A method and system for assembling a modular structure from components configured to be fitted together to create the modular structure in accordance with a construction plan. Each component includes: a communication interface; and an output interface configured to generate sensory signals. The components communicate, via the communication interface of each component, with a controller to establish an availability of the components for the modular structure. A target component is determined at the controller from the components based on the construction plan and the availability of the components. The target component is a starting component used for initiating creation of the modular structure in accordance with the construction plan. A first sensory signal indicating the target component to a user is generated by the output interface of the target component.

In an embodiment, a mobile robotic device includes a mobile base and a mounting column fixed to the mobile base. The robotic device further includes a seven-degree-of-freedom (7DOF) robotic arm, including a rotatable joint that enables rotation of the 7DOF robotic arm relative to the mounting column. The robotic device additionally includes a perception housing comprising at least one sensor, where the mounting column, the rotatable joint of the 7DOF arm, and the perception housing are arranged in a stacked tower such that the rotatable joint of the 7DOF arm is above the mounting column and below the perception housing.

A mobile robotic device includes a mobile base and a mast fixed relative to the mobile base. The mast includes a carved-out portion. The mobile robotic device further includes a three-dimensional (3D) lidar sensor mounted in the carved-out portion of the mast and fixed relative to the mast such that a vertical field of view of the 3D lidar sensor is angled downward toward an are in front of the mobile robotic device.

A robot system includes a robot controller and an object robot including a first storage part storing a hardware identifier, individual discrimination data, and device specific data including an individual difference parameter. The same hardware identifier is assigned to the object robot having the same mechanism. The robot controller includes a second storage part storing common configuration information corresponding to the hardware identifier and the individual discrimination data and the individual difference parameter of the object robot, and a control part configured, in a case that the hardware identifier corresponding to the common configuration information stored in the second storage part and the hardware identifier assigned to the object robot are collated and matched with each other, to create hardware definition information of the object robot based on the common configuration information stored in the second storage part and the individual difference parameter read from the first storage part.

A robotic system includes at least two Hardware Modules, each having at least one sensor for measuring an internal property, a communication unit, a data storage unit and an embedded controller. The embedded controller is configured to collect collected data including status data representing the current status of the Hardware Module; and operating data representing usage of the Hardware Module. At least part of the collected data is determined from sensor data, and the embedded controller is configured to store or transmit the collected data. The robotic system including a central computation and command unit configured to receive the collected data; and to control operation of the robotic system by controlling operation of at least one actuator of the at least two Hardware Modules.

A Hardware Module for a robotic system includes at least one sensor for measuring an internal property of the Hardware Module, a communication unit for communicating with other Hardware Modules, a data storage unit and an embedded controller. The embedded controller is configured to collect collected data, the collected data including: status data representing the current status of the Hardware Module; and operating data representing usage of the Hardware Module wherein at least part of the collected data is determined from sensor data from the at least one sensor, and the embedded controller is configured to perform at least one of: storing the collected data on the data storage unit; and transmitting the collected data via the communication unit.

Modular building blocks for building a robotic system, and the method of building the robotic system using the building blocks, are presented. The building block includes a chassis having a first end and a second end, a first connector positioned closer to the second end than the first end of the chassis, either a second connector or a rotational actuator positioned closer to the first end than the second end of the chassis and configured to couple with the first connector, a signal interface on a surface of the chassis, the signal interface including hardware and circuitry for transferring and receiving signals from and to the building block, and a power and control interface on the chassis for receiving power for the building block.

A robot includes at least two or more types of component units and a control unit configured to control an operation of each component unit. The respective units are configured to be detachable from each other. The control unit is configured to be able to collect configuration data of each of the component units and acquire connection data regarding connection states of all the component units connected to the control unit based on the collected configuration data. A determination portion that stores a predetermined connection form of each component unit, which is controllable by the control unit, in advance as verification data and determines whether or not connection data acquired by the control unit matches the verification data is further provided.

Example implementations may relate a robot part including a processor, at least one sensor, and an interface providing wireless connectivity. The processor may determine that the robot part is removablly connected to a particular robotic system and may responsively obtain identification information to identify the particular robotic system. While the robot part is removablly connected to the particular robotic system, the processor may (i) transmit, to an external computing system, sensor data that the processor received from the at least one sensor and (ii) receive, from the external computing system, environment information (e.g., representing characteristics of an environment in which the particular robotic system is operating) based on interpretation of the sensor data. And based on the identification information and the environment information, the processor may generate a command that causes the particular robotic system to carry out a task in the environment.

A multi-operation unit integration device having scale expandability and includes a plurality of operation units each of which includes a movable unit; and an integration module. The integration module includes an operation timing unit that gives operation timings of the plurality of operation units based on an operation instruction input from an outside, and the operation unit includes: a plurality of operation learning units that generate a control signal given to the movable unit according to an operation timing signal from the operation timing unit of the integration module; drive means for driving the movable unit of the operation unit according to the control signal; and a sensor that detects a state quantity of the movable unit driven by the drive means. An autonomous learning type robot device is configured using the multi-operation unit integration device as a control portion.