International Journal of Analysis of Electrical Machines

Robot kinematics defined as the analytical study of the motion of a robots machinist. The
robot control problem can be explained into two main areas: kinematics control (the
coordination of the links of kinematics chain to produce desired motion of the robot), and
dynamics control (driving the actuator of the mechanism to follow the commanded positions
and velocities). Inverse kinematics (IK) is the mathematical process of recode the movements
of an object in the world from some other data, such as a film of those movements, or a film
of the world as noticed by a camera which is itself making those motion. Frequently, the
kinematics analysis is performed in two ways in robotics: (1) forward kinematics (FK), (2)
inverse kinematics (IK). FK is defined as the mapping from joint space to Cartesian space
(also called task space), on the other hand IK is defined as the mapping from Cartesian space
to joint space, i.e., computation needs to find the joint angles for a given Cartesian position
and orientation of the end-effectors.
Keywords: artificial neural network, forward kinematics, movements, Robot control, inverse
kinematics, robot manipulator, task spaces

. Alavandar S. and Nigam M. J. “Neuro-Fuzzy based Approach for Inverse Kinematics Solution of Industrial Robot Manipulators”, Int. J. Of Computers, Communications & Control, ISSN 1841-9836, E-ISSN 1841- 9844 Vol. III (2008), No. 3, pp. 224-234.

. Morris A. S. And A. Mansor A. “Artificial neural network for finding inverse kinematics of robot manipulator using look up table”, Robotica (1997) volume 15, pp. 617 – 625

. Ahmad Z. and Guez A. “On the Solution to the Inverse Kinematic Problem”, department of electrical and computer engineering Drexel University Philadelphia PA 19104.

Bekir Karlik, Serkan Aydin “An improved approach to the solution of inverse kinematics problems for robot manipulator”.

. L. Npyen. “Neural Network Architectures For The Forward Kinematics Problem in Robotics”.

. G. Jaein, “Robot Control Using Neural Network”.

. Jenhwa Guo and Vladimir Cherkassky “Developed A Solution to the Inverse Kinematic Problem in Robotics Using Neural Network Processing” University of Minnesota inneapolis, Minnesok 55455.

. Dali wang and ali zilouchain “Solutions of Kinematics of Robot Manipulators Using a kohonen Self- Organizing Neural Network”. department of Elect. Engineering Florida Atlantic University Boca Raton FL 33431. 57

. Youshen Xia and Jun Wang “A Dual Neural Network for Kinematic Control of Redundant Robot Manipulators”.

. Choon seng Yee, Kah-bin Lim “Forward kinematics solution of Stewart platform Using neural networks”.

. E. A. Al-Gallaf “Neural Networks for Multi-Finger Robot Hand Control”, JKAU: Eng. Sci., Vol. 19 No. 1, pp: 19-42 (2008 A.D. /1429 A.H.)

. Asko Houvinen and Heikki Handroos “ADAMS –Model for training of neural network for inverse kinematics of flexible robot manipulator”.

. H. Daniel Patiño “Neural Networks for Advanced Control of Robot Manipulators”.

. Ted Hesselroth, “Neural Network Control of a Pneumatic Robot Arm”.

. B. Benhabib, “A solution to the inverse kinematics”.

. Oyama and Tachi “Inverse kinematics computation using an artificial neural network”.

. Manocha and Canny “An algorithm and implementation for efficient inverse kinematics for a general 6R manipulator”.

. Kozalziewicz C. Ogiso T. and Miyake N. “Partitioned Neural Network architecture for Inverse Kinematic calculation of a 6 dof robot manipulator”.

. Mayorga V. and Sanongboon P. “Inverse kinematics and geometrically

bounded singularities prevention of redundant manipulators: An Artificial

Neural Network approach”. Robotics and Autonomous Systems 53 (2005)

–176.

. Kieffe S. Morella V. and Donath M. “Neural Network Learning of the Inverse

Kinematic Relationships for a Robot Arm” Proceedings of the 1991 IEEE

Intemational conference on Robotics and Automation Sacramento,

Califomia - April 1991.

. www.wikipedia.com.

. Sponge Mark W., Seth Hutchinson, Vidyasagar M., “Robot Modeling and Control”, pp. 29-33.