A robot has an electronic surveillance system embedded within a chassis disposed between two wheels. The wheels include a main body and a plurality of treads. The treads are generally disposed radially around the main body and extend distally from outer portion of the main body. The main body generally defines a plurality of compression cells and may present a substantially frustoconical outer surface.

Provided is a robot including: a chassis; wheels; electric motors; a network card; sensors; a processor; and a tangible, non-transitory, machine readable medium storing instructions that when executed by the processor effectuates operations including: capturing, with at least one exteroceptive sensor, a first image and a second image; determining, with the processor, an overlapping area of the first image and the second image by comparing the raw pixel intensity values of the first image to the raw pixel intensity values of the second image; combining, with the processor, the first image and the second image at the overlapping area to generate a digital spatial representation of the environment; and estimating, with the processor using a statistical ensemble of simulated positions of the robot, a corrected position of the robot to replace a last known position of the robot within the digital spatial representation of the environment.

Systems and methods for detection of people are disclosed. In some exemplary implementations, a robot can have a plurality of sensor units. Each sensor unit can be configured to generate sensor data indicative of a portion of a moving body at a plurality of times. Based on at least the sensor data, the robot can determine that the moving body is a person by at least detecting the motion of the moving body and determining that the moving body has characteristics of a person. The robot can then perform an action based at least in part on the determination that the moving body is a person.

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.

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 vehicle transfer robot (10) of the present invention, disposed vertically on the ground, is formed to have four vertical frames (110) disposed at a predetermined distance apart from each other and formed to have a quadrangular frame, and a quadrangle by connecting the upper end parts of the four vertical frames (110), respectively, wherein the vehicle transfer robot (10) includes: a frame part (100) including an upper frame (120); a driving part (200) installed at each of the lower end parts of the vertical frames (110) for moving the frame part (100); and a carriage (300) installed in the frame part (100) for loading a vehicle.

According to the present embodiment, a serving module includes: a tray; a main body formed therein with a tray space configured to accommodate the tray and having a tray entrance; a tray moving device configured to move at least a part of the tray out of the tray entrance or move an entire of the tray into the tray space; a door configured to open and close the tray entrance; and a door driving device connected to the door to open and close the door.

The invention relates to a method for operating a palletizing plant (5) which comprises a palletizing apparatus (10) for forming a layer stack (100) and at least one driverless transport vehicle (40) for transporting the layer stack (100). In the method, the driverless transport vehicle (40) is moved to a palletizing location (41) close to the palletizing apparatus (10) and a layer stack (100) is formed on the driverless transport vehicle (40). The driverless transport vehicle (40) remains at the palletizing location (41) during the formation of the layer stack (100). The invention also relates to a palletizing plant (5) which is set up to carry out the method according to the invention.

The invention relates to a method for operating a palletizing plant (5) which comprises a palletizing apparatus (10) for forming a layer stack (100) and at least one driverless transport vehicle (40) for transporting the layer stack (100). In the method, the driverless transport vehicle (40) is moved to a palletizing location (41) close to the palletizing apparatus (10) and a layer stack (100) is formed on the driverless transport vehicle (40). The driverless transport vehicle (40) remains at the palletizing location (41) during the formation of the layer stack (100). The invention also relates to a palletizing plant (5) which is set up to carry out the method according to the invention.

A teleoperated robotic system that includes master control arms, slave arms, and a mobile platform. In use, a user manipulates the master control arms to control movement of the slave arms. The teleoperated robotic system can include two master control arms and two slave arms. The master control arms and the slave arms can be mounted on the platform. The platform can provide support for the master control arms and for a teleoperator, or user, of the robotic system. Thus, a mobile platform can allow the robotic system to be moved from place to place to locate the slave arms in a position for use. Additionally, the user can be positioned on the platform, such that the user can see and hear, directly, the slave arms and the workspace in which the slave arms operate.