JPH06250702A - Servo control unit - Google Patents

Abstract

PURPOSE:To provide the servo control unit which can greatly reduce position deviation by speedily and automatically adjusting the gain of feedforward. CONSTITUTION:When a position command thetar, a speed command omegar, and an acceleration command omega'r are outputted from a command value generating device 1, a control system operates according to the commands to drive a machine to be controlled. At this time, a feedforward gain error estimation part 11 operates to estimates gain errors of feedforward, i.e., a torque feedforward gain error DELTAj and a speed forward gain error DELTAKVFF from the speed command omegar and acceleration command omega' and the position deviation corresponding to them and output the estimated position to a feedforward control part 8A. This feedforward control part 8A adjusts the feedforward gain of the control system on the basis of the gain errors estimated by the gain error estimation part 11 so that the position deviation thetar-theta becomes zero.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a servo controller having a feedforward control function.

[0002]

2. Description of the Related Art A conventional servo controller having a feedforward control function is constructed as shown in FIG. In FIG. 3, reference numeral 1 denotes a command value generation device that generates a periodic position command θr, a speed command ωr, and an acceleration command ω′r. Reference numeral 2 denotes a motor / control system 2 which detects an angle θ and an angular velocity ω from the motor / control system 2 and inputs the angle θ to the minus terminal of the subtractor 3 and the angular velocity ω to the minus terminal of the adder / subtractor 5. It

The position command θr output from the command value generator 1 is input to the + terminal of the subtracter 3 in the control system, and the detected angle θ of the motor / control system 2 is subtracted from the position command θr. Position deviation θ r −θ is obtained. This position deviation θr−θ is input to the multiplier 4 and multiplied by the position feedback gain Gp, and the multiplication result is input to the + terminal of the adder / subtractor 5.

The speed command ω r and the acceleration command ω'r output from the command value generator 1 are sent to the feedforward control unit 8. This feedforward control unit 8
Is composed of multipliers 9 and 10. Above speed command ω
r is input to the multiplier 9, multiplied by the speed feedforward gain K _VFF to obtain a speed feedforward value, and the acceleration command ω′r is input to the multiplier 10 and multiplied by the torque feedforward gain Jo to calculate the torque feedforward. It becomes a value.

The velocity feedforward value output from the multiplier 9 is input to the + terminal of the adder / subtractor 5. The adder / subtractor 5 adds the velocity feedforward value from the multiplier 9 to the output of the multiplier 4, subtracts the angular velocity ω to obtain the velocity deviation, and outputs the velocity deviation to the multiplier 6. The multiplier 6 calculates the speed feedback gain Gv based on the speed deviation.
And outputs to the adder 7. The adder 7 adds the output of the multiplier 6 and the torque feedforward value output from the multiplier 10 and inputs it to the motor / control system 2 as a torque command u.

[0006]

As described above, in the conventional servo control device, the feedforward gain in the feedforward control unit 8 is fixed, and therefore there is a gain error in the feedforward gain due to fluctuations in the load. In this case, the position deviation is canceled by feedback, but there is a problem that the deviation due to the feedback delay cannot be suppressed for a high-speed command.

The present invention has been made in view of the above points, and an object of the present invention is to provide a servo control device capable of remarkably reducing a position deviation by rapidly and automatically adjusting a feedforward gain.

[0008]

SUMMARY OF THE INVENTION The present invention relates to a servo control device for periodically driving a controlled machine, a command value generating device for generating a periodic position command θr, a speed command ωr, and an acceleration command ω'r. And a control system for driving and controlling the controlled machine according to the position command θr, a feedforward gain error estimator that estimates a feedforward gain error from the speed command ωr, the acceleration command ω′r and the position deviation relative to it. According to the gain error estimated by the gain error estimation unit, a feedforward control unit for adjusting the feedforward gain so that the position deviation becomes zero with respect to the control system is provided.

[0009]

[Operation] Position command θr, speed command ω from command value generator
When r and the acceleration command ω'r are output, the control system operates according to these commands to drive the controlled machine. At this time, the feedforward gain error estimation unit operates to estimate the feedforward gain error, that is, the torque feedforward gain error ΔJ and the speed feedforward gain error, from the speed command, the acceleration command, and the position deviation relative thereto. Then, the estimated position is output to the feedforward control unit. This feedforward control unit adjusts the feedforward gain based on the gain error estimated by the gain error estimation unit so that the position deviation becomes zero with respect to the control system. Therefore, even if a position deviation occurs due to load fluctuation or the like, the position deviation can be reduced by the gain adjustment in the feedforward control unit.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing the configuration of a servo controller according to an embodiment of the present invention. According to the present invention, in the circuit shown in FIG. 3, a feedforward control unit 8A having a variable gain is provided in place of the feedforward control unit 8 having a fixed gain, and the feedforward control unit 8A controls the gain of the feedforward control unit 8A. The gain error estimation unit 11 is provided. Since other configurations are the same as those in FIG. 3, the same reference numerals as those in FIG. 3 are given and detailed description thereof is omitted. The feedforward control unit 8
A is composed of variable gain multipliers 9a and 10a.

Further, the feedforward gain error estimation unit 11 uses the speed command ω output from the command value generation device 1.
From r, the acceleration command ω′r, and the position deviation θr −θ output from the subtractor 3, the torque feedforward gain error ΔJ and the velocity feedforward gain error ΔK _VFF are calculated by the equations (3) and (4) described later. And output. Due to this torque feedforward gain error ΔJ, the torque feedforward gain Jo of the multiplier 10a becomes J.
It is adjusted to o + ΔJ. Similarly, the speed feedforward gain error ΔK _VFF adjusts the speed feedforward gain K _VFF of the multiplier 9a to K _VFF + ΔK _VFF . By the above automatic adjustment, the position deviation θr−θ is changed so as to approach zero. Next, the operation of the above embodiment will be described. The system in the case where the fixed gain feedforward control unit 8 shown in FIG. 3 is used is expressed by the following equations (1) and (2).

That is, the torque command is u, the angle is θ, the angular velocity is ω, the position command is θr, the speed command is ωr, the acceleration command is ω′r, the moment of inertia is J, the viscosity coefficient is D, and the speed feedback gain is Gv. , The position feedback gain is Gp, the velocity feedforward gain is K _VFF , and the torque feedforward gain is Jo, the equation of motion of the motor / control system 2 is Equation (1), and the equation of the torque command u is Equation (2). expressed. Jω ′ = u−Dω (1) u = Jo ω′r + Gv {K _VFF ωr −ω + Gp (θr −θ)} (2) The above (1) and (2) and ωr = θ′r, ω = The transfer function from the position command θr to the position deviation θr−θ according to θ ′ is given by equation (3). (Θr −θ) / θr = (ΔJS ² + ΔK _VFF Gv S) / {JS ² + (Gv + D) S + Gp Gv} (3) However, torque feedforward gain error ΔJ: ΔJ = J−Jo (4) Speed feedforward gain error ΔK _VFF : ΔK _VFF = {1+ (D / GV)} − K _VFF (5). Therefore, the torque feed-forward gain error ΔJ and the speed feed-forward gain error ΔK _VFF are obtained, and the position deviation θr −θ is obtained by automatically adjusting the gain as Jo + ΔJ → Jo K _VFF + ΔK _VFF → K _VFF.
Can be zero. Hereinafter, a method of obtaining the torque feedforward gain error ΔJ and the velocity feedforward gain error ΔK _VFF will be described. Φ as a new signal
(T) is defined as shown in equation (6). φ (t) = (Gp Gv ωr) / {JS ² + (Gv + D) S + Gp Gv} (6) From the above formula (6), the formula (3) becomes θr −θ = (ΔJ / Gp Gv) φ ′ + (ΔK _VFF / Gp) φ (7) . Then, in a certain time section [t1, t2],
When both sides of the equation (7) are multiplied by φ ′ and φ and integrated, the following equations (8) and (9) are obtained.

[0014]

[Equation 1] Since the command value is a periodic function here, φ (t) results
Is a periodic function. Therefore, φ (t + nT) = φ (t + (n + 1) T) (10), where n = 0, 1, 2, ... At this time, t1
= T + nT and t2 = t + (n + 1) T,

[0015]

[Equation 2] Becomes Therefore, from equations (8), (9) and (12),
Expressions (13) and (14) are obtained.

[0016]

[Equation 3]

FIG. 2 shows a configuration example of the feedforward gain error estimation unit 11 using the above equations (6), (13) and (14). Here, since the band of the control system is sufficiently higher than the band of the periodic function of the command value, the unknown parameter J of the equation (6) is
Instead of and D, Jo and the viscosity coefficient Do are used.

By using the above equations (13) and (14), the speed command ωr, the acceleration command ω'r and the position deviation θ
Torque feedforward gain error ΔJ from r − θ,
The velocity feedforward gain error ΔK _VFF can be obtained. By using the torque feedforward gain error ΔJ and the velocity feedforward gain error ΔK _VFF , the feedforward gains Jo and K _VFF are automatically adjusted as follows: Jo + ΔJ → Jo K _VFF + ΔK _VFF → K _VFF However, the position deviation θr−θ can be made zero.

[0019]

As described above in detail, according to the present invention, in the feedforward gain error estimation unit 11, the position deviation θr−θ is made zero from the speed command ωr, the acceleration command ω′r, and the position deviation θr−θ. The torque feedforward gain error ΔJ and the speed feedforward gain error ΔK _VFF are calculated so that the torque feedforward gain Jo and the speed feedforward gain K _{VFF in the} feedforward control unit 8A are adjusted. Therefore, the position deviation θ
Even if r−θ is generated, the position deviation θr−θ can be made zero by automatically adjusting the feedforward gains Jo and K _VFF in the multipliers 9a and 10a in the feedforward control unit 8A.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a servo control device according to an embodiment of the present invention.

FIG. 2 is a diagram showing a configuration example of a feedforward gain error estimation unit in FIG.

FIG. 3 is a block diagram showing a configuration of a conventional servo control device.

[Explanation of symbols]

 1 Command value generator 2 Motor / control system 3 Subtractor 4 Multiplier 5 Adder / subtractor 6 Multiplier 7 Adder 8, 8A Feedforward control unit 9, 9a Multiplier 10, 10a Multiplier 11 Feedforward gain error estimation unit

Claims (1)

[Claims] 1. A servo control device for periodically driving a controlled machine, a command value generation device for generating a periodic position command, a speed command, and an acceleration command, and driving control of the controlled machine according to the position command. Control system, speed command,
The feed-forward gain error estimator that estimates the feed-forward gain error from the acceleration command and the position deviation relative to it, and the gain error estimated by this gain error estimator, make the position error zero for the control system. And a feedforward control unit that adjusts the feedforward gain.