A manufacturing system includes: a first tank configured to store generation fuel; a manufacturing device having a first power generation device configured to generate power using the generation fuel, the manufacturing device being configured to operate using power supplied from the first power generation device; and a transport robot configured to transport the generation fuel from the first tank to the manufacturing device.

A modular mobility base for a modular autonomous bot apparatus transporting an item being shipped including a mobile base platform, a component alignment interface, a mobility controller, a propulsion and steering system, and sensors. The component alignment interface provides an alignment channel into which another modular component can be placed and secured on the platform. The mobility controller generates propulsion control signals for controlling speed of the modular mobility base and steering control signals for navigation of the modular mobility base. The propulsion system is connected to the platform and responsive to the propulsion control signal. The steering system is connected to the mobile base platform and is responsive to the steering control signal to cause changes to directional movement of the modular mobility base. The sensors are disposed on the platform provide feedback sensor data to the mobility controller about a condition of the modular mobility base.

A method and system for capturing, by a camera a sequence of frames at respective locations within a portion of an environment; capturing, by an inertial measurement unit, a sequence of inertial odometry data corresponding to the sequence of frames at the respective locations; storing in a queue a data record includes information extracted from processing the respective frame and information from the inertial measurement unit; in accordance with a determination that the sequence of inertial odometry data satisfies a first criterion: calculating a first relative pose between the first frame and the second frame; and in accordance with a determination that a difference between the first relative pose and the information extracted from processing the respective frame satisfy a first threshold: generating an initial map of the portion of the environment based on the first data record and the second data record.

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 surface supported by the composable robotic posts.

The disclosure provides a method for generating a joint command. The method includes receiving a maneuver script including a plurality of maneuvers for a legged robot to perform where each maneuver is associated with a cost. The method further includes identifying that two or more maneuvers of the plurality of maneuvers of the maneuver script occur at the same time instance. The method also includes determining a combined maneuver for the legged robot to perform at the time instance based on the two or more maneuvers and the costs associated with the two or more maneuvers. The method additionally includes generating a joint command to control motion of the legged robot at the time instance where the joint command commands a set of joints of the legged robot. Here, the set of joints correspond to the combined maneuver.

Apparatuses, methods and systems for dynamically retrieving objects are disclosed herein. In one example, a retrieval apparatus is provided. The example retrieval apparatus comprises: at least one moveable arm mechanism configured to engage a surface of at least one of a plurality of objects; at least one sensing element configured to obtain sensor data describing locations and characteristics of the plurality of objects as the retrieval apparatus traverses an environment associated with the plurality of objects; and a controller component in electronic communication with the at least one arm mechanism and the at least one sensing element, wherein the controller component is configured to modify operational data based at least in part on the sensor data.

An adaptive manipulation apparatus and method are provided. The adaptive manipulation method includes steps of providing a mobile manipulation apparatus comprising a manipulator, a sensor and a processor for a manipulation of an object placed on a carrier having a plurality of markers spaced apart from each other, the sensor detecting the plurality of markers to obtain a run time marker information, the processor, according to the base-case motion plan, generating a run time motion plan, wherein the run time motion plan comprises a plurality of second pose-aware actions, and the plurality of second pose-aware actions are modified from the plurality of first pose-aware actions according to the run time marker information, and the processor further executing the run time motion plan for controlling the manipulator to manipulate the object.

A method for setting more precisely a position and/or an orientation of a device head in a measuring environment by a distance measuring device which has a number of M, M≥1, distance measuring sensors and which is connected to the device head. A control device is communicatively connected to the distance measuring device and an on-board sensor device. The position and/or the orientation of the device head is determined by the on-board sensor device and the position and/or the orientation of the device head determined by the on-board sensor device is set more precisely by the control device.

A method for controlling a robot is provided. The method includes the steps of: determining a target robot to travel to a first loading station among a plurality of robots, on the basis of information on a location of the first loading station and a task situation of each of the plurality of robots, when a first transport target object is placed at the first loading station; and determining a travel route of the target robot with reference to information on the location of the first loading station and a location of a first unloading station associated with the first transport target object.

The present invention proposes a mobile robotic system capable of carrying out the movement, manipulation and precise installation of industrial loads (pipes, plates, equipment, parts, materials, etc.), using a single operator for that and presenting ease of use. The invention is basically composed of an anthropomorphic-type industrial robot (3) and a crawler mobile platform (11). The load capacity of the invention is limited by the maximum load capacity of the industrial robot employed. The precise positioning step has a special force amplification system (external exoskeleton) capable of moving a load fixed on the industrial robot wrist (position and orientation) with the force actions of an operator, directly on the robot wrist, or by means of a security extension. The robotic system can be controlled by radio control, capable of allowing both the control of the robot and the movement of the platform.

The proposed system of this invention comprises a mobile platform for all types of terrain, an industrial robotic arm, an effector for handling pipes, an effector to pick up metal plates, the respective supports of effectors in a quick tool change system, a diesel electric generator, an industrial radio control, safety sensors and a video monitor for two cameras positioned on the robot structure.