diff --git a/.github/workflows/Documentation.yml b/.github/workflows/Documentation.yml index 8a688af7aa..36b3a74cb6 100644 --- a/.github/workflows/Documentation.yml +++ b/.github/workflows/Documentation.yml @@ -15,13 +15,14 @@ jobs: - uses: julia-actions/setup-julia@latest with: version: '1' + - run: sudo apt-get update && sudo apt-get install -y xorg-dev mesa-utils xvfb libgl1 freeglut3-dev libxrandr-dev libxinerama-dev libxcursor-dev libxi-dev libxext-dev - name: Install dependencies - run: julia --project=docs/ -e 'using Pkg; Pkg.develop(PackageSpec(path=pwd())); Pkg.instantiate()' + run: DISPLAY=:0 xvfb-run -s '-screen 0 1024x768x24' julia --project=docs/ -e 'using Pkg; Pkg.develop(PackageSpec(path=pwd())); Pkg.instantiate()' - name: Build and deploy env: GITHUB_TOKEN: ${{ secrets.GITHUB_TOKEN }} # For authentication with GitHub Actions token DOCUMENTER_KEY: ${{ secrets.DOCUMENTER_KEY }} # For authentication with SSH deploy key - run: julia --project=docs/ --code-coverage=user docs/make.jl + run: DISPLAY=:0 xvfb-run -s '-screen 0 1024x768x24' julia --project=docs/ --code-coverage=user docs/make.jl - uses: julia-actions/julia-processcoverage@v1 - uses: codecov/codecov-action@v3 with: diff --git a/docs/Project.toml b/docs/Project.toml index 823f49b206..3369fb4cd4 100644 --- a/docs/Project.toml +++ b/docs/Project.toml @@ -5,6 +5,7 @@ Distributions = "31c24e10-a181-5473-b8eb-7969acd0382f" Documenter = "e30172f5-a6a5-5a46-863b-614d45cd2de4" LinearAlgebra = "37e2e46d-f89d-539d-b4ee-838fcccc9c8e" ModelingToolkit = "961ee093-0014-501f-94e3-6117800e7a78" +ModelingToolkitDesigner = "23d639d0-9462-4d1e-84fe-d700424865b8" NonlinearSolve = "8913a72c-1f9b-4ce2-8d82-65094dcecaec" Optim = "429524aa-4258-5aef-a3af-852621145aeb" Optimization = "7f7a1694-90dd-40f0-9382-eb1efda571ba" diff --git a/docs/pages.jl b/docs/pages.jl index 970e9e3ce2..41b6d05e92 100644 --- a/docs/pages.jl +++ b/docs/pages.jl @@ -6,7 +6,8 @@ pages = [ "tutorials/optimization.md", "tutorials/modelingtoolkitize.md", "tutorials/stochastic_diffeq.md", - "tutorials/parameter_identifiability.md"], + "tutorials/parameter_identifiability.md", + "tutorials/domain_connections.md"], "Examples" => Any["Basic Examples" => Any["examples/higher_order.md", "examples/spring_mass.md", "examples/modelingtoolkitize_index_reduction.md", diff --git a/docs/src/tutorials/domain_connections.md b/docs/src/tutorials/domain_connections.md new file mode 100644 index 0000000000..7b56c8e0f1 --- /dev/null +++ b/docs/src/tutorials/domain_connections.md @@ -0,0 +1,336 @@ +# [Domains](@id domains) + +## Basics + +A domain in ModelingToolkit.jl is a network of connected components that share properties of the medium in the network. For example, a collection of hydraulic components connected together will have a fluid medium. Using the domain feature, one only needs to define and set the fluid medium properties once, in one component, rather than at each component. The way this works in ModelingToolkit.jl is by defining a connector (with Through/Flow and Across variables) with parameters defining the medium of the domain. Then a second connector is defined, with the same parameters, and the same Through/Flow variable, which acts as the setter. For example, a hydraulic domain may have a hydraulic connector, `HydraulicPort`, that defines a fluid medium with density (`ρ`), viscosity (`μ`), and a bulk modulus (`β`), a through/flow variable mass flow (`dm`) and an across variable pressure (`p`). + +```@example domain +using ModelingToolkit + +@parameters t +D = Differential(t) + +@connector function HydraulicPort(; p_int, name) + pars = @parameters begin + ρ + β + μ + end + + vars = @variables begin + p(t) = p_int + dm(t), [connect = Flow] + end + + ODESystem(Equation[], t, vars, pars; name, defaults = [dm => 0]) +end +nothing #hide +``` + +The fluid medium setter for `HydralicPort` may be defined as `HydraulicFluid` with the same parameters and through/flow variable. But now, the parameters can be set through the function keywords. + +```@example domain +@connector function HydraulicFluid(; + density = 997, + bulk_modulus = 2.09e9, + viscosity = 0.0010016, + name) + pars = @parameters begin + ρ = density + β = bulk_modulus + μ = viscosity + end + + vars = @variables begin + dm(t), [connect = Flow] + end + + eqs = [ + dm ~ 0, + ] + + ODESystem(eqs, t, vars, pars; name, defaults = [dm => 0]) +end +nothing #hide +``` + +Now, we can connect a `HydraulicFluid` component to any `HydraulicPort` connector, and the parameters of all `HydraulicPort`'s in the network will be automatically set. Let's consider a simple example, connecting a pressure source component to a volume component. Note that we don't need to define density for the volume component, it's supplied by the `HydraulicPort` (`port.ρ`). + +```@example domain +@component function FixedPressure(; p, name) + pars = @parameters p = p + systems = @named begin + port = HydraulicPort(; p_int = p) + end + + eqs = [port.p ~ p] + + ODESystem(eqs, t, [], pars; name, systems) +end + +@component function FixedVolume(; vol, p_int, name) + pars = @parameters begin + p_int = p_int + vol = vol + end + + systems = @named begin + port = HydraulicPort(; p_int) + end + + vars = @variables begin + rho(t) = port.ρ + drho(t) = 0 + end + + # let + dm = port.dm + p = port.p + + eqs = [D(rho) ~ drho + rho ~ port.ρ * (1 + p / port.β) + dm ~ drho * vol] + + ODESystem(eqs, t, vars, pars; name, systems) +end +nothing #hide +``` + +When the system is defined we can generate a fluid component and connect it to the system. Here `fluid` is connected to the `src.port`, but it could also be connected to `vol.port`, any connection in the network is fine. Note: we can visualize the system using `ModelingToolkitDesigner.jl`, where a dashed line is used to show the `fluid` connection to represent a domain connection that is only transporting parameters and not states. + +```@example domain +@component function System(; name) + systems = @named begin + src = FixedPressure(; p = 200e5) + vol = FixedVolume(; vol = 0.1, p_int = 200e5) + + fluid = HydraulicFluid(; density = 876) + end + + eqs = [connect(fluid, src.port) + connect(src.port, vol.port)] + + ODESystem(eqs, t, [], []; systems, name) +end + +@named odesys = System() +nothing #hide +``` + +```@setup domain +# code to generate diagrams... +# using ModelingToolkitDesigner +# path = raw"C:\Work\Assets\ModelingToolkit.jl\domain_connections" +# design = ODESystemDesign(odesys, path); + +# using CairoMakie +# CairoMakie.set_theme!(Theme(;fontsize=12)) +# fig = ModelingToolkitDesigner.view(design, false) +# save(joinpath(path, "odesys.svg"), fig; resolution=(300,300)) +``` + +![odesys](https://github.com/SciML/ModelingToolkit.jl/assets/40798837/d19fbcf4-781c-4743-87b7-30bed348ff98) + +To see how the domain works, we can examine the set parameter values for each of the ports `src.port` and `vol.port`. First we assemble the system using `structural_simplify()` and then check the default value of `vol.port.ρ`, whichs points to the setter value `fluid₊ρ`. Likewise, `src.port.ρ`, will also point to the setter value `fluid₊ρ`. Therefore, there is now only 1 defined density value `fluid₊ρ` which sets the density for the connected network. + +```@repl domain +sys = structural_simplify(odesys) +ModelingToolkit.defaults(sys)[complete(odesys).vol.port.ρ] +``` + +## Multiple Domain Networks + +If we have a more complicated system, for example a hydraulic actuator, with a separated fluid on both sides of the piston, it's possible we might have 2 separate domain networks. In this case we can connect 2 separate fluids, or the same fluid, to both networks. First a simple actuator is defined with 2 ports. + +```@example domain +@component function Actuator(; p_int, mass, area, name) + pars = @parameters begin + p_int = p_int + mass = mass + area = area + end + + systems = @named begin + port_a = HydraulicPort(; p_int) + port_b = HydraulicPort(; p_int) + end + + vars = @variables begin + x(t) = 0 + dx(t) = 0 + ddx(t) = 0 + end + + eqs = [D(x) ~ dx + D(dx) ~ ddx + mass * ddx ~ (port_a.p - port_b.p) * area + port_a.dm ~ +(port_a.ρ) * dx * area + port_b.dm ~ -(port_b.ρ) * dx * area] + + ODESystem(eqs, t, vars, pars; name, systems) +end +nothing #hide +``` + +A system with 2 different fluids is defined and connected to each separate domain network. + +```@example domain +@component function ActuatorSystem2(; name) + systems = @named begin + src_a = FixedPressure(; p = 200e5) + src_b = FixedPressure(; p = 200e5) + act = Actuator(; p_int = 200e5, mass = 1000, area = 0.1) + + fluid_a = HydraulicFluid(; density = 876) + fluid_b = HydraulicFluid(; density = 999) + end + + eqs = [connect(fluid_a, src_a.port) + connect(fluid_b, src_b.port) + connect(src_a.port, act.port_a) + connect(src_b.port, act.port_b)] + + ODESystem(eqs, t, [], []; systems, name) +end + +@named actsys2 = ActuatorSystem2() +nothing #hide +``` + +```@setup domain +# design = ODESystemDesign(actsys2, path); +# fig = ModelingToolkitDesigner.view(design, false) +# save(joinpath(path, "actsys2.svg"), fig; resolution=(500,300)) +``` + +![actsys2](https://github.com/SciML/ModelingToolkit.jl/assets/40798837/8ed50035-f6ac-48cb-a585-1ef415154a02) + +After running `structural_simplify()` on `actsys2`, the defaults will show that `act.port_a.ρ` points to `fluid_a₊ρ` and `act.port_b.ρ` points to `fluid_b₊ρ`. This is a special case, in most cases a hydraulic system will have only 1 fluid, however this simple system has 2 separate domain networks. Therefore, we can connect a single fluid to both networks. This does not interfer with the mathmatical equations of the system, since no states are connected. + +```@example domain +@component function ActuatorSystem1(; name) + systems = @named begin + src_a = FixedPressure(; p = 200e5) + src_b = FixedPressure(; p = 200e5) + act = Actuator(; p_int = 200e5, mass = 1000, area = 0.1) + + fluid = HydraulicFluid(; density = 876) + end + + eqs = [connect(fluid, src_a.port) + connect(fluid, src_b.port) + connect(src_a.port, act.port_a) + connect(src_b.port, act.port_b)] + + ODESystem(eqs, t, [], []; systems, name) +end + +@named actsys1 = ActuatorSystem1() +nothing #hide +``` + +```@setup domain +# design = ODESystemDesign(actsys1, path); +# fig = ModelingToolkitDesigner.view(design, false) +# save(joinpath(path, "actsys1.svg"), fig; resolution=(500,300)) +``` + +![actsys1](https://github.com/SciML/ModelingToolkit.jl/assets/40798837/054404eb-dbb7-4b85-95c0-c9503d0c4d00) + +## Special Connection Cases (`domain_connect()`) + +In some cases a component will be defined with 2 connectors of the same domain, but they are not connected. For example the `Restrictor` defined here gives equations to define the behavior of how the 2 connectors `port_a` and `port_b` are physcially connected. + +```@example domain +@component function Restrictor(; name, p_int) + pars = @parameters begin + K = 0.1 + p_int = p_int + end + + systems = @named begin + port_a = HydraulicPort(; p_int) + port_b = HydraulicPort(; p_int) + end + + eqs = [port_a.dm ~ (port_a.p - port_b.p) * K + 0 ~ port_a.dm + port_b.dm] + + ODESystem(eqs, t, [], pars; systems, name) +end +nothing #hide +``` + +Adding the `Restrictor` to the original system example will cause a break in the domain network, since a `connect(port_a, port_b)` is not defined. + +```@example domain +@component function RestrictorSystem(; name) + systems = @named begin + src = FixedPressure(; p = 200e5) + res = Restrictor(; p_int = 200e5) + vol = FixedVolume(; vol = 0.1, p_int = 200e5) + + fluid = HydraulicFluid(; density = 876) + end + + eqs = [connect(fluid, src.port) + connect(src.port, res.port_a) + connect(res.port_b, vol.port)] + + ODESystem(eqs, t, [], []; systems, name) +end + +@named ressys = RestrictorSystem() +sys = structural_simplify(ressys) +nothing #hide +``` + +```@setup domain +# design = ODESystemDesign(ressys, path); +# fig = ModelingToolkitDesigner.view(design, false) +# save(joinpath(path, "ressys.svg"), fig; resolution=(500,300)) +``` + +![ressys](https://github.com/SciML/ModelingToolkit.jl/assets/40798837/3740f0e2-7324-4c1f-af8b-eba02cfece81) + +When `structural_simplify()` is applied to this system it can be seen that the defaults are missing for `res.port_b` and `vol.port`. + +```@repl domain +ModelingToolkit.defaults(sys)[complete(ressys).res.port_a.ρ] +ModelingToolkit.defaults(sys)[complete(ressys).res.port_b.ρ] +ModelingToolkit.defaults(sys)[complete(ressys).vol.port.ρ] +``` + +To ensure that the `Restrictor` component does not disrupt the domain network, the [`domain_connect()`](@ref) function can be used, which explicitly only connects the domain network and not the states. + +```@example domain +@component function Restrictor(; name, p_int) + pars = @parameters begin + K = 0.1 + p_int = p_int + end + + systems = @named begin + port_a = HydraulicPort(; p_int) + port_b = HydraulicPort(; p_int) + end + + eqs = [domain_connect(port_a, port_b) # <-- connect the domain network + port_a.dm ~ (port_a.p - port_b.p) * K + 0 ~ port_a.dm + port_b.dm] + + ODESystem(eqs, t, [], pars; systems, name) +end + +@named ressys = RestrictorSystem() +sys = structural_simplify(ressys) +nothing #hide +``` + +Now that the `Restrictor` component is properly defined using `domain_connect()`, the defaults for `res.port_b` and `vol.port` are properly defined. + +```@repl domain +ModelingToolkit.defaults(sys)[complete(ressys).res.port_a.ρ] +ModelingToolkit.defaults(sys)[complete(ressys).res.port_b.ρ] +ModelingToolkit.defaults(sys)[complete(ressys).vol.port.ρ] +``` diff --git a/src/systems/connectors.jl b/src/systems/connectors.jl index 4522a8ff7c..f760e510e8 100644 --- a/src/systems/connectors.jl +++ b/src/systems/connectors.jl @@ -1,3 +1,8 @@ +""" + domain_connect(sys1, sys2, syss...) + +Adds a domain only connection equation, through and across state equations are not generated. +""" function domain_connect(sys1, sys2, syss...) syss = (sys1, sys2, syss...) length(unique(nameof, syss)) == length(syss) || error("connect takes distinct systems!") diff --git a/test/domain_connectors.jl b/test/domain_connectors.jl index 482ef617a8..685ff583fd 100644 --- a/test/domain_connectors.jl +++ b/test/domain_connectors.jl @@ -10,10 +10,6 @@ D = Differential(t) ρ β μ - n - let_gas - ρ_gas - p_gas end vars = @variables begin @@ -150,4 +146,13 @@ function System(; name) end @named odesys = System() +esys = ModelingToolkit.expand_connections(odesys) +@test length(equations(esys)) == length(states(esys)) + +csys = complete(odesys) + sys = structural_simplify(odesys) +@test length(equations(sys)) == length(states(sys)) + +sys_defs = ModelingToolkit.defaults(sys) +@test Symbol(sys_defs[csys.vol.port.ρ]) == Symbol(csys.fluid.ρ)