A method includes presenting a virtual representation of an environment of a robot, receiving a first user command to control the robot within the environment, rendering a predicted version of the virtual representation during a period of latency in which current data pertaining to the environment of the robot is not available, updating the predicted version of the virtual representation based upon a second user command received during the period of latency, and upon conclusion of the period of latency, reconciling the predicted version of the virtual representation with current data pertaining to the environment of the robot.

A robot is configured to move in accordance with an operation instruction made by an operator via a network. The robot includes a moving image acquisition unit, a receiving unit, a movement destination predicting unit, and an autonomous control unit. The moving image acquisition unit is configured to capture, as a moving image, an environment around the robot. The receiving unit is configured to receive the operation instruction. The movement destination predicting unit is configured to predict a movement destination of the robot based on the operation instruction received by the receiving unit. The autonomous control unit is configured to autonomously correct movement to the movement destination in accordance with the operation instruction, based on information on the environment obtained from a moving image at an instant when the operation instruction is received.

When a control message is determined and sent from a master system to a slave system, the control message is accompanied with a time stamp, indicative of the master model version of the environment which was applied when the control data was determined by the master system. When data, triggered by data provided from the environment to the slave system in the form of updated sensor data is provided from the slave system to the master system, also that data, indicative of an updated slave model version of the environment made by the slave system, is provided to the master system, together with a time stamp, indicative of when the update of the slave model version was made. By applying the suggested time stamp, a coordination of model versions can be obtained between the master system and the slave system.

A controller for using a first data item transmitted via a network to generate a second data item for controlling an entity to be controlled over the network, wherein the controller is characterized in being provided with: an adjustment unit for adjusting, with respect to the maximum delay time permissible on the network, the time by which generation of the second data item is started using the first data item after the first data item has been received; and a delay compensation unit, designed using a model of the entity to be controlled and the maximum delay time permissible on the network, for compensating for the delay of the first and second data items that can be generated using the network.

A robot control system includes circuitry configured to: generate a command to a robot; receive a frame image in which a capture position changes according to a motion of the robot based on the command; extract a partial region from the frame image according to the command; superimpose a delay mark on the partial region to generate an operation image; and display the operation image on a display device, so as to represent a delay of the motion of the robot with respect to the command.

A method for using a control center at a remote site to control operation of a robotic medical device system at a local site includes transmitting a control signal from the control center to the robotic medical device system, determining a delay in transmission of the control signal, comparing the delay to a threshold delay value and operating the robotic medical device system based on the comparison of the delay to the threshold delay value.

A method for using a control center at a remote site to control operation of a robotic medical device system at a local site includes transmitting a control signal from the control center to the robotic medical device system, determining a delay in transmission of the control signal, comparing the delay to a threshold delay value and operating the robotic medical device system based on the comparison of the delay to the threshold delay value.

A robotic medical device system includes a robotic medical device and a controller. The controller is configured to control, in response to one or more control signals, movement of the robotic medical device to maintain a substantially constant overshoot for different step responses of the robotic medical device system independent of variations in a delay associated with control of the robotic medical device, the one or more control signals received via a network.