values(series_integrator), values(series_exact))
@test @inferred(order_of_accuracy(series_integrator)) == 4

# not fifth-order accurate
series_integrator = @inferred bseries(rk, 5)
series_exact = @inferred ExactSolution(series_integrator)
@test mapreduce(==, &, values(series_integrator), values(series_exact)) == false
@test @inferred(order_of_accuracy(series_integrator)) == 4
end # @testset "Runge-Kutta methods interface"

@testset "additive Runge-Kutta methods interface" begin
Expand All @@ -1136,6 +1172,7 @@ using Aqua: Aqua
series_integrator = @inferred bseries(ark, 1)
series_exact = @inferred ExactSolution(series_integrator)
@test mapreduce(==, &, values(series_integrator), values(series_exact))
@test @inferred(order_of_accuracy(series_integrator)) == 1

# not second-order accurate
series_integrator = @inferred bseries(ark, 2)
Expand Down Expand Up @@ -1198,6 +1235,7 @@ using Aqua: Aqua
series_integrator = @inferred bseries(ark, 2)
series_exact = @inferred ExactSolution(series_integrator)
@test mapreduce(==, &, values(series_integrator), values(series_exact))
@test @inferred(order_of_accuracy(series_integrator)) == 2

# not third-order accurate
series_integrator = @inferred bseries(ark, 3)
Expand Down Expand Up @@ -1306,6 +1344,7 @@ using Aqua: Aqua
series_integrator = @inferred bseries(ark, 3)
series_exact = @inferred ExactSolution(series_integrator)
@test mapreduce(==, &, values(series_integrator), values(series_exact))
@test @inferred(order_of_accuracy(series_integrator)) == 3

# not fourth-order accurate
series_integrator = @inferred bseries(ark, 4)
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@ranocha
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Registration pull request created: JuliaRegistries/General/66335

After the above pull request is merged, it is recommended that a tag is created on this repository for the registered package version.

This will be done automatically if the Julia TagBot GitHub Action is installed, or can be done manually through the github interface, or via:

git tag -a v0.1.29 -m "<description of version>" 0335ad4f71079384389882111ef6dc7545b5dad0
git push origin v0.1.29

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