The embodiments of present disclosure herein address unresolved problem of cognitive navigation strategies for a telepresence robotic system. This includes giving instruction remotely over network to go to a point in an indoor space, to go an area, to go to an object. Also, human robot interaction to give and understand interaction is not integrated in a common telepresence framework. The embodiments herein provide a telepresence robotic system empowered with a smart navigation which is based on in situ intelligent visual semantic mapping of the live scene captured by a robot. It further presents an edge-centric software architecture of a teledrive comprising a speech recognition based HRI, a navigation module and a real-time WebRTC based communication framework that holds the entire telepresence robotic system together. Additionally, the disclosure provides a robot independent API calls via device driver ROS, making the offering hardware independent and capable of running in any robot.

Example wireless feedback control systems disclosed herein include a receiver to receive a first measurement of a target system via a first wireless link. Disclosed example systems also include a neural network to predict a value of a state of the target system at a future time relative to a prior time associated with the first measurement, the neural network to predict the value of the state of the target system based on the first measurement and a prior sequence of values of a control signal previously generated to control the target system during a time interval between the prior time and the future time, and the neural network to output the predicted value of the state of the target system to a controller. Disclosed example systems further include a transmitter to transmit a new value of the control signal to the target system via a second wireless link.

A method includes providing a virtual representation of an environment of a robot, the virtual representation including an object representation of an object in the environment. The method further includes receiving manipulation input from a user to teleoperate the robot for manipulation of the object. The method also includes alerting the user to an alignment dimension based upon the manipulation input, receiving confirmation input from the user to engage the alignment dimension, and constraining at least one dimension of movement of the object according to the alignment dimension.

For a scalable filtering infrastructure, a library of filters each usable at different control rates is provided by defining filters in a continuous time mode despite eventual use for digital filtering. For implementation, a filter is selected and discretized for the desired control rate. The discretized filter is then deployed as a discrete time realization for convolution. In a distributed system with multiple control rates, the library may be used to more rapidly and conveniently generate the desired filters.

A teaching support device configured to perform teaching to a robot which has a robot arm a tip of which is attached with a polishing tool, and which controls the robot arm with force control to perform a polishing task on an object includes a teaching point acquisition section configured to obtain information related to a plurality of teaching points set to the object, a polishing parameter acquisition section configured to obtain information related to a polishing parameter of the polishing task at the plurality of teaching points obtained by the teaching point acquisition section, and a display control section configured to display the teaching point out of the plurality of teaching points with a color based on the polishing parameter obtained by the polishing parameter acquisition section so as to overlap the object.

According to the present invention, a terminal device has: a transmission unit which transmits, to a robot, operator state information indicating the state of a user operating the robot; a receiving unit which receives, from the robot, robot state information indicating the state of the robot; a sensation imparting unit which imparts a predetermined sensation to the user; and a control unit which, when a delay time required for the receiving unit to receive the robot state information after the transmission unit transmits the operator state information is no longer than a predetermined time, controls the sensation imparting unit so as to impart a sensation based on the robot state information to the user, and when the delay time is longer than the predetermined time, controls the sensation imparting unit to impart, to the user, a sensation based on virtual state information that indicates an estimated robot state.

A mobile character control system includes a platform, a character assembly, a control system, and a transportation assembly. The platform is configured to support an operator. The character assembly is engaged with the platform and includes actuatable features configured to simulate movement of a creature. The control system is configured to control activation of the actuatable features of the character assembly in response to signals received from control features controlled by the operator. The transportation assembly is configured to direct movement of the platform and to support the character assembly.

Shared variable binding and parallel execution of a process and robot workflow activities for robotic process automation (RPA) are disclosed. An RPA robot may be “bound” to a variable that is accessed by and displayed in an application. When the RPA robot is triggered, the RPA robot performs potentially conditional logic that may result in modifications to one or more bound variables. The RPA robot may lookup data, perform calculations, check on the status of other processes, and/or perform any other logical operations. The RPA robot may then modify, delete, or otherwise change the value of one or more bound variables, causing the application associated with those variables to display the results (e.g., when the user interface (UI) of the application is refreshed).

A teleoperated robotic system that includes master control arms, slave arms, and a mobile platform. In use, a user manipulates the master control arms to control movement of the slave arms. The teleoperated robotic system can include two master control arms and two slave arms. The master control arms and the slave arms can be mounted on the platform. The platform can provide support for the master control arms and for a teleoperator, or user, of the robotic system. Thus, a mobile platform can allow the robotic system to be moved from place to place to locate the slave arms in a position for use. Additionally, the user can be positioned on the platform, such that the user can see and hear, directly, the slave arms and the workspace in which the slave arms operate.

In a robotic surgical system, a control device is configured or programmed to perform first scaling on at least a rotational component in a received operation amount, and calculate a rotation angle of a joint axis of a robot arm by performing an inverse kinematics calculation on a translational component and the rotational component after the first scaling is performed.