Title :
Cerebellar dynamic state estimation for a biomorphic robot arm
Author :
Assad, Christopher ; Dastoor, Sanjay ; Trujillo, Salomon ; Xu, Ling
Author_Institution :
Jet Propulsion Lab., California Inst. of Technol., Pasadena, CA, USA
Abstract :
The cerebellum has been called the brain\´s "engine of agility". This paper presents a cerebellum-inspired neural network that performs dynamic state estimation and predictive control. The model combines two types of learning within a radial basis function network. Its performance was demonstrated on a 2-link robot arm built with antagonistic pairs of McKibben air muscles. The arm has a gripper end effector to hold and throw a tennis ball. Trajectory data was collected during multiple throwing trials and used to train the model offline. The data were projected onto 2-dimensional state space maps, from which the network learns to estimate state variables and decision boundaries. It successfully learned to trigger the grip release at the proper state for the ball to hit a target. This algorithm should generalize to benefit a wide variety of biomorphic robots.
Keywords :
control engineering computing; dexterous manipulators; learning (artificial intelligence); manipulator dynamics; neurocontrollers; predictive control; radial basis function networks; state estimation; 2-link robot arm; 2D state space maps; McKibben actuators; McKibben air muscles; biomorphic robot arm; cerebellar dynamic state estimation; grip release; gripper end effector; neural network; predictive control; radial basis function network; state space methods; Biological neural networks; Brain modeling; Engines; Grippers; Muscles; Orbital robotics; Predictive control; Radial basis function networks; Robots; State estimation; Cerebellum; McKibben actuators; biomorphic robotics; dynamic state estimation; state space methods;
Conference_Titel :
Systems, Man and Cybernetics, 2005 IEEE International Conference on
Print_ISBN :
0-7803-9298-1
DOI :
10.1109/ICSMC.2005.1571257
