A method for designing block layouts for use in block placement during construction, the method including, in one or more electronic processing devices, acquiring plan data indicative of a construction plan, identifying walls and intersections within the construction plan, identifying a number of possible intersection layouts for each intersection, generating different block layouts, each block layout including a combination of intersection layouts, the combination including one of the number of possible intersection layouts for each intersection and at least one wall layout for each wall, the wall layouts being generated based on the combination of intersection layouts and selecting one of the different block layouts.

The present invention relates to a near-site robotic construction system. The system includes a work station situated on a near-site position in a close proximity to a building foundation on which a building is under construction and providing shelter and workspace for at least one robot to work; and a computer-assisted cloud based near-site robotic construction platform installed on a cloud server system and configured to provide for a user to operate through a web browser, import and extract a building information modelling data, and plan a predetermined motion command set partly based on the extracted building information modelling data, wherein the at least one robot is configured to work in accordance with the predetermined motion command set to prefabricate a plurality of components for the building in the work station on the near-site position.

A self-contained truck-mounted brick laying machine can include a frame that can support packs or pallets of bricks placed on a platform. A transfer robot can pick up and move the brick(s). A carousel can be coaxial with a tower. The carousel can transfer the brick(s) via the tower to an articulated and/or telescoping boom. The bricks can be moved along the boom by, e.g., linearly moving shuttles, to reach a brick laying and adhesive applying head. The brick laying and adhesive applying head can mount to an element of the stick, about an axis which is disposed horizontally. The poise of the brick laying and adhesive applying head about the axis can be adjusted and can be set in use so that the base of a clevis of the robotic arm mounts about a horizontal axis, and the tracker component is disposed uppermost on the brick laying and adhesive applying head. The brick laying and adhesive applying head can apply adhesive to the brick and can have a robot that lays the brick. Vision and laser scanning and tracking systems can be provided to allow the measurement of as-built slabs, bricks, the monitoring and adjustment of the process and the monitoring of safety zones. The first, or any course of bricks can have the bricks pre machined by the router module so that the top of the course is level once laid.

The present disclosure provides a system for performing interactions within a physical environment, the system including: (a) a robot base; (b) a robot base actuator that moves the robot base relative to the environment; (c) a robot arm mounted to the robot base, the robot arm including an end effector mounted thereon; (d) a tracking system that measures at least one of: (i) a robot base position indicative of a position of the robot base relative to the environment; and, (ii) a robot base movement indicative of a movement of the robot base relative to the environment; (e) an active damping system that actively damps movement of the robot base relative to the environment; and, (f) a control system that: (i) determines a movement correction in accordance with signals from the tracking system; and, (ii) controls the active damping system at least partially in accordance with the movement correction.

A control system for a base supporting a boom assembly comprises long telescopic boom and telescopic stick. Mounted to the remote end of the stick is an end effector that supports a robot arm that moves a further end effector to manipulate the items. The robot arm has a robot base, and mounted above the robot base is a first target in the form of a position sensor, that provides position coordinates relative to a fixed ground reference. Mounted on the end of the robot arm immediately above the end effector is a second target that provides position coordinates relative to the fixed around reference. The fixed ground reference tracks the sensors and feeds data to the control system to move the stick with slow dynamic response and to control movement of the robotic arm and end effector with fast dynamic response.

An intuitive control system for lifting equipment is described. The intuitive control system translates user defined inputs into machine expressions of movement that are in turn used to control a construction lift or similar piece of construction equipment. Orientation and relative position sensors may be incorporated into the translation and control system for correct user control of the lifting equipment in various operating conditions.

A robotic system includes end-effector(s) that combine a plurality of objects in a production process. The system includes sensor(s) that obtain measurement(s) relating to a combination of a first object and one or more other objects during the production process. The system includes a control system communicatively coupled to the sensor(s). The control system stores specifications relating to the combination of the plurality of objects. The control system receives the measurement(s) from the sensor(s), determines a difference based on the measurement(s) and the specifications, determines adjustment(s) to the production process based on the determined difference, and sends, for the end-effector(s), instruction(s) based on the specifications and the one or more adjustment(s). The end-effector(s) combine a second object with the first object and the one or more objects based on the specifications and the one or more adjustment(s).

A system for performing interactions within a physical environment, the system including: a robot having a robot base that undergoes movement relative to the environment and a robot arm mounted to the robot base, the robot arm including an end effector mounted thereon; a communications system including a fieldbus network; a tracking system including a tracking base positioned in the environment and connected to the fieldbus network, and a tracking target mounted to a component of the robot, wherein the tracking base is configured to detect the tracking target to allow a position and/or orientation of the tracking target relative to the tracking base to be determined; and a control system that communicates with the tracking system via the fieldbus network to determine the relative position and/or orientation of the tracking target and controls the robot arm in accordance with the relative position and/or orientation of the tracking target.

A system for performing interactions within a physical environment including a robot having a robot base that undergoes movement relative to the environment, a robot arm mounted to the robot base, the robot arm including an end effector mounted thereon for performing said interactions, a tracking system that measures a robot position indicative of a position of at least part of the robot relative to the environment, and a control system that determines the robot position; and, controls the robot arm in accordance with the robot position. The tracking system measures the position with a frequency that is at least 10 Hz and measures the position with an accuracy that is at least better than 10 mm, whilst the control system operates with a frequency that is at least 10 Hz.

A robotic system includes one or more end-effectors that combine, according to a production process, at least one object and structure(s) at a production site. Sensor(s) generate, from the production site, sensor data relating to the production process. A control system stores specifications for the production process based on a model of the production site and/or the at least one object. The control system: receives, from the sensor(s), the sensor data; determines, from the sensor data, properties of at least one of: the production site or the at least one object; determines difference(s) between the properties and the model; determine(s) adjustment(s) to the production process based on the difference(s); and sends, for the end-effector(s), instruction(s) for combining the at least one object and the structure(s) based on the specifications and the one or more adjustments to the production process.