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TW201638690A - Servomotor control device and conflict detection method - Google Patents

Servomotor control device and conflict detection method Download PDF

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Publication number
TW201638690A
TW201638690A TW105108868A TW105108868A TW201638690A TW 201638690 A TW201638690 A TW 201638690A TW 105108868 A TW105108868 A TW 105108868A TW 105108868 A TW105108868 A TW 105108868A TW 201638690 A TW201638690 A TW 201638690A
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servo motor
speed
signal
unit
acceleration
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TW105108868A
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Chinese (zh)
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TWI716390B (en
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Yoshiaki Momozawa
Akihiro Ito
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Nidec Sankyo Corp
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    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05BCONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
    • G05B19/00Programme-control systems
    • G05B19/02Programme-control systems electric
    • G05B19/18Numerical control [NC], i.e. automatically operating machines, in particular machine tools, e.g. in a manufacturing environment, so as to execute positioning, movement or co-ordinated operations by means of programme data in numerical form
    • G05B19/414Structure of the control system, e.g. common controller or multiprocessor systems, interface to servo, programmable interface controller
    • G05B19/4141Structure of the control system, e.g. common controller or multiprocessor systems, interface to servo, programmable interface controller characterised by a controller or microprocessor per axis
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02PCONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
    • H02P29/00Arrangements for regulating or controlling electric motors, appropriate for both AC and DC motors
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01PMEASURING LINEAR OR ANGULAR SPEED, ACCELERATION, DECELERATION, OR SHOCK; INDICATING PRESENCE, ABSENCE, OR DIRECTION, OF MOVEMENT
    • G01P15/00Measuring acceleration; Measuring deceleration; Measuring shock, i.e. sudden change of acceleration
    • G01P15/001Measuring acceleration; Measuring deceleration; Measuring shock, i.e. sudden change of acceleration by measuring acceleration changes by making use of a triple differentiation of a displacement signal
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01PMEASURING LINEAR OR ANGULAR SPEED, ACCELERATION, DECELERATION, OR SHOCK; INDICATING PRESENCE, ABSENCE, OR DIRECTION, OF MOVEMENT
    • G01P15/00Measuring acceleration; Measuring deceleration; Measuring shock, i.e. sudden change of acceleration
    • G01P15/18Measuring acceleration; Measuring deceleration; Measuring shock, i.e. sudden change of acceleration in two or more dimensions
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05BCONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
    • G05B11/00Automatic controllers
    • G05B11/01Automatic controllers electric
    • G05B11/36Automatic controllers electric with provision for obtaining particular characteristics, e.g. proportional, integral, differential
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05BCONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
    • G05B17/00Systems involving the use of models or simulators of said systems
    • G05B17/02Systems involving the use of models or simulators of said systems electric
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02PCONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
    • H02P21/00Arrangements or methods for the control of electric machines by vector control, e.g. by control of field orientation
    • H02P21/14Estimation or adaptation of machine parameters, e.g. flux, current or voltage
    • H02P21/18Estimation of position or speed
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02PCONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
    • H02P6/00Arrangements for controlling synchronous motors or other dynamo-electric motors using electronic commutation dependent on the rotor position; Electronic commutators therefor
    • H02P6/14Electronic commutators
    • H02P6/16Circuit arrangements for detecting position
    • H02P6/17Circuit arrangements for detecting position and for generating speed information
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05BCONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
    • G05B2219/00Program-control systems
    • G05B2219/30Nc systems
    • G05B2219/34Director, elements to supervisory
    • G05B2219/34013Servocontroller

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  • Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Power Engineering (AREA)
  • Automation & Control Theory (AREA)
  • Computer Hardware Design (AREA)
  • Microelectronics & Electronic Packaging (AREA)
  • Human Computer Interaction (AREA)
  • Manufacturing & Machinery (AREA)
  • Control Of Electric Motors In General (AREA)
  • Feedback Control In General (AREA)
  • Manipulator (AREA)

Abstract

This invention provides a servomotor control device with higher detection precision for conflicts. A position command speed dimension signal output unit 110a of a servomotor control unit 10a outputs a speed dimension signal corresponding to a position command. A speed dimension signal output unit 120 of the servomotor outputs a speed dimension signal of the servomotor 20. When the absolute value of speed differences exceeds a specific value, a first conflict detection unit 130 detects whether it is a conflict. A position command and acceleration dimension transfer unit 140a transfers the speed dimension signal corresponding to the position command into an acceleration dimension signal and outputs it. A servomotor acceleration dimension transfer unit 150 outputs the acceleration dimension signal of the servomotor 20. When the absolute value of acceleration differences exceeds a specific value, a second conflict detection unit 160 detects whether it is a conflict. On the basis of the detection method for a parameter setting unit 190, a selecting unit 180 selects setting 191 to select the first conflict detection unit 130 and the second conflict detection unit 160.

Description

伺服馬達控制裝置及衝突檢測方法 Servo motor control device and conflict detection method

本發明係關於一種伺服馬達控制裝置及衝突檢測方法,尤其是關於一種具備使動作對象物動作之伺服馬達之伺服馬達控制裝置及衝突檢測方法。 The present invention relates to a servo motor control device and a collision detecting method, and more particularly to a servo motor control device and a collision detecting method including a servo motor that operates an object to be operated.

自先前,於伺服馬達之控制裝置中,存在有對機械臂等之動作對象物進行衝突檢測之技術。 In the control device of the servo motor, there has been a technique of detecting a collision of an object to be operated such as a robot arm.

例如,於專利文獻1中記載有對具有移動體之致動器進行控制之致動器控制裝置。專利文獻1之裝置具備:電流檢測單元,其於致動器之驅動過程中即移動體自加速結束後至開始減速前移動之期間,檢測流向致動器內之馬達之電流值;以及衝突檢測單元,其於由電流檢測單元檢測到之電流值超過特定之閾值之情形時,檢測移動體之衝突。即,於專利文獻1之技術中,係若轉矩指令值超過閾值,則輸出衝突檢測信號。 For example, Patent Document 1 describes an actuator control device that controls an actuator having a moving body. The apparatus of Patent Document 1 includes: a current detecting unit that detects a current value of a motor flowing into the actuator during a driving process of the actuator, that is, a period in which the moving body moves from the end of the acceleration to the start of the deceleration; and collision detection The unit detects a collision of the moving body when the current value detected by the current detecting unit exceeds a specific threshold. That is, in the technique of Patent Document 1, if the torque command value exceeds the threshold value, the collision detection signal is output.

[先前技術文獻] [Previous Technical Literature] [專利文獻] [Patent Literature]

[專利文獻1]日本特開2014-87235號公報 [Patent Document 1] Japanese Patent Laid-Open Publication No. 2014-87235

然而,於專利文獻1之技術中,存在有無法在施加偏置負載之情形時或加減速度時檢測到衝突之問題。因此,衝突檢測之檢測精度不 足。 However, in the technique of Patent Document 1, there is a problem that collision cannot be detected when a bias load is applied or when acceleration/deceleration is applied. Therefore, the detection accuracy of conflict detection is not foot.

本發明係鑒於此種狀況研究而成者,其目的在於提供一種能夠解決上述問題並能夠提高衝突檢測之精度之伺服馬達控制裝置。 The present invention has been made in view of such circumstances, and an object of the present invention is to provide a servo motor control device capable of solving the above problems and improving the accuracy of collision detection.

本發明之伺服馬達控制裝置之特徵在於,其係具備使動作對象物動作之伺服馬達及根據位置指令對上述伺服馬達進行控制之伺服馬達控制部者,且上述伺服馬達控制部具備:位置指令速度維度信號輸出部,其輸出與上述位置指令對應之速度維度信號;伺服馬達速度維度信號輸出部,其輸出上述伺服馬達之速度維度信號;第一衝突檢測部,其於由上述位置指令速度維度信號輸出部輸出之速度維度信號、與由上述伺服馬達速度維度信號輸出部輸出之速度維度信號之差分值即速度偏差之絕對值達到特定值以上之情形時,檢測為衝突;位置指令加速度維度轉換部,其將由上述位置指令速度維度信號輸出部輸出之速度維度信號轉換為加速度維度信號並輸出;伺服馬達加速度維度轉換部,其將由上述伺服馬達速度維度信號輸出部輸出之速度維度信號轉換為加速度維度信號並輸出;第二衝突檢測部,其於由上述位置指令加速度維度轉換部輸出之加速度維度信號、與由上述伺服馬達加速度維度轉換部輸出之加速度維度信號之差分值即加速度偏差之絕對值達到特定值以上之情形時,檢測為衝突;以及選擇部,其根據特定之參數,選擇上述第一衝突檢測部與上述第二衝突檢測部。 The servo motor control device according to the present invention includes a servo motor that operates an object to be operated and a servo motor control unit that controls the servo motor based on a position command, and the servo motor control unit includes a position command speed. a dimension signal output unit that outputs a speed dimension signal corresponding to the position command; a servo motor speed dimension signal output unit that outputs a speed dimension signal of the servo motor; and a first collision detecting unit that commands the speed dimension signal by the position When the absolute value of the speed difference between the speed dimension signal output from the output unit and the speed dimension signal outputted by the servo motor speed dimension signal output unit reaches a specific value or more, the detection is a collision; the position command acceleration dimension conversion unit And converting the speed dimension signal outputted by the position command speed dimension signal output unit into an acceleration dimension signal and outputting; the servo motor acceleration dimension conversion unit converting the speed dimension signal output by the servo motor speed dimension signal output unit into acceleration The dimension signal is outputted; the second collision detecting unit is an absolute value of the acceleration deviation between the acceleration dimension signal output by the position command acceleration dimension conversion unit and the acceleration dimension signal output by the servo motor acceleration dimension conversion unit. When a certain value or more is reached, a collision is detected; and a selection unit that selects the first collision detecting unit and the second collision detecting unit based on the specific parameter.

藉由以此方式構成,於位置控制中,能夠對應於應用程式之用途等,適當地選擇第一衝突檢測部與第二衝突檢測部,從而能夠提高衝突檢測之精度。 According to this configuration, in the position control, the first collision detecting unit and the second collision detecting unit can be appropriately selected in accordance with the use of the application, etc., and the accuracy of the collision detection can be improved.

本發明之伺服馬達控制裝置之特徵在於,其係具備使動作對象物動作之伺服馬達及根據速度指令控制上述伺服馬達之伺服馬達控制部者,且上述伺服馬達控制部具備:速度指令速度維度信號輸出部, 其輸出與上述速度指令對應之速度維度信號;伺服馬達速度維度信號輸出部,其輸出上述伺服馬達之速度維度信號;第一衝突檢測部,其於由上述速度指令速度維度信號輸出部輸出之速度維度信號、與由上述伺服馬達速度維度信號輸出部輸出之速度維度信號之差分值即速度偏差值之絕對值達到特定值以上之情形時,檢測為衝突;速度指令加速度維度轉換部,其將由上述速度指令速度維度信號輸出部輸出之速度維度信號轉換為加速度維度信號並輸出;伺服馬達加速度維度轉換部,其將由上述伺服馬達速度維度信號輸出部輸出之速度維度信號轉換為加速度維度信號並輸出;第二衝突檢測部,其於由上述速度指令加速度維度轉換部輸出之加速度維度信號、與由上述伺服馬達加速度維度轉換部輸出之加速度維度信號之差分值即加速度偏差之絕對值達到特定值以上之情形時,檢測為衝突;以及選擇部,其根據特定之參數,選擇上述第一衝突檢測部與上述第二衝突檢測部。 A servo motor control device according to the present invention includes a servo motor that operates an operation target and a servo motor control unit that controls the servo motor according to a speed command, and the servo motor control unit includes a speed command speed dimension signal. Output department, And outputting a speed dimension signal corresponding to the speed command; a servo motor speed dimension signal output unit that outputs a speed dimension signal of the servo motor; and a first collision detecting unit that outputs the speed output by the speed command speed dimension signal output unit When the absolute value of the difference value between the dimension signal and the velocity dimension signal outputted by the servo motor speed dimension signal output unit is equal to or greater than a specific value, the collision is detected; the speed command acceleration dimension conversion unit is to be The speed dimension signal outputted by the speed command speed dimension signal output unit is converted into an acceleration dimension signal and output; the servo motor acceleration dimension conversion unit converts the speed dimension signal output by the servo motor speed dimension signal output unit into an acceleration dimension signal and outputs the same; a second collision detecting unit that is specific to an absolute value of an acceleration dimension signal outputted by the speed command acceleration dimension conversion unit and an acceleration dimension signal output by the servo motor acceleration dimension conversion unit, that is, an acceleration deviation When the above situation, the conflict is detected; and a selecting unit, in accordance with certain of its parameters, selecting the first collision detection portion and the second collision detection portion.

藉由以此方式構成,於速度控制中,能夠對應於應用程式之用途等,適當地選擇第一衝突檢測部與第二衝突檢測部,從而能夠提高衝突檢測之精度。 According to this configuration, in the speed control, the first collision detecting unit and the second collision detecting unit can be appropriately selected in accordance with the use of the application, etc., and the accuracy of the collision detection can be improved.

本發明之伺服馬達控制裝置之特徵在於,上述伺服馬達控制部進而具備第三衝突檢測部,該第三衝突檢測部於由上述伺服馬達加速度維度轉換部輸出之加速度維度信號之絕對值達到特定值以上之情形時,檢測為衝突,上述選擇部根據上述特定之參數亦選擇上述第三衝突檢測部。 In the servo motor control device according to the present invention, the servo motor control unit further includes a third collision detecting unit that reaches a specific value in an absolute value of an acceleration dimension signal output by the servo motor acceleration dimension conversion unit. In the case of the above, the detection is a collision, and the selection unit selects the third collision detecting unit based on the specific parameter.

藉由以此方式構成,於加減速和緩之狀況下,藉由對加速度維度信號自身與特定值進行比較,能夠提高衝突檢測之精度。 By constructing in this manner, the accuracy of the collision detection can be improved by comparing the acceleration dimension signal itself with a specific value in the acceleration/deceleration and gentleness conditions.

本發明之伺服馬達控制裝置之特徵在於,上述伺服馬達速度維度信號輸出部將由檢測上述伺服馬達之位置之位置檢測感測器檢測到之位置信號經微分後之信號,作為速度維度信號輸出。 In the servo motor control device according to the present invention, the servo motor speed dimension signal output unit outputs a signal obtained by differentiating a position signal detected by a position detecting sensor that detects a position of the servo motor as a speed dimension signal.

藉由以此方式構成,能夠藉由微分器簡單地取得速度維度信號,從而能夠簡化構成。 According to this configuration, the speed dimension signal can be easily obtained by the differentiator, and the configuration can be simplified.

本發明之伺服馬達控制裝置之特徵在於,上述伺服馬達速度維度信號輸出部將藉由速度觀測器算出之速度推定信號作為速度維度信號輸出,上述速度觀測器係根據向模型之控制對象輸入之輸入信號與上述控制對象之輸出信號來推定速度。 In the servo motor control device according to the present invention, the servo motor speed dimension signal output unit outputs a speed estimation signal calculated by a speed observer as a speed dimension signal, and the speed observer inputs an input to a control object of the model. The signal is estimated from the output signal of the above control object.

藉由以此方式構成,即使於使用觀測器之構成中,亦能夠進行衝突檢測。 By configuring in this manner, collision detection can be performed even in the configuration using the observer.

本發明之伺服馬達控制裝置之特徵在於,上述伺服馬達控制裝置具備反饋迴路,該反饋迴路算出向上述位置指令之值乘以比例增益後得到之信號、與由上述位置檢測感測器檢測到之位置信號經微分濾波器微分後之信號之偏差,上述伺服馬達速度維度信號輸出部將配設在上述反饋迴路內之上述微分濾波器之輸出信號作為速度維度信號輸出。 In the servo motor control device according to the present invention, the servo motor control device includes a feedback loop that calculates a signal obtained by multiplying a value of the position command by a proportional gain and detected by the position detecting sensor. The servo signal speed dimension signal output unit outputs the output signal of the differential filter disposed in the feedback loop as a velocity dimension signal.

藉由以此方式構成,能夠簡化運算,從而簡化構成。 By configuring in this manner, the calculation can be simplified, and the configuration can be simplified.

本發明之伺服馬達控制裝置之特徵在於,上述第一衝突檢測部算出向上述位置指令之值乘以比例增益後得到之信號、與由上述位置檢測感測器檢測到之位置信號經微分後之信號之差分值作為擬似速度偏差來代替上述速度偏差,並於該擬似速度偏差之絕對值達到特定值以上之情形時,檢測為衝突。 In the servo motor control device according to the present invention, the first collision detecting unit calculates a signal obtained by multiplying a value of the position command by a proportional gain, and a position signal detected by the position detecting sensor is differentiated. The difference value of the signal is used as the pseudo-velocity deviation instead of the above-described speed deviation, and when the absolute value of the pseudo-velocity deviation reaches a certain value or more, it is detected as a collision.

藉由以此方式構成,能夠簡化運算,從而簡化構成。 By configuring in this manner, the calculation can be simplified, and the configuration can be simplified.

本發明之伺服馬達控制裝置之特徵在於,上述第二衝突檢測部算出將上述擬似速度偏差經微分後之信號作為擬似加速度信號來代替上述加速度偏差,並於該擬似加速度偏差之絕對值達到特定值以上之情形時,檢測為衝突。 In the servo motor control device of the present invention, the second collision detecting unit calculates a signal obtained by differentiating the pseudo-velocity deviation as a pseudo-acceleration signal instead of the acceleration deviation, and the absolute value of the pseudo-acceleration deviation reaches a specific value. In the above case, the detection is a conflict.

藉由以此方式構成,能夠簡化運算,從而簡化構成。 By configuring in this manner, the calculation can be simplified, and the configuration can be simplified.

本發明之伺服馬達控制裝置之特徵在於,上述選擇部根據自外部設定之上述參數,選擇上述第一衝突檢測部、上述第二衝突檢測部以及上述第三衝突檢測部中之任意一個。 In the servo motor control device of the present invention, the selection unit selects one of the first collision detecting unit, the second collision detecting unit, and the third collision detecting unit based on the parameter set from the outside.

藉由以此方式構成,能夠隨時自外部設定適於衝突檢測之電路等,且電路變更之負載減少,從而能夠簡單變更。 According to this configuration, it is possible to set a circuit suitable for collision detection from the outside at any time, and the load of the circuit change is reduced, so that it can be easily changed.

本發明之伺服馬達控制裝置之特徵在於,上述選擇部之上述第一衝突檢測部之特定值、上述第二衝突檢測部之特定值以及上述第三衝突檢測部之特定值係自外部設定。 In the servo motor control device according to the present invention, the specific value of the first collision detecting unit, the specific value of the second collision detecting unit, and the specific value of the third collision detecting unit are set from the outside.

藉由以此方式構成,能夠隨時自外部設定特定值,且變更之負載少,從而能夠簡單地變更。 According to this configuration, the specific value can be set from the outside at any time, and the load of the change can be easily changed.

本發明之伺服馬達控制裝置之特徵在於,上述速度維度信號係包含以1/(τ s+1)為傳遞函數之要素作為控制系統模型之濾波器之信號。 The servo motor control device of the present invention is characterized in that the velocity dimension signal includes a signal having a transfer function of 1/(τ s+1) as a filter of a control system model.

藉由以此方式構成,能夠使控制模型之要素包含於濾波器,從而能夠擬似地得到與實際之信號接近之信號。 According to this configuration, the elements of the control model can be included in the filter, and the signal close to the actual signal can be pseudo-obtained.

本發明之伺服馬達控制裝置之特徵在於,上述濾波器自外部設定截止頻率。 The servo motor control device of the present invention is characterized in that the filter sets a cutoff frequency from the outside.

藉由以此方式構成,變更負載減少,從而能夠適當且簡單地選擇截止頻率。 According to this configuration, the load is reduced, and the cutoff frequency can be appropriately and simply selected.

本發明之衝突檢測方法之特徵在於,其係由具備使動作對象物動作之伺服馬達及根據位置指令控制上述伺服馬達之伺服馬達控制部之伺服馬達控制裝置執行者,且包含:輸出與上述位置指令對應之速度維度信號,輸出上述伺服馬達之速度維度信號,並算出所輸出之與上述位置指令對應之速度維度信號、與所輸出之上述伺服馬達之速度維度信號之差分即速度偏差,輸出與上述位置指令對應之加速度維度信號,輸出上述伺服馬達之加速度維度信號,並算出所輸出之與上述 位置指令對應之加速度維度信號、與所輸出之上述伺服馬達之加速度維度信號之差分值即加速度偏差,並於根據特定之參數選擇之上述速度偏差以及加速度偏差中之任一者之絕對值達到特定值以上之情形時,檢測為衝突。 The collision detecting method according to the present invention is characterized in that the servo motor control device includes a servo motor that operates the object to be operated and a servo motor control unit that controls the servo motor based on the position command, and includes: an output and the position a speed dimension signal corresponding to the command, outputting a speed dimension signal of the servo motor, and calculating a speed deviation between the output speed dimension signal corresponding to the position command and the output speed dimension signal of the servo motor, and outputting The acceleration dimension signal corresponding to the position command outputs the acceleration dimension signal of the servo motor, and calculates the output and the above The acceleration dimension corresponding to the position command and the acceleration deviation of the output servo motor acceleration dimension signal, that is, the acceleration deviation, and the absolute value of any one of the speed deviation and the acceleration deviation selected according to the specific parameter reaches a specific value When the value is above, it is detected as a conflict.

藉由以此方式構成,能夠對應於應用程式之用途等,適當地選擇衝突檢測之方式,從而能夠提高衝突檢測之精度。 According to this configuration, it is possible to appropriately select the collision detection method in accordance with the use of the application or the like, and it is possible to improve the accuracy of the collision detection.

根據本發明,能夠根據特定之參數來選擇利用速度偏差進行衝突檢測及利用加速度偏差進行衝突檢測,藉此提供一種衝突檢測之檢測精度良好之伺服馬達控制裝置。 According to the present invention, collision detection using the speed deviation and collision detection using the acceleration deviation can be selected based on the specific parameters, thereby providing a servo motor control device with excellent detection accuracy of the collision detection.

1‧‧‧伺服馬達控制裝置 1‧‧‧Servo motor control unit

2‧‧‧動作對象物 2‧‧‧Action objects

3‧‧‧主機裝置 3‧‧‧ host device

10、10a、10b‧‧‧伺服馬達控制部 10, 10a, 10b‧‧‧ Servo Motor Control Department

20‧‧‧伺服馬達 20‧‧‧Servo motor

30‧‧‧檢測部 30‧‧‧Detection Department

100‧‧‧控制系統 100‧‧‧Control system

110a‧‧‧位置指令速度維度信號輸出部 110a‧‧‧ Position command speed dimension signal output

110b‧‧‧速度指令速度維度信號輸出部 110b‧‧‧Speed command speed dimension signal output

111、310‧‧‧微分器 111, 310‧‧‧ Differentiator

112‧‧‧濾波器 112‧‧‧ filter

120‧‧‧伺服馬達速度維度信號輸出部 120‧‧‧Servo motor speed dimension signal output

130‧‧‧第一衝突檢測部 130‧‧‧First Conflict Detection Department

140a‧‧‧位置指令加速度維度轉換部 140a‧‧‧ Position Command Acceleration Dimensional Conversion Unit

140b‧‧‧速度指令加速度維度轉換部 140b‧‧‧Speed Command Acceleration Dimensional Conversion Unit

150‧‧‧伺服馬達加速度維度轉換部 150‧‧‧Servo motor acceleration dimension conversion unit

160‧‧‧第二衝突檢測部 160‧‧‧Second Conflict Detection Department

170‧‧‧第三衝突檢測部 170‧‧‧ Third Conflict Detection Department

180‧‧‧選擇部 180‧‧‧Selection Department

190‧‧‧參數設定部 190‧‧‧Parameter Setting Department

191‧‧‧檢測方法選擇設定 191‧‧‧Test method selection setting

192‧‧‧特定值設定 192‧‧‧Specific value setting

193‧‧‧截止設定 193‧‧‧ cut-off setting

200‧‧‧比例增益要素 200‧‧‧Proportional Gain Elements

210‧‧‧積分濾波器要素 210‧‧‧Integral filter elements

220‧‧‧馬達增益要素 220‧‧‧Motor gain elements

230‧‧‧控制對象要素 230‧‧‧Control object elements

240‧‧‧微分濾波器要素 240‧‧‧Differential filter elements

250‧‧‧向前路徑 250‧‧‧ forward path

260‧‧‧第一反饋路徑 260‧‧‧First feedback path

270‧‧‧第二反饋路徑 270‧‧‧second feedback path

300‧‧‧觀測器 300‧‧‧ Observer

X‧‧‧控制系統 X‧‧‧Control System

圖1係本發明之實施形態之伺服馬達控制裝置之系統構成圖。 Fig. 1 is a system configuration diagram of a servo motor control device according to an embodiment of the present invention.

圖2係表示圖1所示之伺服馬達控制部執行位置控制時之控制構成之方塊圖。 Fig. 2 is a block diagram showing a control structure when the servo motor control unit shown in Fig. 1 performs position control.

圖3係表示圖1所示之伺服馬達控制部執行速度控制時之控制構成之方塊圖。 Fig. 3 is a block diagram showing a control structure when the servo motor control unit shown in Fig. 1 executes speed control.

圖4係表示圖1或圖2所示之包括控制系統之控制構成之方塊圖。 Figure 4 is a block diagram showing the control structure of the control system shown in Figure 1 or Figure 2.

<實施形態> <Embodiment> 〔控制系統X之構成〕 [Composition of Control System X]

參照圖1,對本發明之實施形態之控制系統X之構成進行說明。控制系統X為用於對機器人、機床、車輛、船舶、飛機、工廠設備等各種機器進行控制之系統。 The configuration of the control system X according to the embodiment of the present invention will be described with reference to Fig. 1 . The control system X is a system for controlling various machines such as robots, machine tools, vehicles, ships, airplanes, and factory equipment.

又,本實施形態之控制系統X包含伺服馬達控制裝置1、動作對象物2及主機裝置3。 Further, the control system X of the present embodiment includes the servo motor control device 1, the operation target 2, and the host device 3.

伺服馬達控制裝置1係根據位置指令或者速度指令調整控制量同 時對伺服馬達20進行控制,從而使動作對象物2動作之裝置。又,伺服馬達控制裝置1進行動作對象物2之衝突檢測。 The servo motor control device 1 adjusts the control amount according to the position command or the speed command. The device that controls the servo motor 20 to operate the object 2 is operated. Further, the servo motor control device 1 performs collision detection of the moving object 2.

於根據位置指令執行位置控制之情形時,伺服馬達控制裝置1檢測到機械臂因與障礙物接觸等而停止作為該衝突檢測。並且,於根據速度指令執行速度控制之情形時,伺服馬達控制裝置1檢測到機床之旋轉部件因缺齒或傳動帶故障等而停止。 When the position control is executed in accordance with the position command, the servo motor control device 1 detects that the arm is stopped as the collision detection due to contact with an obstacle or the like. Further, when the speed control is executed in accordance with the speed command, the servo motor control device 1 detects that the rotating member of the machine tool is stopped due to missing teeth or a belt failure or the like.

又,伺服馬達控制裝置1成為執行本實施形態之衝突檢測方法之硬體資源。 Further, the servo motor control device 1 is a hardware resource for executing the collision detecting method of the present embodiment.

動作對象物2係成為由伺服馬達控制裝置1實施動作控制之對象之部件。動作對象物2例如為工業用機器人之臂、機床之旋轉部件、車輛之車輪或齒輪或傳動帶、船舶之軸、飛機之螺旋槳、工廠設備之致動器等。 The moving object 2 is a component that is controlled by the servo motor control device 1 to perform operation control. The moving object 2 is, for example, an arm of an industrial robot, a rotating part of a machine tool, a wheel or a gear of a vehicle, a belt, a shaft of a ship, a propeller of an aircraft, an actuator of a factory equipment, or the like.

主機裝置3為用於控制並管理各種機器等之外部機器。具體而言,主機裝置3例如為PLC(Programmable Logic Controller:可編程邏輯控制器)、FC(Factory Computer:工廠電腦)、伺服器(Server)、PC(Personal Computer:個人電腦)等。主機裝置3執行用於控制並管理伺服馬達控制裝置1之應用程式(Application Program)。藉此,主機裝置3向伺服馬達控制裝置1發送位置指令或者速度指令,並自伺服馬達控制裝置1接收各種信息。又,主機裝置3亦可取得用戶之指示,對後述之參數設定部190(圖2、圖3)設定各種設定值。 The host device 3 is an external device for controlling and managing various machines and the like. Specifically, the host device 3 is, for example, a PLC (Programmable Logic Controller), an FC (Factory Computer), a server (Server), a PC (Personal Computer), or the like. The host device 3 executes an application program for controlling and managing the servo motor control device 1. Thereby, the host device 3 transmits a position command or a speed command to the servo motor control device 1, and receives various kinds of information from the servo motor control device 1. Further, the host device 3 can also obtain an instruction from the user, and set various setting values to the parameter setting unit 190 (FIGS. 2 and 3) to be described later.

又,伺服馬達控制裝置1包含伺服馬達控制部10、伺服馬達20以及檢測部30。 Further, the servo motor control device 1 includes a servo motor control unit 10, a servo motor 20, and a detecting unit 30.

伺服馬達控制部10根據來自主機裝置3之位置指令或者速度指令來控制伺服馬達20。具體而言,伺服馬達控制部10例如包括:FPGA(Field Programmable Gate Array:現場可編程閘陣列)、ASIC(Application Specific Integrated Circuit:特殊應用積體電路)、 DSP(Digital Signal Processor:數位信號處理器)、CPU(Central Processing Unit:中央處理單元)、MPU(Micro Processing Unit:微處理單元)等控制運算單元;以及類比或數位驅動部(放大器),其用於向伺服馬達20供給電力進行驅動。 The servo motor control unit 10 controls the servo motor 20 based on a position command or a speed command from the host device 3. Specifically, the servo motor control unit 10 includes, for example, an FPGA (Field Programmable Gate Array) and an ASIC (Application Specific Integrated Circuit). Control arithmetic unit such as DSP (Digital Signal Processor), CPU (Central Processing Unit), MPU (Micro Processing Unit), and analog or digital drive unit (amplifier) The electric power is supplied to the servo motor 20 to be driven.

此處,伺服馬達控制部10係如下述般可於根據位置指令執行位置控制之情形時與根據速度指令執行速度控制之情形時,藉由主機裝置3之應用程式變更構成。 Here, the servo motor control unit 10 can be configured by the application of the host device 3 when the position control is executed based on the position command and when the speed control is executed according to the speed command.

伺服馬達20為AC伺服馬達20、DC伺服馬達20以及線性致動器等。伺服馬達20使動作對象物2動作。 The servo motor 20 is an AC servo motor 20, a DC servo motor 20, a linear actuator, or the like. The servo motor 20 operates the moving object 2 .

檢測部30包含檢測伺服馬達20之軸等之位置之位置檢測感測器,具體而言,檢測部30包含檢測伺服馬達20之位置並輸出之位置檢測感測器。該位置檢測感測器例如為磁式或光學式之編碼器(Encoder)等。 The detecting unit 30 includes a position detecting sensor that detects the position of the axis of the servo motor 20 or the like. Specifically, the detecting unit 30 includes a position detecting sensor that detects the position of the servo motor 20 and outputs it. The position detecting sensor is, for example, a magnetic or optical encoder or the like.

又,檢測部30之輸出信號係輸入至伺服馬達控制部10,並用於位置控制或速度控制之反饋(Feedback)控制。 Further, the output signal of the detecting unit 30 is input to the servo motor control unit 10, and is used for feedback control of position control or speed control.

再者,藉由伺服馬達控制部10之控制運算單元實現之後述之各部分亦可由特定之數位電路構成。又,除數位電路之外,既可由類比電路構成,亦可藉由於RAM(Random Access Memory:隨機存取記憶體)中展開並執行儲存於ROM(Read Only Memory:唯讀記憶體)之控制程式,來構成藉由硬體資源執行軟體之電路。 Further, each of the portions described later by the control arithmetic unit of the servo motor control unit 10 may be constituted by a specific digital circuit. Further, in addition to the digital circuit, the analog circuit may be used, or the control program stored in the ROM (Read Only Memory) may be expanded and executed by a RAM (Random Access Memory). To form a circuit for executing software by hardware resources.

又,亦可構成為不使用擬似微分器而取得馬達之速度維度信號。於此種情形時,如後述般,藉由觀測器300(圖4)根據動作對象物2之動作模型推測伺服馬達20之速度等而進行控制。 Further, it is also possible to obtain a speed dimension signal of the motor without using a pseudo-differentiator. In this case, as will be described later, the observer 300 (FIG. 4) controls the speed of the servo motor 20 based on the motion model of the moving object 2, and the like.

〔伺服馬達控制部10之構成〕 [Configuration of Servo Motor Control Unit 10]

其次,參照圖2至圖4,對圖1之伺服馬達控制部10之詳細之控制構成進行說明。 Next, a detailed control configuration of the servo motor control unit 10 of Fig. 1 will be described with reference to Figs. 2 to 4 .

圖2係執行以伺服馬達20之位置指令為輸入、以伺服馬達20之位置為輸出之位置控制而進行衝突檢測之情形時的伺服馬達控制部10a之構成。 2 is a configuration of the servo motor control unit 10a when the collision detection is performed with the position command of the servo motor 20 as an input and the position control of the position of the servo motor 20 as the output.

伺服馬達控制部10a包含位置指令速度維度信號輸出部110a、伺服馬達速度維度信號輸出部120、第一衝突檢測部130、位置指令加速度維度轉換部140a、伺服馬達加速度維度轉換部150、第二衝突檢測部160、第三衝突檢測部170、選擇部180以及參數設定部190。 The servo motor control unit 10a includes a position command speed dimension signal output unit 110a, a servo motor speed dimension signal output unit 120, a first collision detecting unit 130, a position command acceleration dimension conversion unit 140a, a servo motor acceleration dimension conversion unit 150, and a second conflict. The detecting unit 160, the third collision detecting unit 170, the selecting unit 180, and the parameter setting unit 190.

控制系統100具有動作對象物2之模型,並表示藉由反饋進行控制之控制系統100之整體。 The control system 100 has a model of the moving object 2 and represents the entirety of the control system 100 controlled by feedback.

位置指令速度維度信號輸出部110a自主機裝置3等輸入位置指令,並輸出與該位置指令對應之速度維度信號。 The position command speed dimension signal output unit 110a inputs a position command from the host device 3 or the like, and outputs a speed dimension signal corresponding to the position command.

又,位置指令速度維度信號輸出部110a包含微分器111以及濾波器112。 Further, the position command speed dimension signal output unit 110a includes a differentiator 111 and a filter 112.

微分器111係對位置指令實施微分並轉換成速度維度之擬似微分部等。 The differentiator 111 differentiates the position command and converts it into a pseudo-differentiation portion of the velocity dimension or the like.

濾波器112例如為一次IIR濾波器(Infinite Impulse Response Filter:無限脈衝應答濾波器)。藉此,濾波器112輸出時間延遲之信號。又,濾波器112包含以1/(τ s+1)為傳遞函數之要素作為控制系統100之模型。此處,τ為時間常數,s為拉普拉斯算子。又,濾波器112之截止頻率等之參數可自外部設定,具體而言,藉由參數設定部190之截止設定193來設定。 The filter 112 is, for example, a primary IIR filter (Infinite Impulse Response Filter). Thereby, the filter 112 outputs a signal of time delay. Further, the filter 112 includes an element having a transfer function of 1/(τ s+1) as a model of the control system 100. Here, τ is a time constant and s is a Laplacian. Further, the parameters such as the cutoff frequency of the filter 112 can be set from the outside, specifically, by the cutoff setting 193 of the parameter setting unit 190.

再者,該截止設定193亦可根據伺服增益之設定值來算出濾波器之截止頻率。 Furthermore, the cutoff setting 193 can also calculate the cutoff frequency of the filter based on the set value of the servo gain.

又,亦可使用除一次濾波器之外之各種濾波器作為濾波器112。 Further, various filters other than the primary filter may be used as the filter 112.

伺服馬達速度維度信號輸出部120輸出伺服馬達20之速度維度信號。 The servo motor speed dimension signal output unit 120 outputs a speed dimension signal of the servo motor 20.

作為一例,伺服馬達速度維度信號輸出部120取得由檢測部30之位置檢測感測器檢測到之伺服馬達20之位置信號,並藉由微分器對其實施微分並作為速度維度信號輸出。於此種情形時,伺服馬達速度維度信號輸出部120算出自實際之控制系統100得到之位置反饋值之微分值即速度反饋值。 As an example, the servo motor speed dimension signal output unit 120 acquires the position signal of the servo motor 20 detected by the position detecting sensor of the detecting unit 30, and differentiates it by the differentiator and outputs it as a speed dimension signal. In this case, the servo motor speed dimension signal output unit 120 calculates a speed feedback value which is a differential value of the position feedback value obtained from the actual control system 100.

再者,伺服馬達速度維度信號輸出部120能夠藉由其他方式算出速度維度信號。關於該速度維度信號之取得、算出方法,將於下文敍述。 Furthermore, the servo motor speed dimension signal output unit 120 can calculate the velocity dimension signal by other means. The method of obtaining and calculating the velocity dimension signal will be described below.

第一衝突檢測部130被輸入由位置指令速度維度信號輸出部110a輸出之速度維度信號與由伺服馬達速度維度信號輸出部120輸出之速度維度信號之差分值即速度偏差。於此基礎之上,當已輸入之速度偏差之絕對值達到特定值以上時,第一衝突檢測部130檢測為衝突。第一衝突檢測部130於檢測為衝突之情形時,輸出衝突檢測信號。 The first collision detecting unit 130 receives a speed deviation which is a difference value between the speed dimension signal output from the position command speed dimension signal output unit 110a and the speed dimension signal output from the servo motor speed dimension signal output unit 120. On the basis of this, when the absolute value of the input speed deviation reaches a certain value or more, the first collision detecting unit 130 detects a collision. The first collision detecting unit 130 outputs a collision detecting signal when it detects a collision.

位置指令加速度維度轉換部140a將由位置指令速度維度信號輸出部110a輸出之速度維度信號轉換為加速度維度信號並輸出。具體而言,位置指令加速度維度轉換部140a藉由微分器對已輸入之與位置指令相關之速度維度信號進一步實施微分並轉換為加速度維度,並將加速度維度作為加速度維度信號輸出。 The position command acceleration dimension conversion unit 140a converts the speed dimension signal output by the position command speed dimension signal output unit 110a into an acceleration dimension signal and outputs it. Specifically, the position command acceleration dimension conversion unit 140a further differentiates the input speed dimension signal associated with the position command by the differentiator and converts it into an acceleration dimension, and outputs the acceleration dimension as an acceleration dimension signal.

伺服馬達加速度維度轉換部150將伺服馬達20之速度維度信號轉換為加速度維度信號並輸出。具體而言,作為一例,伺服馬達加速度維度轉換部150藉由微分器對由伺服馬達速度維度信號輸出部120輸出之速度維度信號進一步實施微分並轉換為加速度維度,並將加速度維度作為加速度維度信號輸出。 The servo motor acceleration dimension conversion unit 150 converts the velocity dimension signal of the servo motor 20 into an acceleration dimension signal and outputs it. Specifically, as an example, the servo motor acceleration dimension conversion unit 150 further differentiates and converts the velocity dimension signal output by the servo motor speed dimension signal output unit 120 into an acceleration dimension by using a differentiator, and uses the acceleration dimension as an acceleration dimension signal. Output.

第二衝突檢測部160被輸入由位置指令加速度維度轉換部140a輸出之加速度維度信號與由伺服馬達加速度維度轉換部150輸出之加速度維度信號之差分值即加速度偏差。於此基礎之上,於加速度偏差之 絕對值達到特定值以上之情形時,第二衝突檢測部160檢測為衝突。第二衝突檢測部160於檢測到衝突之情形時,輸出衝突檢測信號。 The second collision detecting unit 160 receives the acceleration deviation which is the difference value between the acceleration dimension signal output from the position command acceleration dimension conversion unit 140a and the acceleration dimension signal output from the servo motor acceleration dimension conversion unit 150. On the basis of this, in the acceleration deviation When the absolute value reaches a certain value or more, the second collision detecting unit 160 detects a collision. The second collision detecting unit 160 outputs a collision detecting signal when a situation of a collision is detected.

在由伺服馬達加速度維度轉換部150輸出之加速度維度信號之絕對值達到特定值以上之情形時,第三衝突檢測部170檢測為衝突。第三衝突檢測部170於檢測到衝突之情形時,輸出衝突檢測信號。 When the absolute value of the acceleration dimension signal output by the servo motor acceleration dimension conversion unit 150 reaches a certain value or more, the third collision detecting unit 170 detects a collision. The third collision detecting unit 170 outputs a collision detecting signal when a situation of a collision is detected.

選擇部180根據參數設定部190之檢測方法選擇設定191來選擇將第一衝突檢測部130、第二衝突檢測部160以及第三衝突檢測部170中之哪一個用於衝突判定。又,選擇部180將該已選擇之部之衝突檢測信號輸出到主機裝置3等。 The selection unit 180 selects which of the first collision detecting unit 130, the second collision detecting unit 160, and the third collision detecting unit 170 to use for collision determination based on the detection method selection setting 191 of the parameter setting unit 190. Further, the selection unit 180 outputs the conflict detection signal of the selected portion to the host device 3 or the like.

參數設定部190主要設定各種設定,且將各種設定儲存於RAM、EEPROM等非暫時性之記錄媒體中。參數設定部190之各設定值能夠藉由主機裝置3等之外部之機器來設定。又,各設定值亦可藉由雙列直插式封裝開關等來設定。 The parameter setting unit 190 mainly sets various settings, and stores various settings in a non-transitory recording medium such as a RAM or an EEPROM. Each set value of the parameter setting unit 190 can be set by a device external to the host device 3 or the like. Further, each set value can also be set by a dip-in package switch or the like.

又,參數設定部190包含檢測方法選擇設定191、特定值設定192以及截止設定193。 Further, the parameter setting unit 190 includes a detection method selection setting 191, a specific value setting 192, and an OFF setting 193.

檢測方法選擇設定191係指定選擇部180係採用第一衝突檢測部130、第二衝突檢測部160以及第三衝突檢測部170中之哪一個來設定衝突檢測之特定之參數之設定信息。於以正常之速度使伺服馬達20動作之應用程式中,該特定之參數優先選擇採用了速度偏差之第一衝突檢測部130。並且,於加減速快之應用程式中,特定之參數優先選擇採用了加速度偏差之第二衝突檢測部160。並且,於加減速和緩之應用程式中,特定之參數優先選擇採用了加速度之反饋之第三衝突檢測部170。 The detection method selection setting 191 is a setting selection unit 180 that sets the setting information of the specific parameter of the collision detection using which of the first collision detection unit 130, the second collision detection unit 160, and the third collision detection unit 170. In the application that operates the servo motor 20 at a normal speed, the specific parameter preferentially selects the first collision detecting unit 130 that uses the speed deviation. Further, in the application in which the acceleration/deceleration is fast, the specific parameter preferentially selects the second collision detecting unit 160 using the acceleration deviation. Further, in the acceleration/deceleration and slow application, the specific parameter preferentially selects the third collision detecting unit 170 that uses the feedback of the acceleration.

再者,該特定之參數不僅由數值指定,亦可由如特定之數學模型、模糊函數、人工類神經網路之函數形式來指定。 Furthermore, the particular parameter is specified not only by the numerical value, but also by a function such as a specific mathematical model, a fuzzy function, or an artificial neural network.

特定值設定192係第一衝突檢測部130之特定值、第二衝突檢測 部160之特定值、第三衝突檢測部170之特定值。該特定值設定192亦可準備單一之值,於每一個應用程式中替換使用。再者,亦可準備特定值設定192之特定值分別用於第一衝突檢測部130、第二衝突檢測部160以及第三衝突檢測部170。 The specific value setting 192 is a specific value of the first conflict detecting unit 130, and the second conflict detecting is performed. The specific value of the unit 160 and the specific value of the third collision detecting unit 170. This particular value setting 192 can also be prepared as a single value for use in each application. Further, the specific values of the specific value setting 192 may be used for the first collision detecting unit 130, the second collision detecting unit 160, and the third collision detecting unit 170, respectively.

截止設定193設定濾波器112之截止頻率。再者,由於能夠根據伺服增益之設定值算出該截止頻率,因此亦可藉由利用截止設定193變更設定伺服增益,來設定截止頻率。 The cutoff setting 193 sets the cutoff frequency of the filter 112. Further, since the cutoff frequency can be calculated from the set value of the servo gain, the cutoff frequency can be set by changing the set servo gain by the cutoff setting 193.

再者,第一衝突檢測部130、第二衝突檢測部160以及第三衝突檢測部170亦可藉由其他方式來進行衝突檢測。關於其他衝突檢測之方法將於下文敍述。 Furthermore, the first collision detecting unit 130, the second collision detecting unit 160, and the third collision detecting unit 170 may perform collision detection by other methods. The methods for other conflict detection will be described below.

又,亦可為不存在第三衝突檢測部170之構成。 Further, the configuration of the third collision detecting unit 170 may not be present.

其次,參照圖3,對執行以伺服馬達20之速度指令為輸入、以伺服馬達20之速度為輸出之速度控制時之伺服馬達控制部10b之構成進行說明。於圖2與圖3中,對相同之構成要素標註相同之符號。 Next, a configuration of the servo motor control unit 10b when the speed command of the servo motor 20 is input and the speed of the servo motor 20 is output is controlled will be described with reference to Fig. 3 . In FIGS. 2 and 3, the same components are denoted by the same reference numerals.

伺服馬達控制部10b具備速度指令速度維度信號輸出部110b以及速度指令加速度維度轉換部140b。 The servo motor control unit 10b includes a speed command speed dimension signal output unit 110b and a speed command acceleration dimension conversion unit 140b.

速度指令速度維度信號輸出部110b自主機裝置3等輸入速度指令,並輸出與該速度指令對應之速度維度信號。 The speed command speed dimension signal output unit 110b inputs a speed command from the host device 3 or the like, and outputs a speed dimension signal corresponding to the speed command.

速度指令速度維度信號輸出部110b由於此時速度指令為速度維度之值不實施微分,而輸入至與包含在位置指令速度維度信號輸出部110a中之濾波器相同之濾波器112中。 The speed command speed dimension signal output unit 110b is input to the same filter 112 as the filter included in the position command speed dimension signal output unit 110a because the speed command is not differentiated at the speed dimension.

速度指令加速度維度轉換部140b將由速度指令速度維度信號輸出部110b輸出之速度維度信號轉換為加速度維度信號並輸出。該處理與位置指令加速度維度轉換部140a相同。 The speed command acceleration dimension conversion unit 140b converts the speed dimension signal output by the speed command speed dimension signal output unit 110b into an acceleration dimension signal and outputs it. This processing is the same as the position command acceleration dimension conversion unit 140a.

〔控制系統100之模型之構成〕 [Composition of the model of the control system 100]

其次,參照圖4,於控制系統100中,採用考慮到內部狀態之狀 態空間表現之模型,對取得速度維度信號以及加速度維度信號等時之細節、其他衝突檢測方式等,進行說明。 Next, referring to FIG. 4, in the control system 100, taking into consideration the internal state The model of the state space representation describes the details of the speed dimension signal and the acceleration dimension signal, and other conflict detection methods.

控制系統100結合理想傳遞函數(模型)進行模型匹配控制,上述理想傳遞函數為具有用於對應於動作對象物2而適當地控制伺服馬達20之理想特性之傳遞函數。 The control system 100 performs model matching control in conjunction with an ideal transfer function (model) having a transfer function for appropriately controlling the ideal characteristics of the servo motor 20 in accordance with the object 2 to be moved.

若將拉普拉斯算子設為s,則該模型能夠表現為m0/(s2+m1s+m0)。 該模型例如能夠如下述般變形。 If the Laplacian is set to s, the model can be expressed as m0/(s 2 +m1s+m0). This model can be modified, for example, as follows.

m0/(s2+m1s+m0)=ω1ω2/(s+ω1)(s+ω2)) M0/(s 2 +m1s+m0)=ω1ω2/(s+ω1)(s+ω2))

此處,ω 1、ω 2為模型之截止頻率,且以下之關係式成立。 Here, ω 1 and ω 2 are the cutoff frequencies of the model, and the following relation holds.

m0=ω1ω2,m1=ω1+ω2……式(1) M0=ω1ω2,m1=ω1+ω2...(1)

再者,由於根據動作對象物2以及伺服馬達20之特性或控制之目地來設定ω 1、ω 2,因此能夠得到所需之控制應答特性。 Further, since ω 1 and ω 2 are set in accordance with the characteristics of the moving object 2 and the servo motor 20 or the purpose of control, the required control response characteristics can be obtained.

又,控制系統100具備比例增益要素200、積分濾波器要素210、馬達增益要素220、包含伺服馬達及動作對象物之控制對象要素230、微分濾波器要素240、向前路徑250、第一反饋路徑260以及第二反饋路徑270。 Further, the control system 100 includes a proportional gain element 200, an integral filter element 210, a motor gain element 220, a control target element 230 including a servo motor and an operation target, a differential filter element 240, a forward path 250, and a first feedback path. 260 and a second feedback path 270.

此處,將用包含向伺服馬達20供給電力之放大器(未圖示)之特定之增益與伺服馬達20之轉矩常數的特定值除以動作對象物2以及伺服馬達20之慣性力矩之值(慣性,inertia)得到之值(增益)設為K。 Here, the specific gain of the amplifier (not shown) including the electric power supplied to the servo motor 20 and the specific value of the torque constant of the servo motor 20 are divided by the values of the moment of inertia of the operating object 2 and the servo motor 20 ( Inertia, the value obtained (gain) is set to K.

又,將用與動作對象物2以及伺服馬達20之黏性相關之項除以動作對象物2以及伺服馬達20之慣性得到之值即增益設為p。 Further, the gain obtained by dividing the viscosity of the moving object 2 and the servo motor 20 by the inertia of the moving object 2 and the servo motor 20 is set to p.

於此種情形時,各個要素表現如下: In this case, the various elements behave as follows:

比例增益要素200為m0。 The proportional gain element 200 is m0.

又,積分濾波器要素210係以(s2+q1s+q0)/(s2+a1s)表示之傳遞函數。 Further, the integral filter element 210 is a transfer function expressed by (s 2 + q1s + q0) / (s 2 + a1s).

又,馬達增益要素220為1/K。 Further, the motor gain element 220 is 1/K.

又,包含伺服馬達以及動作對象物之控制對象要素230係表示控制對象,且以K/(s2+ps)表示之傳遞函數。 Further, the control target element 230 including the servo motor and the operation target is a transfer function expressed by K/(s 2 + ps) indicating the control target.

又,微分濾波器要素240係以(b2s2+b1s)/(s2+q1s+q0)表示之傳遞函數。 Further, the differential filter element 240 is a transfer function expressed by (b2s 2 + b1s) / (s 2 + q1s + q0).

又,向前路徑250係自控制系統100之輸入向輸出之路徑。 Again, the forward path 250 is the path from the input to the output of the control system 100.

又,第一反饋路徑260係自控制系統100之輸出部向輸入側之第一反饋迴路。 Further, the first feedback path 260 is a first feedback loop from the output of the control system 100 to the input side.

又,第二反饋路徑270係自控制系統100之輸出部向輸入側之第二反饋迴路。此處,第二反饋路徑270算出向位置指令之值乘以比例增益而得到之信號之偏差。即,第二反饋路徑270係算出向位置指令之值乘以比例增益而得到之信號、與由位置檢測感測器檢測到之位置信號經微分濾波器要素240微分後之信號之偏差的反饋迴路。 Further, the second feedback path 270 is a second feedback loop from the output of the control system 100 to the input side. Here, the second feedback path 270 calculates a deviation of the signal obtained by multiplying the value of the position command by the proportional gain. In other words, the second feedback path 270 is a feedback loop that calculates a signal obtained by multiplying the value of the position command by the proportional gain and a signal differentiated from the position signal detected by the position detecting sensor by the differential filter element 240. .

再者,a1、b1、b2滿足以下關係。 Furthermore, a1, b1, and b2 satisfy the following relationship.

a1=q1+m1-p……式(2) A1=q1+m1-p...(2)

b1=q0×m1……式(3) B1=q0×m1......(3)

b2=(q1-p)×(m1-p)+q0……式(4) B2=(q1-p)×(m1-p)+q0...(4)

又,上述之q0、q1係用於對動作對象物2以及伺服馬達20進行適當地控制而任意設定之值。 Further, the above-described q0 and q1 are used to appropriately control the object 2 and the servo motor 20 to be arbitrarily set.

藉由此種構成,伺服馬達速度維度信號輸出部120可選擇圖4所示之速度反饋(a)、速度反饋(b)、速度反饋(c)中之任一者之值作為速度維度信號,並用於速度維度信號之算出與輸出。 With such a configuration, the servo motor speed dimension signal output unit 120 can select the value of any of the speed feedback (a), the speed feedback (b), and the speed feedback (c) shown in FIG. 4 as the velocity dimension signal. And used for the calculation and output of the velocity dimension signal.

如上所述,速度反饋(a)為藉由微分器算出由檢測部30之位置檢測感測器等檢測到之伺服馬達20之位置信號(位置反饋值)之速度反饋值。 As described above, the speed feedback (a) is a speed feedback value obtained by the positioner detecting the position signal (position feedback value) of the servo motor 20 detected by the position detecting sensor or the like of the detecting unit 30.

速度反饋(b)為由觀測器300推定之速度推定信號。觀測器300為根據向模型之控制對象輸入之輸入信號與控制對象之輸出信號來推定 速度之速度觀測器。具體而言,觀測器300基於向控制對象要素230之輸入與自控制對象要素230之輸出來推定增益K與p。此時,觀測器300亦可構成為:例如藉由最小二乘法等推定增益K。於此種情形時,於已知增益K與p之情形時,觀測器300可使用增益K與p之值。又,於該等值為未知之情形時,以特定時間間隔來逐次執行增益K與p之推定。 The speed feedback (b) is a speed estimation signal estimated by the observer 300. The observer 300 estimates the input signal input to the control object of the model and the output signal of the control object. Speed speed observer. Specifically, the observer 300 estimates the gains K and p based on the input to the control target element 230 and the output of the self-control target element 230. At this time, the observer 300 may be configured to estimate the gain K by, for example, a least square method or the like. In this case, the observer 300 can use the values of the gains K and p when the gains K and p are known. Further, when the values are unknown, the estimation of the gains K and p is successively performed at specific time intervals.

再者,於不使用速度反饋(b)之情形時,亦可為不使用觀測器300之構成。 Furthermore, when the speed feedback (b) is not used, the configuration of the observer 300 may not be used.

速度反饋(c)為第二反饋路徑270之微分濾波器要素240之輸出信號。即,速度反饋(c)將配設在第二反饋迴路內之微分濾波器之輸出信號作為速度維度信號輸出。 The speed feedback (c) is the output signal of the differential filter element 240 of the second feedback path 270. That is, the speed feedback (c) outputs the output signal of the differential filter disposed in the second feedback loop as a velocity dimension signal.

再者,關於伺服馬達速度維度信號輸出部120使用哪一個速度反饋值,可於參數設定部190中進行設定。 Further, which speed feedback value is used by the servo motor speed dimension signal output unit 120 can be set in the parameter setting unit 190.

又,第一衝突檢測部130算出向位置指令值乘以比例增益而得到之信號與由位置檢測感測器檢測到之位置信號經微分後之信號之差分值作為擬似速度偏差代替上述之速度偏差,並且能夠使用擬似速度偏差代替速度偏差進行衝突檢測。即,第一衝突檢測部130算出比例增益要素200之輸出值與第二反饋路徑270之微分濾波器要素240之輸出值之差分值作為擬似速度偏差。並且,於此種情形時,第一衝突檢測部130於已算出之擬似速度偏差之絕對值達到特定值以上之情形時檢測為衝突。 Further, the first collision detecting unit 130 calculates a difference value between the signal obtained by multiplying the position command value by the proportional gain and the signal differentiated by the position detecting sensor by the position detecting sensor as the pseudo-velocity deviation instead of the above-described speed deviation. And can use the pseudo-velocity deviation instead of the speed deviation for collision detection. That is, the first collision detecting unit 130 calculates a difference value between the output value of the proportional gain element 200 and the output value of the differential filter element 240 of the second feedback path 270 as the pseudo-velocity deviation. Further, in such a case, the first collision detecting unit 130 detects a collision when the absolute value of the calculated pseudo-velocity deviation reaches a certain value or more.

又,同樣,第二衝突檢測部160亦可算出由微分器310將擬似速度偏差經微分後之信號作為擬似加速度偏差來代替加速度偏差。於此種情形時,第二衝突檢測部160於已算出之擬似加速度偏差之絕對值達到特定值以上之情形時,檢測為衝突。又,第三衝突檢測部170亦能夠使用擬似加速度偏差之值來進行衝突檢測。 Further, similarly, the second collision detecting unit 160 may calculate a signal obtained by the differentiator 310 by differentiating the pseudo-velocity deviation as a pseudo-acceleration deviation instead of the acceleration deviation. In this case, the second collision detecting unit 160 detects a collision when the absolute value of the calculated pseudo-acceleration deviation reaches a certain value or more. Further, the third collision detecting unit 170 can also perform collision detection using the value of the pseudo acceleration deviation.

〔本實施形態之效果〕 [Effect of this embodiment]

藉由如上所述般構成,能夠獲得如下效果。 By configuring as described above, the following effects can be obtained.

先前,如專利文獻1所記載之進行使用了轉矩之衝突檢測之方式中,無法獲得充分之衝突檢測精度。 In the prior art, in the method of detecting the collision using the torque described in Patent Document 1, sufficient collision detection accuracy cannot be obtained.

本發明之實施形態之伺服馬達控制裝置1之特徵在於,其係具備使動作對象物動作之伺服馬達20及根據位置指令對伺服馬達20進行控制之伺服馬達控制部10a者,且伺服馬達控制部10a具備:位置指令速度維度信號輸出部110a,其輸出與位置指令對應之速度維度信號;伺服馬達速度維度信號輸出部120,其輸出伺服馬達20之速度維度信號;第一衝突檢測部130,其於由位置指令速度維度信號輸出部110a輸出之速度維度信號與由伺服馬達速度維度信號輸出部120輸出之速度維度信號之差分值即速度偏差之絕對值達到特定值以上之情形時,檢測為衝突;位置指令加速度維度轉換部140a,其將由上述位置指令速度維度信號輸出部110a輸出之速度維度信號轉換為加速度維度信號並輸出;伺服馬達加速度維度轉換部150,其將由上述伺服馬達速度維度信號輸出部120輸出之速度維度信號轉換為加速度維度信號並輸出;第二衝突檢測部160,其於由上述位置指令加速度維度轉換部140a輸出之加速度維度信號與由上述伺服馬達加速度維度轉換部150輸出之加速度維度信號之差分值即加速度偏差之絕對值達到特定值以上之情形時,檢測為衝突;以及選擇部180,其根據參數設定部190之檢測方法選擇設定191來選擇上述第一衝突檢測部130與上述第二衝突檢測部160。 The servo motor control device 1 according to the embodiment of the present invention includes a servo motor 20 that operates an object to be operated, and a servo motor control unit 10a that controls the servo motor 20 based on a position command, and a servo motor control unit. 10a includes: a position command speed dimension signal output unit 110a that outputs a speed dimension signal corresponding to the position command; a servo motor speed dimension signal output unit 120 that outputs a speed dimension signal of the servo motor 20; and a first collision detecting unit 130 When the absolute value of the speed difference between the speed dimension signal outputted by the position command speed dimension signal output unit 110a and the speed dimension signal outputted by the servo motor speed dimension signal output unit 120 reaches a specific value or more, the collision is detected as a collision. a position command acceleration dimension conversion unit 140a that converts the speed dimension signal output by the position command speed dimension signal output unit 110a into an acceleration dimension signal and outputs the servo motor acceleration dimension conversion unit 150, which is output by the servo motor speed dimension signal Speed dimension of the output of section 120 The number is converted into an acceleration dimension signal and output; the second collision detecting unit 160 is different from the acceleration dimension signal output by the position command acceleration dimension conversion unit 140a and the acceleration dimension signal output by the servo motor acceleration dimension conversion unit 150. That is, when the absolute value of the acceleration deviation reaches a certain value or more, the detection is a collision; and the selection unit 180 selects the first collision detection unit 130 and the second collision detection based on the detection method selection setting 191 of the parameter setting unit 190. Department 160.

藉由以此方式構成,能夠適當地選擇並使用與應用程式之用途等相應之第一衝突檢測部130與第二衝突檢測部160。此處,第一衝突檢測部130與使用位置偏差、轉矩之情形相比,能夠高精度地進行衝突檢測。又,第二衝突檢測部160能夠於伺服馬達20之加減速快之狀 況下精度更高地進行衝突檢測。因此,由於能夠根據與應用程式對應之特定之參數進行選擇,從而能夠提高衝突檢測之檢測精度。 With this configuration, the first collision detecting unit 130 and the second collision detecting unit 160 corresponding to the use of the application or the like can be appropriately selected and used. Here, the first collision detecting unit 130 can perform collision detection with higher accuracy than when the positional deviation and the torque are used. Further, the second collision detecting unit 160 can accelerate and decelerate the servo motor 20 Collision detection is performed with higher precision. Therefore, since the selection can be made based on the specific parameters corresponding to the application, the detection accuracy of the collision detection can be improved.

又,於專利文獻1之技術中,無法在加減速時檢測衝突,但本發明藉由選擇第二衝突檢測部160而可於加減速時亦檢測衝突。 Further, in the technique of Patent Document 1, the collision cannot be detected during acceleration/deceleration, but the present invention can detect the collision even during acceleration/deceleration by selecting the second collision detecting unit 160.

又,本發明之實施形態之伺服馬達控制裝置1之特徵在於,其係具備使動作對象物動作之伺服馬達20及根據速度指令對伺服馬達20進行控制之伺服馬達控制部10b者,且伺服馬達控制部10b具備:速度指令速度維度信號輸出部110b,其輸出與速度指令對應之速度維度信號;伺服馬達速度維度信號輸出部120,其輸出伺服馬達20之速度維度信號;第一衝突檢測部130,其於由速度指令速度維度信號輸出部110b輸出之速度維度信號與由伺服馬達速度維度信號輸出部120輸出之速度維度信號之差分即速度偏差之絕對值達到特定值以上之情形時,檢測為衝突;速度指令加速度維度轉換部140b,其將由速度指令速度維度信號輸出部110b輸出之速度維度信號轉換為加速度維度信號並輸出;伺服馬達加速度維度轉換部150,其將由伺服馬達速度維度信號輸出部120輸出之速度維度信號轉換為加速度維度信號並輸出;第二衝突檢測部160,其於由速度指令加速度維度轉換部140b輸出之加速度維度信號與由伺服馬達加速度維度轉換部150輸出之加速度維度信號之差分值即加速度偏差之絕對值達到特定值以上之情形時,檢測為衝突;以及選擇部180,其根據參數設定部190之檢測方法選擇設定191選擇第一衝突檢測部130與第二衝突檢測部160。 Further, the servo motor control device 1 according to the embodiment of the present invention includes a servo motor 20 that operates an object to be operated, and a servo motor control unit 10b that controls the servo motor 20 based on a speed command, and a servo motor. The control unit 10b includes a speed command speed dimension signal output unit 110b that outputs a speed dimension signal corresponding to the speed command, and a servo motor speed dimension signal output unit 120 that outputs a speed dimension signal of the servo motor 20; the first collision detecting unit 130 When the absolute value of the speed deviation between the speed dimension signal outputted by the speed command speed dimension signal output unit 110b and the speed dimension signal outputted by the servo motor speed dimension signal output unit 120 reaches a specific value or more, it is detected as a speed command acceleration dimension conversion unit 140b that converts the speed dimension signal output by the speed command speed dimension signal output unit 110b into an acceleration dimension signal and outputs the servo motor acceleration dimension conversion unit 150, which is to be output by the servo motor speed dimension signal 120 output speed dimension signal turn And outputting the acceleration dimension signal; the second collision detecting unit 160 is different from the acceleration dimension signal output by the speed command acceleration dimension conversion unit 140b and the acceleration dimension signal output by the servo motor acceleration dimension conversion unit 150. When the absolute value is equal to or greater than the specific value, the collision is detected; and the selection unit 180 selects the first collision detection unit 130 and the second collision detection unit 160 based on the detection method selection setting 191 of the parameter setting unit 190.

藉由以此方式構成,與上述之伺服馬達控制部10a相同,能夠提高衝突檢測之精度。又,若採用速度指令,則可減少微分要素,故而可簡化部。 According to this configuration, similarly to the above-described servo motor control unit 10a, the accuracy of collision detection can be improved. Moreover, if the speed command is used, the differential element can be reduced, so that the part can be simplified.

又,先前於僅利用位置指令進行衝突檢測之技術中,無法於速度控制時進行衝突檢測。針對該點,藉由本實施形態之伺服馬達控制 部10b,於速度控制時亦可高精度地進行衝突檢測。 Further, in the technique of performing collision detection using only the position command, collision detection cannot be performed at the time of speed control. For this point, the servo motor control of this embodiment is controlled. The portion 10b can also perform collision detection with high precision during speed control.

又,本發明之實施形態之伺服馬達控制部10之特徵在於,進而具備第三衝突檢測部170,該第三衝突檢測部170於由伺服馬達加速度維度轉換部150輸出之加速度維度信號之絕對值達到特定值以上之情形時,檢測為衝突,且選擇部180根據特定之參數亦選擇第三衝突檢測部170。 Further, the servo motor control unit 10 according to the embodiment of the present invention further includes a third collision detecting unit 170 that detects the absolute value of the acceleration dimension signal output by the servo motor acceleration dimension conversion unit 150. When the specific value or more is reached, the collision is detected, and the selection unit 180 also selects the third collision detecting unit 170 based on the specific parameter.

藉由以此方式構成,能夠將作為加速度之值之維度信號本身與特定值進行比較,從而於加減速和緩之狀況下提高衝突檢測之精度。 By configuring in this way, it is possible to compare the dimensional signal itself, which is the value of the acceleration, with a specific value, thereby improving the accuracy of the collision detection in the case of acceleration and deceleration and slowness.

又,本發明之實施形態之伺服馬達控制裝置1之特徵在於,伺服馬達速度維度信號輸出部120將由檢測伺服馬達20之位置之位置檢測感測器檢測到之位置信號經微分後之信號作為速度維度信號輸出。 Further, the servo motor control device 1 according to the embodiment of the present invention is characterized in that the servo motor speed dimension signal output unit 120 uses a signal obtained by differentiating the position signal detected by the position detecting sensor that detects the position of the servo motor 20 as a speed. Dimension signal output.

藉由以此方式構成,能夠藉由微分器簡單地獲得速度維度信號。因此,能夠簡化構成、削減成本。 By constructing in this manner, the velocity dimension signal can be simply obtained by the differentiator. Therefore, it is possible to simplify the configuration and reduce the cost.

又,本發明之實施形態之伺服馬達控制裝置1之特徵在於,伺服馬達速度維度信號輸出部120將藉由觀測器300算出之速度推定信號作為速度維度信號輸出,上述觀測器300係根據向模型之控制對象輸入之輸入信號與控制對象之輸出信號來推定速度。 Further, the servo motor control device 1 according to the embodiment of the present invention is characterized in that the servo motor speed dimension signal output unit 120 outputs a speed estimation signal calculated by the observer 300 as a velocity dimension signal, and the observer 300 is based on a model. The input signal input to the control object and the output signal of the control object are used to estimate the speed.

藉由以此方式構成,即使於不採用伺服馬達速度維度信號輸出電路120而採用觀測器300之構成中,亦可進行衝突檢測。 With this configuration, collision detection can be performed even in the configuration in which the observer 300 is employed without using the servo motor speed dimension signal output circuit 120.

又,本發明之實施形態之伺服馬達控制裝置1之特徵在於,具備第二反饋路徑270,該第二反饋路徑270係算出向位置指令之值乘以比例增益後得到之信號與由位置檢測感測器檢測到之位置信號經微分濾波器要素240微分後之信號之偏差之反饋迴路,伺服馬達速度維度信號輸出部120將配設在第二反饋路徑270內之微分濾波器要素240之輸出信號作為速度維度信號輸出。 Further, the servo motor control device 1 according to the embodiment of the present invention includes a second feedback path 270 that calculates a signal obtained by multiplying a value of a position command by a proportional gain and a sense of position detection. a feedback loop of the deviation of the signal after the position signal detected by the detector is differentiated by the differential filter element 240, and the servo motor speed dimension signal output unit 120 outputs the output signal of the differential filter element 240 disposed in the second feedback path 270. Output as a speed dimension signal.

藉由以此方式構成,由於可將反饋迴路內之輸出直接作為速度 維度信號使用,因此能夠簡化運算,從而能夠簡化構成、削減成本。 By constructing in this way, the output in the feedback loop can be directly used as the speed Since the dimension signal is used, the calculation can be simplified, and the configuration can be simplified and the cost can be reduced.

又,本發明之實施形態之伺服馬達控制裝置1之特徵在於,第一衝突檢測部130算出將對位置指令值乘以比例增益而得到之信號與由位置檢測感測器檢測到之位置信號經微分後之信號之差分值作為擬似速度偏差來代替速度偏差,並於擬似速度偏差之絕對值達到特定值以上之情形時,檢測為衝突。 Further, the servo motor control device 1 according to the embodiment of the present invention is characterized in that the first collision detecting unit 130 calculates a signal obtained by multiplying the position command value by the proportional gain and a position signal detected by the position detecting sensor. The difference value of the signal after the differentiation is used as the pseudo-velocity deviation instead of the speed deviation, and when the absolute value of the pseudo-velocity deviation reaches a certain value or more, it is detected as a collision.

藉由以此方式構成,由於可將傳遞函數之運算中途之值即擬似速度偏差直接作為速度維度信號使用,因此能夠簡化運算,從而能夠簡化構成、削減成本。 According to this configuration, since the value of the transfer function, that is, the pseudo-speed deviation, can be directly used as the velocity dimension signal, the calculation can be simplified, and the configuration and cost can be simplified.

又,本發明之實施形態之伺服馬達控制裝置1之特徵在於,第二衝突檢測部160算出將擬似速度偏差經微分後之信號作為擬似加速度偏差來代替加速度偏差,並於擬似加速度偏差之絕對值達到特定值以上之情形時,檢測為衝突。 Further, the servo motor control device 1 according to the embodiment of the present invention is characterized in that the second collision detecting unit 160 calculates a signal obtained by differentiating the pseudo-velocity deviation as a pseudo-acceleration deviation instead of the acceleration deviation, and the absolute value of the pseudo-acceleration deviation. When a situation above a certain value is reached, it is detected as a conflict.

藉由以此方式構成,由於僅對傳遞函數之運算中途之值實施微分便可將擬似加速度偏差直接作為加速度維度信號使用,因此能夠簡化運算,從而能夠簡化構成、削減成本。 According to this configuration, since the pseudo-acceleration deviation can be directly used as the acceleration dimension signal by differentiating only the value in the middle of the calculation of the transfer function, the calculation can be simplified, and the configuration can be simplified and the cost can be reduced.

又,本發明之實施形態之伺服馬達控制裝置1之特徵在於,選擇部180根據自外部設定之參數,選擇第一衝突檢測部130、第二衝突檢測部160以及第三衝突檢測部170中之任意一個。 Further, the servo motor control device 1 according to the embodiment of the present invention is characterized in that the selection unit 180 selects the first collision detecting unit 130, the second collision detecting unit 160, and the third collision detecting unit 170 based on parameters set from the outside. anyone.

藉由以此方式構成,能夠隨時自外部設定使用適合哪一種衝突檢測之電路。因此,變更之負載減少,從而能夠簡單地變更衝突檢測之方式。 By configuring in this manner, it is possible to externally set a circuit suitable for which collision detection is appropriate. Therefore, the load of the change is reduced, and the method of collision detection can be easily changed.

又,本發明之實施形態之伺服馬達控制裝置1之特徵在於,選擇部180之第一衝突檢測部130之特定值、第二衝突檢測部160之特定值以及第三衝突檢測部170之特定值係自外部設定。 Further, the servo motor control device 1 according to the embodiment of the present invention is characterized in that the specific value of the first collision detecting unit 130 of the selecting unit 180, the specific value of the second collision detecting unit 160, and the specific value of the third collision detecting unit 170. It is set from the outside.

藉由以此方式構成,亦可隨時自外部設定特定值之設定。因 此,變更負載減少,從而能夠簡單地變更作為衝突檢測之閾值之特定值。 By configuring in this way, it is also possible to set a specific value from the outside at any time. because Thus, by changing the load reduction, it is possible to easily change the specific value as the threshold of the collision detection.

又,本發明之實施形態之伺服馬達控制裝置1之特徵在於,速度維度信號係包含以1/(τ s+1)為傳遞函數之要素作為控制系統100之模型之濾波器112之信號。 Further, the servo motor control device 1 according to the embodiment of the present invention is characterized in that the velocity dimension signal includes a signal of a filter 112 having a transfer function of 1/(τ s+1) as a model of the control system 100.

藉由以此方式構成,可使控制模型之要素包含於濾波器112,且可將位置指令值或速度指令值用作輸入至實際之控制對象之值。藉此,可擬似地獲得與實際之信號接近之信號,從而與先前相比,能夠高精度地進行衝突檢測。 By configuring in this manner, the elements of the control model can be included in the filter 112, and the position command value or the speed command value can be used as the value input to the actual control object. Thereby, a signal close to the actual signal can be pseudo-obtained, so that collision detection can be performed with higher precision than before.

又,本發明之實施形態之伺服馬達控制裝置1之特徵在於,濾波器112自外部設定截止頻率。 Further, the servo motor control device 1 according to the embodiment of the present invention is characterized in that the filter 112 sets the cutoff frequency from the outside.

藉由以此方式構成,由於能夠隨時自外部設定截止頻率,因此變更負載減少。又,能夠結合伺服馬達20適當並簡單地選擇截止頻率。再者,如上所述,亦可根據伺服增益之設定值來算出該截止頻率。 According to this configuration, since the cutoff frequency can be set from the outside at any time, the load change is reduced. Further, the cutoff frequency can be appropriately and simply selected in conjunction with the servo motor 20. Furthermore, as described above, the cutoff frequency can also be calculated from the set value of the servo gain.

又,本發明之實施形態之衝突檢測方法之特徵在於,其係由具備使動作對象物動作之伺服馬達20及根據位置指令對上述伺服馬達20進行控制之伺服馬達控制部10之伺服馬達控制裝置1執行者,且包含:輸出與上述位置指令對應之速度維度信號,輸出上述伺服馬達20之速度維度信號,並算出所輸出之對應於上述位置指令之速度維度信號與所輸出之上述伺服馬達20之速度維度信號之差分值即速度偏差,輸出與上述位置指令對應之加速度維度信號,輸出上述伺服馬達20之加速度維度信號,並算出所輸出之對應於上述位置指令之加速度維度信號與所輸出之上述伺服馬達20之加速度維度信號之差分值即加速度偏差,並於根據特定之參數選擇之上述速度偏差以及加速度偏差中之任一個絕對值達到特定值以上之情形時,檢測為衝突,藉由以此方式 構成,能夠根據應用程式之用途等適當地選擇並使用衝突檢測之方式。因此,能夠提高衝突檢測之精度。 Further, the collision detecting method according to the embodiment of the present invention is characterized in that the servo motor 20 including the servo motor 20 for operating the object and the servo motor control unit 10 for controlling the servo motor 20 based on the position command is provided. An executor, comprising: outputting a speed dimension signal corresponding to the position command, outputting a speed dimension signal of the servo motor 20, and calculating a output speed dimension signal corresponding to the position command and the output servo motor 20; The differential value of the velocity dimension signal, that is, the velocity deviation, outputs an acceleration dimension signal corresponding to the position command, outputs an acceleration dimension signal of the servo motor 20, and calculates an output acceleration dimension signal corresponding to the position command and the output. The difference value of the acceleration dimension signal of the servo motor 20, that is, the acceleration deviation, is detected as a conflict when the absolute value of the speed deviation and the acceleration deviation selected according to the specific parameter reaches a certain value or more. This way In the configuration, it is possible to appropriately select and use the method of collision detection depending on the use of the application or the like. Therefore, the accuracy of collision detection can be improved.

〔其他實施形態〕 [Other Embodiments]

再者,於上述之實施形態中,對伺服馬達20之衝突檢測之例進行了說明。 Furthermore, in the above-described embodiment, an example of collision detection of the servo motor 20 has been described.

但,本發明之衝突檢測方法亦可用於檢測控制系統100變得不穩定而引起振動等之狀態之用途。藉此,能夠使伺服馬達20之控制針對於外部干擾等而穩定。 However, the collision detecting method of the present invention can also be used for detecting the state in which the control system 100 becomes unstable and causes vibration or the like. Thereby, the control of the servo motor 20 can be stabilized with respect to external disturbance or the like.

並且,於上述之實施形態中,記載了藉由第一衝突檢測部130、第二衝突檢測部160以及第三衝突檢測部170,將速度偏差之絕對值、加速度偏差之絕對值以及加速度維度信號之絕對值與特定值進行比較來實施衝突檢測。 Further, in the above-described embodiment, the absolute value of the speed deviation, the absolute value of the acceleration deviation, and the acceleration dimension signal are described by the first collision detecting unit 130, the second collision detecting unit 160, and the third collision detecting unit 170. The absolute value is compared to a specific value to implement collision detection.

但,亦可構成為:於將速度偏差之絕對值、加速度偏差之絕對值以及加速度維度信號之絕對值輸入至選擇電路180,藉由檢測方法選擇設定191選擇使用哪一個絕對值後,由參數設定部190之特定值設定192設定之值達到特定值以上之情形時,利用選擇部180後之比較器等檢測為衝突。藉由以此方式構成,能夠藉由一個比較器對衝突檢測之輸出進行處理,從而能夠縮小電路規模、削減成本。 However, the absolute value of the speed deviation, the absolute value of the acceleration deviation, and the absolute value of the acceleration dimension signal may be input to the selection circuit 180, and the absolute value of the absolute value may be selected by the detection method selection setting 191. When the value set by the specific value setting 192 of the setting unit 190 reaches a predetermined value or more, the comparator or the like after the selection unit 180 detects a collision. According to this configuration, the output of the collision detection can be processed by one comparator, whereby the circuit scale can be reduced and the cost can be reduced.

再者,上述實施形態之構成以及動作為一例,當然於不脫離本發明之主旨之範圍內可實施適當之變更。 In addition, the configuration and operation of the above-described embodiment are merely examples, and it is a matter of course that appropriate modifications can be made without departing from the spirit and scope of the invention.

10a‧‧‧伺服馬達控制部 10a‧‧‧Servo Motor Control Department

20‧‧‧伺服馬達 20‧‧‧Servo motor

30‧‧‧檢測部 30‧‧‧Detection Department

100‧‧‧控制系統 100‧‧‧Control system

110a‧‧‧位置指令速度維度信號輸出部 110a‧‧‧ Position command speed dimension signal output

111‧‧‧微分器 111‧‧‧Differentiator

112‧‧‧濾波器 112‧‧‧ filter

120‧‧‧伺服馬達速度維度信號輸出部 120‧‧‧Servo motor speed dimension signal output

130‧‧‧第一衝突檢測部 130‧‧‧First Conflict Detection Department

140a‧‧‧位置指令加速度維度轉換部 140a‧‧‧ Position Command Acceleration Dimensional Conversion Unit

150‧‧‧伺服馬達加速度維度轉換部 150‧‧‧Servo motor acceleration dimension conversion unit

160‧‧‧第二衝突檢測部 160‧‧‧Second Conflict Detection Department

170‧‧‧第三衝突檢測部 170‧‧‧ Third Conflict Detection Department

180‧‧‧選擇部 180‧‧‧Selection Department

190‧‧‧參數設定部 190‧‧‧Parameter Setting Department

191‧‧‧檢測方法選擇設定 191‧‧‧Test method selection setting

192‧‧‧特定值設定 192‧‧‧Specific value setting

193‧‧‧截止設定 193‧‧‧ cut-off setting

Claims (23)

一種伺服馬達控制裝置,其特徵在於其係具備使動作對象物動作之伺服馬達及根據位置指令對上述伺服馬達進行控制之伺服馬達控制部者,上述伺服馬達控制部具備:位置指令速度維度信號輸出部,其輸出與上述位置指令對應之速度維度信號;伺服馬達速度維度信號輸出部,其輸出上述伺服馬達之速度維度信號;第一衝突檢測部,其於由上述位置指令速度維度信號輸出部輸出之速度維度信號、與由上述伺服馬達速度維度信號輸出部輸出之速度維度信號之差分值即速度偏差值之絕對值達到特定值以上之情形時,檢測為衝突;位置指令加速度維度轉換部,其將由上述位置指令速度維度信號輸出部輸出之速度維度信號轉換為加速度維度信號並輸出;伺服馬達加速度維度轉換部,其將由上述伺服馬達速度維度信號輸出部輸出之速度維度信號轉換為加速度維度信號並輸出;第二衝突檢測部,其於由上述位置指令加速度維度轉換部輸出之加速度維度信號、與由上述伺服馬達加速度維度轉換部輸出之加速度維度信號之差分值即加速度偏差之絕對值達到特定值以上之情形時,檢測為衝突;以及選擇部,其根據特定之參數,選擇上述第一衝突檢測部與上述第二衝突檢測部。 A servo motor control device including a servo motor that operates an object to be operated and a servo motor control unit that controls the servo motor based on a position command, wherein the servo motor control unit includes a position command speed dimension signal output a speed dimension signal corresponding to the position command; a servo motor speed dimension signal output unit that outputs a speed dimension signal of the servo motor; and a first collision detecting unit that outputs the position command speed dimension signal output unit When the absolute value of the speed difference signal, which is a difference value between the speed dimension signal output from the servo motor speed dimension signal output unit, is equal to or greater than a specific value, the collision is detected; the position command acceleration dimension conversion unit is Converting the speed dimension signal outputted by the position command speed dimension signal output unit into an acceleration dimension signal and outputting; the servo motor acceleration dimension conversion unit converting the speed dimension signal output by the servo motor speed dimension signal output unit into the acceleration dimension And outputting a signal; the second collision detecting unit is configured to obtain an absolute value of an acceleration value of the acceleration dimension signal output by the position command acceleration dimension conversion unit and the acceleration dimension signal output by the servo motor acceleration dimension conversion unit When the specific value is equal to or greater than the specific value, the collision is detected; and the selection unit selects the first collision detecting unit and the second collision detecting unit based on the specific parameter. 如請求項1之伺服馬達控制裝置,其中上述伺服馬達控制部進而具備第三衝突檢測部,該第三衝突檢測部於由上述伺服馬達加速度維度轉換部輸出之加速度維度信號之絕對值達到特定值以上之情形時,檢測為衝突,上述選擇部根據上述特定之參數亦選擇上述第三衝突檢測部。 The servo motor control device according to claim 1, wherein the servo motor control unit further includes a third collision detecting unit that reaches a specific value of an absolute value of an acceleration dimension signal output by the servo motor acceleration dimension conversion unit. In the case of the above, the detection is a collision, and the selection unit selects the third collision detecting unit based on the specific parameter. 如請求項1之伺服馬達控制裝置,其中上述伺服馬達速度維度信號輸出部將由檢測上述伺服馬達之位置之位置檢測感測器檢測到之位置信號經微分後之信號,作為速度維度信號輸出。 The servo motor control device according to claim 1, wherein the servo motor speed dimension signal output unit outputs a signal obtained by differentiating the position signal detected by the position detecting sensor that detects the position of the servo motor as a speed dimension signal. 如請求項1之伺服馬達控制裝置,其中上述伺服馬達速度維度信號輸出部將藉由速度觀測器算出之速度推定信號,作為速度維度信號輸出,上述速度觀測器係根據向模型之控制對象輸入之輸入信號與上述控制對象之輸出信號來推定速度。 The servo motor control device according to claim 1, wherein the servo motor speed dimension signal output unit outputs a speed estimation signal calculated by the speed observer as a speed dimension signal, and the speed observer inputs the control object according to the model. The input signal and the output signal of the above control object are used to estimate the speed. 如請求項1之伺服馬達控制裝置,其具備反饋迴路,該反饋迴路算出向上述位置指令之值乘以比例增益後得到之信號、與由上述位置檢測感測器檢測到之位置信號經微分濾波器微分後之信號的偏差,上述伺服馬達速度維度信號輸出部將配設在上述反饋迴路內之上述微分濾波器之輸出信號,作為速度維度信號輸出。 A servo motor control device according to claim 1, comprising: a feedback loop that calculates a signal obtained by multiplying a value of the position command by a proportional gain, and a differential signal filtered by a position signal detected by the position detecting sensor The servo motor speed dimension signal output unit outputs the output signal of the differential filter disposed in the feedback loop as a velocity dimension signal. 如請求項3至5中任一項之伺服馬達控制裝置,其中上述第一衝突檢測部算出向上述位置指令之值乘以比例增益後得到之信號、與上述位置檢測感測器檢測到之位置信號經微分後之信號之差分值作為擬似速度偏差來代替上述速度偏差,並於該擬似速度偏差之絕對值達到特定值以上之情形時,檢測 為衝突。 The servo motor control device according to any one of claims 3 to 5, wherein the first collision detecting unit calculates a signal obtained by multiplying a value of the position command by a proportional gain, and a position detected by the position detecting sensor The difference value of the signal after the differential signal is used as the pseudo-velocity deviation instead of the above-mentioned speed deviation, and when the absolute value of the pseudo-velocity deviation reaches a certain value or more, the detection is performed. For conflict. 如請求項6上述之伺服馬達控制裝置,其中上述第二衝突檢測部算出上述擬似速度偏差經微分後之信號作為擬似加速度偏差來代替上述加速度偏差,並於該擬似加速度偏差之絕對值達到特定值以上之情形時,檢測為衝突。 The servo motor control device according to claim 6, wherein the second collision detecting unit calculates a signal obtained by differentiating the pseudo-velocity deviation as a pseudo-acceleration deviation instead of the acceleration deviation, and the absolute value of the pseudo-acceleration deviation reaches a specific value. In the above case, the detection is a conflict. 如請求項2之伺服馬達控制裝置,其中上述選擇部根據自外部設定之上述參數,選擇上述第一衝突檢測部、上述第二衝突檢測部以及上述第三衝突檢測部中之任一個。 The servo motor control device according to claim 2, wherein the selection unit selects one of the first collision detecting unit, the second collision detecting unit, and the third collision detecting unit based on the parameter set from the outside. 如請求項2之伺服馬達控制裝置,其中上述選擇部之上述第一衝突檢測部之特定值、上述第二衝突檢測部之特定值以及上述第三衝突檢測部之特定值係自外部設定。 The servo motor control device according to claim 2, wherein the specific value of the first collision detecting unit of the selection unit, the specific value of the second collision detecting unit, and the specific value of the third collision detecting unit are set externally. 如請求項1之伺服馬達控制裝置,其中上述速度維度信號係包含以1/(τ s+1)為傳遞函數之要素作為控制系統模型之濾波器之信號。 The servo motor control device of claim 1, wherein the velocity dimension signal comprises a signal having a transfer function of 1/(τ s+1) as a filter of a control system model. 如請求項10之伺服馬達控制裝置,其中上述濾波器係自外部設定截止頻率。 The servo motor control device of claim 10, wherein the filter is configured to set a cutoff frequency from the outside. 一種衝突檢測方法,其特徵在於其係由具備使動作對象物動作之伺服馬達及根據位置指令來控制上述伺服馬達之伺服馬達控制部之伺服馬達控制裝置執行者,且包含輸出與上述位置指令對應之速度維度信號,輸出上述伺服馬達之速度維度信號,算出所輸出之與上述位置指令對應之速度維度信號、與所輸出之上述伺服馬達之速度維度信號之差分值即速度偏差,輸出與上述位置指令對應之加速度維度信號, 輸出上述伺服馬達之加速度維度信號,算出所輸出之與上述位置指令對應之加速度維度信號、與所輸出之上述伺服馬達之加速度維度信號之差分值即加速度偏差,於根據特定之參數選擇之上述速度偏差及加速度偏差中之任一者之絕對值達到特定值以上之情形時,檢測為衝突。 A collision detecting method comprising: a servo motor including a servo motor that operates an object to be operated; and a servo motor control device that controls a servo motor control unit of the servo motor according to a position command, and includes an output corresponding to the position command a velocity dimension signal, outputting a velocity dimension signal of the servo motor, calculating a velocity deviation of a velocity dimension signal corresponding to the position command outputted from the position command and a speed dimension signal of the output servo motor, and outputting the position and the position The acceleration dimension signal corresponding to the instruction, And outputting an acceleration dimension signal of the servo motor, and calculating an acceleration dimension signal corresponding to the position command and a difference value of the acceleration dimension signal of the servo motor output, that is, the speed difference selected according to the specific parameter When the absolute value of any of the deviation and the acceleration deviation reaches a certain value or more, the collision is detected. 一種伺服馬達控制裝置,其特徵在於其係具備使動作對象物動作之伺服馬達及根據位置指令對上述伺服馬達進行控制之伺服馬達控制部者,且上述伺服馬達控制部具備:速度指令速度維度信號輸出部,其輸出與上述速度指令對應之速度維度信號;伺服馬達速度維度信號輸出部,其輸出上述伺服馬達之速度維度信號;第一衝突檢測部,其於由上述速度指令速度維度信號輸出部輸出之速度維度信號、與由上述伺服馬達速度維度信號輸出部輸出之速度維度信號之差分值即速度偏差值之絕對值達到特定值以上之情形時,檢測為衝突;速度指令加速度維度轉換部,其將由上述速度指令速度維度信號輸出部輸出之速度維度信號轉換為加速度維度信號並輸出;伺服馬達加速度維度轉換部,其將由上述伺服馬達速度維度信號輸出部輸出之速度維度信號轉換為加速度維度信號並輸出;第二衝突檢測部,其於由上述速度指令加速度維度轉換部輸出之加速度維度信號、與由上述伺服馬達加速度維度轉換部輸 出之加速度維度信號之差分值即加速度偏差之絕對值達到特定值以上之情形時,檢測為衝突;以及選擇部,其根據特定之參數來選擇上述第一衝突檢測部與上述第二衝突檢測部。 A servo motor control device including a servo motor that operates an object to be operated and a servo motor control unit that controls the servo motor according to a position command, and the servo motor control unit includes a speed command speed dimension signal An output unit that outputs a speed dimension signal corresponding to the speed command; a servo motor speed dimension signal output unit that outputs a speed dimension signal of the servo motor; and a first collision detecting unit that is configured by the speed command speed dimension signal output unit When the absolute value of the output speed dimension signal and the speed difference value outputted by the servo motor speed dimension signal output unit, that is, the speed deviation value reaches a certain value or more, the collision is detected; the speed command acceleration dimension conversion unit, The speed dimension signal outputted by the speed command speed dimension signal output unit is converted into an acceleration dimension signal and output; the servo motor acceleration dimension conversion unit converts the speed dimension signal output by the servo motor speed dimension signal output unit into an acceleration. Signal component, and; second collision detection unit, in which the speed command by the acceleration output of the acceleration dimensional conversion unit dimension signal, and output by the servo motor acceleration conversion section dimensions When the difference value of the acceleration dimension signal, that is, the absolute value of the acceleration deviation reaches a certain value or more, the detection is a collision; and the selection unit selects the first collision detection unit and the second collision detection unit according to the specific parameter. . 如請求項13之伺服馬達控制裝置,其中上述伺服馬達控制部進而具備第三衝突檢測部,該第三衝突檢測部於由上述伺服馬達加速度維度轉換部輸出之加速度維度信號之絕對值達到特定值以上之情形時,檢測為衝突,上述選擇部根據上述特定之參數亦選擇上述第三衝突檢測部。 The servo motor control device according to claim 13, wherein the servo motor control unit further includes a third collision detecting unit that reaches a specific value of an absolute value of an acceleration dimension signal output by the servo motor acceleration dimension conversion unit. In the case of the above, the detection is a collision, and the selection unit selects the third collision detecting unit based on the specific parameter. 如請求項13之伺服馬達控制裝置,其中上述伺服馬達速度維度信號輸出部將由檢測上述伺服馬達之位置之位置檢測感測器檢測到之位置信號經微分後之信號作為速度維度信號輸出。 The servo motor control device of claim 13, wherein the servo motor speed dimension signal output portion outputs a signal obtained by differentiating the position signal detected by the position detecting sensor that detects the position of the servo motor as a speed dimension signal. 如請求項13之伺服馬達控制裝置,其中上述伺服馬達速度維度信號輸出部將藉由速度觀測器算出之速度推定信號作為速度維度信號輸出,上述速度觀測器係根據向模型之控制對象輸入之輸入信號與上述控制對象之輸出信號推定速度。 The servo motor control device according to claim 13, wherein the servo motor speed dimension signal output unit outputs a speed estimation signal calculated by the speed observer as a speed dimension signal, wherein the speed observer is input according to a control object input to the model. The signal and the output signal of the above control object are estimated speed. 如請求項13之伺服馬達控制裝置,其具備反饋迴路,該反饋迴路算出向上述位置指令之值乘以比例增益後得到之信號、與由上述位置檢測感測器檢測到之位置信號經微分濾波器微分後之信號的偏差,上述伺服馬達速度維度信號輸出部將配設在上述反饋迴路內之上述微分濾波器之輸出信號作為速度維度信號輸出。 The servo motor control device of claim 13 further comprising: a feedback loop that calculates a signal obtained by multiplying the value of the position command by a proportional gain, and a differential signal filtered by a position signal detected by the position detecting sensor The servo motor speed dimension signal output unit outputs the output signal of the differential filter disposed in the feedback loop as a speed dimension signal. 如請求項15至17中任一項之伺服馬達控制裝置,其中 上述第一衝突檢測部算出向上述位置指令之值乘以比例增益後得到之信號、與由上述位置檢測感測器檢測到之位置信號經微分後之信號之差分值作為擬似速度偏差來代替上述速度偏差,並於上述擬似速度偏差之絕對值達到特定值以上之情形時,檢測為衝突。 A servo motor control device according to any one of claims 15 to 17, wherein The first collision detecting unit calculates a difference value between a signal obtained by multiplying a value of the position command by a proportional gain and a signal differentiated by a position signal detected by the position detecting sensor as a pseudo speed deviation instead of the above The speed deviation is detected as a collision when the absolute value of the pseudo-speed deviation is above a certain value. 如請求項18之伺服馬達控制裝置,其中上述第二衝突檢測部算出上述擬似速度偏差經微分後之信號作為擬似加速度偏差來代替上述加速度偏差,並於上述擬似速度偏差之絕對值達到特定值以上之情形時,檢測為衝突。 The servo motor control device according to claim 18, wherein the second collision detecting unit calculates a signal obtained by differentiating the pseudo-velocity deviation as a pseudo-acceleration deviation instead of the acceleration deviation, and the absolute value of the pseudo-velocity deviation reaches a specific value or more In the case of a situation, it is detected as a conflict. 如請求項14之伺服馬達控制裝置,其中上述選擇部係根據自外部設定之上述參數,選擇上述第一衝突檢測部、上述第二衝突檢測部以及上述第三衝突檢測部中之任意一個。 The servo motor control device according to claim 14, wherein the selection unit selects one of the first collision detecting unit, the second collision detecting unit, and the third collision detecting unit based on the parameter set from the outside. 如請求項14之伺服馬達控制裝置,其中上述選擇部之上述第一衝突檢測部之特定值、上述第二衝突檢測部之特定值以及上述第三衝突檢測部之特定值係自外部設定。 The servo motor control device according to claim 14, wherein the specific value of the first collision detecting unit, the specific value of the second collision detecting unit, and the specific value of the third collision detecting unit are set from the outside. 如請求項13之伺服馬達控制裝置,其中上述速度維度信號係包含以1/(τ s+1)為傳遞函數之要素作為控制系統模型之濾波器之信號。 The servo motor control device of claim 13, wherein the velocity dimension signal comprises a signal having a transfer function of 1/(τ s+1) as a filter of a control system model. 如請求項22之伺服馬達控制裝置,其中上述濾波器係自外部設定截止頻率。 The servo motor control device of claim 22, wherein the filter is configured to set a cutoff frequency from the outside.
TW105108868A 2015-03-31 2016-03-22 Servo motor control device and conflict detection method TWI716390B (en)

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