Direct sensorimotor control for low-cost mobile tracking applications

A biologically inspired system for tracking objects in a visual scene is presented. The uniqueness of the system is in the absence of a microcontroller to convert sensory information to tracking decisions, reducing power, size, weight, and cost of the overall system. The system consists of a mobile vehicle outfitted with a custom analog VLSI architecture for encoding the position of an object of interest in the vehicles's field of view. Once determined, the object of interest retains hysteresis proportional to its size and intensity to limit the potential for distraction by other objects in the sensing environment. The encoded position of the object of interest is directly converted to a series of motor control signals to drive the vehicle in the direction of the object. The motor drive signals are pulse width modulated to control the speed and direction of travel induced by two de motors via a conventional differential steering arrangement. Neural oscillators are used to drive the de motors to provide a compact single-chip system for tracking bright objects. The nature of the system is sufficiently modular so that it can be adapted relatively easily to tracking other features of visual objects and even to objects representative of other sensing modalities. The system described here is one of the first efforts to fully integrate and apply analog VLSI (aVLSI) sensorimotor control to a mobile vehicle and to analyze the complete system from a control systems' perspective. The system described here has the advantages of aVLSI integration in its small size (0.011-mm/sup 2/ elements), low power (0.3 /spl mu/W per element), and fast system response time (1.5 ms from sensory input to motor response).