Analog.IdealSwitch
This component extends from OnePort This component extends from ConditionalHeatPort
Usage
TranslatedComponents.Analog.IdealSwitch(T=293.15, unitVoltage=1, unitCurrent=1, Ron=1.0e-5, Goff=1.0e-5)
Parameters:
| Name | Description | Units | Default value |
|---|---|---|---|
useHeatPort | = true, if heatPort is enabled | – | false |
T | Fixed device temperature if useHeatPort = false | K | 293.15 |
unitVoltage | V | 1 | |
unitCurrent | A | 1 | |
Ron | Closed switch resistance | Ω | 0.00001 |
Goff | Opened switch conductance | S | 0.00001 |
Connectors
p- This connector represents an electrical pin with voltage and current as the potential and flow variables, respectively. (Pin)n- This connector represents an electrical pin with voltage and current as the potential and flow variables, respectively. (Pin)heatPort- Thermal port for 1-dim. heat transfer
This component is translated by DyadAI (HeatPort)
Variables
| Name | Description | Units |
|---|---|---|
v | Voltage drop of the two pins (= p.v - n.v) | V |
i | Current flowing from pin p to pin n | A |
LossPower | Loss power leaving component via heatPort | W |
T_heatPort | Temperature of heatPort | K |
off | Indicates off-state | – |
s | Auxiliary variable | – |
Source
dyad
partial component IdealSwitch
extends OnePort
extends ConditionalHeatPort(T = 293.15)
parameter unitVoltage::Dyad.Voltage = 1
parameter unitCurrent::Dyad.Current = 1
# Closed switch resistance
parameter Ron::Dyad.Resistance(final min = 0) = 1.0e-5
# Opened switch conductance
parameter Goff::Dyad.Conductance(final min = 0) = 1.0e-5
# Indicates off-state
variable off::Boolean
# Auxiliary variable
variable s::Real
relations
v = s * (off ? unitVoltage : Ron * unitCurrent)
i = s * (off ? Goff * unitVoltage : unitCurrent)
LossPower = v * i
endFlattened Source
dyad
partial component IdealSwitch
p = Pin()
n = Pin()
# Voltage drop of the two pins (= p.v - n.v)
variable v::Dyad.Voltage
# Current flowing from pin p to pin n
variable i::Dyad.Current
heatPort = TranslatedComponents.HeatTransfer.HeatPort() if useHeatPort
# = true, if heatPort is enabled
structural parameter useHeatPort::Boolean = false
# Fixed device temperature if useHeatPort = false
parameter T::Dyad.Temperature = 293.15
# Loss power leaving component via heatPort
variable LossPower::Dyad.Power
# Temperature of heatPort
variable T_heatPort::Dyad.Temperature
parameter unitVoltage::Dyad.Voltage = 1
parameter unitCurrent::Dyad.Current = 1
# Closed switch resistance
parameter Ron::Dyad.Resistance(final min = 0) = 1.0e-5
# Opened switch conductance
parameter Goff::Dyad.Conductance(final min = 0) = 1.0e-5
# Indicates off-state
variable off::Boolean
# Auxiliary variable
variable s::Real
relations
v = p.v - n.v
0 = p.i + n.i
i = p.i
if !(useHeatPort)
T_heatPort = T
else
initial heatPort.T = T_heatPort
initial heatPort.Q_flow = -LossPower
end
v = s * (off ? unitVoltage : Ron * unitCurrent)
i = s * (off ? Goff * unitVoltage : unitCurrent)
LossPower = v * i
metadata {}
endTest Cases
No test cases defined.
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