JPH01320501A - Actuator control method - Google Patents

Abstract

PURPOSE:To observe operating data without attaching a specific measuring instrument and to easily perform adjusting work by performing an operation display processing by utilizing a time not being used for an operation control processing within a unit time. CONSTITUTION:The operation control processing 12 consists of a targeted position calculation means 2, a present location fetch means 3, a speed command calculation means 4, a speed command output means 6, and a data sampling means 8. Also, the operation display processing 13 consists of an operating data calculation means 10 and an operating data display means 11. And the precedence of the operation control processing 12 is set higher than that of the operation display processing 13, and the former is executed at every unit time. Next, the operation display processing 13 is performed by utilizing the time out of the unit time not being used for the operation control processing 12. In such a way, it is possible to observe the operating data without attaching the specific measuring instrument.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a method of controlling an actuator used in a drive unit of an industrial robot or a positioning device.

BACKGROUND OF THE INVENTION In recent years, with the automation of factories, various automatic positioning devices have been used, and what has made this possible is progress in actuator control methods.

In the current actuator control method, a target position is memorized and a current position received from a position detection device coupled to the actuator is compared with the target position.
Positioning is performed by outputting a speed command proportional to the difference to a drive device constituted by hardware, and the above processing is generally programmed into a ROM within the control device. Furthermore, when the inertia of the loads to be driven differs, the current practice is to set the control parameters of the actuator and the gain of the drive device for each load.

Problems to be Solved by the Invention However, with the above configuration, in order to optimally adjust the control parameters of the actuator and the gain of the drive device, a special measuring instrument that can observe operational data such as position and speed during operation is required. However, in many cases, it is necessary to rely on the experience and intuition of the adjuster.

In view of the above-mentioned problems, the present invention controls the operation of an actuator, samples and stores operation data such as position and speed during operation, and displays the operation data without using special measuring instruments. The present invention provides an actuator control method that allows easy adjustment work.

Means for Solving the Problems In order to solve the above problems, an actuator control method according to claim 1 comprises a target position calculation means, a current position number input means, a speed command calculation means, a speed command output means, and a data sampling means. The priority of the series of motion control processing by the motion data calculation means and the motion data display means is set higher than the series of motion display processing by the motion data calculation means and the motion data display means, and the priority is set to be higher than the series of motion display processing by the motion data calculation means and the motion data display means. The present invention is characterized in that the motion display processing is performed using unused time.

Further, in the actuator control method of claim 2, the priority of a series of test operation processing by the current position acquisition means, the speed command extraction means, the speed command output means, and the data sampling means is determined by the operation data calculation means and the operation data calculation means. The setting is set higher than a series of motion display processing by the data display means, and the motion display processing is executed every unit time, and the time not used for the test motion processing of the unit time is used to perform the motion display processing. This is a characteristic feature.

The invention of claim 1 performs data display processing using the time that is not used for motion control processing within a unit time with the above-described configuration, so motion data can be observed without adding a special measuring instrument. , control parameters can be easily adjusted.

Further, according to the second aspect of the invention, since data display processing is performed using the time that is not used for test operation processing with the set speed command pattern, gain adjustment of the drive device of the actuator can be easily performed.

Embodiment Hereinafter, an actuator control method according to a first embodiment of the present invention will be explained with reference to FIGS. 1 to 4.

FIG. 1 is an overall configuration diagram when the actuator control method in this embodiment is realized by software. 1st
In the figure, 1 is a timing signal output means, 2 is a target value calculation means, 3 is a current position acquisition means, 4 is a speed command calculation means, 5 is a parameter setting means, 6 is a speed command output means, 7 is a mode switching means, 8 is a data sampling means, 9 is a data storage means, 1o is an operation data calculation means, 1
1 is an operation data display means, 12 is an operation control process, 13 is an operation display process, and 14 is a process switching means.

First, the entire process will be explained.

The timing signal outputted from the timing signal output means 1 is a so-called interrupt signal, which executes a high-priority operation control process 12 every unit time T, returns after the process is completed, and continues the operation display process 13. Take
The processing switching means 14 performs the processing switching.

First, the contents of the operation control process 12 will be explained. The motion control processing 12 is composed of a target position calculation means 2, a current position acquisition means 3, a speed command calculation means 4, a speed command output means 6, and a data sampling means 8.The target position calculation means 2 calculates a new target position every T. calculate. An example of a method for calculating the target position 0 when moving between two points will be described below.

Acceleration/deceleration α and maximum speed W from movement start position θS to movement end position θE. a! When moving at a trapezoidal speed as shown in FIG. 2, the target position θT(n) after nXT from the start of movement is expressed by the following formula.

(n=o, 1, 2...) Further, the value of the target position θT while the motor is stopped is maintained.

The target position θT for each unit time T is calculated according to the above formula.

Next, the current position area input means 3 takes in the current position θC for each unit time T from the position detection device 20 coupled to the actuator 19. Then, the speed command calculation means 4 calculates a speed command vc proportional to the deviation between the target position 0 and the current position θC. Assuming that the proportionality constant is K, the speed command vc is expressed by the following formula.

V C=K X (θT-θC) ・・・・・・
(4) It is assumed that the proportional constant can be freely set by the adjuster using the parameter setting means 6 in accordance with the load inertia.

The speed command output means 6 converts the speed command VC into an analog value and outputs it to the drive device 21, thereby driving and controlling the actuator 19.

Whether or not the mode is the data sample mode can be set by the adjuster using the mode switching means 7, and it is assumed that the mode is normally set to the data sample mode.

When the mode is the data sample mode, the data sample means 8 sequentially stores the current position θC1 target position θT and speed command vc data in the data storage means 9, and stops storing when the storage capacity becomes full. Then, when the actuator 19 starts moving, the data storage means 9 starts storing data again from the beginning. Therefore, the data stored in the data storage means 9 is always the latest data at the time of movement. FIG. 3 shows the contents of the data storage means 9 when the storage capacity is 3Xm.

Next, the motion display processing 13 will be explained. The operation display processing 13 is composed of an operation data calculation means 10 and an operation data display means 11, and is in a standby state until the mode is set to the operation data display mode by the adjuster.

When the mode is set to the operation data display mode, the operation data calculation means 1o takes in each data from the data storage means 9 and calculates the following operation data.

(n=1, 2, ---, m, the value at n<o is n
= 1) Finally, display the above data on the screen 22 on the operation data display means 11.
By displaying it above, you can check the operation for the setting parameters without adding any special hardware. FIG. 4 shows an example of displaying operation data.

Next, an actuator control method according to a second embodiment of the present invention will be described with reference to FIGS. 5 to 7.

In FIG. 5, 15 is a speed command pattern storage means, 16
17 is a speed command pattern setting means, 17 is a speed command extraction means, and 18 is a test operation process.

The overall processing form is the same as that of the first embodiment, and the operation control process 12 in FIG. 1 can be considered to be replaced by the test operation process 18 in FIG. Here, only the test operation processing 18 will be explained.

The test operation processing 18 is carried out by the device sampling means 8, which is composed of the current position importing means 3, the speed command retrieval means 17, the speed command output means 6, and the data sampling means 8, and the contents of the processing are the same as in the first embodiment.

The feature of this embodiment is that the actuator 19 is driven by a set speed command pattern, and a plurality of speed command patterns are stored in the speed command pattern storage means 16 as speed command data for each unit time T.

An example of the speed command pattern is shown in FIG. Also, in Figure 7, 1
The contents of the speed command pattern storage means 16 are shown when one speed command pattern consists of one piece of data.

A pattern can be selected by the adjuster, and the leading position of the pattern in the speed command pattern storage means 16 is held during processing by the speed command pattern setting means 16.

The speed command retrieval means 1a sequentially retrieves data from the speed command pattern storage means 16 every unit time T based on the setting data of the speed command pattern setting means 1e, and returns to the beginning after retrieving l pieces of data. The speed command output unit 6 outputs the speed command for each unit time T taken out in this way.
output, and drives the actuator 19. The operation at this time.

By displaying the "-" on the screen 22 as in the first embodiment, the operation of the drive device 21 during gain adjustment can be easily checked.

Effects of the Invention As described above, according to the invention of claim 1, the operation data of the actuator during operation can be observed without adding a special measuring device, and the control parameters can be easily adjusted.

Further, the invention of claim 2 facilitates gain adjustment of the drive device, and has a great practical effect.

[Brief explanation of the drawing]

Fig. 1 is an overall configuration diagram of an embodiment of the first invention of the present invention, Fig. 2 is a time-velocity relationship diagram at the time of trapezoidal speed command, Fig. 3 is a diagram showing the contents of the data storage means, and Fig. 4 is FIG. 5 is an overall configuration diagram of the second embodiment of the present invention, FIG. 6 is a speed command pattern diagram, and FIG. 7 is a diagram showing the contents of the speed command pattern storage means. 1... Timing signal output means, 2... Target value calculation means, 3... Current position acquisition means,
4... Speed command output means, 6... Parameter setting means, 6... Speed command output means, 7
...Mode switching means, 8...Data sampling means, 9...Data storage means, 10
. . . Operation data calculation means, 11 . . . Operation data display means, 12 . . . Operation control processing, 1
3...Operation display processing, 16...Speed command pattern storage means, 1e...Speed command pattern setting means, 17...Speed command retrieval means,
18... Test operation processing, 19... Actuator, 20... Position detection device, 21...
・・・・Drive device. Name of agent: Patent attorney Toshio Nakao et al. 16th
2 Figure 3 Figure 4 O'tJ&gt 3 X rn Figure 4

Claims (2)

[Claims] (1) A position detection device, a drive device that drives an actuator, a timing signal output means that outputs a timing signal for each set unit time, and a target position that calculates a target position for each unit time during positioning operation. a calculation means, a current position acquisition means for acquiring the current position for each unit of time from the position detection device, a speed command calculation means for calculating a speed command for matching the current position with the target position for each unit of time, and the speed control parameter setting means that can change control parameters at the time of command calculation to desired values; speed command output means that outputs the speed command to the drive device; and whether or not the data sampling mode is used to sample the target position and current position. mode switching means for switching the mode, data sampling means for sampling the target position and current position when the mode by the mode switching means is determined to be the data sampling mode, and data sampling means for sampling the data sampled by the data sampling means. If the mode determined by the data storage means to be stored and the mode switching means is not the data sample mode, it is determined that the mode is the operation data display mode, and operation data such as speed and acceleration is stored based on the data stored in the storage area. In the actuator control method, the actuator control method includes a motion data calculation means for calculating the motion data and a motion data display means for displaying the motion data on a screen or the like, and the motion control method for the drive device is performed by a speed command for each unit time The priority of a series of operation control processing by the calculation means, the current position acquisition means, the speed command calculation means, the speed command output means, and the data sampling means is determined by the operation data calculation means and the operation data calculation means. The setting is set higher than a series of motion display processing by the data display means, and the motion display processing is executed every unit time, and the time not used for the motion control processing of the unit time is used to perform the motion display processing. Featured actuator control method. (2) a position detection device, a drive device that drives an actuator, a timing signal output means that outputs a set timing signal for each unit time, and a current position capture that captures the current position for each unit time from the position detection device; means, a speed command pattern storage outlet for storing a plurality of speed command patterns consisting of speed command data for each unit time, speed command pattern setting means for setting the speed command pattern to be used, and the speed command pattern a speed command retrieving means for retrieving speed command data stored in the speed command pattern storage means corresponding to the speed command pattern set by the setting means for each unit time; and a speed for outputting the speed command to the drive device. a command output means; a mode switching means for switching whether or not a data sample mode is used to sample the speed command and the current position; a data sampling means for sampling a position; a data storage means for storing data sampled by the data sampling means; and a data storage means for storing data sampled by the data sampling means, and determining that the mode by the mode switching means is an operation data display mode when the mode is not the data sampling mode. a motion data calculation means for calculating motion data such as speed and acceleration based on the data stored in the storage area; and a motion data display means for displaying the motion data on a screen or the like; In an actuator control method in which operation is controlled by a speed command for each unit time, the current position acquisition means, the speed command extraction means,
The priority of a series of test motion processing by the speed command output means and the data sampling means is set higher than that of a series of motion display processing by the motion data calculation means and the motion data display means, and the unit time The actuator control method is characterized in that the operation display processing is performed by executing the operation display processing every time, and the operation display processing is performed using a time that is not used for the test operation processing out of the unit time.