Provided are a computer program product, moveable robot block, and method for a moveable robot block deployed to form a barrier and sense environmental conditions. A command is received to couple to a location in a coordinate system comprising the barrier formed of a plurality of moveable robot blocks. Movement motors are controlled to cause the moveable robot block to move to the location in the coordinate system to couple to the barrier according to the command. An environmental sensor senses an environmental condition related to water sensed external to the moveable robot block when the moveable robot block is coupled to the barrier. The environmental condition is transmitted to the assembly management system over the network.

Methods, systems, and apparatus, including computer programs encoded on computer storage media, for using simulated local demonstration data for robotic demonstration learning. One of the methods includes receiving perceptual data of a workcell of a robot to be configured to execute a task according to a skill template, wherein the skill template specifies one or more subtasks required to perform the skill, wherein at least one of the subtasks is a demonstration subtask that relies on learning visual characteristics of the workcell. A virtual model is generated of a portion of the workcell. A training system generates simulated local demonstration data from the virtual model of the portion of the workcell and tunes a base control policy for the demonstration subtask using the simulated local demonstration data generated from the virtual model of the portion of the workcell.

A system includes an inspection robot having a plurality of input sensors, the plurality of input sensors distributed horizontally relative to an inspection surface and configured to provide inspection data of the inspection surface at selected horizontal positions; a controller, comprising: a position definition circuit structured to determine an inspection robot position of the inspection robot on the inspection surface; a data positioning circuit structured to interpret the inspection data, and to correlate the inspection data to the inspection robot position on the inspection surface; and wherein the data positioning circuit is further structured to determine position informed inspection data in response to the correlating of the inspection data with the inspection robot position.

In an aspect of the disclosure, a first manufacturing cell for assembling a structure is provided. The first manufacturing cell for assembling the structure may include a plurality of first robots positioned around a common point in a first configuration, and a plurality of second robots positioned around the common point in a second configuration, the second configuration being closer to the common point than the first configuration. One of the plurality of first robots is configured to translate towards and away from the common point to interact with one of the plurality of second robots or one of the plurality of second robots is configured to translate towards and away from the common point to interact with one of the plurality of first robots.

The present disclosure relates to the field of modular robot control, and more particularly, to a method for controlling a modular robot and a system thereof. The method includes the following steps: T1: providing a plurality of module units; T2: assembling the plurality of module units into an initial entity structure; T3: acquiring initial virtual configuration information of the initial entity structure; T4: generating an initial virtual configuration based on the initial virtual configuration information; T5: setting an action frame to generate preset action control information; and T6: transmitting the preset action control information to the modular robot which executes a motion according to the preset action control information.

Provided is a control technique that enables a time required for platoon control operations to be shortened. A mobile robot includes, for example, a position distance calculation instruction transmission unit 1, a position distance calculation instruction transfer unit 2, a reply position distance calculation instruction transmission unit 3, a direction storage unit 4, a reply position distance calculation instruction transfer unit 5, an operation clock time announcement instruction transmission unit 6, an operation clock time announcement instruction transfer unit 7, a first moving unit 8, a movement start instruction transmission unit 9, a movement start instruction transfer unit 10, a second moving unit 11, a third moving unit 12, a determination unit 13, a fourth moving unit 14, a fifth moving unit 15, a waiting instruction transmission unit 16, and a waiting instruction transfer unit 17.

A system including an inspection robot having a plurality of sensors, a further sensor, and a controller. The controller having circuitry to receive inspection data with a first resolution from the plurality of sensors, determine a characteristic on the inspection surface based on the inspection data, and provide an inspection operation adjustment in response to the characteristic, wherein the inspection operation adjustment includes a change from the first resolution to a second resolution. The change from the first resolution to the second resolution includes enabling the further sensor where the further sensor is at least one of: horizontally distributed with or vertically displaced from the plurality of sensors relative to a travel path of the plurality of sensors, and at least one of: offset in alignment from the travel path of the plurality of sensors, or operated out of phase with the plurality of sensors.

A sensing flux system includes a memory and a processor in communication with the memory and a sensing device, the memory storing a plurality of capabilities and a plurality of semantic fluxes associated with the plurality of capabilities. The computing system is configured to infer a semantic associated with an indicated user interest based on received inputs and route the inputs to the semantic fluxes based on semantic drift inference between their associated capabilities and inferred semantic in association with a time preference indicated by the user interest.

A robotic post system includes one or more composable robotic posts each having a processor and a memory. At least one composable post includes a set of modules including one or more pairable latches which is configured to couple and lock with another pairable latch from among another set of modules included on another of the composable posts, such that the composable robotic posts form a composable carrier structure defined by the composable robotic posts.

Inspection robots with a multi-function piston connecting a drive module to a central chassis and systems thereof are disclosed. An example inspection robot may include a center chassis coupled to a payload coupled to at least two inspection sensors. The inspection robot may further include a drive module coupled to the center chassis, the drive module having a drive wheel to engage an inspection surface and a drive piston mechanically interposed between the center chassis and the drive module. The example may further include wherein the drive piston in a first position couples the drive module to the center chassis at a minimum distance between and the drive piston in a second position couples the drive module to the center chassis at a maximum distance between. The example may further include wherein the drive module is independently rotatable relative to the center chassis.