Mean Deviation Coupling Control for Multimotor System via Global Fast Terminal Sliding Mode Control

Zhu, Changlin; Tu, Qunzhang; Jiang, Chengming; Pan, Ming; Huang, Hao; Tu, Zhiwen

doi:https://doi.org/10.1155/2021/9200267

Advances in Mathematical Physics

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Abstract Introduction Conclusions Data Availability Conflicts of Interest Acknowledgments References Copyright Related Articles

Research Article | Open Access

Volume 2021 | Article ID 9200267 | https://doi.org/10.1155/2021/9200267

Mean Deviation Coupling Control for Multimotor System via Global Fast Terminal Sliding Mode Control

Changlin Zhu,¹Qunzhang Tu,¹Chengming Jiang,¹Ming Pan,¹Hao Huang,¹and Zhiwen Tu¹

Academic Editor: Leopoldo Greco

Received26 Jul 2021

Accepted02 Sept 2021

Published13 Sept 2021

Abstract

In view of the shortcomings of the existing multimotor synchronous control strategy, a new method of mean deviation coupling control for multimotor system via global fast terminal sliding mode control is proposed. Firstly, the mathematical model of permanent magnet synchronous motor (PMSM) under a - reference frame is established. Next, based on the deviation coupling control, the deviation is calculated by the average speed, and the structure of the deviation coupling control strategy is optimized. The speed controller of the multimotor system is designed based on the global fast terminal sliding mode control (GFTSMC) algorithm to improve the synchronization accuracy of the system. In addition, a load torque Luenberger observer is designed to observe the load in real time. Then, the stability analysis of the controller is carried out by using the Lyapunov function. Finally, a four-motor experimental platform is built to verify the effectiveness of the proposed control strategy.

1. Introduction

Permanent magnet synchronous motor is widely used in industrial production and electric vehicle because of its high-power density, simple structure, and high efficiency [1]. However, a single motor is difficult to meet the needs of high performance and high precision in many applications, so multi-motor drive system has become a research hotspot in recent years [2, 3]. Although the same speed signal is given to each motor, the output speed of each motor would be inconsistent due to the load interference in the working process, and the synchronization performance of the system would be affected. Therefore, multimotor synchronous control has become one of the key technologies of the multimotor drive system [4]. As early as last century, research on the synchronous control strategy of multimotors has been carried out by researchers. After decades of development, the master-slave control strategy, crosscoupling control strategy, adjacent crosscoupling control strategy, ring coupling control strategy, deviation coupling control strategy, virtual spindle synchronous control strategy, and so on have been proposed for the multimotor system [5–13].

In the master-slave control strategy, one motor is selected as the master motor, the other motor is the slave motor, and the output speed signal of the master motor is used as the input speed signal of the slave motor. The structure is simple [14]. When the master motor speed changes, the speed of the slave motor changes accordingly. But when the speed of one slave motor changes, the signal cannot be fed back to other motors, which causes the speed to be out of sync [15]. In the crosscoupling control strategy, the speed difference between the two motors is used as the compensation signal and fed back to the motor controller [16]. In order to improve the synchronization performance, fuzzy control algorithm, adaptive control-algorithm, neural network algorithm, and second-order sliding mode control algorithm are applied to the crosscoupling control strategy [17–21]. However, the crosscoupling control strategy is only suitable for the dual motor system. For this reason, Zhao et al. [9] proposed adjacent crosscoupling control. For any motor, only the speed of two motors adjacent to it is taken into account. But when the number of motors is greater than 3, there will always be a motor whose control is lagging behind [22].

The ring coupling control takes into account the error between the motor output speed and the given speed and the error between the adjacent motor speeds, so it can be applied to the multimotor system with more than three motors [11]. However, the speed difference feedback of adjacent motors in the ring coupling control is unidirectional. When the number of motors is large, the whole system has a large feedback delay, and its response speed needs to be improved. According to the relationship between the speed difference and the speed deviation of each motor, the deviation coupling control compensates the speed of each motor to achieve the advantages of good synchronization performance and fast response speed [4]. But the structure of the system is complex, and the calculation of the system is very large [23]. The synchronous control of virtual spindle is evolved from mechanical axis, and the link of each unit is no longer constrained by distance and has larger output power. However, there is an essential defect in its structure; there is a steady-state error between the output of the motor and the reference of the output of the virtual axis. When the system is started or stopped or when a single motor is disturbed, there would be a phenomenon of misalignment between the axes [24].

The control accuracy of multimotor synchronous control strategy is closely related to its control algorithm. In this regard, many control algorithms have been proposed, such as proportional integral derivative (PID) control, sliding mode control (SMC), fuzzy control, and neural network control [25–28]. Because PMSM is a nonlinear, multivariable, and strongly coupled control object [29] and sliding mode control has the advantages of simple algorithm and insensitive to parameter changes and disturbances, so sliding mode control algorithm is very suitable for multimotor synchronous control [30]. However, because of the discontinuous switching characteristics of conventional SMC, the chattering phenomenon of increasing system energy consumption and reducing system stability is caused. In order to suppress the chattering phenomenon, the concepts of “quasisliding mode” and “boundary layer” were introduced into the design of SMC [31], and the chattering phenomenon is suppressed effectively. However, the control effect and inhibition effect cannot be optimal at the same time because of the selection of boundary layer thickness. Gao introduced the concept of reaching law into the design of sliding mode variable structure control [32] and proposed a chattering elimination method, which ensures the dynamic quality of sliding mode dynamic arrival process by adjusting the parameters of reaching law. But larger parameters will cause chattering. Sun et al. [33] proposed a fuzzy sliding mode control strategy by combining fuzzy control rules with sliding mode variable structure control to achieve the purpose of suppressing chattering.

Although the above methods can suppress the chattering to a certain extent, the chattering problem cannot be solved fundamentally, which is rooted in the switching term in the conventional SMC. One of the methods to solve the chattering problem is to design terminal sliding mode control (TSMC) strategy by using nonlinear function instead of switching term in SMC [34]. Zhuang et al. [35] designed a terminal sliding surface for high-order nonlinear systems to overcome the disadvantage of discontinuous derivatives of conventional SMC sliding surface. But the common terminal sliding mode controller has singularity problem. In order to solve the singular problem in the ordinary TSMC, Feng et al. [36] put forward a nonsingular terminal sliding mode control strategy, which solves the singular problem better. For nonlinear systems, Liu et al. [37] proposed GFTSMC, which avoids the singularity problem, and the response speed of the system is improved, and the chattering in the SMC is eliminated effectively.

Aiming at the shortcomings of the existing multimotor synchronization control strategy, mean deviation coupling control for multimotor system via global fast terminal sliding mode control is proposed in this paper, and the advantages of good synchronization performance and fast response speed of deviation coupling control is retained. The average speed is used to replace the speed difference between each motor, which simplifies the structure of deviation coupling control strategy and reduces the calculation of the system. The GFTSMC algorithm is used to solve the chattering problem in sliding mode control and to improve the response speed and control accuracy of the system. In addition, to solve the problem of unmeasurable load torque, a load torque Luenberger observer is designed to estimate the load of the motor in real time and feedback it to the controller. The remaining chapters of this paper are arranged as follows: in Section 2, the mathematical model of PMSM is established. The mean deviation coupling controller for multimotor system via global fast terminal sliding mode control and load torque Luenberger observer is designed in Section 3. In Section 4, the stability of the controller is analyzed by using the Lyapunov function, and the four-motor system platform is built to verify the effectiveness of the mean deviation coupling control strategy for multimotor system via global fast terminal sliding mode control in Section 5, and the conclusion of this paper is given in Section 6.

2. Mathematical Mode of PMSM

The rotor field-oriented control of PMSM with is adopted to establish the dynamic mathematical model of PMSM in - coordinate system: where and represent the components of the and axis of stator voltage, respectively; and represent the components of the and axis of stator current, respectively; represents the stator resistance; represents the rotor electric angular velocity; and and represent the components of the and axis of stator flux, respectively. The stator flux linkage equation of PMSM is as follows: where is the flux from the rotor permanent magnet turn chain to the stator winding and and are the inductance of the - axis, respectively. The electromagnetic torque equation of PMSM is as follows:

Since the motor is surface-mounted PMSM, , substituting equation (2) into equation (3), the following equation can be obtained:

The motion equation of PMSM is as follows: where is the load torque of the motor, is viscous damping, and is the moment of inertia of the rotor. By substituting equation (4) into equation (5), the following equation can be obtained:

For the multimotor system, the motion equation of the th motor is as follows: where is the subscript (the same below) used to mark the variables of the th motor. represents the speed of the th motor, represents the axis component of the stator current of the th motor, and represents the external load of the th motor. Set

Then, equation (7) can be abbreviated as

3. Controller Design

Based on the idea of deviation coupling control and the GFTSMC algorithm, the mean deviation coupling control strategy via global fast terminal sliding mode control is proposed. The control structure block diagram is shown in Figure 1.

Given the reference speed of each motor, there is an error between the actual speed and the given speed when the motor system starts or changes speed, which is called tracking speed error :

Under the action of the speed tracking controller, the actual speed will finally reach the given speed:

Due to the interference of the external load of each motor, the speed of the motor changes in a certain period of time, which makes the speed of each motor inconsistent. Under the multimotor synchronous control strategy proposed in this paper, the speed of a single motor is compared with the average speed, and the error between the speed of each motor and the average speed is obtained:

The GFTSMC algorithm is used to compensate the average speed error, so that the speed of each motor is the same, and the synchronization of multimotor is realized, and the control goal is finally achieved: where is the speed of each motor and is the average speed:

From the above control process, it can be seen that the controller of each motor can be regarded as two subcontrollers, as shown in Figure 2. One is the speed tracking controller , which makes the motor track the given speed signal accurately; the other is the speed compensation controller , which compensates the difference between the motor speed and the average speed. This control structure solves the coupling problem of multimotor system. In the deviation coupling control, there is direct speed feedback between motors, which leads to the coupling problem of the multimotor system. Through the mean deviation coupling control strategy, the speed feedback obtained by the motor comes from its own speed and the average speed of all motors. The two fed back speeds form two speed differences, which are output to the current signal of a single motor through the action of the speed controller. This simplifies the problem of multimotor synchronous control to the problem of single motor speed control. The coupling problem of the multimotor system is solved.

3.1. A General Method for GFTSMC Design

A high-order single-input single-output nonlinear system is considered: where and are smooth functions in the field and , . A fast sliding mode with recursive structure is represented as [38] where , (), and are odd numbers. In order to avoid the singularity problem in the global fast terminal sliding mode, the following conditions must be satisfied [39]:

The global fast terminal sliding mode control law is designed as follows [38]: where s₀ = x₁, , , and () are positive odd numbers. In the control law (18), the time for the state of the system to reach the sliding surface along the sliding surface is [38]

3.2. Design of Speed Tracking Controller

The first derivative of velocity tracking error is

Since PMSM is a second-order single-input single-output nonlinear control system, according to equation (15), the system state variable of the speed tracking controller can be set as

The global fast terminal sliding surface of the speed tracking controller is defined as where and and () are positive odd numbers. In order to avoid the singularity problem, according to equation (10), when and , and should satisfy the following conditions:

The speed tracking controller is designed as follows:

3.3. Design of Speed Compensation Controller

The first derivative of average velocity error is as follows:

The speed compensation controller is defined as

Equation (25) can be simplified as

The system state variables of speed compensation controller are set as follows:

The global fast terminal sliding mode surface of the speed compensation controller is expressed as follows:

The speed compensation controller is designed as follows:

3.4. Design of Load Torque Luenberger Observer

In the actual motor control system, the speed is measurable, but the load torque is not so and are unknown. In the design of motor controller, one of them includes . Therefore, it is necessary to design a load torque observer to feed back the observed values of and to the speed controller.

The state variable, input, and output of load torque Luenberger observer are selected as follows:

The general form of state space variables is as follows: where , , , and are coefficient matrices, which depend on the parameters of PMSM. In this paper, when the control frequency is very high and the sampling period is very small, the load torque is a constant value in a sampling period. By changing equation (32) to the state space expression, it can be obtained that

The load torque Luenberger observer is designed as follows: where is a coefficient matrix and

Equation (34) is derived as follows:

Substituting equations (31) and (35) into equation (36), the following results can be obtained:

Equation (37) is simplified as following:

To make the observed load torque approach the real value, another constraint is that the eigenvalue of the - matrix is less than 0 [40]. The eigenvalues of the - matrix are obtained: where is the unit matrix. Equation (39) is converted into the following form:

Set the value of the eigenvalue as , and the following result can be obtained:

By comparing equations (40) and (41), the following equation can be obtained:

By changing the values of and , the speed of the observed load torque value approaching the real value is adjusted. After the load torque observed values of each motor is obtained, the observed values of can be obtained as follows:

Substitute for in equations (24) and (30) to obtain

4. Stability Analysis

Consider a Lyapunov function:

The first derivative of is obtained:

The first-order differential of is obtained:

Substituting equation (20) into equation (47), it can be obtained that

Substituting equation (24) into equation (48), it can be obtained that

The first derivative of is obtained:

Substituting equation (27) into equation (51), it can be obtained that

Substituting equation (30) into equation (52), the following equation can be obtained:

Substituting equations (50) and (54) into (46), the following equation can be obtained:

Since and are positive odd numbers and are even numbers, the following result can be obtained:

It can be obtained that . According to the Lyapunov stability theorem, the controller is asymptotically stable.

5. Experiments

In order to verify the effectiveness of the control strategy proposed in this paper, a multimotor experimental platform is built, which is composed of four permanent magnet synchronous motors with the same parameters. The experimental platform is shown in Figure 3. The work process of the experimental platform is as follows: (1) edit instruction data; (2) the upper computer software imports instruction data; (3) the upper computer sends the instruction data to each motor controller through an RS-485 multifunction converter; (4) the controller performs control according to the received instruction; and (5) the data acquisition card EM9636 collects the speed and torque signals and processes them through LabVIEW software, and then, the data are recorded. The parameters of the motor are shown in Table 1. The control structure of a single motor using the control strategy proposed in this paper is shown in Figure 4.

(a)

(b)

In the experiment, the master-slave control (MSC) strategy (motor 1 is the master motor), ring coupling control (RCC) strategy, adjacent crosscoupling control (ACCC) strategy, and mean deviation coupling control (MDCC) strategy are compared. In order to simulate the variety of load changes in the actual situation, two kinds of load forms are given to the multimotor system in the experiment: (1)Alternate loading of each motor after no-load start(2)Step change or continuous change of load after starting under unbalanced load

5.1. Alternate Loading of Each Motor after No-Load Start

After the motor reaches the given speed 0 r/min, load motor 1 with 10 N·m at 1 s and remove the load at 2 s; load motor 2 with 20 N·m at 3 s and remove the load at 4 s; load motor 3 with 30 N·m at 5 s and remove the load at 6 s; and load motor 4 with 40 N·m at 7 s and remove the load at 8 s. Table 2 shows the load size and time period of each motor.

Figure 5 shows the motor speed curves of the four control strategies. The orange curve represents the speed curve of motor 1, the green curve represents the speed curve of motor 2, the blue curve represents the speed curve of motor 3, and the red curve represents the speed curve of motor 4. It can be seen from the Figure 5 that when the load changes suddenly, the motor speed will fluctuate. Under the action of the controller, it will reach the steady state again after a period of time. Among the four control strategies, the speed fluctuation of the MSC is the largest, and the speed fluctuation reaches 138 r/min when the motor 4 is suddenly loaded at 7 s; under the same condition, the speed fluctuation of the MDCC is only 55 r/min, which is the smallest of the four control strategies, and its adjustment time is also the shortest. From the speed curve distribution of the four motors, the speed curve distribution of the MSC is the most discrete. The RCC and the ACCC are better than the MSC; however, they are all worse than the MDCC.

(a) Master-slave control

(b) Adjacent crosscoupling control

(c) Ring coupling control

(d) Mean deviation coupling control

In order to evaluate the synchronization performance of each control strategy more intuitively, two kinds of statistics are used to describe the synchronization degree of each control strategy: (1)Range(2)Mean deviation (MD)

Figure 6 shows the range curves of the four control strategies. The orange curve represents the MSC, the green curve represents the ACCC, the blue curve represents the RCC, and the red curve represents the MDCC. It can be seen from Figure 6 that when the load increases suddenly, with the increase of the load value, the range of the four control strategies become larger. When loading motor 1, since motor 1 of the MSC is the master motor, the range value of the MSC at 1 s is not the largest. When the load is suddenly increased on the slave motor, the range of MSC is the largest. The range of the four control strategies at the moment of sudden load is shown in Table 3.

It can be seen from Table 3 that when motor 1 load changes suddenly, the range of the RCC is the largest, reaching 18.0 r/min and 18.1 r/min, and the range of the MDCC is the smallest, being 8.0 r/min and 7.7 r/min, respectively. When motor 2 load changes suddenly, the range of the MSC is the largest, reaching 66.7 r/min and 67.0 r/min. The range of the RCC is 36.4 r/min, and the range of the ACCC is 36.4 r/min. The range is 26.0 r/min and 26.1 r/min, and the range of the MDCC is the smallest, which is 16.8 r/min and 16.5 r/min. When motor 3 load changes suddenly, the range value of the MSC is the largest, which is 101.5 r/min and 101.9 r/min, followed by the RCC, which is 54.7 r/min and 55.1 r/min. The range of the ACCC is 39.3 r/min and 38.6 r/min, and the range of the MDCC is 25.6 r/min and 25.9 r/min. When the load of motor 4 changes suddenly, the range of MSC is still the largest, 137.4 r/min and 136.9 r/min; the range of ACCC is 51.6 r/min and 51.3 r/min; the range of RCC is 73.1 r/min and 73.3 r/min; and the range of MDCC is the smallest, 34.9 r/min and 33.9 r/min.

Figure 7 shows the mean deviation curves of the four control strategies. The orange curve represents the MSC, the green curve represents the ACCC, the blue curve represents the RCC, and the red curve represents the MDCC. It can be seen from Figure 7 that when the load changes suddenly, the mean deviation of each control strategy increases with the increase of the load value. When the load of motor 1 changes suddenly, the RCC has the largest mean deviation, which is 5.9 r/min and 5.8 r/min; the ACCC has the mean deviation of 4.3 r/min and 4.2 r/min; the MSC has the mean deviation of 3.7 r/min and 3.4 r/min; and the MDCC has the smallest mean deviation, which is 3.0 r/min and 2.9 r/min. When the load of motor 2 changes suddenly, the mean deviation of the MSC is the largest, being 25.1 r/min and 25.2 r/min, followed by the mean deviation of the RCC, 11.8 r/min, and the mean deviation of ACCC is 8.5 r/min and 8.4 r/min; the mean deviation of the MDCC is the smallest, which is 6.3 r/min and 6.2 r/min. When the load of motor 3 changes suddenly, the mean deviation of the MSC is still the largest, which is 38.0 r/min and 38.1 r/min, followed by the mean deviation of the RCC, which is 17.6 r/min and 17.8 r/min. The mean deviation of the ACCC is 12.7 r/min and 12.6 r/min, and the mean deviation of the MDCC is the smallest, which is 9.5 r/min and 9.6 r/min. When the load of motor 4 changes suddenly, the mean deviation of MSC is the largest, which is 68.6 r/min and 68.4 r/min, about three times of the mean deviation of RCC; the mean deviation of ACCC is 16.8 r/min and 16.9 r/min; and the mean deviation of MDCC is the smallest, which is 13.0 r/min and 12.6 r/min. Table 4 shows the mean deviation of the four control strategies when the motor load changes suddenly.

It can be seen from the data that no matter the range or the average difference, under the same load conditions, the four-motor system adopting the MDCC can get the minimum range and mean deviation, and it can be seen from Figures 6 and 7 that the range and mean deviation of the MDCC converge faster than the other three strategies. The experimental results show that under the condition of single motor loading successively, the speed synchronization degree of multimotor system with MDCC is better.

Figure 8 shows the curve of the real value of the load torque and the observed value obtained by the Luenberger observer. In Figure 8, the red curve represents the real value of load torque, and the blue curve represents the observed value. It can be seen from the figure that the observed value of load torque can better track the real value. Only when the load changes suddenly, there is an error between the observed value and the real value, and the error will converge to zero quickly.

(a) Motor 1

(b) Motor 2

(c) Motor 3

(d) Motor 4

5.2. Step Change or Continuous Change of Load after Starting under Unbalanced Load

The given speed of each motor is r/min, where motor 1 and motor 2 start with no load, motor 3 starts with a load of 10 N·m, and motor 4 starts with a load of 30 N·m. After reaching the given speed, motor 1 loads 10 N·m at 1.5 s, until 3 s, the load increases to 30 N·m, and the load drops to 0 at 4 s; motor 2 has a sudden load increase of 30 N·m at 2 s, then a sudden load drop of 10 N·m at 3.5 s, and then a sudden drop to 0 at 4.5 s; motor 3 started under a load of 10 N·m, and then, from 2.5 s, the load torque suddenly dropped to 0 when the speed increased to 5 s at a speed of 4 t; motor 4 was started under a load of 30 N·m, and then, from 2.5 s, the load torque suddenly dropped to 0 when the speed decreases to 5 s at a speed of 6 t. Table 5 shows the load of each motor in each time period.

Figure 9 shows the motor speed curves of each control strategy under this kind of load. The orange curve, green curve, blue curve, and red curve represent the speed of motor 1, motor 2, motor 3, and motor 4, respectively. It can be seen from Figure 9 that the speed fluctuation of the motor is the biggest at the two moments when the load changes the most. The speed fluctuation of the four-motor system adopting the MSC reaches 100 r/min at these two moments, while the speed fluctuation of the four-motor system adopting the MDCC is 38 r/min at these two moments, and the speed fluctuation values of the four-motor system adopting ACCC and RCC are between them, which are 52 r/min and 59 r/min, respectively. Figure 9 also shows that the controller can better regulate the speed of the motor to keep it in a steady state during the period of gradual load change of the motor.

(a) Master-slave control

(b) Adjacent crosscoupling control

(c) Ring coupling control

(d) Mean deviation coupling control

Figure 10 shows the range curve of the four control strategies under the second load form. Due to unbalanced starting, there will be speed difference when the motor starts to a stable state. It can be seen from Figure 10 that the range of the MSC at startup is the largest, reaching 110.2 r/min, followed by the range of the RCC, 49.7 r/min, and the range of ACCC is 29.1 r/min. The range of the MDCC is the smallest, which is 24.4 r/min. At 1.5 s, when the load of motor 1 suddenly increases by 10 N·m, the range of the MSC, ACCC, RCC, and MDCC is 15.0 r/min, 13 r/min, 18.5 r/min, and 8.1 r/min, respectively. At 2 s, when the load of motor 2 increased by 30 N·m, the range of the MSC is the largest, which is 102.7 r/min, followed by the range of the RCC, which is 55.0 r/min. The range of the ACCC is 38.7 r/min, and the range of the MDCC is the smallest, which is 25.7 r/min. At 3 s, when the load of motor 1 increases from 10 N·m to 30 N·m, the range of the RCC is the largest, which is 36.5 r/min, and the range of the MSC is 28.8 r/min, the range of the ACCC is 26.3 r/min, and the range of the MDCC is the smallest, which is 17.5 r/min. At 3.5 s, the load of motor 2 dropped from 30 N·m to 10 N·m. At this moment, the range of the MSC is the largest, which is 67.9 r/min, and the range of the RCC is 36.6 r/min, the range of the ACCC is 26.2 r/min, and the range of the MDCC is 16.6 r/min. At 4 s, when the load of motor 1 suddenly drops from 30 N·m to 0, the range of the RCC is the largest at 54.6 r/min, and the range of the MSC is 45.4 r/min. The range of the ACCC is 39.0 r/min, and the range of the MDCC is the smallest, which is 25.3 r/min. At 4.5 s, when the load of motor 2 drops suddenly from 10 N·m to 0, the range of MSC, ACCC, RCC, and MDCC is 35.5 r/min, 13.0 r/min, 18.0 r/min, and 8.3 r/min, respectively. At 5 s, the load of motor 3 dropped from 20 N·m to 0, and the load of motor 4 dropped from 15 N·m to 0. At this moment, the range of the MSC is the largest, which is 67.7 r/min. The range of the RCC is 28.0 r/min, the range of the ACCC is 17.1 r/min, and the range of the MDCC is the smallest, which is 16.9 r/min. Table 6 shows the range of the four control strategies at the moment of the motor load changes suddenly.

Figure 11 shows the mean deviation curve of the four control strategies under the second load form. When the load of motor 1 changes suddenly, among the four control strategies, the mean deviation of the RCC is the largest; when the load of other motors changes suddenly, the mean deviation of the MSC is the largest. Table 7 shows the mean deviation of the four control strategies when the load of each motor changes suddenly under this type of load.

It can be seen from Table 7 that when there is a sudden change in the load of motor 1, the mean deviation of the RCC is the largest; the order from large to small is as follows: the mean deviation of RCC, the mean deviation of MSC, the mean deviation of ACCC, and the mean deviation of MDCC; when there is a sudden change in the load of the other motors, the mean deviation of the MSC is the largest, followed by the mean deviation of the RCC, the mean deviation of the MDCC is the smallest, and the mean deviation of the ACCC is between the mean deviation of RCC and the MDCC.

Tables 6 and 7 and Figures 10 and 11 show that under the second load form, the range and mean deviation of the four-motor system using MDCC are the smallest, and the time for the range and average difference to converge to 0 are the shortest. The test results show that the multimotor system using MDCC has the best degree of synchronization in the case of sudden or gradual changes in load after unbalanced startup.

Figure 12 shows the curve of the real value of the load torque and observed value obtained by the observer. It can be seen from Figure 12 that no matter the load is abrupt or gradual, the load torque Luenberger observer can better track the actual value, and the error between them can quickly converge to 0. The experimental results show that the load torque Luenberger observer is effective.

(a) Motor 1

(b) Motor 2

(c) Motor 3

(d) Motor 4

6. Conclusions

This study has successfully proved the effectiveness of the proposed mean deviation coupling control for the multimotor system via global fast terminal sliding mode control. First, the mathematical model of the PMSM is established, which provides a mathematical foundation for the controller design; secondly, combined with the global fast terminal sliding mode control algorithm, the multimotor mean deviation coupling synchronous controller is designed, and the deviation coupling control strategy is optimized. The structure reduces the calculation amount of the control system and improves the synchronization accuracy of the system. In addition, the load torque Luenberger observer is designed to observe the external load of the motor in real time and feed it back to the controller. The stability of the controller is analyzed based on the Lyapunov stability theorem, and it is concluded that the designed controller is asymptotically stable. Finally, a four-motor experimental platform was built. The experimental results show that the load torque Luenberger observer can better estimate the actual load value. By comparing with other commonly used multimotor synchronous control strategies, the result of the proposed control strategy with higher synchronization accuracy is obtained, and the effectiveness of the proposed control strategy is verified. The effectiveness of the proposed control strategy is verified.

Data Availability

The data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Acknowledgments

This study was funded by National Key Research and Development Plan of China, grant number 2016YFC0802903.

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