Boost Converter

Controller-driven DC-DC step-up voltage regulator

Library:
Simscape / Electrical / Semiconductors & Converters / Converters

Description

The Boost Converter block represents a converter that steps up DC voltage as driven by an attached controller and gate-signal generator. Boost converters are also known as step-up voltage regulators because they increase voltage magnitude.

The Boost Converter block allows you to model an asynchronous converter with one switching device or a synchronous converter with two switching devices. Options for the type of switching devices are:

GTO — Gate turn-off thyristor. For information about the I-V characteristic of the device, see GTO.
Ideal semiconductor switch — For information about the I-V characteristic of the device, see Ideal Semiconductor Switch.
IGBT — Insulated-gate bipolar transistor. For information about the I-V characteristic of the device, see IGBT (Ideal, Switching).
MOSFET — N-channel metal-oxide-semiconductor field-effect transistor. For information about the I-V characteristic of the device, see MOSFET (Ideal, Switching).
Thyristor — For information about the I-V characteristic of the device, see Thyristor (Piecewise Linear).
Averaged Switch.

Model

There are three model variants for the block. To access the model variants, in the model window, right-click the block. From the context menu, select Simscape > Block choices.

The model variants are:

PS control port — Asynchronous converter with a physical signal port. This block choice is the default.
Electrical control ports — Asynchronous converter with one positive and one negative electrical conserving port. To control switching device gates using Simscape™ Electrical™ blocks, select this option.
Synchronous converter — Synchronous converter with an electrical conserving port.

The asynchronous boost converter models contain an inductor, a switching device, a diode, and an output capacitor.

The synchronous boost converter model contains an inductor, two switching devices, and an output capacitor.

In each case, the capacitor smoothes the output voltage.

Protection

For the synchronous converter model, you can include an integral protection diodes. Integral diodes protect the semiconductor device by providing a conduction path for reverse current. An inductive load can produce a high reverse-voltage spike when the semiconductor device suddenly switches off the voltage supply to the load.

To include and configure the internal protection diodes, use the Diode parameters. This table shows how to set the Model dynamics parameter based on your goals.

Goals		Value to Select	Integral Protection Diode
Do not include protection.		`None`	None
Include protection.	Prioritize simulation speed.	`Diode with no dynamics`	The Diode block
Include protection.	Prioritize model fidelity by precisely specifying reverse-mode charge dynamics.	`Diode with charge dynamics`	The dynamic model of the Diode block

You can also include a snubber circuit for each switching device. Snubber circuits contain a series-connected resistor and capacitor. They protect switching devices against high voltages that inductive loads produce when the device turns off the voltage supply to the load. Snubber circuits also prevent excessive rates of current change when a switching device turns on.

To include and configure a snubber circuit for each switching device, use the Snubbers parameters.

Gate Control

To connect gate-control voltage signals to the gate ports of the switching devices, for the:

PS control port model:
1. Convert a Simulink^® gate-control voltage signal to a physical signal using a Simulink-PS Converter block.
2. Connect the Simulink-PS Converter block to the G port.
Electrical control ports model:
1. Connect a Simscape electrical-domain positive DC voltage signal to the G+ port.
2. Connect the Simscape electrical-domain negative DC voltage signal to the G- port.
Synchronous converter model:
1. Convert each Simulink gate-control voltage signal to a physical signal using Simulink-PS Converter blocks.
2. Multiplex the converted gate-control signals into a single vector using a Two-Pulse Gate Multiplexer.
3. Connect the vector signal to the G port.

Variables

Use the Variables settings to specify the priority and initial target values for the block variables before simulation. For more information, see Set Priority and Initial Target for Block Variables.

Ports

Input

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`G` — Switching device gate control
physical signal | vector

Physical signal port associated with the gate terminals of the switching device.

Dependencies

This port is enabled only for the PS control port block choice.

Data Types: double

Conserving

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`G` — Switching device gate control
electrical | vector

Electrical conserving port associated with the gate terminals of the switching devices.

Dependencies

This port is enabled only for the Synchronous converter block choice.

Data Types: double

`G+` — Switching device gate control positive terminal
electrical | scalar

Positive electrical conserving port associated with the positive gate terminal of the switching device.

Dependencies

This port is enabled only for the Electrical control ports block choice.

Data Types: double

`G-` — Switching device gate control negative terminal
electrical | scalar

Negative electrical conserving port associated with the negative gate terminal of the switching device.

Dependencies

This port is enabled only for the Electrical control ports block choice.

Data Types: double

`1+` — Positive DC voltage 1
electrical | scalar

Electrical conserving port associated with the positive terminal of the first DC voltage.

Data Types: double

`1-` — Negative DC voltage 1
electrical | scalar

Electrical conserving port associated with the negative terminal of the first DC voltage.

Data Types: double

`2+` — Positive DC voltage 2
electrical | scalar

Electrical conserving port associated with the positive terminal of the second DC voltage.

Data Types: double

`2-` — Negative DC voltage 2
electrical | scalar

Electrical conserving port associated with the negative terminal of the second DC voltage.

Data Types: double

Parameters

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Switching Devices

This table shows how the visibility of Switching Devices parameters depends on the Switching device that you select. To learn how to read the table, see Parameter Dependencies.

Switching Devices Parameter Dependencies

Parameters and Options
Switching device
`Ideal Semiconductor Switch`	`GTO`	`IGBT`	`MOSFET`	`Thyristor`	`Averaged Switch`
On-state resistance	Forward voltage	Forward voltage	Drain-source on resistance	Forward voltage	On-state resistance
Off-state conductance	On-state resistance	On-state resistance	Off-state conductance	On-state resistance
Threshold voltage	Off-state conductance	Off-state conductance	Threshold voltage	Off-state conductance
	Gate trigger voltage, Vgt	Threshold voltage		Gate trigger voltage, Vgt
	Gate turn-off voltage, Vgt_off			Gate turn-off voltage, Vgt_off
	Holding current			Holding current

`Switching device` — Switch type
`Ideal Semiconductor Switch` (default) | `GTO` | `IGBT` | `MOSFET` | `Thyristor` | `Averaged Switch`

Switching device type for the converter. For the synchronous model, the switches are identical.

Dependencies

See the Switching Devices Parameter Dependencies table.

`Forward voltage` — Voltage
`0.8` `V` (default) | scalar

For the different switching device types, the Forward voltage is taken as:

GTO — Minimum voltage required across the anode and cathode block ports for the gradient of the device I-V characteristic to be 1/R_on, where R_on is the value of On-state resistance
IGBT — Minimum voltage required across the collector and emitter block ports for the gradient of the diode I-V characteristic to be 1/R_on, where R_on is the value of On-state resistance
Thyristor — Minimum voltage required for the device to turn on

Dependencies

See the Switching Devices Parameter Dependencies table.

`On-state resistance` — Resistance
`0.001` `Ohm` (default) | scalar

For the different switching device types, the On-state resistance is taken as:

GTO — Rate of change of voltage versus current above the forward voltage
Ideal semiconductor switch — Anode-cathode resistance when the device is on
IGBT — Collector-emitter resistance when the device is on
Thyristor — Anode-cathode resistance when the device is on
Averaged switch — Anode-cathode resistance when the device is on

Dependencies

See the Switching Devices Parameter Dependencies table.

`Drain-source on resistance` — Resistance
`0.001` `Ohm` (default) | scalar

Resistance between the drain and the source, which also depends on the gate-to-source voltage.

Dependencies

See the Switching Devices Parameter Dependencies table.

`Off-state conductance` — Conductance
`1e-5` `1/Ohm` (default) | scalar

Conductance when the device is off. The value must be less than 1/R, where R is the value of On-state resistance.

For the different switching device types, the On-state resistance is taken as:

GTO — Anode-cathode conductance
Ideal semiconductor switch — Anode-cathode conductance
IGBT — Collector-emitter conductance
MOSFET — Drain-source conductance
Thyristor — Anode-cathode conductance

Dependencies

See the Switching Devices Parameter Dependencies table.

`Threshold voltage` — Voltage threshold
`6` `V` (default) | scalar

Gate voltage threshold. The device turns on when the gate voltage is above this value. For the different switching device types, the device voltage of interest is:

Ideal semiconductor switch — Gate-emitter voltage
IGBT — Gate-cathode voltage
MOSFET — Gate-source voltage

Dependencies

See the Switching Devices Parameter Dependencies table.

`Gate trigger voltage, Vgt` — Voltage threshold
`1` `V` (default) | scalar

Gate-cathode voltage threshold. The device turns on when the gate-cathode voltage is above this value.

Dependencies

See the Switching Devices Parameter Dependencies table.

`Gate turn-off voltage, Vgt_off` — Voltage threshold
`-1` `V` (default) | scalar

Gate-cathode voltage threshold. The device turns off when the gate-cathode voltage is below this value.

Dependencies

See the Switching Devices Parameter Dependencies table.

`Holding current` — Current threshold
`1` `A` (default) | scalar

Gate current threshold. The device stays on when the current is above this value, even when the gate-cathode voltage falls below the gate trigger voltage.

Dependencies

See the Switching Devices Parameter Dependencies table.

Diode

This table shows how the visibility of Diode parameters depends on how you configure the Block choice, Model dynamics, and Reverse recovery time parameterization parameters. To learn how to read this table, see Parameter Dependencies.

Diode Parameter Dependencies

Parameters and Options
Block choice
`PS control port` or `Electrical control ports`				`Synchronous converter`
Model dynamics				Model dynamics
`Diode with no dynamics`	`Diode with charge dynamics`			`None`	`Diode with no dynamics`	`Diode with charge dynamics`
Forward voltage	Forward voltage				Forward voltage	Forward voltage
On resistance	On resistance				On resistance	On resistance
Off conductance	Off conductance				Off conductance	Off conductance
	Junction capacitance					Junction capacitance
	Peak reverse current, iRM					Peak reverse current, iRM
	Initial forward current when measuring iRM					Initial forward current when measuring iRM
	Rate of change of current when measuring iRM					Rate of change of current when measuring iRM
	Reverse recovery time parameterization					Reverse recovery time parameterization
	`Specify stretch factor`	`Specify reverse recovery time directly`	`Specify reverse recovery charge`			`Specify stretch factor`	`Specify reverse recovery time directly`	`Specify reverse recovery charge`
	Reverse recovery time stretch factor	Reverse recovery time, trr	Reverse recovery charge, Qrr			Reverse recovery time stretch factor	Reverse recovery time, trr	Reverse recovery charge, Qrr

`Model dynamics` — Diode model
`Diode with no dynamics` (default) | `Diode with charge dynamics` | `None`

Diode type. The options are:

None — This option is not available for the asynchronous converter.
Diode with no dynamics — Select this option to prioritize simulation speed using the Diode block. This option is the default for the asynchronous converter.
Diode with charge dynamics — Select this option to prioritize model fidelity in terms of reverse mode charge dynamics using the commutation diode model of the Diode block.

Note

If you select Averaged Switch for the Switching Device parameter in the Switching Device setting, this parameter is not visible and Diode with no dynamics is automatically selected.

Dependencies

See the Diode Parameter Dependencies table.

`Forward voltage` — Voltage
`0.8` `V` (default) | scalar

Minimum voltage required across the positive and negative block ports for the gradient of the diode I-V characteristic to be 1/R_on, where R_on is the value of On resistance.

`On resistance` — Resistance
`0.001` `Ohm` (default) | scalar

Rate of change of voltage versus current above the Forward voltage.

`Off conductance` — Conductance
`1e-5` `1/Ohm` (default) | scalar

Conductance of the reverse-biased diode.

`Junction capacitance` — Capacitance
`50` `nF` (default) | scalar

Diode junction capacitance.

Dependencies

See the Diode Parameter Dependencies table.

`Peak reverse current, iRM` — Current
`-235` `A` (default) | scalar less than `0`

Peak reverse current measured by an external test circuit.

Dependencies

See the Diode Parameter Dependencies table.

`Initial forward current when measuring iRM` — Current
`300` `A` (default) | scalar greater than `0`

Initial forward current when measuring peak reverse current. This value must be greater than zero.

Dependencies

See the Diode Parameter Dependencies table.

`Rate of change of current when measuring iRM` — Current change rate
`-50` `A/us` (default) | scalar

Rate of change of current when measuring peak reverse current.

Dependencies

See the Diode Parameter Dependencies table.

`Reverse recovery time parameterization` — Recovery-time model
`Specify stretch factor` (default) | `Specify reverse recovery time directly` | `Specify reverse recovery charge`

Model for parameterizing the recovery time. When you select Specify stretch factor or Specify reverse recovery charge, you can specify a value that the block uses to derive the reverse recovery time.

Dependencies

See the Diode Parameter Dependencies table.

`Reverse recovery time stretch factor` — Stretch factor
`3` (default) | scalar greater than `1`

Value that the block uses to calculate Reverse recovery time, trr. Specifying the stretch factor is an easier way to parameterize the reverse recovery time than specifying the reverse recovery charge. The larger the value of the stretch factor, the longer it takes for the reverse recovery current to dissipate.

Dependencies

See the Diode Parameter Dependencies table.

`Reverse recovery time, trr` — Time
`15` `us` (default) | scalar

Interval between the time when the current initially goes to zero (when the diode turns off) and the time when the current falls to less than 10 percent of the peak reverse current.

The value of the Reverse recovery time, trr parameter must be greater than the value of the Peak reverse current, iRM parameter divided by the value of the Rate of change of current when measuring iRM parameter.

Dependencies

See the Diode Parameter Dependencies table.

`Reverse recovery charge, Qrr` — Charge
`1500` `s*uA` (default) | scalar

Value that the block uses to calculate Reverse recovery time, trr. Use this parameter if the data sheet for your diode device specifies a value for the reverse recovery charge instead of a value for the reverse recovery time.

The reverse recovery charge is the total charge that continues to dissipate when the diode turns off. The value must be less than $- \frac{i^{2}_{R M}}{2 a}$ ,

where:

i_RM is the value specified for Peak reverse current, iRM.
a is the value specified for Rate of change of current when measuring iRM.

Dependencies

See the Diode Parameter Dependencies table.

LC Parameters

`Inductance` — Inductance
`1e-6` `H` (default) | positive scalar

Inductance.

`Capacitance` — Capacitance
`1e-7` `F` (default) | positive scalar

Capacitance.

`Capacitor effective series resistance` — Capacitor resistance
`1e-6` `Ohm` (default) | zero or positive scalar

Series resistance of the capacitor.

Snubbers

The Snubbers parameters tab is not visible if you set Switching device to Averaged Switch.

The table summarizes the Snubbers parameter dependencies. To learn how to read the table, see Parameter Dependencies.

Snubbers Parameter Dependencies

Snubbers Parameter Dependencies
Snubber
`None`	`RC Snubber`
	Snubber resistance
	Snubber capacitance

`Snubber` — Snubber model
`None` (default) | `RC snubber`

Switching device snubber.

Dependencies

See the Snubbers Parameter Dependencies table.

`Snubber resistance` — Resistance
`0.1` (default) | `Ohm` | scalar

Resistance of the switching device snubber.

Dependencies

See the Snubbers Parameter Dependencies table.

`Snubber capacitance` — Capacitance
`1e-7` (default) | `F` | scalar

Capacitance of the switching device snubber.

Dependencies

See the Snubbers Parameter Dependencies table.

Model Examples

Boost Converter Voltage Control

Control the output voltage of a boost converter. To adjust the duty cycle, the Control subsystem uses a PI-based control algorithm. The input voltage is considered constant throughout the simulation. A variable resistor provides the load for the system. The total simulation time (t) is 0.25 seconds. At t = 0.15 seconds, the load changes.

Power Factor Correction for CCM Boost Converter

Correct the power factor using a PFC pre-converter. This technique is useful when non-linear impedances, such as Switch Mode Power Supplies, are connected to an AC grid. As the current flowing through the inductor is never zero during the switching cycle, the boost converter operates in Continuous Conduction Mode (CCM). The inductor current and the output voltage profiles are controlled using simple integral control. During start up, the reference output voltage is ramped up to the desired voltage.

References

[1] Trzynadlowski, A. M. Introduction to Modern Power Electronics, 2nd Edition. Hoboken, NJ: John Wiley & Sons Inc., 2010.

[2] Han, D. and B. Sarlioglu, "Deadtime Effect on GaN-Based Synchronous Boost Converter and Analytical Model for Optimal Deadtime Selection." IEEE Transactions on Power Electronics.Vol. 31, Number 1, 2016, pp 601-612.

Documentation

Boost Converter

Description

Model

Protection

Gate Control

Variables

Ports

Input

G — Switching device gate control physical signal | vector

Dependencies

Conserving

G — Switching device gate control electrical | vector

Dependencies

G+ — Switching device gate control positive terminal electrical | scalar

Dependencies

G- — Switching device gate control negative terminal electrical | scalar

Dependencies

1+ — Positive DC voltage 1 electrical | scalar

1- — Negative DC voltage 1 electrical | scalar

2+ — Positive DC voltage 2 electrical | scalar

2- — Negative DC voltage 2 electrical | scalar

Parameters

Switching Devices

Switching device — Switch type Ideal Semiconductor Switch (default) | GTO | IGBT | MOSFET | Thyristor | Averaged Switch

Dependencies

Forward voltage — Voltage 0.8 V (default) | scalar

Dependencies

On-state resistance — Resistance 0.001 Ohm (default) | scalar

Dependencies

Drain-source on resistance — Resistance 0.001 Ohm (default) | scalar

Dependencies

Off-state conductance — Conductance 1e-5 1/Ohm (default) | scalar

Dependencies

Threshold voltage — Voltage threshold 6 V (default) | scalar

Dependencies

Gate trigger voltage, Vgt — Voltage threshold 1 V (default) | scalar

Dependencies

Gate turn-off voltage, Vgt_off — Voltage threshold -1 V (default) | scalar

Dependencies

Holding current — Current threshold 1 A (default) | scalar

Dependencies

Diode

Model dynamics — Diode model Diode with no dynamics (default) | Diode with charge dynamics | None

Dependencies

Forward voltage — Voltage 0.8 V (default) | scalar

On resistance — Resistance 0.001 Ohm (default) | scalar

Off conductance — Conductance 1e-5 1/Ohm (default) | scalar

Junction capacitance — Capacitance 50 nF (default) | scalar

Dependencies

Peak reverse current, iRM — Current -235 A (default) | scalar less than 0

Dependencies

Initial forward current when measuring iRM — Current 300 A (default) | scalar greater than 0

Dependencies

Rate of change of current when measuring iRM — Current change rate -50 A/us (default) | scalar

Dependencies

Reverse recovery time parameterization — Recovery-time model Specify stretch factor (default) | Specify reverse recovery time directly | Specify reverse recovery charge

Dependencies

Reverse recovery time stretch factor — Stretch factor 3 (default) | scalar greater than 1

Dependencies

Reverse recovery time, trr — Time 15 us (default) | scalar

Dependencies

Reverse recovery charge, Qrr — Charge 1500 s*uA (default) | scalar

Dependencies

LC Parameters

Inductance — Inductance 1e-6 H (default) | positive scalar

Capacitance — Capacitance 1e-7 F (default) | positive scalar

Capacitor effective series resistance — Capacitor resistance 1e-6 Ohm (default) | zero or positive scalar

Snubbers

Snubber — Snubber model None (default) | RC snubber

Dependencies

Snubber resistance — Resistance 0.1 (default) | Ohm | scalar

Dependencies

Snubber capacitance — Capacitance 1e-7 (default) | F | scalar

Dependencies

Model Examples

Boost Converter Voltage Control

Power Factor Correction for CCM Boost Converter

References

Extended Capabilities

`G` — Switching device gate control
physical signal | vector

`G` — Switching device gate control
electrical | vector

`G+` — Switching device gate control positive terminal
electrical | scalar

`G-` — Switching device gate control negative terminal
electrical | scalar

`1+` — Positive DC voltage 1
electrical | scalar

`1-` — Negative DC voltage 1
electrical | scalar

`2+` — Positive DC voltage 2
electrical | scalar

`2-` — Negative DC voltage 2
electrical | scalar

`Switching device` — Switch type
`Ideal Semiconductor Switch` (default) | `GTO` | `IGBT` | `MOSFET` | `Thyristor` | `Averaged Switch`

`Forward voltage` — Voltage
`0.8` `V` (default) | scalar

`On-state resistance` — Resistance
`0.001` `Ohm` (default) | scalar

`Drain-source on resistance` — Resistance
`0.001` `Ohm` (default) | scalar

`Off-state conductance` — Conductance
`1e-5` `1/Ohm` (default) | scalar

`Threshold voltage` — Voltage threshold
`6` `V` (default) | scalar

`Gate trigger voltage, Vgt` — Voltage threshold
`1` `V` (default) | scalar

`Gate turn-off voltage, Vgt_off` — Voltage threshold
`-1` `V` (default) | scalar

`Holding current` — Current threshold
`1` `A` (default) | scalar

`Model dynamics` — Diode model
`Diode with no dynamics` (default) | `Diode with charge dynamics` | `None`

`Forward voltage` — Voltage
`0.8` `V` (default) | scalar

`On resistance` — Resistance
`0.001` `Ohm` (default) | scalar

`Off conductance` — Conductance
`1e-5` `1/Ohm` (default) | scalar

`Junction capacitance` — Capacitance
`50` `nF` (default) | scalar

`Peak reverse current, iRM` — Current
`-235` `A` (default) | scalar less than `0`

`Initial forward current when measuring iRM` — Current
`300` `A` (default) | scalar greater than `0`

`Rate of change of current when measuring iRM` — Current change rate
`-50` `A/us` (default) | scalar

`Reverse recovery time parameterization` — Recovery-time model
`Specify stretch factor` (default) | `Specify reverse recovery time directly` | `Specify reverse recovery charge`

`Reverse recovery time stretch factor` — Stretch factor
`3` (default) | scalar greater than `1`

`Reverse recovery time, trr` — Time
`15` `us` (default) | scalar

`Reverse recovery charge, Qrr` — Charge
`1500` `s*uA` (default) | scalar

`Inductance` — Inductance
`1e-6` `H` (default) | positive scalar

`Capacitance` — Capacitance
`1e-7` `F` (default) | positive scalar

`Capacitor effective series resistance` — Capacitor resistance
`1e-6` `Ohm` (default) | zero or positive scalar

`Snubber` — Snubber model
`None` (default) | `RC snubber`

`Snubber resistance` — Resistance
`0.1` (default) | `Ohm` | scalar

`Snubber capacitance` — Capacitance
`1e-7` (default) | `F` | scalar

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