# Current-Controlled Switch

Current-controlled switch with hysteresis

• Library:
• Simscape / Electrical / Additional Components / SPICE Passives

• ## Description

The Current-Controlled Switch block represents the electrical characteristics of a switch whose state is controlled by the current through the input ports (the controlling current).

This block models either a variable-resistance or a short-transition switch. For a variable-resistance switch, set the Switch model parameter to `Smooth transition between Ion and Ioff`. For a short-transition switch, set Switch model to ```Abrupt transition after delay```.

### Short-transition Switch

In a short-transition switch, the transition between the off and on states is instantaneous:

• When the controlling current is greater than or equal to the sum of the Threshold current, IT and Hysteresis current, IH parameter values, the switch is closed and has a resistance equal to the On resistance, RON parameter value.

• When the controlling current is less than the Threshold current, IT parameter value minus the Hysteresis current, IH parameter value, the switch is open and has a resistance equal to the Off resistance, ROFF parameter value.

• When the controlling current is greater than or less than the Threshold current, IT parameter value by an amount less than or equal to the Hysteresis current, IH parameter value, the current is in the crossover region and the state of the switch remains unchanged.

Note

If the Hysteresis current, IH parameter value is less than `0`, the block models a variable-resistance switch independently of the value you set for the Switch model parameter.

### Variable-resistance Switch

In a variable-resistance switch, the transition between the off and on states is exponential:

• When the Control current for on state, ION is greater than the Control current for off state, IOFF:

• If the controlling current is greater than the Control current for on state, ION parameter value, the switch is closed and has a resistance equal to the On resistance, RON parameter value.

• If the controlling current is less than the Control current for off state, IOFF parameter value, the switch is open and has a resistance equal to the Off resistance, ROFF parameter value.

• If the controlling current is greater than the Control current for off state, IOFF parameter value or less than the Control current for on state, ION parameter value, the resistance is defined by:

`${R}_{s}=\mathrm{exp}\left[{L}_{m}+3{L}_{r}\left(\frac{{I}_{c}-{I}_{m}}{2{I}_{d}}\right)-2{L}_{r}\left(\frac{{\left({I}_{c}-{I}_{m}\right)}^{3}}{{I}_{d}^{3}}\right)\right]$`

where:

• Rs is the switch resistance.

• ${L}_{m}=ln\left[{\left({R}_{ON}*{R}_{OFF}\right)}^{\frac{1}{2}}\right]$ is the log-mean of resistor values.

• ${L}_{r}=ln\left(\frac{{R}_{ON}}{{R}_{OFF}}\right)$ is the log-ratio of resistor values.

• Ic is the controlling current.

• ${I}_{m}=\frac{{I}_{ON}+{I}_{OFF}}{2}$ is the mean of the control currents.

• ${I}_{d}={I}_{ON}-{I}_{OFF}$ is the difference between the control currents.

• When the Control current for on state, ION is less than the Control current for off state, IOFF:

• If the controlling current is less than the Control current for on state, ION parameter value, the switch is closed and has a resistance equal to the On resistance, RON parameter value.

• If the controlling current is greater than the Control current for off state, IOFF parameter value, the switch is open and has a resistance equal to the Off resistance, ROFF parameter value.

• If the controlling current is less than the Control current for off state, IOFF parameter value or greater than the Control current for on state, ION parameter value, the resistance is defined by:

`${R}_{s}=\mathrm{exp}\left[{L}_{m}+3{L}_{r}\left(\frac{{I}_{c}-{I}_{m}}{2{I}_{d}}\right)-2{L}_{r}\left(\frac{{\left({I}_{c}-{I}_{m}\right)}^{3}}{{I}_{d}^{3}}\right)\right]$`

## Assumptions and Limitations

The block output resistance model is discontinuous during switching. The discontinuity might cause numerical issues. Try the following actions to resolve the issues:

• Set the On resistance, RON and Off resistance, ROFF parameter values to keep RON divided by ROFF as large as possible, and more than `1e+12`.

• Increase the Hysteresis current, IH parameter value to reduce switch chatter.

• If a variable-step solver is employed, decrease the Max step size parameter value (in the Configuration Parameters block dialog box).

Note

This increases the simulation time.

## Ports

### Conserving

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Electrical conserving port associated with the current controlled switch positive input.

Electrical conserving port associated with the current controlled switch negative input.

Electrical conserving port associated with the current controlled switch positive output.

Electrical conserving port associated with the current controlled switch negative output.

## Parameters

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Whether the transition between on state and off state current is instantaneous or not. To model this block as a variable-resistance switch, select `Smooth transition between Ion and Ioff`. To model this block as a short-transition switch, select ```Abrupt transition after delay```.

Current above which the block interprets the controlling current as HIGH.

Note

The controlling current must differ from the threshold current by at least the Hysteresis current, IH parameter value to change the state of the switch.

#### Dependencies

To enable this parameter, set Switch model to `Abrupt transition after delay`.

Amount by which the controlling current must exceed or fall below the Threshold current, IT parameter value to change the state of the switch.

#### Dependencies

To enable this parameter, set Switch model to `Abrupt transition after delay`.

Switch control current for the on state.

#### Dependencies

To enable this parameter, set Switch model to ```Smooth transition between Ion and Ioff```.

Switch control current for the off state.

#### Dependencies

To enable this parameter, set Switch model to ```Smooth transition between Ion and Ioff```.

Resistance of the switch when it is closed.

Whether to automatically calculate the off resistance of this switch as `1/GMIN`.

Note

The value of the parallel conductance, GMIN, depends on whether your model contains an Environment Parameters block.

By default, GMIN matches the GMIN parameter of the Environment Parameters block, whose default value is 1e–12. To change GMIN, add an Environment Parameters block to your model and set the GMIN parameter to the desired value.

#### Dependencies

To enable this parameter, set Switch model to `Abrupt transition after delay`.

Resistance of the switch when it is open.

#### Dependencies

To enable this parameter either:

• Set Switch model to `Abrupt transition after delay` and Use 1/GMIN as Off resistance to `No`. The default value is `1e12`.

• Set Switch model to ```Smooth transition between Ion and Ioff```. The default value is `1e6`.

, .

Time delay after which the switch transition takes place.

#### Dependencies

To enable this parameter, set Switch model to `Abrupt transition after delay`.

## Version History

Introduced in R2009a