Model coupling for users
PlantSimEngine.jl
is designed to make model coupling simple for both the modeler and the user. For example, PlantBiophysics.jl
implements the Fvcb
model to simulate the photosynthesis process. This model needs the stomatal conductance process to be simulated, so it calls again run!
inside its implementation at some point. Note that it does not force any kind of conductance model over another, just that there is one to simulate the process. This ensures that users can choose whichever model they want to use for this simulation, independent of the photosynthesis model.
We provide an example script that implements seven dummy processes in examples/dummy
. The processes are simply called "process1", "process2"..., and the model implementations are called Process1Model
, Process2Model
...
Hard coupled models
The Process3Model
calls Process2Model
, and Process2Model
calls Process1Model
. This explicit call is called a hard-dependency in PlantSimEngine.
The other models for the other processes are called Process4Model
, Process5Model
... and they do not call explicitly other models when running, but some outputs of the models are used as inputs of other models. This is called a soft-dependency in PlantSimEngine.
Hard-coupling of models is usually done when there are some kind of iterative computation in one of the models that depend on one another. This is not the case in our example here as it is obviously just a simple one. In this case the coupling is not really necessary as models could just be called sequentially one after the other. For a more representative example, you can look at the energy balance computation of Monteith in PlantBiophysics.jl
, which is hard-coupled to a photosynthesis model.
Back to our example, using Process3Model
requires a "process2" model, and in our case the only model available is Process2Model
. The latter also requires a "process1" model, and again we only have one model implementation for this process, which is Process1Model
.
Let's use the Examples
sub-module so we can play around:
# Import the example models defined in the `Examples` sub-module:
using PlantSimEngine.Examples
Use subtype(x) to know which models are available for a process, e.g. for "process1" you can do subtypes(AbstractProcess1Model)
.
Here is how we can make the model coupling:
m = ModelList(Process1Model(2.0), Process2Model(), Process3Model())
[ Info: Some variables must be initialized before simulation: (process1 = (:var1, :var2), process2 = (:var1,)) (see `to_initialize()`)
We can see that only the first model has a parameter. You can usually know that by looking at the help of the structure (e.g. ?Process1Model
), else, you can still look at the field names of the structure like so fieldnames(Process1Model)
.
Note that the user only declares the models, not the way the models are coupled because PlantSimEngine.jl
deals with that automatically.
Now the example above returns some warnings saying we need to initialize some variables: var1
and var2
. PlantSimEngine.jl
automatically computes which variables should be initialized based on the inputs and outputs of all models, considering their hard or soft-coupling.
For example, Process1Model
requires the following variables as inputs:
inputs(Process1Model(2.0))
(:var1, :var2)
And Process2Model
requires the following variables:
inputs(Process2Model())
(:var1, :var3)
We see that var1
is needed as inputs of both models, but we also see that var3
is an output of Process2Model
:
outputs(Process2Model())
(:var4, :var5)
So considering those two models, we only need var1
and var2
to be initialized, as var3
is computed. This is why we recommend to_initialize
instead of inputs
, because it returns only the variables that need to be initialized, considering that some inputs are duplicated between models, and some are computed by other models (they are outputs of a model):
m = ModelList(
Process1Model(2.0),
Process2Model(),
Process3Model(),
variables_check=false # Just so we don't have the warning printed out
)
to_initialize(m)
(process1 = (:var1, :var2), process2 = (:var1,))
The most straightforward way of initializing a model list is by giving the initializations to the status
keyword argument during instantiation:
m = ModelList(
Process1Model(2.0),
Process2Model(),
Process3Model(),
status = (var1=15.0, var2=0.3)
)
Our component models structure is now fully parameterized and initialized for a simulation!
Let's simulate it:
using PlantMeteo
meteo = Atmosphere(T = 22.0, Wind = 0.8333, P = 101.325, Rh = 0.4490995)
run!(m, meteo)
m[:var5]
1-element Vector{Float64}:
38.0138985
Soft coupled models
All following models (Process4Model
to Process7Model
) do not call explicitly other models when running, but some outputs of the models are used as inputs of other models. This is called a soft-dependency in PlantSimEngine.
Let's make a new model list including the soft-coupled models:
m = ModelList(
Process1Model(2.0),
Process2Model(),
Process3Model(),
Process4Model(),
Process5Model(),
Process6Model(),
Process7Model(),
)
[ Info: Some variables must be initialized before simulation: (process4 = (:var0,), process7 = (:var0,)) (see `to_initialize()`)
With this list of models, we only need to initialize var0
, that is an input of Process4Model
and Process7Model
:
to_initialize(m)
(process4 = (:var0,), process7 = (:var0,))
We can initialize it like so:
m = ModelList(
Process1Model(2.0),
Process2Model(),
Process3Model(),
Process4Model(),
Process5Model(),
Process6Model(),
Process7Model(),
status = (var0=15.0,)
)
Let's simulate it:
using PlantMeteo
meteo = Atmosphere(T = 22.0, Wind = 0.8333, P = 101.325, Rh = 0.4490995)
run!(m, meteo)
status(m)
TimeStepTable{Status{(:var0, :var1, :var2, ...}(1 x 10):
╭─────┬─────────┬─────────┬─────────┬─────────┬─────────┬─────────┬─────────┬───
│ Row │ var0 │ var1 │ var2 │ var5 │ var4 │ var6 │ var3 │ ⋯
│ │ Float64 │ Float64 │ Float64 │ Float64 │ Float64 │ Float64 │ Float64 │ ⋯
├─────┼─────────┼─────────┼─────────┼─────────┼─────────┼─────────┼─────────┼───
│ 1 │ 15.0 │ 15.01 │ 15.03 │ 480.214 │ 910.401 │ 1390.62 │ 227.6 │ ⋯
╰─────┴─────────┴─────────┴─────────┴─────────┴─────────┴─────────┴─────────┴───
3 columns omitted
Simulation order
When calling run!
, the models are run in the right order using a dependency graph that is computed automatically based on the hard and soft dependencies of the models following a simple set of rules:
- Independent models are run first. A model is independent if it can be run alone, or only using initializations. It is not dependent on any other model.
- From their children dependencies:
- Hard dependencies are always run before soft dependencies. Inner hard dependency graphs are considered as a whole, i.e. as a single soft dependency.
- Soft dependencies are then run sequentially. If a soft dependency has several parent nodes (i.e. its inputs are computed by several models), it is run only if all its parent nodes have been run already. In practice, when we visit a node that has one of its parent that did not run already, we stop the visit of this branch. The node will eventually be visited from the branch of the last parent that was run.