• Title/Summary/Keyword: Position/force Control

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A Design and Implementation of Position Based Impedance Controller with Self-Adjusted Impedance Parameters (임피던스 파라미터의 자기 조절 기능을 갖는 위치 기반 임피던스 제어기의 설계 및 적용)

  • 황인호;박영칠
    • 제어로봇시스템학회:학술대회논문집
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    • 2000.10a
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    • pp.410-410
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    • 2000
  • Impedance control is recognised as one of the most proper control scheme to carry out the assembly tasks, since it can control the dynamic relationship between the manipulator and environment directly. However, it is well known that the contact force cannot be controlled directly using the impedance control. Also impedance parameters should be properly defined depending on the task to be performed. We propose a new position based impedance control, which has self-adjusted impedance parameters and can control the contact force explicitly, Impedance parameters, as time-varying parameters, are adjusted automatically based on the measured contact force and the position error during the task. A proposed algorithm was implemented on the peg-in-hole task with the industrial manipulator. We shows the effectiveness of proposed control method experimentally.

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A Study on Hybrid(Position/Force) Control of Robot Using Time Delay Control (시간지연제어기법을 이용한 로봇의 혼합(위치/힘) 제어에 관한 연구)

  • 장평훈;박병석;박주이
    • Transactions of the Korean Society of Mechanical Engineers
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    • v.18 no.10
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    • pp.2554-2566
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    • 1994
  • Robot position/force control has been a difficult task owing to the interaction between a robot and an environment with a rather high stiffness. In addition to the dynamic instability, the interaction causes the following problem : 1) chattering at steady-state, 2) dynamic coupling effect of robot, and 3) performance degradation due to a titled environment. To solve the problem, the Time Delay Control(TDC), which has been known to be quiet robust to plant uncertainties and disturbances, has been applied. In conjunction to TDC, the following three ideas were also used : 1) To reduce the amplitude of the chattering at the steady state, a novel scheme was adopted to enhance the resolution type solution of A/D conversion for the force sensor. 2) To reduce the dynamic coupling, a trajectory type position command was tried on a comparative basis to the step command, as well as a more accurate mass matrix was used instead of the constant mass matrix. 3) And finally to improve the performance in the tilted environment, force derivatives instead of position derivatives were used in the TDC law. Computer simulations and experiments resulted in obvious improvements on the quality of the hybrid control, thereby clearly demonstrating the effectiveness of TDC with the proposed ideas.

Simultaneous Trajectory Tracking Control of Position and Force with Pneumatic Cylinder Driving Apparatus

  • Jang Ji Seong
    • Journal of Mechanical Science and Technology
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    • v.19 no.5
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    • pp.1107-1115
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    • 2005
  • In this study, a position and force simultaneous trajectory tracking control algorithm is proposed for a driving apparatus that consists of two pneumatic cylinders connected in series. The controller applied to the driving apparatus is composed of a non-interaction controller to compensate for interaction between cylinders and a disturbance observer aimed to reduce the effect of model discrepancy that cannot be compensated by the non-interaction controller. The effectiveness of the proposed control algorithm is proved by experimental results.

A Force Reflecting Position Control for Teleoperation Systems with Signal Transmission Time Delay (신호전송 시간지연을 갖는 원격조작시스템의 힘반영 위치제어)

  • 안성호;진재현;박병석;윤지섭
    • Proceedings of the IEEK Conference
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    • 2002.06e
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    • pp.157-160
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    • 2002
  • When the teleoperation system has a signal transmission time delay between slave system and control system, the position tracking performance of the slave system and system stability are likely to be deteriorated. This paper proposes a force reflecting position control scheme for teleoperation system with signal transmission time delay. The proposed scheme not only satisfy the system internal stability but also improves the position tracking performance with disturbance rejection capability. The simulation results show that the proposed control method provides excellent performances.

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Implementation and experiment of bilateral force control for a telemanipulator (원격조작기의 양방향 힘제어의 구현과 실험)

  • 천자홍;정명진
    • 제어로봇시스템학회:학술대회논문집
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    • 1991.10a
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    • pp.838-843
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    • 1991
  • A telemanipulator that reflects grasping force of the slave gripper to the human operator was implemented in order for manipulation to be more delicate and safe. An industrial robot gripper was used as the slave manipulator. The master manipulator was constructed to make it easy for a human operator to direct the slave and to feel the reflected gripping force. Reflected force was generated by the servomotor of the master. The force signal and position signals of the master and the slave was used to generate driving force signal. Basically position-position type control was used. Miner force feedback is added to improve the performance of the system. Implemented system was tested by colliding two fingers of the slave manipulator, and here switching was used to archive more fast and easy manipulation.

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Hybrid Position/Force Control for Dynamic Walking of Biped Walking Robot (이족보행로봇의 동적 보행을 위한 혼합 위치/힘 제어)

  • 박인규;김진걸
    • Proceedings of the Korean Society of Precision Engineering Conference
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    • 2000.05a
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    • pp.566-569
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    • 2000
  • This hybrid position/force control for the dynamic walking of the biped robot is performed in this paper. After the biped robot was modeled with 14 degrees of freedom of the multibody dynamics, the equations of motion are constructed using velocity transformation technique. Then the inverse dynamic analysis is performed for determining the driving torques and the ground reaction forces. From this analysis, obtains the maximum ground contact force at the moment of contacting which act on the rear of the sole of swing leg and the distribution curve of the ground reaction. Because these maximum force and distribution type acts an important role to the stability of the whole dynamic walking, they are reduced and distributed smoothly by means of the trajectory of the modified ground reaction force. This new trajectory is used to the reference input for more stable dynamic walking of the whole walking region.

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Position / Force Control of Industrial Robots using the Fuzzy PI Algorithm (퍼지 PI 알고리즘을 이용한 산업용 로봇의 위치/힘 제어)

  • Suh, Il-Hong;Hong, Jong-Hyuck;Oh, Sang-Rok;Kim, Kwang-Bae
    • Proceedings of the KIEE Conference
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    • 1991.07a
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    • pp.795-798
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    • 1991
  • The hybrid positon/force control is required when two or more robots perform a coorperative task in a uncertain environment, or when single robot does a task with a constant force to the environment. In this paper, a new control algorithm which control simultaneously the position and the force are proposed, however, especially the conventional position controller employed in the present robot control is used. Moreover, in order to improve the output response characteristics of the system, the PI gains which were computed from the PI gain tunning techniques, are varied based on the results of the Fuzzy algorithm.

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Position/Force Control of Robotic Manipulator with Fuzzy Compensation (퍼지 보상을 이용한 로봇 매니퓰레이터의 위치/힘제어)

  • 심귀보
    • Journal of the Korean Institute of Intelligent Systems
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    • v.5 no.3
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    • pp.36-51
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    • 1995
  • An approach to robot hybrid position/force control, which allows force manipulations to be realized without overshoot and overdamping while in the presence of unknown environment, is given in this paper. The manin idea is to used dynamic compensation for known robot parts and fuzzy compensation for unknown environment so as to improve system performance. The fuzzy compensation is implemented by using rule based fuzzy approach to identify the unknown environment. The establishment of proposed control system consists of following two stages. First, similar to the resovled acceleration control method, dynamic compensation and PD control based on known robot dynamics, kinematics and estimated environment stiffness is introduced. To avoid overshoot the whole control system is constructed with overdamping. In the second stage, the unknown environment stiffness is identified by using fuzzy reasoning, where the fuzzy compensation rules are obtained priori as the expression of the relationship betweenenvironment stiffness and system. Based on the simulation result, comparison between cases with or without fuzzy identifications are given, which illustrate the improvement achieced.

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A Position Control for a Parallel Stage with 6 degrees of freedom Using Magnetic Actuators (전자기 구동장치를 이용한 병렬형 6자유도 스테이지의 위치제어)

  • Lee Se-Han
    • Journal of the Korean Society for Precision Engineering
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    • v.22 no.7 s.172
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    • pp.102-111
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    • 2005
  • In this paper, we address a position control for a parallel stage, which is levitated and driven by electric magnetic force. This consists of a levitating object (called platen) with 4 permanent magnetic linear synchronous motors in parallel. Each motor generates vertical force for suspension against gravity and propulsion force horizontally as well. This stage can generate six degrees of freedom motion by the vertical and horizontal force. A dynamic equation of the stage system is derived based on Newton-Euler method and it's special Jacobian matrix describing a relation between the limited velocity and Cartesian velocity is done. There are proposed two control methods for positioning which are Cartesian space controller and Actuator space controller. The control performance of the Cartesian space controller is better than the Actuator space controller in task space trajectory while the Actuator space controller is simpler than the Cartesian space controller in controller realization.

Force Control of a Blind Mobile Robot: Analysis, Simulations and Experiments (장님 이동 로봇의 힘 제어 : 분석, 시뮬레이션 및 실험)

  • Jeon, Poong-Woo;Jung, Seul
    • Journal of Institute of Control, Robotics and Systems
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    • v.9 no.10
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    • pp.798-807
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    • 2003
  • We propose a blind mobile robot force control algorithm that uses force information as a guidance toward to the goal position. Based on the mobile robot dynamics, the control law is formed from explicit force errors. Simulation studies are conducted based on the kinematics and the dynamics of the mobile robot. Simulation results show that good force tracking can be achieved. In order to confirm simulation results, experiments are performed. The robot is commanded to follow unknown environment with maintaining a certain desired force. Experimental results show that the blind mobile robot successfully maintains contact with a regulated desired force and arrives at the goal position.