BIOLOGICALLY INSPIRED CALIBRATION-FREE ADAPTIVE SACCADE CONTROL OF A BINOCULAR CAMERA-HEAD

This paper describes fast and accurate calibration-free adaptive sacca de control of a four-degrees-of-freedom binocular camera-head by means of Dynamic Cell Structures (DCS). The approach has been inspired by b iology because primates face a similar problem and there is strong evi dence that they have solved it in a similar way, i.e., by error feedba ck learning of an inverse model. Yet the emphasis of this article is n ot on detailed biological modeling but on how incremental growth of ou r artificial neural network model up to a prespecified precision resul ts in very small networks suitable for real-time saccade control. Erro r-feedback-based training of this network proceeds in two phases. In t he first phase we use a crude model of the cameras and the kinematics of the head to learn the topology of the input manifold together with a rough approximation of the control function off-line. In contrast to , for example, Kohonen-type adaptation rules, the distribution of neur al units minimizes the control error and does not merely mimic the inp ut probability density. In the second phase, the operating phase, the linear output units of the network continue to adapt on-line. Besides our TRC binocular camera-head we use a Datacube image processing syste m and a Staubli R90 robot arm for automated training in the second pha se. It will be demonstrated that the controller successfully corrects errors in the model and rapidly adapts to changing parameters.