A robotic system is integrated with one or more mobile computing devices. Physical configurations of individual components of the system in physical space, or agents, under control of a user or users, are duplicated in a representation in virtual space. Some degree of real-time parity is maintained between the physical and virtual spaces, so as to implement a virtual environment that mirrors the physical one. Events occurring within one environment can directly influence and bear consequence on the course of events occurring within the other environment. Elements of virtual space thereby become truly interdependent and unified on a peer footing with elements in physical space. In at least one embodiment, the system is implemented as an application in entertainment, such as the manifestation of a video game in physical space.

In an aspect, a robotic system is provided and includes at least two digital servo modules, each of which includes a position-controlled motor and a position sensor for sensing a servo position, a plurality of building block elements that are connectable with the digital servo modules to create position-controlled joints of a robotic figure, at least two wheel modules enabling wheeled movement of the robotic figure and a central controller communicating with and controlling the digital servo modules and the wheel modules. The central controller operatively places a selected group of digital servo modules in a learned motion mode, wherein a corresponding group of position-controlled joints is enabled to be manually manipulated, and wherein each of the selected digital servo module periodically transmits servomotor position to the central controller. The central controller can steer the robotic figure wheel modules based on servo positions of the selected digital servo modules.

An element having a holding mechanism, adapted for interacting with a functionally aligned holding mechanism of a similar element, and including a holding state and a released state. The holding mechanism in the holding state is engaged with the aligned holding mechanism of the similar element for holding the element positioned with respect to the similar element. The holding element in the released state is disengaged with the aligned holding mechanism. The element also includes a sensing mechanism for providing grab-detection, the grab-detection including detection of an action leading to a grip of the element, having a grip on the element, an action of releasing a grip of the element, and a combination thereof. The sensing mechanism is functionally coupled to the holding mechanism for upon the grab-detection actuating at least one of the functionally aligned holding mechanism between the holding state and the released state.

A robot system includes a primary robot frame including a computerized control module providing control commands for the robot system, the primary robot frame including an outer perimeter. The robot system further includes a plurality of submodules, each submodule capable of being selectively docked with the primary robot frame, the submodules each providing different functionality to the robot system. The submodules, when docked with the primary robot frame, fit within the outer perimeter, enabling the robot system to operate in a closed mode, wherein all movement of the robot system is based upon the outer perimeter.

A manufacturing process adopting the reconfigurable robotic manufacturing cells that can work conjointly and yet have the capabilities to be reconfigured to disconnect from other cells and handle multiple tasks. The reconfigurable robotic cell is not dependent on any other robotic cells to complete work in progress.

Mobile agents automatically manipulate components such as blocks on a working surface, to perform operations such as construction of generalized structures. The working surface and/or the components can have machine-readable codes to assist the agents in maintaining current knowledge of their respective locations. Agents identify components by type and location, and can move components according to directions; such directions can be provided by a user, or can be based on a pre-programmed directive, or can be determined dynamically based on current conditions or in response to actions of other agents. Agents may cooperate with one another. Agents can also respond to changes in the environment, alterations in works in progress, and/or other conditions, and may be configured to exhibit responses simulating emotional reactions. Different mobile agents can be associated with different character traits, which may be configured to change based on environmental conditions and/or the behavior of other mobile agents.

In an aspect, a robotic system is provided and includes at least two digital servo modules, each of which includes a position-controlled motor and a position sensor for sensing a servo position, a plurality of building block elements that are connectable with the digital servo modules to create position-controlled joints of a robotic figure, at least two wheel modules enabling wheeled movement of the robotic figure and a central controller communicating with and controlling the digital servo modules and the wheel modules. The central controller operatively places a selected group of digital servo modules in a learned motion mode, wherein a corresponding group of position-controlled joints is enabled to be manually manipulated, and wherein each of the selected digital servo module periodically transmits servomotor position to the central controller. The central controller can steer the robotic figure wheel modules based on servo positions of the selected digital servo modules.

In an aspect, a robotic system is provided and includes at least two digital servo modules, each of which includes a position-controlled motor and a position sensor for sensing a servo position, a plurality of building block elements that are connectable with the digital servo modules to create position-controlled joints of a robotic figure, at least two wheel modules enabling wheeled movement of the robotic figure and a central controller communicating with and controlling the digital servo modules and the wheel modules. The central controller operatively places a selected group of digital servo modules in a learned motion mode, wherein a corresponding group of position-controlled joints is enabled to be manually manipulated, and wherein each of the selected digital servo module periodically transmits servomotor position to the central controller. The central controller can steer the robotic figure wheel modules based on servo positions of the selected digital servo modules.

An action control device controls movement of a plurality of control subjects. In particular, the present technology relates to a cooperative control of robots. The cooperative control comprises determining an action plan for each of a plurality of robots for respective movements. Given the action plan, the present case enables movements of the respective robots cooperatively from a state of rank formation in starting positions and cause the respective robots to form a rank in target position. In particular, the action plan comprises a set of operations where a plurality of robots extracted by deconstruction of parts of intermediate positions of robots are moved simultaneously to the locations to which the robots are to be added during construction of a subsequent intermediate positions of robots. The set of operations with simultaneous movements enables an increase in the speed of transformation of ranks formed by the plurality of robots.

In an aspect, a robotic system is provided and includes at least two digital servo modules, each of which includes a position-controlled motor and a position sensor for sensing a servo position, a plurality of building block elements that are connectable with the digital servo modules to create position-controlled joints of a robotic figure, at least two wheel modules enabling wheeled movement of the robotic figure and a central controller communicating with and controlling the digital servo modules and the wheel modules. The central controller operatively places a selected group of digital servo modules in a learned motion mode, wherein a corresponding group of position-controlled joints is enabled to be manually manipulated, and wherein each of the selected digital servo module periodically transmits servomotor position to the central controller. The central controller can steer the robotic figure wheel modules based on servo positions of the selected digital servo modules.