Modeling And Control Of A Hyper Redundant Manipulator

Bayram, Atilla

01 February 2010

The hyper redundant manipulators (HRMs) have excessively large degrees of freedom. As a special but practicable subset, the binary HRMs use binary (on-off) actuators with only two stable states such as pneumatic cylinders and solenoids. Such actuators are simple, cheap, and easy to control. Therefore, a binary HRM has been studied in this thesis. The thesis work covers the conceptual design of a spatial binary HRM together with its controlled motion simulations. The manipulator consists of many modules, each of which has the same constructive characteristics and consists of three submodules which are two cascaded variable geometry truss structures working in mutually orthogonal planes and a discrete twister. The manipulator is assumed to be powered with pneumatic on-off actuators. Because of the discrete nature of the binary actuators, a small but continuously actuated manipulator with six degrees of freedom is installed as the last module of the HRM in order to compensate the discretization errors. To solve the inverse kinematics problem of the HRM, three methods have been presented. These are the spline fitting, the extended spline fitting, and the workspace filling methods. The spline fitting method is based on forcing the spine (i.e. the center line) of the manipulator to approximate a spatial reference spline which is specified as a desired curve. In the extended spline fitting method, the result found in the first method is improved by using a genetic algorithm. In the work space filling method, the workspace of the manipulator is filled randomly with a sufficiently large finite number of discrete configurational samples. If it is desired to have concentration on a particular region of the work space, then that region is filled by using a genetic algorithm. After the filling stage, the sample closest to the desired configuration is determined by a suitable search algorithm. Finally, in order to simulate the motion of the HRM between two successive configurational steps, the equations of motions of the HRM are obtained in terms of the pressure forces generated by the binary pneumatic actuators. Then, the necessary simulations are carried out to demonstrate the performance of the HRM in some typical applications.

Biologically-inspired Motion Control for Kinematic Redundancy Resolution and Self-sensing Exploitation for Energy Conservation in Electromagnetic Devices

Babakeshizadeh, Vahid

January 2014

This thesis investigates particular topics in advanced motion control of two distinct mechanical systems: human-like motion control of redundant robot manipulators and advanced sensing and control for energy-efficient operation of electromagnetic devices. Control of robot manipulators for human-like motions has been one of challenging topics in robot control for over half a century. The first part of this thesis considers methods that exploits robot manipulators??? degrees of freedom for such purposes. Jacobian transpose control law is investigated as one of the well-known controllers and sufficient conditions for its universal convergence are derived by using concepts of ???stability on a manifold??? and ???transferability to a sub-manifold???. Firstly, a modification on this method is proposed to enhance the rectilinear trajectory of the robot end-effector. Secondly, an abridged Jacobian controller is proposed that exploits passive control of joints to reduce the attended degrees of freedom of the system. Finally, the application of minimally-attended controller for human-like motion is introduced. Electromagnetic (EM) access control systems are one of growing electronic systems which are used in applications where conventional mechanical locks may not guarantee the expected safety of the peripheral doors of buildings. In the second part of this thesis, an intelligent EM unit is introduced which recruits the selfsensing capability of the original EM block for detection purposes. The proposed EM device optimizes its energy consumption through a control strategy which regulates the supply to the system upon detection of any eminent disturbance. Therefore, it draws a very small current when the full power is not needed. The performance of the proposed control strategy was evaluated based on a standard safety requirement for EM locking mechanisms. For a particular EM model, the proposed method is verified to realize a 75% reduction in the power consumption.

Controle de Manipulador Redundante Utilizando Realimenta??o Visual

Dias, Anfranserai Morais

02 August 2002

Made available in DSpace on 2014-12-17T14:56:04Z (GMT). No. of bitstreams: 1 AnfranseraiMD.pdf: 2426744 bytes, checksum: d0579aab855282deeac9bb5717c5ab5a (MD5) Previous issue date: 2002-08-02 / In conventional robot manipulator control, the desired path is specified in cartesian space and converted to joint space through inverse kinematics mapping. The joint references generated by this mapping are utilized for dynamic control in joint space. Thus, the end-effector position is, in fact, controlled indirectly, in open-loop, and the accuracy of grip position control directly depends on the accuracy of the available kinematic model. In this report, a new scheme for redundant manipulator kinematic control, based on visual servoing is proposed. In the proposed system, a robot image acquired through a CCD camera is processed in order to compute the position and orientation of each link of the robot arm. The robot task is specified as a temporal sequence of reference images of the robot arm. Thus, both the measured pose and the reference pose are specified in the same image space, and its difference is utilized to generate a cartesian space error for kinematic control purposes. The proposed control scheme was applied in a four degree-of-freedom planar redundant robot arm, experimental results are shown / No controle convencional de manipuladores rob?ticos, a trajet?ria desejada ? especificada em espa?o cartesiano e mapeada para espa?o de juntas atrav?s do modelo cinem?tico inverso do manipulador. As novas refer?ncias assim geradas s?o utilizadas para fins de controle din?mico em espa?o de juntas, desde modo a posi??o da garra ? controlada efetivamente em malha aberta e a precis?o do controle depende diretamente da precis?o do modelo cinem?tico dispon?vel. Esta disserta??o apresenta um novo algoritmo de controle cinem?tico para bra?os redundantes baseado em realimenta??o visual. No sistema proposto, a imagem do rob? ? captada por uma c?mera e processada, para obter a posi??o e orienta??o de cada um dos elos do rob?. A trajet?ria do rob? ? especificada na forma de uma seq??ncia temporal de imagens de refer?ncia do bra?o rob?tico. Assim, ambas as poses, a medida e a de refer?ncia s?o especificadas no mesmo espa?o de imagem e a sua diferen?a ? utilizada para gerar um erro em espa?o cartesiano para prop?sitos de controle cinem?tico. O esquema de controle proposto foi aplicado a um manipulador redundante planar de quatro graus de liberdade, resultados experimentais s?o apresentados

Manipulador Redundante

Realimenta??o Visual

Controle

Servo-vis?o

Redundant Manipulator

Visual Feedback

Control

Servo-vision

CNPQ::ENGENHARIAS::ENGENHARIA ELETRICA

冗長関節アームの協調動作のためのUCM参照フィードバック制御法

UNO, Yoji, KAGAWA, Takahiro, TOGO, Shunta, 宇野, 洋二, 香川, 高弘, 東郷, 俊太

02 1900

No description available.

redundant manipulator

feedback control

redundancy

UCM analysis

joint coordination

冗長マニピュレータ

フィードバック制御

冗長性

UCM解析

関節間協調

Motion planning for redundant manipulators and other high degree-of-freedom systems

Keselman, Leo

22 May 2014

Motion planning for redundant manipulators poses special challenges because the required inverse kinematics are difficult and not complete. This thesis investigates and proposes methods for motion planning for these systems that do not require inverse kinematics and are potentially complete. These methods are also compared in performance to standard inverse kinematics based methods.

Motion planning

RRT

Manipulators

Manipulator

Redundant manipulator

Planning

Inverse kinematics

Kinematics

Robotics

Serial link

Machinery, Kinematics of

Robots Kinematics

Manipulators (Mechanism)

Robots, Industrial

Robots