Main Content

Optocoupler

Behavioral model of optocoupler as LED, current sensor, and controlled current source

  • Optocoupler block

Libraries:
Simscape / Electrical / Semiconductors & Converters

Description

This block represents an optocoupler using a model that consists of the following components:

  • An exponential light-emitting diode in series with a current sensor on the input side

  • A controlled current source on the output side

The output-side current flows from the collector junction to the emitter junction. It has a value of CTR·Id, where CTR is the Current transfer ratio parameter value and Id is the diode current.

Use the Optocoupler block to interface two electrical circuits without making a direct electrical connection. A common reason for doing this is that the two circuits work at very different voltage levels.

Note

Each electrical circuit must have its own Electrical Reference block.

If the output circuit is a phototransistor, typical values for the Current transfer ratio parameter are 0.1 to 0.5. If the output stage consists of a Darlington pair, the parameter value can be much higher than this. The Current transfer ratio value also varies with the light-emitting diode current, but this effect is not modeled by the Photodiode block.

Some manufacturers provide a maximum data rate for optocouplers. In practice, the maximum data rate depends on the following factors:

  • The capacitance of the photodiode and the type of the driving circuit

  • The construction of the phototransistor and its associated capacitance

The Optocoupler block only lets you define the capacitance on the light-emitting diode. You can use the Junction capacitance parameter to add your own capacitance across the collector and emitter connections.

The Optocoupler block lets you model temperature dependence of the underlying diode. For details, see the Diode reference page.

Thermal Port

You can expose the thermal port to model the effects of generated heat and device temperature. To expose the thermal port, set the Modeling option parameter to either:

  • No thermal port — The block does not contain a thermal port and does not simulate heat generation in the device.

  • Show thermal port — The block contains a thermal port that allows you to model the heat that conduction losses generate. For numerical efficiency, the thermal state does not affect the electrical behavior of the block.

For more information on using thermal ports and on the Thermal Port parameters, see Simulating Thermal Effects in Semiconductors.

Variables

To set the priority and initial target values for the block variables before simulation, use the Initial Targets section in the block dialog box or Property Inspector. For more information, see Set Priority and Initial Target for Block Variables.

Use nominal values to specify the expected magnitude of a variable in a model. Using system scaling based on nominal values increases the simulation robustness. Nominal values can come from different sources. One of these sources is the Nominal Values section in the block dialog box or Property Inspector. For more information, see System Scaling by Nominal Values.

Assumptions and Limitations

  • The output side is modeled as a controlled current source. As such, it only correctly approximates a bipolar transistor operating in its normal active region. To create a more detailed model, connect the Optocoupler output directly to the base of an NPN Bipolar Transistor block, and set the parameters to maintain a correct overall value for the current transfer ratio. If you need to connect optocouplers in series, use this approach to avoid the invalid topology of two current sources in series.

  • The temperature dependence of the forward current transfer ratio is not modeled. Typically the temperature dependence of this parameter is much less than that of the optical diode I-V characteristic.

  • You may need to use nonzero ohmic resistance and junction capacitance values to prevent numerical simulation issues, but the simulation may run faster with these values set to zero.

Ports

Conserving

expand all

Electrical conserving port associated with the diode positive terminal

Electrical conserving port associated with the diode negative terminal

Electrical conserving port associated with the transistor collector terminal

Electrical conserving port associated with the transistor emitter terminal

Thermal conserving port.

Dependencies

To enable this port, set Modeling option to Show thermal port.

Parameters

expand all

Whether to enable the thermal port of the block and model the effects of generated heat and device temperature.

Main

The output current flowing from the transistor collector to emitter junctions is equal to the product of the current transfer ratio and the current flowing in the light-emitting diode.

Select one of the following methods for model parameterization:

  • Use I-V curve data points — Specify measured data at two points on the diode I-V curve.

  • Use parameters IS and N — Specify saturation current and emission coefficient.

A vector of the current values at the two points on the diode I-V curve that the block uses to calculate IS and N.

Dependencies

This parameter is visible only when you select Use I-V curve data points for the Diode parameterization parameter.

A vector of the voltage values at the two points on the diode I-V curve that the block uses to calculate IS and N.

Dependencies

This parameter is visible only when you select Use I-V curve data points for the Diode parameterization parameter.

The series diode connection resistance.

The magnitude of the current that the ideal diode equation approaches asymptotically for very large reverse bias levels.

Dependencies

This parameter is visible only when you select Use parameters IS and N for the Diode parameterization parameter.

The temperature at which IS or the I-V curve was measured. The default value is 25 °C.

The diode emission coefficient or ideality factor.

Dependencies

This parameter is visible only when you select Use parameters IS and N for the Diode parameterization parameter.

Junction Capacitance

Select one of the following options for modeling the diode junction capacitance:

  • Fixed or zero junction capacitance — Model the junction capacitance as a fixed value.

  • Use C-V curve data points — Specify measured data at three points on the diode C-V curve.

  • Use parameters CJ0, VJ, M & FC — Specify zero-bias junction capacitance, junction potential, grading coefficient, and forward-bias depletion capacitance coefficient.

Fixed junction capacitance value.

Dependencies

This parameter is visible only when you select Fixed or zero junction capacitance for the Capacitance parameter.

The value of the capacitance placed in parallel with the exponential diode term.

Dependencies

This parameter is visible only when you select Use parameters CJ0, VJ, M & FC for the Capacitance parameter.

The junction potential.

Dependencies

This parameter is visible only when you select Use parameters CJ0, VJ, M & FC for the Capacitance parameter.

The coefficient that quantifies the grading of the junction.

Dependencies

This parameter is visible only when you select Use parameters CJ0, VJ, M & FC for the Capacitance parameter.

A vector of the reverse bias voltage values at the three points on the diode C-V curve that the block uses to calculate CJ0, VJ, and M.

Dependencies

This parameter is visible only when you select Use C-V curve data points for the Capacitance parameter.

A vector of the capacitance values at the three points on the diode C-V curve that the block uses to calculate CJ0, VJ, and M.

Dependencies

This parameter is visible only when you select Use C-V curve data points for the Capacitance parameter.

Fitting coefficient that quantifies the decrease of the depletion capacitance with applied voltage.

Dependencies

This parameter is visible only when you select Use C-V curve data points or Use parameters CJ0, VJ, M & FC for the Capacitance parameter.

Temperature Dependence

Select one of the following methods for temperature dependence parameterization:

  • None — Simulate at parameter measurement temperature — Temperature dependence is not modeled, or the model is simulated at the measurement temperature Tm1 (as specified by the Measurement temperature parameter on the Main tab). This is the default method.

  • Use an I-V data point at second measurement temperature T2 — If you select this option, you specify a second measurement temperature Tm2, and the current and voltage values at this temperature. The model uses these values, along with the parameter values at the first measurement temperature Tm1, to calculate the energy gap value.

  • Specify saturation current at second measurement temperature T2 — If you select this option, you specify a second measurement temperature Tm2, and saturation current value at this temperature. The model uses these values, along with the parameter values at the first measurement temperature Tm1, to calculate the energy gap value.

  • Specify the energy gap EG — Specify the energy gap value directly.

Specify the diode current I1 value when the voltage is V1 at the second measurement temperature.

Dependencies

This parameter is visible only when you select Use an I-V data point at second measurement temperature T2 for the Parameterization parameter.

Specify the diode voltage V1 value when the current is I1 at the second measurement temperature.

Dependencies

This parameter is visible only when you select Use an I-V data point at second measurement temperature T2 for the Parameterization parameter.

Specify the saturation current IS value at the second measurement temperature.

Dependencies

This parameter is visible only when you select Specify saturation current at second measurement temperature T2 for the Parameterization parameter.

Specify the value for the second measurement temperature.

Dependencies

This parameter is visible only when you select Use an I-V data point at second measurement temperature T2 or Specify saturation current at second measurement temperature T2 for the Parameterization parameter.

Select a value for the energy gap from a list of predetermined options, or specify a custom value:

  • Use nominal value for silicon (EG=1.11eV) — This is the default.

  • Use nominal value for 4H-SiC silicon carbide (EG=3.23eV)

  • Use nominal value for 6H-SiC silicon carbide (EG=3.00eV)

  • Use nominal value for germanium (EG=0.67eV)

  • Use nominal value for gallium arsenide (EG=1.43eV)

  • Use nominal value for selenium (EG=1.74eV)

  • Use nominal value for Schottky barrier diodes (EG=0.69eV)

  • Specify a custom value — If you select this option, the Energy gap, EG parameter appears in the dialog box, to let you specify a custom value for EG.

Dependencies

This parameter is visible only when you select Specify the energy gap EG for the Parameterization parameter.

Specify a custom value for the energy gap, EG.

Dependencies

This parameter is visible only when you select Specify a custom value for the Energy gap parameterization parameter.

Select one of the following options to specify the saturation current temperature exponent value:

  • Use nominal value for pn-junction diode (XTI=3) — This is the default.

  • Use nominal value for Schottky barrier diode (XTI=2)

  • Specify a custom value — If you select this option, the Saturation current temperature exponent, XTI parameter appears in the dialog box, to let you specify a custom value for XTI.

Specify a custom value for the saturation current temperature exponent, XTI.

Dependencies

This parameter is visible only when you select Specify a custom value for the Saturation current temperature exponent parameterization parameter.

Specify the value for the temperature Ts, at which the device is to be simulated.

References

[1] G. Massobrio and P. Antognetti. Semiconductor Device Modeling with SPICE. 2nd Edition, McGraw-Hill, 1993.

[2] H. Ahmed and P.J. Spreadbury. Analogue and digital electronics for engineers. 2nd Edition, Cambridge University Press, 1984.

Extended Capabilities

C/C++ Code Generation
Generate C and C++ code using Simulink® Coder™.

Version History

Introduced in R2008a