The purpose of the article is to improve the characteristics a radio-controlled object servo drive pool control system in case of communication loss and solve the problems: reduce the transmission time of the driving influence to the object control system, the influence compensate for random disturbances and actuators backlash on the control object based on mathematical statistics methods. The article describes the radio-controlled object control system implementation. It is shown that the operator acts as a regulator. The problems that arise when the connection between the control object and the operator are lost are considered. The influence of random disturbing on the control object is considered. The use of statistical methods in the facility control system is proposed. A statistical method is used that implements the statistical hypotheses theory acceptance. As a hypotheses criterion for the adoption, a likelihood ratio criterion was used. It is shown that in the autonomous mode it is necessary to compensate for backlash and random disturbances. The functional diagram of the control system is developed. The architecture of the control program is developed. The cycle of obtaining the driving action and the control cycle of servos are divided. Reduced response time of the system to a change in the set action value. The receiving cycle the master action has a duration of 0.03 ms. The servo control cycle has a value from 8 ms. Implementation of the developed servo pool management system has shown the effectiveness of the selected architecture for creating software and hardware for radio-controlled robotic systems. Solved tasks to reduce the transmission time of the master object exposure control system to minimize the influence of the time delay cycle master receiving the impact on the duration and servo control loop is provided a synchronous servo control pool.

control system, servo, backlash, object, statistical hypothesis

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