CN111726048A - Permanent magnet synchronous motor rotor position and speed estimation method based on sliding-mode observer - Google Patents

Abstract

The invention discloses a sliding-mode observer-based permanent magnet synchronous motor rotor position and speed estimation method, wherein the sliding-mode observer is a sliding-mode observer based on a boundary layer self-adjusting arcsine saturation function, and comprises a current state observer, a current comparator, a boundary layer self-adjusting arcsine saturation function module, an extended Kalman filter and a software phase-locked loop. The invention replaces the sign function in the existing sliding mode observer with a boundary layer-based self-adjusting arcsine function, simultaneously adopts an extended Kalman filter to extract extended back electromotive force, removes a low-pass filter in the existing sliding mode observer, and feeds back the extracted extended back electromotive force to a current state observer for amplitude compensation. Compared with the conventional sliding mode controller, the sliding mode observer based on the boundary layer self-adjusting arcsine function can effectively inhibit torque pulsation, improve the steady-state performance of the system and improve the tracking accuracy of the position and the rotating speed of the rotor.

Description

Permanent magnet synchronous motor rotor position and speed estimation method based on sliding-mode observer

Technical Field

The invention relates to the field of electromechanical control, in particular to a method for estimating the position and the speed of a permanent magnet synchronous motor rotor based on a sliding-mode observer.

Background

The control technology without the position sensor samples relevant electric signals in the motor to estimate the position and speed information of the rotor, and a mechanical position sensor is removed, so that the volume and the weight of the system are reduced, the cost and the hardware complexity are reduced, and the running performance of the system is improved.

The permanent magnet synchronous motor position sensorless control method mainly comprises a high-frequency injection method and an observer method, wherein the observer method comprises an extended Kalman filter, model reference self-adaption, a sliding-mode observer and the like. The sliding mode observer is a nonlinear control method, is simple in structure, low in modeling precision requirement and strong in robustness, and also has the problems of large system buffeting, delay of position angle phase and poor steady-state performance.

The traditional sliding mode observer adopts a sign function as a sliding mode surface control function, so that the system buffeting is serious, a large amount of harmonic waves exist in observed back electromotive force, the rotating speed estimation precision is influenced, the torque pulsation is large, the system buffeting can be effectively reduced by adopting a saturation function to replace the sign function, but the boundary layer thickness of the saturation function is always fixed to a constant value, and the steady state performance under certain rotating speed or certain load applying working conditions is poor. The use of a low-pass filter can effectively filter out high-frequency harmonics, but causes the amplitude of the back electromotive force to be reduced and the phase of the position angle to be delayed, and needs additional position compensation. Therefore, the research on the position-free sensor control algorithm which can effectively inhibit torque pulsation, is accurate in tracking the position and the rotating speed of the rotor, has good steady-state performance and is simple in structure has wide development prospect.

Disclosure of Invention

The purpose of the invention is as follows: aiming at the prior art, the method for estimating the position and the speed of the permanent magnet synchronous motor based on the sliding-mode observer is provided, the position and the rotating speed information of the rotor can be accurately tracked, the torque pulsation is restrained, and the steady-state performance of the system is improved.

The technical scheme is as follows: the method for estimating the position and the speed of the permanent magnet synchronous motor rotor based on the sliding-mode observer is characterized in that the sliding-mode observer is based on a boundary layer self-adjusting arcsine saturation function and comprises a current state observer, a current comparator, a boundary layer self-adjusting arcsine saturation function module, an extended Kalman filter and a software phase-locked loop;

the inputs of the current state observer are the sampled α and β axis voltages u, respectively_α、u_βα and β axial sliding mode surface control function value z_α、z_βAnd α and β axis extended back EMF observations

The outputs of the current state observer are α and β axis current estimates

The α and β axis current estimates

With sampled α and β axis currents i_α、i_βIs input into a boundary layer self-adjusting arcsine saturation function module, the output of the boundary layer self-adjusting arcsine saturation function module is α and β shaft sliding mode surface control function values z_α、z_βThe control function value z of the α and β axial sliding mode surfaces_α、z_βAnd estimating the rotational speed

Input to an extended Kalman filter whose outputs are α and β axis extended back EMF observations

The α and β axis extended back EMF observations

Input to a software phase locked loop, whereby said software phase locked loop outputs an estimated rotor position angle

And estimating the rotational speed

Further, the current state observer is:

wherein R is stator resistance, ω is electrical angular velocity, L_d、L_qD and q axis inductance values, respectively;

the α and β axis sliding mode surface control function value z_α、z_βExpressed as:

wherein k is_sIs the switching gain, k_s>max(|E_α|,|E_β|)，E_α、E_βExtended back emf for the α and β axes, respectively, narcsin(s) is a boundary layer self-regulating arcsine saturation function;

the extended Kalman filter is as follows:

wherein k is_kFor the adaptive rate of the filter, k_k>0；

Extended back EMF error observation for the α and β axes, respectivelyThe difference value is obtained by comparing the difference value,

further, the boundary layer self-adjusting arcsine saturation function is as follows:

wherein the content of the first and second substances,

s_α、s_βexpanding back EMF E for α and β axes, respectively_α、E_βCorresponding to the slip-form surface, λ is the basic boundary layer thickness.

Has the advantages that: the invention replaces the symbolic function in the existing sliding-mode observer with a boundary layer-based self-adjusting arcsine function, simultaneously adopts an extended Kalman filter to extract extended back electromotive force, removes a low-pass filter in the existing sliding-mode observer, and feeds back the extracted extended back electromotive force to a current state observer for amplitude compensation; compared with the conventional sliding mode controller, the sliding mode observer based on the boundary layer self-adjusting arcsine function can effectively inhibit torque pulsation, improve the steady-state performance of the system and improve the tracking accuracy of the position and the rotating speed of the rotor. The rotor position and speed estimation method provided by the invention can effectively reduce the system buffeting, improve the rotor position and speed estimation precision and inhibit the torque pulsation, and meets the requirements of the permanent magnet synchronous motor driving fields such as a high-speed hydrogen pump and an air compressor on the system reliability and efficiency.

Drawings

FIG. 1 is a control block diagram of a vector control system of an embodiment of the present invention;

FIG. 2 is a structural block diagram of a sliding-mode observer based on a boundary layer self-adjusting arcsine saturation function according to an embodiment of the invention;

FIG. 3 is a block diagram of a software phase locked loop according to an embodiment of the present invention;

FIG. 4 is a static experimental result of a sliding-mode observer of an embodiment of the present invention; wherein, (a) is an expanded counter electromotive force observation value, (b) is an estimated value, an actual value and an error value thereof of the rotation speed, and (c) is an estimated value, an actual value and an error value thereof of the rotor position angle.

FIG. 5 is a dynamic experimental result of a sliding mode observer according to an embodiment of the present invention; wherein, (a) is the estimated value, the actual value and the error value and the torque of the rotating speed under the condition of the rotating speed abrupt change, and (b) is the estimated value, the actual value and the error value and the torque of the rotating speed under the condition of the torque abrupt change.

Detailed Description

The invention is further explained below with reference to the drawings.

The vector control system of fig. 1 is composed of links such as a speed PI regulator, d-and q-axis current PI regulators, inverse Park coordinate transformation, SVPWM (space vector pulse width modulation), a three-phase inverter, a permanent magnet synchronous motor, Clarke coordinate transformation, Park coordinate transformation, a sliding mode observer based on a boundary layer self-adjusting arcsine saturation function, and a Software Phase Locked Loop (SPLL). The system is a speed (outer loop) and current (inner loop) double closed loop structure. A sliding-mode observer based on a boundary layer self-adjusting arcsine saturation function and a software phase-locked loop are used for estimating the position and the speed of a motor rotor in real time to replace a mechanical position sensor.

The estimated rotor position angle is used for Park coordinate transformation and inverse Park coordinate transformation in a vector control system, and the estimated speed is used as a feedback value of a speed loop. Sliding mode observer based on boundary layer self-adjusting arcsine saturation function for estimating rotating speed

α and β Axis Voltage u_α、u_βAnd α and β axis currents i_α、i_βThe output values are α and β axis expansion counter electromotive force observed values as input values

The input quantity of the software phase-locked loop is α and β axis expansion counter electromotive force observed value

The output being estimatedRotor position angle

And rotational speed

As shown in FIG. 2, the sliding-mode observer based on the boundary layer self-adjusting arcsine saturation function comprises a current state observer, a current comparator, a boundary layer self-adjusting arcsine saturation function module, an extended Kalman filter and a software phase-locked loop. The current state observer is connected with a boundary layer self-adjusting arcsine saturation function module, the boundary layer self-adjusting arcsine saturation function module is connected with an extended Kalman filter and a current state observer module, the extended Kalman filter module is connected with a software phase-locked loop module and the current state observer module, and the software phase-locked loop module is connected with the extended Kalman filter module.

The inputs to the current state observer are the sampled α and β axis voltages u, respectively_α、u_βα and β axial sliding mode surface control function value z_α、z_βAnd α and β axis extended back EMF observations

The outputs of the current state observer are α and β axis current estimates

α and β axis current estimates

With sampled α and β axis currents i_α、i_βThe difference value of (a) is input into a boundary layer self-adjusting arcsine saturation function, and the output of the boundary layer self-adjusting arcsine saturation function is α and β shaft sliding mode surface control function values z_α、z_βα and β Axis sliding mode surface control function value z_α、z_βAnd estimating the rotational speed

Inputting the data into an extended Kalman filter, wherein the output of the extended Kalman filter is α and β axis extended back electromotive force observed values

α and β axis extended back EMF observations

Input to a software phase locked loop, whereby the software phase locked loop outputs an estimated rotor position angle

And estimating the rotational speed

The design process of the current state observer and the boundary layer self-adjusting arcsine saturation function in the estimation method comprises the following steps:

the stator voltage equation in the α β coordinate system is:

wherein u is_α、u_βα and β axis voltages, respectively_α、i_βα and β axis currents, respectively_eIs the rotor position angle; e_α、E_βα and β axis extended back electromotive force, R is stator resistance, omega is electrical angular velocity, L_d、L_qD and q axis inductance values, respectively; i.e. i_d、i_qD and q axis currents, respectively; psi_fIs a permanent magnet flux linkage.

Equation (1) is rewritten as a state equation with α and β axis currents as state variables:

selecting a sliding mode surface on a stator current track, namely:

wherein the content of the first and second substances,

current estimates for the α and β axes, respectively;

current error values for the α and β axes, respectively.

In order to obtain the extended back electromotive force and reduce the influence of filtering on the amplitude of the extended back electromotive force, the extended back electromotive force value observed value is fed back to the current observation loop, and the current state observer is designed as follows:

in the formula (I), the compound is shown in the specification,

is a sliding mode surface control function; k is a radical of_sIs the switching gain, k_s>max(|E_α|,|E_βI)); narcsin(s) is a boundary layer self-adjusting arcsine saturation function, s is a sliding mode surface parameter, and the expression is as follows:

wherein the content of the first and second substances,

s_α、s_βexpanding back EMF E for α and β axes, respectively_α、E_βCorresponding to the slip-form surface, λ is the basic boundary layer thickness.

As can be seen from the formula (6), the Narcsin function can adjust the boundary layer in real time according to the slip form surface error, the control speed cannot be influenced by overlarge thickness of the boundary layer due to the small slip form surface error, and meanwhile, the slip form surface error is indirectly influenced by the change of the rotating speed, the torque or other parameter values, so that the Narcsin function is suitable for implementing adjustment under various working conditions.

α and β axis sliding mode surface control function value z in estimation method_α、z_βThe calculation process of (2) is as follows:

the stator current error equation obtained by subtracting the equations (5) and (3) is:

the extended back emf available from the equivalent control principle is:

α and β axis extended back electromotive force observed values in estimation method

Control of function value z by α and β axis sliding mode surfaces_α、z_βThe filter is obtained after the filter processing of an extended Kalman filter, and the extended Kalman filter is as follows:

wherein k is_kFor the adaptive rate of the filter, k_k>0；

Extending the back emf observed error values for the α and β axes respectively,

E_α、E_βextending the back emf for the α and β axes, respectively.

Since the mechanical time constant is much larger than the electromagnetic time constant, the rotational speed is assumed to be constant in one estimation period, which can be obtained from equation (9):

to demonstrate the stability of equation (10), the lyapunov function is defined:

obtained by substituting formula (10) for formula (11):

the extended kalman filter is therefore stable.

The estimation method estimates the position angle and the speed of the rotor through a software phase-locked loop and estimates the position angle of the rotor

And estimating the rotational speed

The calculation process of (2) is as follows:

wherein, K_p/K_iRespectively proportional/integral coefficients. The structure block diagram of the software phase-locked loop is shown in fig. 3.

According to the control block diagram shown in fig. 1, experimental verification is performed based on a dSPACE semi-physical simulation experiment platform, and the parameters of the permanent magnet synchronous motor are selected as follows: the rated power is 600W, the rated rotation speed is 750r/min, the rated torque is 7.6 N.m, the pole pair number is 14, the amplitude of the permanent magnet flux linkage is 0.0679Wb, the resistance of an armature winding is 2.3 omega, the alternating-direct axis inductance is 2.22mH and 2.23mH respectively, and the rotational inertia is 0.004 kg.m²The friction torque viscosity coefficient was 0.0004N · m · s. FIG. 4 shows the experimental results at a given rotation speed of 200r/min, FIG. 5(a) shows the experimental results of the motor suddenly changing from 100r/min to 200r/min when no load is applied, and FIG. 5(b) shows the experimental results of the motor suddenly changing from no load to 4 N.m when 100r/min is applied. As can be seen from FIG. 4(a), the extended electromotion of the method of the present inventionThe potential observations have a high degree of sinusoidality and the back-emf observations have a low harmonic THD. As can be seen from FIGS. 4(b) and 5(a), the estimated value of the rotational speed of the method of the present invention can track the actual value well, the error of the rotational speed is about + -3 r/min, which is only 1.5% of the given rotational speed, and as can be seen from FIG. 4(c), the estimated rotor position angle of the method of the present invention is substantially consistent with the actual value, and almost no phase delay is generated. As can be seen from FIG. 5(b), the rotational speed fluctuation of the method of the present invention is maintained substantially constant after the application of 4 N.m, and the torque ripple is small. Experimental results show that the method has the advantages of accurate estimation of the position and the rotating speed of the rotor, quick response of the rotating speed, good robustness and small torque pulsation.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims (3)

1. The method for estimating the position and the speed of the permanent magnet synchronous motor rotor based on the sliding-mode observer is characterized in that the sliding-mode observer is based on a boundary layer self-adjusting arcsine saturation function and comprises a current state observer, a current comparator, a boundary layer self-adjusting arcsine saturation function module, an extended Kalman filter and a software phase-locked loop;

the inputs of the current state observer are the sampled α and β axis voltages u, respectively_α、u_βα and β axial sliding mode surface control function value z_α、z_βAnd α and β axis extended back EMF observations

The outputs of the current state observer are α and β axis current estimates

The α and β axis current estimates

With sampled α and β axis currents i_α、i_βIs input into a boundary layer self-adjusting arcsine saturation function module, the output of the boundary layer self-adjusting arcsine saturation function module is α and β shaft sliding mode surface control function values z_α、z_βThe control function value z of the α and β axial sliding mode surfaces_α、z_βAnd estimating the rotational speed

Input to an extended Kalman filter whose outputs are α and β axis extended back EMF observations

The α and β axis extended back EMF observations

Input to a software phase locked loop, whereby said software phase locked loop outputs an estimated rotor position angle

And estimating the rotational speed

2. The sliding-mode observer-based estimation method for the position and the speed of the rotor of the permanent magnet synchronous motor according to claim 1, wherein the current state observer is:

wherein R is stator resistance, ω is electrical angular velocity, L_d、L_qInductances of d and q axes, respectivelyA value;

the α and β axis sliding mode surface control function value z_α、z_βExpressed as:

wherein k is_sIs the switching gain, k_s>max(|E_α|,|E_β|)，E_α、E_βExtended back emf for the α and β axes, respectively, narcsin(s) is a boundary layer self-regulating arcsine saturation function;

the extended Kalman filter is as follows:

wherein k is_kFor the adaptive rate of the filter, k_k>0；

Extending the back emf observed error values for the α and β axes respectively,

the software phase-locked loop estimates the rotor position angle

And estimating the rotational speed

The calculation process of (2) is as follows:

wherein, K_p、K_iRespectively, proportional and integral coefficients.

3. The sliding-mode observer-based permanent magnet synchronous motor rotor position and speed estimation method according to claim 2, wherein the boundary layer self-adjusting arcsine saturation function is:

wherein the content of the first and second substances,

s_α、s_βexpanding back EMF E for α and β axes, respectively_α、E_βCorresponding to the slip-form surface, λ is the basic boundary layer thickness.

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