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Math.Tests.BooleanToInteger.md

Math.Tests.BooleanToInteger

Converts constant and time-varying Boolean signals to Integer.

Chains Constant(1.0) → RealToBoolean(threshold=0.5) → BooleanToInteger and verifies that a true Boolean input produces integerTrue=1. A second chain feeds a sine wave (amplitude 1) through RealToBoolean into BooleanToInteger so the Boolean toggles and the Integer output alternates between 0 and 1.

Usage

BlockComponents.Math.Tests.BooleanToInteger()

Behavior

julia
using BlockComponents #hide
using ModelingToolkit #hide
@named sys = BlockComponents.Math.Tests.BooleanToInteger() #hide
let eqs = full_equations(sys); Base.length(eqs) > 25 ? nothing : eqs end #hide
<< @example-block not executed in draft mode >>

Source

dyad
"""
Converts constant and time-varying Boolean signals to Integer.

Chains Constant(1.0) → RealToBoolean(threshold=0.5) → BooleanToInteger and
verifies that a true Boolean input produces integerTrue=1. A second chain
feeds a sine wave (amplitude 1) through RealToBoolean into BooleanToInteger so
the Boolean toggles and the Integer output alternates between 0 and 1.
"""
test component BooleanToInteger
  "Constant source providing a value above the threshold"
  c1 = BlockComponents.Sources.Constant(k = 1.0) {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 20, "y1": 20, "x2": 120, "y2": 120, "rot": 0}
      },
      "tags": []
    }
  }
  "RealToBoolean adapter to produce Boolean signal"
  r2b = BlockComponents.Math.RealToBoolean(threshold = 0.5) {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 161, "y1": 20, "x2": 261, "y2": 120, "rot": 0}
      },
      "tags": []
    }
  }
  "BooleanToInteger block under test"
  b2i = BlockComponents.Math.BooleanToInteger() {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 310, "y1": 20, "x2": 410, "y2": 120, "rot": 0}
      },
      "tags": []
    }
  }
  "Sine source crossing the threshold"
  sine = BlockComponents.Sources.Sine(amplitude = 1, frequency = 1) {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 20, "y1": 140, "x2": 120, "y2": 240, "rot": 0}
      },
      "tags": []
    }
  }
  "RealToBoolean adapter for the second chain"
  r2b_2 = BlockComponents.Math.RealToBoolean(threshold = 0.5) {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 161, "y1": 140, "x2": 261, "y2": 240, "rot": 0}
      },
      "tags": []
    }
  }
  "Second BooleanToInteger block driven by the sine chain"
  b2i_2 = BlockComponents.Math.BooleanToInteger() {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 301, "y1": 140, "x2": 401, "y2": 240, "rot": 0}
      },
      "tags": []
    }
  }
relations
  connect(c1.y, r2b.u) {"Dyad": {"edges": [{"S": 1, "M": [], "E": 2}], "renderStyle": "standard"}}
  connect(r2b.y, b2i.u) {"Dyad": {"edges": [{"S": 1, "M": [], "E": 2}], "renderStyle": "standard"}}
  connect(sine.y, r2b_2.u) {"Dyad": {"edges": [{"S": 1, "M": [], "E": 2}], "renderStyle": "standard"}}
  connect(r2b_2.y, b2i_2.u) {"Dyad": {"edges": [{"S": 1, "M": [], "E": 2}], "renderStyle": "standard"}}
metadata {
  "Dyad": {
    "icons": {"default": "dyad://BlockComponents/Example.svg"},
    "tests": {"case1": {"stop": 1, "expect": {"signals": ["b2i.y", "b2i_2.y", "sine.y"]}}}
  }
}
end
Flattened Source
dyad
"""
Converts constant and time-varying Boolean signals to Integer.

Chains Constant(1.0) → RealToBoolean(threshold=0.5) → BooleanToInteger and
verifies that a true Boolean input produces integerTrue=1. A second chain
feeds a sine wave (amplitude 1) through RealToBoolean into BooleanToInteger so
the Boolean toggles and the Integer output alternates between 0 and 1.
"""
test component BooleanToInteger
  "Constant source providing a value above the threshold"
  c1 = BlockComponents.Sources.Constant(k = 1.0) {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 20, "y1": 20, "x2": 120, "y2": 120, "rot": 0}
      },
      "tags": []
    }
  }
  "RealToBoolean adapter to produce Boolean signal"
  r2b = BlockComponents.Math.RealToBoolean(threshold = 0.5) {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 161, "y1": 20, "x2": 261, "y2": 120, "rot": 0}
      },
      "tags": []
    }
  }
  "BooleanToInteger block under test"
  b2i = BlockComponents.Math.BooleanToInteger() {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 310, "y1": 20, "x2": 410, "y2": 120, "rot": 0}
      },
      "tags": []
    }
  }
  "Sine source crossing the threshold"
  sine = BlockComponents.Sources.Sine(amplitude = 1, frequency = 1) {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 20, "y1": 140, "x2": 120, "y2": 240, "rot": 0}
      },
      "tags": []
    }
  }
  "RealToBoolean adapter for the second chain"
  r2b_2 = BlockComponents.Math.RealToBoolean(threshold = 0.5) {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 161, "y1": 140, "x2": 261, "y2": 240, "rot": 0}
      },
      "tags": []
    }
  }
  "Second BooleanToInteger block driven by the sine chain"
  b2i_2 = BlockComponents.Math.BooleanToInteger() {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 301, "y1": 140, "x2": 401, "y2": 240, "rot": 0}
      },
      "tags": []
    }
  }
relations
  connect(c1.y, r2b.u) {"Dyad": {"edges": [{"S": 1, "M": [], "E": 2}], "renderStyle": "standard"}}
  connect(r2b.y, b2i.u) {"Dyad": {"edges": [{"S": 1, "M": [], "E": 2}], "renderStyle": "standard"}}
  connect(sine.y, r2b_2.u) {"Dyad": {"edges": [{"S": 1, "M": [], "E": 2}], "renderStyle": "standard"}}
  connect(r2b_2.y, b2i_2.u) {"Dyad": {"edges": [{"S": 1, "M": [], "E": 2}], "renderStyle": "standard"}}
metadata {
  "Dyad": {
    "icons": {"default": "dyad://BlockComponents/Example.svg"},
    "tests": {"case1": {"stop": 1, "expect": {"signals": ["b2i.y", "b2i_2.y", "sine.y"]}}}
  }
}
end


Test Cases

julia
using BlockComponents
using DyadInterface: TransientAnalysis, rebuild_sol, ODEAlg
using ModelingToolkit: toggle_namespacing, get_initial_conditions, @named
using CSV, DataFrames, Plots

snapshotsdir = joinpath(dirname(dirname(pathof(BlockComponents))), "test", "snapshots")
<< @setup-block not executed in draft mode >>

Test Case case1

julia
@named model_case1 = BlockComponents.Math.Tests.BooleanToInteger()
model_case1 = toggle_namespacing(model_case1, false)

model_case1 = toggle_namespacing(model_case1, true)
result_case1 = TransientAnalysis(; model = model_case1, alg = ODEAlg.Auto(), start = 0e+0, stop = 1e+0, abstol=1e-6, reltol=1e-6)
sol_case1 = rebuild_sol(result_case1)
<< @setup-block not executed in draft mode >>
julia
df_case1 = DataFrame(:t => sol_case1[:t], :actual => sol_case1[model_case1.b2i.y])
dfr_case1 = try CSV.read(joinpath(snapshotsdir, "BlockComponents.Math.Tests.BooleanToInteger_case1_sig0.ref"), DataFrame); catch e; nothing; end
plt = plot(sol_case1, idxs=[model_case1.b2i.y], width=2, label="Actual value of b2i.y")
if !isnothing(dfr_case1)
  scatter!(plt, dfr_case1.t, dfr_case1.expected, mc=:red, ms=3, label="Expected value of b2i.y")
end
<< @setup-block not executed in draft mode >>
julia
plt
<< @example-block not executed in draft mode >>
julia
df_case1 = DataFrame(:t => sol_case1[:t], :actual => sol_case1[model_case1.b2i_2.y])
dfr_case1 = try CSV.read(joinpath(snapshotsdir, "BlockComponents.Math.Tests.BooleanToInteger_case1_sig1.ref"), DataFrame); catch e; nothing; end
plt = plot(sol_case1, idxs=[model_case1.b2i_2.y], width=2, label="Actual value of b2i_2.y")
if !isnothing(dfr_case1)
  scatter!(plt, dfr_case1.t, dfr_case1.expected, mc=:red, ms=3, label="Expected value of b2i_2.y")
end
<< @setup-block not executed in draft mode >>
julia
plt
<< @example-block not executed in draft mode >>
julia
df_case1 = DataFrame(:t => sol_case1[:t], :actual => sol_case1[model_case1.sine.y])
dfr_case1 = try CSV.read(joinpath(snapshotsdir, "BlockComponents.Math.Tests.BooleanToInteger_case1_sig2.ref"), DataFrame); catch e; nothing; end
plt = plot(sol_case1, idxs=[model_case1.sine.y], width=2, label="Actual value of sine.y")
if !isnothing(dfr_case1)
  scatter!(plt, dfr_case1.t, dfr_case1.expected, mc=:red, ms=3, label="Expected value of sine.y")
end
<< @setup-block not executed in draft mode >>
julia
plt
<< @example-block not executed in draft mode >>