JPH08297512A - Method for positioning control by sliding mode control - Google Patents

Abstract

PURPOSE: To perform accurate and stable control following up the standard output of a model controller even if the state value of a load to be controlled varies by performing sliding mode control on the basis of the position deviation of the actual position of a servo motor from a model position and the speed deviation of the actual speed of the servo motor from a model speed as switching lines. CONSTITUTION: In this method, a sliding mode controller 220 which inputs the model position and model speed outputted from a standard model 10, and the servo motor position and servo motor speed respectively and outputs a sliding mode control input Tcomp, is used, and the position deviation and speed deviation are regarded as the switching lines and the sliding mode control is performed. In this case, the sliding mode control input Tcomp is added to the multiplication value obtained by adding the deviation of the servo motor speed from the model speed to the speed command obtained by multiplying the deviation of the servo motor position from the model position by a position gain Kp and multiplying the addition result by a speed gain Kv to obtain an acceleration command U.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a positioning control method for a servomotor for driving a robot, an NC or the like, and more particularly, a positioning control method for a servomotor for performing accurate and stable control with respect to changes in the conditions of the controlled object. Regarding the method.

[0002]

2. Description of the Related Art Conventionally, in order to improve the command followability of a drive system by a servo motor, a positioning control method for a servo motor such as a robot or NC has been used as a method of positioning the 1994 Annual Conference of the Institute of Electrical Engineers of Japan, No. 178. A two-degree-of-freedom control system having a two-degree-of-freedom position control system that applies a reference model such as that disclosed in "A two-degree-of-freedom position control method for a motor to which a reference system model is applied" can independently design target value tracking performance and disturbance suppression characteristics. Has been adopted. FIG. 3 is a block diagram showing a configuration of a two-degree-of-freedom position control method for a servo motor to which a reference model is applied. In the figure, reference numeral 300 surrounded by a dotted line is a reference model, and reference numerals 301 to 306 are transmission elements 311, 312. Is the addition point. Reference numeral Xref is a position command from a position command generator (not shown), Kp _M is a model position gain, K
v _M is the model velocity gain, J _M is the model moment of inertia, X _M is the model position,

[0003]

[Outside 1]

Is the model speed,

[0005]

[Outside 2]

[0006] indicates a model acceleration. This reference model 3
When the position command Xref is input from the outside to 00, the model model X _M and the model velocity are input as shown in the reference model 300.

[0007]

[Outside 3]

Is output to the outside and is fed back to the addition points 311, 312 to calculate and output the model acceleration command U _M. (Hereinafter, each element which is the output of the model controller is represented by adding "model" before the word). In the figure, 401 to 406 are transmission elements of the motor control system, 41
Reference numerals 1 to 413 are addition points of the motor control system. The sign Kp is position gain, Kv is velocity gain, J _L is the moment of inertia of the motor and load,

[0009]

[Outside 4]

Is the inertial moment nominal value of the motor and load, X is the motor position,

[0011]

[Outside 5]

Is the motor speed,

[0013]

[Outside 6]

Is a motor acceleration, and U and Uref are acceleration commands. Model position X output from the reference model 300
_The model speed output from the reference model 300 by multiplying the deviation between _M and the motor position X by a position gain Kp to obtain a speed command.

[0015]

[Outside 7]

And motor speed

[0017]

[Outside 8]

The deviation between and the speed command is added and multiplied by the speed gain Kv to obtain the acceleration command U. A model acceleration command U _M output from the reference model 300 in a feedforward manner is added to this acceleration command U to obtain an acceleration command Ure.
It is configured to output to the motor as f. That is, the acceleration command Uref to the motor can be expressed by the following equation.

[0019]

[Equation 1]

At this time, if the parameters of the reference model match the motor of the actual machine, the motor position X, the motor speed

[0021]

[Outside 9]

Is the model position X _M , the model velocity

[0023]

[Outside 10]

[0024] Each of the deviation becomes 0 in order to match, the control system becomes Uref = U _M is controlled by the model acceleration commands U _M which is feed-forward outputted from the reference model. When the position and speed of the model and the motor deviate from each other due to the torque disturbance applied to the motor, feedback control is performed by the position gain Kp and the speed gain Kv.
Since the motor position follows the model position X _M which is the output of the reference model, the command followability can be improved.

[0025]

However, in the conventional two-degree-of-freedom control system, when the parameter of the actual system fluctuates from the nominal value (for example, fluctuation of load inertia), the motor position X is the output of the reference model. There is a problem that a tracking error occurs with respect to a certain model position X _M.
As an example, FIG. 4 shows the position step response when the inertia moment J _L of the motor and the load fluctuates twice in the control system of FIG. In the figure, the dotted line is the model position X _M which is the output of the reference model, and the solid line is the motor position X. As described above, in the conventional two-degree-of-freedom control system, the motor position X cannot follow the model position X _M with respect to parameter fluctuations, and there is a problem that an overshoot or the like occurs even with respect to a position command.

An object of the present invention is to provide a positioning control method for a servo motor, which is capable of performing accurate and stable control by following the reference output of the model controller even if the state value of the load to be controlled changes. is there.

[0027]

In the positioning control method by sliding mode control according to the present invention, a reference model composed of a model of a servo motor drive system and a model controller for controlling the model is applied to provide two free modes. In the positioning control method of the servo motor which is controlled by the degree control system, the model position which is the output from the reference model,
Sliding mode control is performed with a positional deviation from the actual position of the servo motor, a model speed output from the reference model, and a speed deviation from the actual speed of the servo motor as switching lines.

[0028]

Since the sliding mode control is performed in the positioning control method of the two-degree-of-freedom control system to which the reference model is applied, even if the load state value such as the load inertia moment to be controlled fluctuates from the nominal value, the state remains unchanged. Since it converges to the sliding mode switching line, the deviation of the state value is restricted to the reference state value line including the preset target value, and the coefficient is switched in the direction in which the deviation value decreases each time the reference line is crossed, and the control target It is possible to asymptotically and stably converge to the deviation value 0 with the passage of time without being affected by the fluctuation of the parameter of, and to make the state quantity of the controlled object follow the target state quantity of the model.

[0029]

Embodiments of the present invention will now be described with reference to the drawings. FIG. 1 is a configuration block diagram of a two-degree-of-freedom position control method for a servo motor to which the reference model of the present invention is applied. In the figure, 100 surrounded by a dotted line is a reference model.
1 to 106 are transmission elements, and 111 and 112 are addition points. Reference symbol Xref is a position command from a position command generator (not shown), Kp _M is a model position gain, Kv _M is a model velocity gain, J _M is a model moment of inertia, X _M is a model position,

[0030]

[Outside 11]

Is the model speed,

[0032]

[Outside 12]

Represents the model acceleration. 201-2 in the figure
Reference numeral 06 is a transmission element of the motor control system, 220 is a sliding mode controller, and 211 to 214 are addition points of the motor control system. The sign Kp is position gain, Kv is velocity gain, J _L is the moment of inertia of the motor and load,

[0034]

[Outside 13]

Is the nominal moment of inertia of the motor and load, X is the motor position,

[0036]

[Outside 14]

Is the motor speed,

[0038]

[Outside 15]

Is a motor acceleration, Tcomp is a sliding mode control input (compensation value), and U and Uref are acceleration commands. The basic configuration and operation of the two-degree-of-freedom control system to which the reference model is applied are the same as those of the conventional example shown in FIG. In the embodiment of the present invention, the model position X _M , the model velocity

[0040]

[Outside 16]

, Motor position X, motor speed

[0042]

[Outside 17]

The model position X _M output from the reference model 100 is provided with a sliding mode controller 220 for inputting a sliding mode control input Tcomp
Of the model speed output from the reference model 100 to the speed command obtained by multiplying the deviation between the motor position X and the position gain Kp.

[0044]

[Outside 18]

And the motor speed

[0046]

[Outside 19]

The sliding mode control input Tcomp is added to the multiplication value obtained by adding the deviation of
Is added to form the acceleration command U. In this embodiment, the sliding mode switching line is defined as follows. That is, the position deviation obtained by subtracting the motor position X from the model position X _M which is the output of the reference model, and the model speed which is the output of the reference model.

[0048]

[Outside 20]

From motor speed

[0050]

[Outside 21]

The speed deviation obtained by subtracting is the switching line.

[0052]

[Equation 2]

Here, C is a positive constant. In addition, the existence condition of sliding mode is

[0054]

(Equation 3)

Therefore, the existence condition of the global sliding mode is

[0056]

[Equation 4]

It becomes From equation (1),

[0058]

(Equation 5)

It becomes Acceleration command Ure to servo motor
f is

[0060]

(Equation 6)

However, Tcomp is a sliding mode control input. Due to fluctuations in system parameters, acceleration command Uref to servo motor is multiplied by a

[0062]

(Equation 7)

Is the motor acceleration

[0064]

[Outside 22]

Then, from equations (4) and (5),

[0066]

(Equation 8)

From equation (1),

[0068]

[Equation 9]

Since equation (7) is substituted into equation (6),
Moreover, when rearranging as C = Kp,

[0070]

[Equation 10]

Here, the model acceleration

[0072]

[Outside 23]

Assuming that the model acceleration command U _M is equal to

[0074]

[Equation 11]

It becomes Therefore,

[0076]

[Outside 24]

Is given by the following equation.

[0078]

(Equation 12)

Here, since the normal design is Kp <aKv, the first term in the equation (10) becomes negative. Therefore, in order to satisfy the expression (1), (−Kp ² (X _M −X) + (1−a) U _M −aTcomp) S <0 (11) may be satisfied. Therefore, when S <0, 1) For (X _M −X) When (X _M −X)> 0 −Kp ² (X _M −X) −aTcomp1> 0 Tcomp1 = −Kp ² (X _M− X) / a _MIN (X _M -X) <0-Kp ² (X _M -X) -a Tcomp1> 0 From Tcomp1 = 0 2) U _{M When} U _M > 0 (1-a) U _M over aTcomp2> 0 Tcomp2 = (1 over _{a MAX) U M / a MAX} U (1 over a) when _M <0 U _M over aTcomp2> 0 Tcomp2 = (1 over a _MIN) U _M / a _MIN where a _MIN and a _MAX are the minimum value and the maximum value of the parameter fluctuation.

When S> 0, the above ( _XM -X),
The positive and negative values of U _M are replaced. Therefore, the sliding mode control input Tcomp may be input as Tcomp = Tcomp1 + Tcomp2. FIG. 2 shows a step response simulation result in the present invention when the moment of inertia of the motor and the load fluctuate twice. In the figure, the dotted line is the model position X _M which is the output of the reference model, and the solid line is the motor position X. As described above, in the present invention, the state of the motor is restricted by the sliding switching line, so that the motor position X follows the model position X _M , which is the output of the reference model, and is accurate and stable even if the system parameters change. It becomes possible to control.

The speed control of the servo motor has been described as proportional control, but sliding mode control can also be performed in the case of proportional and integral control.

[0082]

As described above, according to the present invention, the service is
The sliding motor is used as a positioning control method for the servomotor.
Model, which is the output of the reference model,
Position X _M Position deviation obtained by subtracting the motor position X from
Model speed, which is the output of the model

[0083]

[Outside 25]

From motor speed

[0085]

[Outside 26]

The state of the motor is constrained by the sliding mode switching line consisting of the speed deviation obtained by subtracting, and an accurate, stable and robust control system can be provided against fluctuations in system parameters.

[Brief description of drawings]

FIG. 1 is a configuration block diagram of a two-degree-of-freedom position control method for a servo motor to which a reference model according to an embodiment of the present invention is applied.

FIG. 2 is a position step response graph when the moment of inertia of the motor and the load of the embodiment of the present invention fluctuates twice.

FIG. 3 is a configuration block diagram of a two-degree-of-freedom position control method of a servo motor to which a reference model of a conventional example is applied.

FIG. 4 is a position step response graph in the case where the inertia moments of the motor and the load are doubled in the conventional example.

[Explanation of symbols]

100, 300 normative models 101-106, 201-206, 301-306, 4
01-406 Transmission element 111, 112, 211-214, 311, 312, 4
11-413 Addition point 220 Sliding mode controller Xref Position command Kp _M model position gain Kv _M model speed gain J _M model inertia moment X _M model position

(Equation 13) Kp Position gain Kv Speed gain J _L Moment of inertia of motor and load

[Equation 14] X motor position

(Equation 15) Tcomp Sliding mode control input (compensation value) U, Uref Acceleration command

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Yuatsu Inazumi 2-1, Kurosaki Shiroishi, Yawatanishi-ku, Kitakyushu, Fukuoka Prefecture Yasukawa Electric Co., Ltd.

Claims (1)

[Claims] 1. A positioning control method for a servo motor, wherein a reference model consisting of a model of a servo motor drive system and a model controller for controlling the model is applied to control by a two-degree-of-freedom control system. A switching line is provided for a position deviation between a model position which is an output from the reference model and an actual position of the servo motor, a model speed which is an output from the reference model, and a speed deviation between an actual speed of the servo motor. Positioning control method characterized in that sliding mode control is performed as the above.