This device allows current to flow in both directions and can also block the voltage in both directions. Its states depends only on gate control signal (controlled commutation).
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An Ideal switch is a switch that neither consumes nor dissipates any power from its sources.
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Internal resistance (Ron) | The diode internal on resistance, in ohms (Ω). |
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Internal off resistance (Roff) | The diode internal off resistance, in ohms (Ω). |
Gate control signal (g) | The signal to control on/off state of the switch. |
Discrete-time switch conductance (Gs) | The discrete-time switch conductance, in S. See How to tune discrete-time switch condutance for detailed explanation. |
Relaxation (Relax) | The relaxation parameter of the switch. Values can range between 0.1 for maximum performance or 10 for maximum stability. See How to tune single switch parameters for detailed explanation. |
Damping resistance (Rdamp) | Damping resistance value, in ohms (Ω). See How to tune single switch parameters for detailed explanation. |
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Parameters
Electrical Ports
From top to bottom, the electrical ports are the positive and negative ports of the source respectively named p1 and n1
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g | Digital input controlling the gate. This input could be assigned to a digital input channel or a signal coming from Simulink or HYPERSIM. |
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Characteristics
Advanced - Gen 4
Advanced parameters for Gen 4 solver architecture:
Discrete-time switch conductance (Gs)
are only visible when selecting Nodal Analysis (Gen4) circuit analysis method in Solver Settings.
Precision on how to tune this parameter can be found here: /wiki/spaces/FPET/pages/22924052.
Advanced - Gen 5
Advanced parameters for Gen 5 solver architecture:
Relaxation (Relax)
Damping resistance (Rdamp)
are only visible when selecting State-space Analysis (Gen5) circuit analysis method in Solver Settings.
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