In various embodiments, safe robot operation is achieved by combining commercial, off-the-shelf, safety-rated components with the inherent safety-design mechanism of the robot to provide various allowable power levels to robotic actuators and thereby limit the forces and/or speeds generated by robotic appendages driven by the actuators.

A mobile robot is configured for operation in a commercial or industrial setting, such as an office building or retail store. The robot can patrol one or more routes within a building, and can detect violations of security policies by objects, building infrastructure and security systems, or individuals. In response to the detected violations, the robot can perform one or more security operations. The robot can include a removable fabric panel, enabling sensors within the robot body to capture signals that propagate through the fabric. In addition, the robot can scan RFID tags of objects within an area, for instance coupled to store inventory. Likewise, the robot can generate or update one or more semantic maps for use by the robot in navigating an area and for measuring compliance with security policies.

Systems and methods are disclosed herein for a robotic manipulator arm deployment and control system. The system comprises at least a vertical mast, a mast deployment system comprising at least two cams, an elbow, an arm wherein the arm is operable to deploy tools, and one or more sensors including a non-contact sensor and a dynamic measurement unit. The cams cause the vertical mast and the arm to remain vertical during deployment into an operating space. The non-contact sensor may be used for measuring range and bearing to objects in the operating space in polar coordinates. The dynamic measurement unit comprises accelerometers and rate sensors and is configured as a six degree of freedom three axis sensor operating in a Cartesian coordinate system. The system further comprises a controller operable to receive the polar and Cartesian coordinates from the sensors and convert them to a Cartesian coordinate system.

A raising/lowering conveyance apparatus has at least two sets of container holders operable to be raised/lowered in conjunction with each other, and to be freely movable closer to or away from containers in the back-and-forth horizontal direction. A sensor operable to detect the upper end height of the transferred containers which have been transferred and raised is attached to a position near the lower end of each container holder, to determine abnormality in posture of the transferred containers through a comparison operation between the value of the upper end height of the transferred containers detected by the sensor and the normal value of the upper end height of the transferred containers calculated on the basis of the height of the container being handled.

A mobile robot is configured for operation in a commercial or industrial setting, such as an office building or retail store. The mobile robot can have a motorized base and a robot body on the motorized base, the robot body including a rotatable ring that rotates horizontally around the robot body. A mechanical arm that can contract and extend relative to the robot body is coupled to the rotatable ring and performs a plurality of actions. A controller of the mobile robot provides instructions to the rotatable ring and the mechanical arm and can cause the mechanical arm to open a door, take an elevator to move to a different floor, and test whether a door is locked properly.

Systems and methods for autonomous robot distributed processing are provided. A method includes receiving, at a robot, camera output from a camera located on the robot. The method may further include outputting the camera output to a mobile client device. The method may also further include receiving at the robot, from the mobile client device, object recognition metadata based upon the camera output. The method may additionally include outputting a notification from the robot to a user of the mobile client device based upon the object recognition metadata.

An automatic guiding method for a self-propelled apparatus (10) is provided. The self-propelled apparatus (10) turns and irradiates when a signal light emitted by a charging dock (20) is sensed by a flank sensor (103), and changes its turn direction when another different signal light from the charging dock (20) is sensed by a forward sensor (102). The charging dock (20) switches to emit another signal light different from the signal light currently emitted when each time is triggered by the signal light emitted by the self-propelled apparatus (10). Repeatedly execute the above actions and make the self-propelled apparatus approach the light-emitting unit (202) until the self-propelled apparatus (10) reaches a charging position. It can accurately guide the self-propelled apparatus (10) to the charging position by arranging only two sensors on the self-propelled apparatus.

An information processing device including: an information obtaining unit that obtains environmental information from sensor information obtained by a sensor with which an autonomous moving body is provided; an extraction unit that extracts, from the environmental information, specific environmental information to be saved; and an action control unit that controls an action of the autonomous moving body so as to output the specific environmental information to the outside.

The invention relates to a robot (100) for performing a process of picking rubber blocks arranged in a container toward a target location. The invention also relates to a process of picking rubber blocks arranged in a container, performed by the disclosed robot (100).

A modular robotic vehicle (MRV) having a modular chassis configured for a vehicle utilizing two-wheel steering, four-wheel steering, six-wheel steering, eight-wheel steering controlled by a semiautonomous system or an autonomous driving system, either system is associated with operating modes which may include a two-wheel steering mode, an all-wheel steering mode, a traverse steering mode, a park mode, or an omni-directional mode utilized for steering sideways, driving diagonally or move crab like. Accordingly, during semiautonomous control a driver of the modular robotic vehicle may utilize smart I/O devices including a smartphone, tablet like devices, or a control panel to select a preferred driving mode. The driver may communicate navigation instructions via smart I/O devices to control steering, speed and placement of the MRV in respect to the operating mode. Accordingly, GPS and a wireless network provides navigation instructions during an autonomous operation involving driving, parking, docking or connecting to another MRV.