JP2005078479A - Positioning control unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve positioning performance of two linear sliders at the same time by considering influences given by one of the sliders upon the other. <P>SOLUTION: The unit comprises a controller 1 for a slider 1; a controller 2 for a slider 2; a power part 1 for driving the slider 1 by an output of the controller 1; a power part 2 for driving the slider 2 by an output of the controller 2; and a non-interference compensation operation part for operating on the basis of a machine constant, a control input 1, and a control input 2 of the linear sliders a non-interference compensation amount 1 to be outputted to the controller 1 and a non-interference compensation amount to be outputted to the controller 2 so as to remove the influences which the slider 1 and the slider 2 give to each other. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a positioning control device used in, for example, an electronic component mounting apparatus or an exposure apparatus, which has two sliders on one machine base and each slider conveys another object.

In recent years, with the aim of improving productivity, the transport system of machine tools and electronic component mounting apparatuses has been accelerated. Along with this, a reaction force of the table is applied to the machine base, and the machine base vibrates due to the spring element existing between the machine base and the ground, which has an adverse effect on the positioning performance of the slider on the machine base. It has been reported and an improved invention thereof has been reported (for example, see Patent Document 1).
An example of improving the machine vibration problem by the conventional linear slider will be described with reference to FIG. 4 (from Patent Document 1).
FIG. 4 is a diagram showing a conventional example. In FIG. 4, 101 is a motor transfer function, 102 is a speed reducer and pole / rectangular coordinate conversion constant, 103 is a table displacement / force conversion spring constant, 104 is a table drive transfer function, 105 is a machine base drive transfer function, and 106 is a machine. Table displacement / force conversion spring constant, 107 is the absolute displacement of the table viewed from the ground, 108 is the table displacement viewed from the machine base, 109 is the machine table displacement viewed from the ground, 110 is the propulsive force that drives the table, 111 is the table and electric motor Displacement difference from output; 112, motor displacement; 113, torque (propulsive force) for driving the motor; 114, decelerator and direct / polar coordinate conversion constant; 121, motor; 126, motor controller; 128, motor position Detection signal, 134 is a position target value signal, 135 is a motor position compensator, 139 is a precompensator based on a conventional model, and 141 is a motor control. Position command for, 142 motor model position time series data, 144 is a torque model command time series data, the 151 is a predistorter in the controller.
In the conventional example, first, the motor transfer function 101 for generating the motor displacement 112 from the input of the table torque 110 multiplied by the input torque 113, the speed reducer, and the direct / polar coordinate conversion constant 102, and the motor displacement 112 with the speed reducer and The table driving force 110 is generated by multiplying the deviation between the output obtained by multiplying the polar / rectangular coordinate conversion constant 102 and the table displacement 108 viewed from the machine base by the table displacement / force converting spring constant 103. The table transfer function 104 that outputs the absolute displacement 107 viewed from the ground of the table and the machine table displacement 109 multiplied by the machine table displacement / force conversion spring constant 106 are input together with the table driving force 110 to generate the machine table displacement 109. The machine table drive transfer function 105 is arranged, and the absolute displacement 107 and the front of the table as viewed from the ground. A table vibration model that generates a table displacement 108 as seen from the table due to the difference from the table displacement 109 is defined, the model calculation is executed in the precompensator, and each state quantity obtained as a result is calculated. By using the compensator 151 to design, the table displacement in the model is stably controlled, and the motor controller 126 is configured using the state quantity that is stably controlled. If it is sufficiently reflected, it is assumed that the actual control target is stably controlled as in the model in the precompensator 139.
International Publication Number WO00 / 52543 (Fig. 8 etc.)

However, the conventional model is for a single slider table. In a linear slider having two sliders on one machine base, which has been increasingly applied in recent years, the influence of the thrust of each slider on the machine base also affects the other slider. It does not mean that they should be used in parallel. For this reason, the linear slider with two sliders has a vibration problem different from the conventional one, and has a problem of performance deterioration.
Therefore, the present invention has been made in view of such problems, considering the influence of each slider on the other slider, and suppressing the influence, so that the positioning performance of both the two linear sliders can be improved simultaneously. An object of the present invention is to provide a positioning control device that can be improved.

In order to solve the above problem, the present invention is configured as follows.
The invention described in claim 1
In a positioning control device for controlling each of the two slider positions of a linear slider having two sliders on one machine base,
A controller 1 that controls the position of the slider 1, a controller 2 that controls the position of the slider 2, and a power unit 1 that provides thrust for driving the slider 1 based on a control input 1 output from the controller 1. Based on the control input 2 output from the controller 2, the power unit 2 that gives thrust for driving the slider 2, the mechanical constant of the linear slider, the control input 1, and the slider 1 based on the control input 2 And a non-interference compensation calculation unit for calculating a non-interference compensation amount 1 output to the controller 1 and a non-interference compensation amount 2 output to the controller 2 for removing the influence of the slider 2 on the other slider. Have
The controller 1 outputs the control input 1 using the position command 1 for the slider 1 and the non-interference compensation amount 1,
The controller 2 is configured to output the control input 2 using the position command 2 for the slider 2 and the non-interference compensation amount 2.
Since it is in this way, the influence of interference received from the sliders can be removed, and the positioning performance can be improved.

According to a second aspect of the present invention, in the first aspect of the invention, the slider 1 includes a position detector 1, the slider 2 includes a position detector 2, and each position detector detects each slider position. The position detection value 1 of the slider 1 is output to the controller 1, the position detection value 2 of the slider 2 is output to the controller 2,
The controller 1 outputs a control input 1 using the position command 1 for the slider 1, the non-interference compensation amount 1 and the position detection value 1,
The controller 2 is configured to output a control input 2 using the position command 2 for the slider 2, the non-interference compensation amount 2 and the position detection value 2.
Thus, in addition to the effect of the first aspect, the feedback controller can be configured using the position detection value, so that the control performance can be further improved.

According to a third aspect of the present invention, the configuration of the non-interference compensation calculation unit is configured by two primary filters and two differentiators.
Since this is the case, the compensation calculation can be easily performed.

The invention according to claim 4
In a positioning control device that has two sliders on one machine base, and each slider position is controlled by a sensor, and each of the two slider positions is controlled by a sensor.
Based on an actual controller 1 for controlling the position of the slider 1, an actual controller 2 for controlling the position of the slider 2, and an actual control input 1 output from the actual controller 1, thrust for driving the slider 1 is obtained. The power unit 1 for applying power and the power unit 2 for applying thrust for driving the slider 2 based on the actual control input 2 output from the actual controller 2 and the state quantities of the slider 1, the slider 2, and the machine base Is calculated by calculating a dynamic characteristic map, and a simulated linear slider model calculating unit that outputs a simulated state amount of the linear slider and the simulated state amount output from the simulated linear slider model calculating unit, A simulated control input computing unit that computes a compensation input for the simulated linear slider model by multiplying and adding a gain to the state quantity, and the actual controller 1 and the actual controller 2 are: Position command 1 for rider 1, position command 2 for slider 2, at least one of the simulated state quantity and simulated control input, position detection value 1 which is the output of position detector 1 of slider 1, and position detector of slider 2 The actual control input 1 and the actual control input 2 to the power unit 1 and the power unit 2 are determined using a position detection value 2 that is an output of 2. .
Thus, the positioning performance can be stably improved, and the degree of freedom for setting the control response is increased by setting the simulated control input calculation unit, so that the response can be set finely.

The invention according to claim 5
According to a fourth aspect of the present invention, the simulated linear slider model calculation unit is composed of at least six integrators.
Because of this, the control system can be designed easily.

Further, in the invention according to claim 6, the simulated linear slider model calculation unit in the invention according to claim 4 or claim 5,
Outputting at least one of a simulated position, simulated speed, simulated acceleration, and simulated thrust of the slider 1 and at least one of a simulated position, simulated speed, simulated acceleration, and simulated thrust of the slider 2; To do.
As a result, the simulated state quantity of the simulated linear slider model calculation unit can be reflected in the actual controller.

According to a seventh aspect of the invention, the position command 1 in the invention of the fourth, fifth, or sixth aspect is the simulated position 1 of the slider 1 in the simulated linear slider model calculation unit, and the position command 2 is It is a simulated position 2 of the slider 2 in the simulated linear slider model calculation unit.
Thus, the stabilized simulated state quantity of the simulated linear slider model calculation unit controlled by the simulated control input can be reflected in the actual controller.

According to the positioning control device according to the first aspect of the present invention, the influence of each slider on the other slider can be effectively removed, so that the positioning control performance can be improved.
Further, according to the positioning control device of the second invention, the simulated linear slider model calculation unit is mounted on the device, and the simulated control input is configured using all simulated state quantities. Since the simulated state quantity of each slider and machine base is stabilized and the simulated state quantity is used in the actual controller, the control system can be stabilized and the positioning performance can be improved. Further, since the simulation control input calculation unit and the simulation linear slider model calculation unit are provided, the degree of freedom in design of the control system is increased, so that the response can be set finely.

  Hereinafter, specific embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing the configuration of a positioning control device according to the present invention. In the figure, 1 is a positioning control device according to the present invention, 2 is a controller 1, 3 is a controller 2, 4 is a position command 1, 5 is a position command 2, 5 a is a non-interference compensation calculation unit, and 6 is a non-interference compensation amount. 1 and 7 are non-interference compensation amounts 2, 8 is a control input 1, 9 is a control input 2, 10 is a power unit 1, 11 is a power unit 2, 12 is a slider 1, 13 is a slider 2, and 14 is a slider 1. , 15 is a thrust for driving the slider 2, and 16 is a machine base.
A position command 1 for the slider 1 is input to the controller 1, and a position command 2 for the slider 2 is input to the controller 2, and a thrust command is output from each controller to each power unit. Each power unit generates a thrust based on the input command and drives the slider.
FIG. 5 is a block diagram showing the dynamics when a machine base equipped with two movers is joined to the ground by a spring element. In FIG. 5, 31 is a thrust f ₁ input to the slider ₁ , 32 is a thrust f ₂ input to the slider ₂ , 33 is a transfer function in which the thrust of the slider 1 is input and a position is output, and 34 is the slider 2. A transfer function that takes a thrust as an input and outputs a position, 35 is a transfer function that takes a thrust of the machine base as an input and outputs a position, 36 is a displacement / force conversion constant that represents a spring element existing between the ground and the machine base, 37 Is the viscous friction transfer function that outputs force with the machine base displacement as input, 38 is the absolute position χ _T1 of the slider 1 viewed from the ground, 39 is the absolute position χ _T2 of the slider 2 viewed from the ground, 40 is the slider 1 viewed from the machine base Relative positions χ _t1 , 41 are relative positions χ _t2 of the slider 2 as seen from the machine base, and 42 are absolute positions χ _B of the machine base as seen from the ground. Here, if the block diagram is modified, the block diagram of FIG. 6 is obtained. In FIG. 6, 51 is a position transfer function of the slider 1, 52 is a position transfer function of the slider 2, 53 is an interference force transfer function between the sliders, and other symbols are the same as those in FIG. In this way, the interference force between the sliders can be described by a mathematical model, so the interference force can be removed in advance by mapping the interference force in some way (for example, using a fuzzy rule or applying a neural network). A non-interference compensation amount can be determined.
For example, the interference force transfer function is

Therefore, the interference force can be expressed by using two primary filters and two differentiators. Therefore, as shown in claim 3, the non-interference compensation amount calculation unit is composed of two primary filters and two differentiators. be able to.
FIG. 2 shows a configuration diagram in the case of detecting the position of each slider. In FIG. 2, 17 is a position detector 1, 18 is a position detector 2, 19 is a position detection value 1, and 20 is a position detection value 2. As shown in FIG. 2, the position detection value 1 and the position detection value 2 are detected using the position detector 1 and the position detector 2 of each slider, and the detected values are fed back to the controller 1 and the controller 2. By using the positioning control device shown in claim 2 in which the control system has a feedback control configuration, the positioning control performance can be further improved.

FIG. 3 is a diagram showing the configuration of the second embodiment. In FIG. 3, 2a is an actual controller 1, 3a is an actual controller 2, 8a is an actual control input 1, 9a is an actual control input 2, 21 is a simulated control input calculation unit, 22 is a simulated linear slider model calculation unit, 23 Are simulated control inputs 1 and 24, simulated control inputs 2 and 25 are simulated state quantities, and the other symbols are the same as those in FIGS.
The simulated linear slider calculation unit 22 maps the relationship between the thrust applied to the slider 1 and the slider 2 and the state quantities of the slider 1, the slider 2, and the machine base (for example, use of fuzzy rules, application of a neural network). Structure. For example, as in the invention of claim 5, the simulated linear slider model calculation unit may be configured using at least six integrators such as the mathematical model shown in FIG. The simulation control input calculation unit calculates the simulation control input 1 and the simulation control input 2 using the simulation state quantity obtained therefrom. Since the simulated control input computing unit can simulate and use a state quantity that cannot be detected by the actual control target, it is possible to realize a more stable control system than when control is performed using only the state of the actual control target. The simulated control input of the simulated control input calculation unit and the state quantity stabilized by the simulated control input are output to the actual controller 1 and the actual controller 2, and the actual controller 1 and the actual controller 2 The actual control input is determined using the position detection values of the slider 1 and the slider 2. The present invention greatly improves the positioning performance of the slider 1 and the slider 2 if the mapping of the simulated linear slider model calculation unit to the simulated state quantity with respect to the control input accurately reflects the actual control target. it can.
According to the sixth aspect of the present invention, if the simulated linear slider model calculation unit outputs the position, speed, acceleration, and thrust of the slider and the machine base, each actual controller can reflect the behavior of the linear slider throughout. Can be improved.
Further, as described in claim 7, by using the simulated position of the simulated linear slider model calculation unit as the position command itself, a stabilized command can be introduced and the control performance can be improved.

1 is a configuration diagram of a positioning control apparatus showing a first embodiment of the present invention. The block diagram of the positioning control apparatus of Claim 2 of this invention Configuration diagram of positioning control apparatus showing second embodiment Block diagram showing conventional positioning method Block diagram for explaining the operation of the control object of the positioning control device 1 Block diagram for explaining the operation of the control object of the positioning control device

Explanation of symbols

1 Positioning control device 2 Controller 1
2a Actual controller 1
3 Controller 2
3a Actual controller 2
4 Position command 1
5 Position command 2
5a Non-interference compensation calculation unit 6 Non-interference compensation amount 1
7 Non-interference compensation amount 2
8 Control input 1
8a Actual control input 1
9 Control input 2
9a Actual control input 2
10 Power section 1
11 Power section 2
12 Slider 1
13 Slider 2
14 Thrust for driving the slider 1 15 Thrust for driving the slider 2 16 Machine base 17 Position detector 1
18 Position detector 2
19 Position detection value 1
20 Position detection value 2
21 Simulated control input computing unit 22 Simulated linear slider model computing unit 23 Simulated control input 1
24 Simulated control input 2
25 Simulated state quantity 31 Thrust f ₁ input to the slider ₁
32 Thrust f ₂ input to slider ₂
33 Transfer function 34 that takes the thrust of the slider 1 as an input and outputs the position 34 Transfer function 35 that takes the thrust of the slider 2 as an input and outputs the position 35 Transfer function that takes the thrust of the machine base as an input and outputs the position 36 Ground and machine base Displacement / force conversion constant K _B representing spring element in between
37 Viscous frictional transfer function 38 that outputs force with machine base displacement as input 38 Absolute position χ _{T1 of} slider 1 viewed from the ground
39 Absolute position χ _{T2 of} slider 2 as seen from the ground
40 Relative position χ _{t1 of} slider 1 from the stand
41 Relative position χ _{t2 of} slider 2 from the stand
42 Absolute position of machine base from the ground χ _B
51 Position transfer function 52 of slider 1 Position transfer function 53 of slider 2 Interference force transfer function 101 between sliders Motor transfer function 102 Reducer and pole / rectangular coordinate conversion constant 103 Table displacement / force conversion spring constant 104 Table drive transfer function 105 Machine table transfer function 106 Machine table displacement / force conversion spring constant 107 Absolute displacement of table viewed from the ground 108 Table displacement viewed from machine table 109 Machine table displacement viewed from the ground 110 Propulsive force driving table 111 Table and motor output Displacement difference 112 Motor displacement 113 Torque for driving the motor (propulsion force)
114 Speed reducer and direct / polar coordinate conversion constant 121 Motor 126 Motor controller 128 Motor position detection signal 134 Position target value signal 135 Motor position compensator 139 Precompensator 141 based on model of conventional example Position command 142 for motor controller 142 Motor model Position time series data 144 Torque model command time series data 151 Controller in precompensator

Claims (7)

Of a linear slider with two sliders on one machine stand,
In the positioning control device for controlling each of the two slider positions,
A controller 1 for controlling the position of the slider 1;
A controller 2 for controlling the position of the slider 2;
Based on a control input 1 output from the controller 1, a power unit 1 that gives a thrust for driving the slider 1;
Based on the control input 2 output from the controller 2, a power unit 2 that gives a thrust for driving the slider 2;
Non-interference compensation amount 1 output to the controller 1 and control for removing the influence of the slider 1 and the slider 2 on the other slider based on the mechanical constant of the linear slider and the control input 1 and control input 2, respectively. A non-interference compensation calculation unit for calculating a non-interference compensation amount 2 to be output to the device 2;
The controller 1 outputs the control input 1 using the position command 1 for the slider 1 and the non-interference compensation amount 1,
The controller 2 is configured to output the control input 2 using a position command 2 for the slider 2 and the non-interference compensation amount 2. The slider 1 includes a position detector 1, and the slider 2 includes a position detector 2. Each position detector detects each slider position, and outputs the position detection value 1 of the slider 1 to the controller 1. The position detection value 2 of the slider 2 is output to the controller 2,
The controller 1 outputs a control input 1 using the position command 1 for the slider 1, the non-interference compensation amount 1 and the position detection value 1,
2. The controller 2 is configured to output a control input 2 using the position command 2 for the slider 2, the non-interference compensation amount 2, and the position detection value 2. Positioning control device. The positioning control device according to claim 1, wherein the non-interference compensation calculation unit includes two primary filters and two differentiators. In a positioning control device that has two sliders on one machine base, and each slider position is controlled by a sensor, and each of the two slider positions is controlled by a sensor.
An actual controller 1 for controlling the position of the slider 1;
An actual controller 2 for controlling the position of the slider 2;
Based on the actual control input 1 output from the actual controller 1, a power unit 1 that provides a thrust for driving the slider 1,
Based on the actual control input 2 output from the actual controller 2, a power unit 2 that gives a thrust for driving the slider 2,
A simulated linear slider model calculation unit that calculates the state quantities of the slider 1, the slider 2, and the machine base by calculating a dynamic characteristic map, and outputs a simulated state quantity of the linear slider;
A simulated control input computing unit that inputs the simulated state quantity output from the simulated linear slider model computing unit, calculates a compensation input for the simulated linear slider model by multiplying and adding each state quantity by a gain, and
The actual controller 1 and the actual controller 2 include at least one of a position command 1 for the slider 1, a position command 2 for the slider 2, the simulated state quantity, and the simulated control input, and an output of the position detector 1 of the slider 1. The actual control input 1 and the actual control input 2 to the power unit 1 and the power unit 2 are determined using the detected position value 1 and the detected position value 2 which is the output of the position detector of the slider 2. A positioning control device comprising: The positioning control device according to claim 4, wherein the simulated linear slider model calculation unit includes at least six integrators. The simulated linear slider model calculation unit includes at least one of a simulated position, simulated speed, simulated acceleration, and simulated thrust of the slider 1, and at least one of a simulated position, simulated speed, simulated acceleration, and simulated thrust of the slider 2. 6. The positioning control device according to claim 4, wherein one is output. The position command 1 is a simulated position 1 of the slider 1 in the simulated linear motor model calculation unit, and the position command 2 is a simulated position 2 of the slider 2 in the simulated linear slider model calculation unit. The positioning control device according to any one of claims 4 to 6.