LIBRARY

Analog.Basic.Tests.CCV

Test circuit for CCV (current-controlled voltage source).

A sine voltage source (amplitude=1 V, frequency=1 Hz) drives a 5 Ω series resistor into the CCV input port (port 1). Since v1=0, the full source voltage drops across the resistor, producing i1 = V_source/R_series. A 10 Ω resistor loads the output port (port 2). CCV transResistance = 20 Ω.

Expected (algebraic, holds for all t):

• v1 = 0 (zero input impedance)

• i1 = sin(2π·t)/5 = 0.2·sin(2π·t)

• v2 = transResistance·i1 = 4·sin(2π·t)

• i2 = −v2/R_load = −0.4·sin(2π·t)

Usage

ElectricalComponents.Analog.Basic.Tests.CCV()

Behavior

$$\left[\begin{array}{c}\mathrm{connect}(sin{e}_{+}y,v{s}_{+}V)\\ \mathrm{connect}(v{s}_{+}p,r_{serie{s}_{+}p})\\ \mathrm{connect}(r_{serie{s}_{+}n},cc{v}_{+}p1)\\ \mathrm{connect}(v{s}_{+}n,gnd{1}_{+}g)\\ \mathrm{connect}(v{s}_{+}n,cc{v}_{+}n1)\\ \mathrm{connect}(cc{v}_{+}p2,r_{loa{d}_{+}p})\\ \mathrm{connect}(r_{loa{d}_{+}n},cc{v}_{+}n2)\\ \mathrm{connect}(gnd{2}_{+}g,cc{v}_{+}n2)\\ \mathtt{sine}\mathtt{.}\mathtt{y}\left(t\right)=\mathtt{sine}\mathtt{.}\mathtt{offset}+\mathtt{sine}\mathtt{.}\mathtt{amplitude}\cdot \mathrm{ifelse}(t\ge \mathtt{sine}\mathtt{.}{\mathtt{start}}_{\mathtt{time}},\sin (\mathtt{sine}\mathtt{.}\mathtt{phase}+6.283185307179586\cdot \mathtt{sine}\mathtt{.}\mathtt{frequency}\cdot (-\mathtt{sine}\mathtt{.}{\mathtt{start}}_{\mathtt{time}}+t)),\sin \left(\mathtt{sine}\mathtt{.}\mathtt{phase}\right))\\ \mathtt{vs}\mathtt{.}\mathtt{v}\left(t\right)=-\mathtt{vs}\mathtt{.}\mathtt{n}\mathtt{.}\mathtt{v}\left(t\right)+\mathtt{vs}\mathtt{.}\mathtt{p}\mathtt{.}\mathtt{v}\left(t\right)\\ \mathtt{vs}\mathtt{.}\mathtt{i}\left(t\right)=\mathtt{vs}\mathtt{.}\mathtt{p}\mathtt{.}\mathtt{i}\left(t\right)\\ \mathtt{vs}\mathtt{.}\mathtt{n}\mathtt{.}\mathtt{i}\left(t\right)+\mathtt{vs}\mathtt{.}\mathtt{p}\mathtt{.}\mathtt{i}\left(t\right)=0\\ \mathtt{vs}\mathtt{.}\mathtt{v}\left(t\right)=\mathtt{vs}\mathtt{.}\mathtt{uV}\cdot \mathtt{vs}\mathtt{.}\mathtt{V}\left(t\right)\\ {\mathtt{r}}_{\mathrm{series}.\mathrm{v}}\left(t\right)={\mathtt{r}}_{\mathrm{series}.\mathrm{p}.\mathrm{v}}\left(t\right)-{\mathtt{r}}_{\mathrm{series}.\mathrm{n}.\mathrm{v}}\left(t\right)\\ {\mathtt{r}}_{\mathrm{series}.\mathrm{i}}\left(t\right)={\mathtt{r}}_{\mathrm{series}.\mathrm{p}.\mathrm{i}}\left(t\right)\\ {\mathtt{r}}_{\mathrm{series}.\mathrm{n}.\mathrm{i}}\left(t\right)+{\mathtt{r}}_{\mathrm{series}.\mathrm{p}.\mathrm{i}}\left(t\right)=0\\ {\mathtt{r}}_{\mathrm{series}.\mathrm{v}}\left(t\right)={\mathtt{r}}_{\mathtt{series}\mathtt{.}\mathtt{R}}\cdot {\mathtt{r}}_{\mathrm{series}.\mathrm{i}}\left(t\right)\\ \mathtt{ccv}\mathtt{.}\mathtt{v}\mathtt{1}\left(t\right)=\mathtt{ccv}\mathtt{.}\mathtt{p}\mathtt{1.}\mathtt{v}\left(t\right)-\mathtt{ccv}\mathtt{.}\mathtt{n}\mathtt{1.}\mathtt{v}\left(t\right)\\ \mathtt{ccv}\mathtt{.}\mathtt{v}\mathtt{2}\left(t\right)=\mathtt{ccv}\mathtt{.}\mathtt{p}\mathtt{2.}\mathtt{v}\left(t\right)-\mathtt{ccv}\mathtt{.}\mathtt{n}\mathtt{2.}\mathtt{v}\left(t\right)\\ \mathtt{ccv}\mathtt{.}\mathtt{i}\mathtt{1}\left(t\right)=\mathtt{ccv}\mathtt{.}\mathtt{p}\mathtt{1.}\mathtt{i}\left(t\right)\\ \mathtt{ccv}\mathtt{.}\mathtt{i}\mathtt{2}\left(t\right)=\mathtt{ccv}\mathtt{.}\mathtt{p}\mathtt{2.}\mathtt{i}\left(t\right)\\ 0=\mathtt{ccv}\mathtt{.}\mathtt{n}\mathtt{1.}\mathtt{i}\left(t\right)+\mathtt{ccv}\mathtt{.}\mathtt{p}\mathtt{1.}\mathtt{i}\left(t\right)\\ 0=\mathtt{ccv}\mathtt{.}\mathtt{p}\mathtt{2.}\mathtt{i}\left(t\right)+\mathtt{ccv}\mathtt{.}\mathtt{n}\mathtt{2.}\mathtt{i}\left(t\right)\\ \mathtt{ccv}\mathtt{.}\mathtt{v}\mathtt{2}\left(t\right)=\mathtt{ccv}\mathtt{.}\mathtt{transResistance}\cdot \mathtt{ccv}\mathtt{.}\mathtt{i}\mathtt{1}\left(t\right)\\ \mathtt{ccv}\mathtt{.}\mathtt{v}\mathtt{1}\left(t\right)=0\\ {\mathtt{r}}_{\mathrm{load}.\mathrm{v}}\left(t\right)=-{\mathtt{r}}_{\mathrm{load}.\mathrm{n}.\mathrm{v}}\left(t\right)+{\mathtt{r}}_{\mathrm{load}.\mathrm{p}.\mathrm{v}}\left(t\right)\\ {\mathtt{r}}_{\mathrm{load}.\mathrm{i}}\left(t\right)={\mathtt{r}}_{\mathrm{load}.\mathrm{p}.\mathrm{i}}\left(t\right)\\ {\mathtt{r}}_{\mathrm{load}.\mathrm{n}.\mathrm{i}}\left(t\right)+{\mathtt{r}}_{\mathrm{load}.\mathrm{p}.\mathrm{i}}\left(t\right)=0\\ {\mathtt{r}}_{\mathrm{load}.\mathrm{v}}\left(t\right)={\mathtt{r}}_{\mathtt{load}\mathtt{.}\mathtt{R}}\cdot {\mathtt{r}}_{\mathrm{load}.\mathrm{i}}\left(t\right)\\ \mathtt{gnd}\mathtt{1.}\mathtt{g}\mathtt{.}\mathtt{v}\left(t\right)=0\\ \mathtt{gnd}\mathtt{2.}\mathtt{g}\mathtt{.}\mathtt{v}\left(t\right)=0\end{array}\right]$$

Source

"""
Test circuit for CCV (current-controlled voltage source).

A sine voltage source (amplitude=1 V, frequency=1 Hz) drives a 5 Ω series
resistor into the CCV input port (port 1). Since v1=0, the full source
voltage drops across the resistor, producing i1 = V_source/R_series.
A 10 Ω resistor loads the output port (port 2).
CCV transResistance = 20 Ω.

Expected (algebraic, holds for all t):
- v1 = 0  (zero input impedance)
- i1 = sin(2π·t)/5 = 0.2·sin(2π·t)
- v2 = transResistance·i1 = 4·sin(2π·t)
- i2 = −v2/R_load = −0.4·sin(2π·t)
"""
test component CCV
  "Sine signal: amplitude=1, frequency=1 Hz"
  sine = BlockComponents.Sources.Sine(amplitude = 1, frequency = 1) {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 0, "y1": 310, "x2": 100, "y2": 410, "rot": 0}
      },
      "tags": []
    }
  }
  "Input voltage source"
  vs = ElectricalComponents.Analog.Sources.VoltageSource() {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 160, "y1": 410, "x2": 260, "y2": 310, "rot": 90}
      },
      "tags": []
    }
  }
  "Series resistor to convert voltage to current"
  r_series = ElectricalComponents.Analog.Basic.Resistor(R = 5) {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 310, "y1": 200, "x2": 410, "y2": 300, "rot": 0}
      },
      "tags": []
    }
  }
  "CCV with transResistance=20 Ω"
  ccv = ElectricalComponents.Analog.Basic.CCV(transResistance = 20) {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 510, "y1": 320, "x2": 610, "y2": 420, "rot": 0}
      },
      "tags": []
    }
  }
  "Output load resistor"
  r_load = ElectricalComponents.Analog.Basic.Resistor(R = 10) {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 790, "y1": 410, "x2": 890, "y2": 310, "rot": 90}
      },
      "tags": []
    }
  }
  "Input-side ground"
  gnd1 = ElectricalComponents.Analog.Basic.Ground() {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 160, "y1": 580, "x2": 260, "y2": 680, "rot": 0}
      },
      "tags": []
    }
  }
  "Output-side ground"
  gnd2 = ElectricalComponents.Analog.Basic.Ground() {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 580, "y1": 590, "x2": 680, "y2": 690, "rot": 0}
      },
      "tags": []
    }
  }
relations
  connect(sine.y, vs.V) {"Dyad": {"edges": [{"S": 1, "M": [], "E": 2}], "renderStyle": "standard"}}
  connect(vs.p, r_series.p) {
    "Dyad": {
      "edges": [{"S": 1, "M": [{"x": 210, "y": 250}, {"x": 310, "y": 250}], "E": 2}],
      "renderStyle": "standard"
    }
  }
  connect(r_series.n, ccv.p1) {
    "Dyad": {
      "edges": [{"S": 1, "M": [{"x": 460, "y": 250}, {"x": 460, "y": 321}], "E": 2}],
      "renderStyle": "standard"
    }
  }
  connect(vs.n, gnd1.g) {"Dyad": {"edges": [{"S": 1, "M": [], "E": 2}], "renderStyle": "standard"}}
  connect(vs.n, ccv.n1) {
    "Dyad": {
      "edges": [
        {
          "S": 1,
          "M": [
            {"x": 210, "y": 470},
            {"x": 450, "y": 470},
            {"x": 450, "y": 420},
            {"x": 511, "y": 420}
          ],
          "E": 2
        }
      ],
      "renderStyle": "standard"
    }
  }
  connect(ccv.p2, r_load.p) {
    "Dyad": {
      "edges": [
        {
          "S": 1,
          "M": [
            {"x": 611, "y": 320},
            {"x": 680, "y": 320},
            {"x": 680, "y": 250},
            {"x": 840, "y": 250}
          ],
          "E": 2
        }
      ],
      "renderStyle": "standard"
    }
  }
  connect(r_load.n, ccv.n2) {
    "Dyad": {
      "edges": [
        {
          "S": 1,
          "M": [{"x": 840, "y": 470}, {"x": 631, "y": 470}, {"x": 631, "y": 420}],
          "E": 2
        }
      ],
      "renderStyle": "standard"
    }
  }
  connect(gnd2.g, ccv.n2) {
    "Dyad": {
      "renderStyle": "standard",
      "edges": [{"S": 1, "M": [{"x": 630, "y": 420}], "E": 2}]
    }
  }
metadata {
  "Dyad": {
    "icons": {"default": "dyad://ElectricalComponents/Example.svg"},
    "tests": {
      "case1": {"stop": 1, "expect": {"signals": ["ccv.v1", "ccv.v2", "ccv.i1", "ccv.i2"]}}
    }
  }
}
end

Flattened Source

"""
Test circuit for CCV (current-controlled voltage source).

A sine voltage source (amplitude=1 V, frequency=1 Hz) drives a 5 Ω series
resistor into the CCV input port (port 1). Since v1=0, the full source
voltage drops across the resistor, producing i1 = V_source/R_series.
A 10 Ω resistor loads the output port (port 2).
CCV transResistance = 20 Ω.

Expected (algebraic, holds for all t):
- v1 = 0  (zero input impedance)
- i1 = sin(2π·t)/5 = 0.2·sin(2π·t)
- v2 = transResistance·i1 = 4·sin(2π·t)
- i2 = −v2/R_load = −0.4·sin(2π·t)
"""
test component CCV
  "Sine signal: amplitude=1, frequency=1 Hz"
  sine = BlockComponents.Sources.Sine(amplitude = 1, frequency = 1) {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 0, "y1": 310, "x2": 100, "y2": 410, "rot": 0}
      },
      "tags": []
    }
  }
  "Input voltage source"
  vs = ElectricalComponents.Analog.Sources.VoltageSource() {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 160, "y1": 410, "x2": 260, "y2": 310, "rot": 90}
      },
      "tags": []
    }
  }
  "Series resistor to convert voltage to current"
  r_series = ElectricalComponents.Analog.Basic.Resistor(R = 5) {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 310, "y1": 200, "x2": 410, "y2": 300, "rot": 0}
      },
      "tags": []
    }
  }
  "CCV with transResistance=20 Ω"
  ccv = ElectricalComponents.Analog.Basic.CCV(transResistance = 20) {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 510, "y1": 320, "x2": 610, "y2": 420, "rot": 0}
      },
      "tags": []
    }
  }
  "Output load resistor"
  r_load = ElectricalComponents.Analog.Basic.Resistor(R = 10) {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 790, "y1": 410, "x2": 890, "y2": 310, "rot": 90}
      },
      "tags": []
    }
  }
  "Input-side ground"
  gnd1 = ElectricalComponents.Analog.Basic.Ground() {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 160, "y1": 580, "x2": 260, "y2": 680, "rot": 0}
      },
      "tags": []
    }
  }
  "Output-side ground"
  gnd2 = ElectricalComponents.Analog.Basic.Ground() {
    "Dyad": {
      "placement": {
        "diagram": {"iconName": "default", "x1": 580, "y1": 590, "x2": 680, "y2": 690, "rot": 0}
      },
      "tags": []
    }
  }
relations
  connect(sine.y, vs.V) {"Dyad": {"edges": [{"S": 1, "M": [], "E": 2}], "renderStyle": "standard"}}
  connect(vs.p, r_series.p) {
    "Dyad": {
      "edges": [{"S": 1, "M": [{"x": 210, "y": 250}, {"x": 310, "y": 250}], "E": 2}],
      "renderStyle": "standard"
    }
  }
  connect(r_series.n, ccv.p1) {
    "Dyad": {
      "edges": [{"S": 1, "M": [{"x": 460, "y": 250}, {"x": 460, "y": 321}], "E": 2}],
      "renderStyle": "standard"
    }
  }
  connect(vs.n, gnd1.g) {"Dyad": {"edges": [{"S": 1, "M": [], "E": 2}], "renderStyle": "standard"}}
  connect(vs.n, ccv.n1) {
    "Dyad": {
      "edges": [
        {
          "S": 1,
          "M": [
            {"x": 210, "y": 470},
            {"x": 450, "y": 470},
            {"x": 450, "y": 420},
            {"x": 511, "y": 420}
          ],
          "E": 2
        }
      ],
      "renderStyle": "standard"
    }
  }
  connect(ccv.p2, r_load.p) {
    "Dyad": {
      "edges": [
        {
          "S": 1,
          "M": [
            {"x": 611, "y": 320},
            {"x": 680, "y": 320},
            {"x": 680, "y": 250},
            {"x": 840, "y": 250}
          ],
          "E": 2
        }
      ],
      "renderStyle": "standard"
    }
  }
  connect(r_load.n, ccv.n2) {
    "Dyad": {
      "edges": [
        {
          "S": 1,
          "M": [{"x": 840, "y": 470}, {"x": 631, "y": 470}, {"x": 631, "y": 420}],
          "E": 2
        }
      ],
      "renderStyle": "standard"
    }
  }
  connect(gnd2.g, ccv.n2) {
    "Dyad": {
      "renderStyle": "standard",
      "edges": [{"S": 1, "M": [{"x": 630, "y": 420}], "E": 2}]
    }
  }
metadata {
  "Dyad": {
    "icons": {"default": "dyad://ElectricalComponents/Example.svg"},
    "tests": {
      "case1": {"stop": 1, "expect": {"signals": ["ccv.v1", "ccv.v2", "ccv.i1", "ccv.i2"]}}
    }
  }
}
end

Test Cases

Test Case case1

plt

plt

plt

plt

Related

• Examples

• Experiments

• Analyses

• Tests

  • CCV

  • CCV

  • Ground

  • Resistor

  • Sine

  • VoltageSource