PMSM HDL

Three-phase permanent magnet synchronous motor with sinusoidal back electromotive force

Since R2022b

Libraries:
Motor Control Blockset HDL Support / Electrical Systems / Motors

Description

The PMSM HDL block implements a three-phase permanent magnet synchronous motor (PMSM) with a sinusoidal back-electromotive force. The block uses three-phase input voltages to regulate the individual phase currents, thereby controlling the motor torque or speed.

The block generates code for fixed-step double- and single-precision targets using the Sample Time (s) parameter. It supports code generation for FPGA deployment and generates HDL-compatible code.

You can specify the PMSM parameters and operating mode using the Config input port. You can also use the PMSM Configuration block to generate the required configuration signal to specify at the Config input port.

Motor Construction

These diagrams show the interior and surface-mount PMSM construction with a single-pole pair on the motor.

The motor magnetic field due to the permanent magnets creates a sinusoidal rate of change of flux with the motor angle.

For the axes convention, the phase-a aligns with d-axis when the motor angle θ_r is zero.

Three-Phase Sinusoidal Model Electrical System

The block implements these equations expressed in the motor flux reference frame (dq frame). All quantities in the motor reference frame are referred to as the stator.

$\begin{array}{l} ω_{e} = P ω_{m} \\ \frac{d}{d t} i_{d} = \frac{1}{L_{d}} v_{d} - \frac{R}{L_{d}} i_{d} + \frac{L_{q}}{L_{d}} P ω_{m} i_{q} \end{array}$

$\frac{d}{d t} i_{q} = \frac{1}{L_{q}} v_{q} - \frac{R}{L_{q}} i_{q} - \frac{L_{d}}{L_{q}} P ω_{m} i_{d} - \frac{λ_{p m} P ω_{m}}{L_{q}}$

$T_{e} = 1.5 P [λ_{p m} i_{q} + (L_{d} - L_{q}) i_{d} i_{q}]$

The L_q and L_d inductances represent the relation between the phase inductance and the motor position due to the saliency of the motor magnets. For a surface mount PMSM, $L_{d} = L_{q}$ .

The equations use these variables.

L_q, L_d	q- and d-axis inductances (H)
R	Resistance of the stator windings (ohm)
i_q, i_d	q- and d-axis currents (A)
v_q, v_d	q- and d-axis voltages (V)
ω_m	Angular mechanical velocity of the motor (rad/s)
ω_e	Angular electrical velocity of the motor (rad/s)
λ_pm	Permanent magnet flux linkage (Wb)
K_e	Back electromotive force (EMF) (Vpk_LL/krpm, where Vpk_LL is the peak voltage line-to-line measurement)
K_t	Torque constant (N·m/A) K_t = Rated torque of motor / Ia_peak_rated, where Ia_peak_rated is the peak amplitude of phase-a at rated current operation.
P	Number of pole pairs
T_e	Electromagnetic torque (Nm)
Θ_e	Electrical angle (rad)

Mechanical System

The motor angular velocity is given by:

$\begin{matrix} \frac{d}{d t} ω_{m} = \frac{1}{J} (T_{e} - T_{f} - F ω_{m} - T_{m}) \\ \frac{d θ_{m}}{d t} = ω_{m} \end{matrix}$

The equations use these variables.

J	Combined inertia of motor and load (kgm^2)
F	Combined viscous friction of motor and load (N·m/(rad/s))
θ_m	Motor mechanical angular position (rad)
T_m	Motor shaft torque (Nm)
T_e	Electromagnetic torque (Nm)
T_f	Motor shaft static friction torque (Nm)
ω_m	Angular mechanical velocity of the motor (rad/s)

Power Accounting

For motor power accounting, the block implements these equations.

Bus Signal			Description	Variable	Equations
`PwrInfo`	`PwrTrnsfrd` — Power transferred between blocks Positive signals indicate flow into block Negative signals indicate flow out of block	`PwrMtr`	Mechanical power	P_mot	$P_{m o t} = - ω_{m} T_{e}$
		`PwrBus`	Electrical power	P_bus	$P_{b u s} = v_{a n} i_{a} + v_{b n} i_{b} + v_{c n} i_{c}$
	`PwrNotTrnsfrd` — Power crossing the block boundary, but not transferred Positive signals indicate an input Negative signals indicate a loss	`PwrElecLoss`	Resistive power loss	P_elec	$P_{e l e c} = - \frac{3}{2} (R_{s} i_{s d}^{2} + R_{s} i_{s q}^{2})$
		`PwrMechLoss`	Mechanical power loss	P_mech	When Port Configuration is set to `Torque`: $P_{m e c h} = - (ω_{m}^{2} F + \| ω_{m} \| T_{f})$ When Port Configuration is set to `Speed`: $P_{m e c h} = 0$
	`PwrStored` — Stored energy rate of change Positive signals indicate an increase Negative signals indicate a decrease	`PwrMtrStored`	Stored motor power	P_str	$P_{s t r} = P_{b u s} + P_{m o t} + P_{e l e c} + P_{m e c h}$

The equations use these variables.

R_s	Stator resistance (ohm)
i_a, i_b, i_c	Stator phase a, b, and c current (A)
i_sq, i_sd	Stator q- and d-axis currents (A)
v_an, v_bn, v_cn	Stator phase a, b, and c voltage (V)
ω_m	Angular mechanical velocity of the motor (rad/s)
F	Combined motor and load viscous damping N·m/(rad/s)
T_e	Electromagnetic torque (Nm)
T_f	Combined motor and load friction torque (Nm)

Amplitude Invariant dq Transformation

The block uses these equations to implement amplitude invariant dq transformation to ensure that the dq and three phase amplitudes are equal.

$[\begin{matrix} v_{s d} \\ v_{s q} \end{matrix}] = \frac{2}{3} [\begin{matrix} cos (Θ_{d a}) & cos (Θ_{d a} - \frac{2 π}{3}) & cos (Θ_{d a} + \frac{2 π}{3}) \\ - sin (Θ_{d a}) & - sin (Θ_{d a} - \frac{2 π}{3}) & - sin (Θ_{d a} + \frac{2 π}{3}) \end{matrix}] [\begin{matrix} v_{a} \\ v_{b} \\ v_{c} \end{matrix}]$

$[\begin{matrix} i_{a} \\ i_{b} \\ i_{c} \end{matrix}] = [\begin{matrix} cos (Θ_{d a}) & - sin (Θ_{d a}) \\ \begin{matrix} cos (Θ_{d a} - \frac{2 π}{3}) \\ cos (Θ_{d a} + \frac{2 π}{3}) \end{matrix} & \begin{matrix} - sin (Θ_{d a} - \frac{2 π}{3}) \\ - sin (Θ_{d a} + \frac{2 π}{3}) \end{matrix} \end{matrix}] [\begin{matrix} i_{s d} \\ i_{s q} \end{matrix}]$

The equations use these variables.

Θ_da	dq stator electrical angle with respect to the rotor a-axis (rad)
v_sq, v_sd	Stator q- and d-axis voltages (V)
i_sq, i_sd	Stator q- and d-axis currents (A)
v_a, v_b, v_c	Stator voltage phases a, b, c (V)
i_a, i_b, i_c	Stator currents phases a, b, c (A)

Examples

Field-Oriented Control (FOC) of PMSM Using Hardware-In-The-Loop (HIL) Simulation

Uses hardware-in-the-loop (HIL) simulation to implement the field-oriented control (FOC) algorithm to control the speed of a three-phase permanent magnet synchronous motor (PMSM). The FOC algorithm requires rotor position feedback, which is obtained by a quadrature encoder sensor. For more information on FOC, see Field-Oriented Control (FOC).

Open Example

Ports

Input

expand all

Config — Block configuration signal
vector

Configuration signal for the PMSM HDL block containing the block configuration parameters. For more information about the constituent parameters, see the Config output of the PMSM Configuration block.

Data Types: single

PhaseVolt — Stator terminal voltages
`1`-by-`3` array

Stator terminal voltages V_a, V_b, and V_c, in V.

Data Types: single

LdTrq/Spd — Load torque on motor or speed of motor shaft
scalar

Based on the mode of operation defined by the Port Configuration parameter available in the multiplexed Config input, the port supports one of these inputs:

T_m — Load torque on the motor shaft, in N·m.
ω_m — Angular velocity of the motor, in rad/s.

Data Types: single

Reset — Reset bus signal
scalar

Reset bus signal that the block uses to reset the internal integrators.

Data Types: Boolean

Output

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Info — Bus signal
bus

The bus signal contains these block calculations.

Signal			Description	Variable	Units
`IaStator`			Stator phase current A	i_a	A
`IbStator`			Stator phase current B	i_b	A
`IcStator`			Stator phase current C	i_c	A
`IdSync`			Direct axis current	i_d	A
`IqSync`			Quadrature axis current	i_q	A
`VdSync`			Direct axis voltage	v_d	V
`VqSync`			Quadrature axis voltage	v_q	V
`MtrSpd`			Angular mechanical velocity of the motor	ω_m	rad/s
`MtrPos`			Motor mechanical angular position	θ_m	rad
`MtrTrq`			Electromagnetic torque	T_e	N·m
`PwrInfo`	`PwrTrnsfrd`	`PwrMtr`	Mechanical power	P_mot	W
	`PwrTrnsfrd`	`PwrBus`	Electrical power	P_bus	W
	`PwrNotTrnsfrd`	`PwrElecLoss`	Resistive power loss	P_elec	W
	`PwrNotTrnsfrd`	`PwrMechLoss`	Mechanical power loss	P_mech	W
	`PwrStored`	`PwrMtrStored`	Stored motor power	P_str	W

PhaseCurr — Current for phase a, b, and c
`1`-by-`3` array

Current for phase a, b, and c, i_a, i_b, and i_c, respectively, in A.

Torque — Motor torque
`scalar`

Motor torque, T_mtr, in N·m.

Speed — Motor speed
`scalar`

Angular speed of the motor, ω_mtr, in rad/s.

MtrElecAngle — Motor electrical angle
scalar

Electrical position of the motor, θ_e, in rad.

Data Types: single

Parameters

expand all

Sample time (s) — Sample time after which block executes again
`1e-6` (default) | scalar

The fixed time interval (in seconds) between consecutive instances of block execution.

Extended Capabilities

HDL Code Generation
Generate VHDL, Verilog and SystemVerilog code for FPGA and ASIC designs using HDL Coder™.

HDL Coder™ provides additional configuration options that affect HDL implementation and synthesized logic.

HDL Architecture

This block has one default HDL architecture.

HDL Block Properties


ConstrainedOutputPipeline	Number of registers to place at the outputs by moving existing delays within your design. Distributed pipelining does not redistribute these registers. The default is `0`. For more details, see ConstrainedOutputPipeline (HDL Coder).
InputPipeline	Number of input pipeline stages to insert in the generated code. Distributed pipelining and constrained output pipelining can move these registers. The default is `0`. For more details, see InputPipeline (HDL Coder).
OutputPipeline	Number of output pipeline stages to insert in the generated code. Distributed pipelining and constrained output pipelining can move these registers. The default is `0`. For more details, see OutputPipeline (HDL Coder).

Version History

Introduced in R2022b

PMSM HDL

Description

Motor Construction

Three-Phase Sinusoidal Model Electrical System

Mechanical System

Power Accounting

Amplitude Invariant dq Transformation

Examples

Field-Oriented Control (FOC) of PMSM Using Hardware-In-The-Loop (HIL) Simulation

Ports

Input

Config — Block configuration signal
vector

PhaseVolt — Stator terminal voltages
`1`-by-`3` array

LdTrq/Spd — Load torque on motor or speed of motor shaft
scalar

Reset — Reset bus signal
scalar

Output

Info — Bus signal
bus

PhaseCurr — Current for phase a, b, and c
`1`-by-`3` array

Torque — Motor torque
`scalar`

Speed — Motor speed
`scalar`

MtrElecAngle — Motor electrical angle
scalar

Parameters

Sample time (s) — Sample time after which block executes again
`1e-6` (default) | scalar

Extended Capabilities

HDL Code Generation
Generate VHDL, Verilog and SystemVerilog code for FPGA and ASIC designs using HDL Coder™.

Version History

See Also

Topics

PMSM HDL

Description

Motor Construction

Three-Phase Sinusoidal Model Electrical System

Mechanical System

Power Accounting

Amplitude Invariant dq Transformation

Examples

Field-Oriented Control (FOC) of PMSM Using Hardware-In-The-Loop (HIL) Simulation

Ports

Input

Config — Block configuration signal vector

PhaseVolt — Stator terminal voltages 1-by-3 array

LdTrq/Spd — Load torque on motor or speed of motor shaft scalar

Reset — Reset bus signal scalar

Output

Info — Bus signal bus

PhaseCurr — Current for phase a, b, and c 1-by-3 array

Torque — Motor torque scalar

Speed — Motor speed scalar

MtrElecAngle — Motor electrical angle scalar

Parameters

Sample time (s) — Sample time after which block executes again 1e-6 (default) | scalar

Extended Capabilities

HDL Code Generation Generate VHDL, Verilog and SystemVerilog code for FPGA and ASIC designs using HDL Coder™.

Version History

See Also

Topics

Config — Block configuration signal
vector

PhaseVolt — Stator terminal voltages
`1`-by-`3` array

LdTrq/Spd — Load torque on motor or speed of motor shaft
scalar

Reset — Reset bus signal
scalar

Info — Bus signal
bus

PhaseCurr — Current for phase a, b, and c
`1`-by-`3` array

Torque — Motor torque
`scalar`

Speed — Motor speed
`scalar`

MtrElecAngle — Motor electrical angle
scalar

Sample time (s) — Sample time after which block executes again
`1e-6` (default) | scalar

HDL Code Generation
Generate VHDL, Verilog and SystemVerilog code for FPGA and ASIC designs using HDL Coder™.