Disclosed is a transporting robot which executes a mounted artificial intelligence (AI) algorithm and/or machine learning algorithm and communicates with different electronic devices and external servers in a 5G communication environment. The transporting robot includes a wheel driver, a loading box, and a robot controller. The transporting robot is provided such that a transporting service using an autonomous robot may be provided.

A smart container yard includes systems for intelligently controlling operations of vehicles in the container yard using teleoperation and/or autonomous operations. A remote support server controls remote support sessions associated with vehicles in the container yard to provide teleoperation support for loading and unloading operations. Aerial drones may be utilized to maintain positions above a teleoperated vehicle and act as signal re-transmitters. An augmented reality view may be provided at a teleoperator workstation to enable a teleoperator to control vehicle operations in the smart container yard.

Systems and methods described herein are directed to an environment involving a plurality of robots, wherein for receipt of a plurality of orders, the systems and methods generate a plurality of task batches to fulfill the plurality of orders; generate a parameter set for execution by the plurality of robots to execute the plurality of task batches. For a determination by a controller that one or more of the plurality of robots is to execute the plurality of task batches, the systems and methods load the parameter set; and control the one or more of the plurality of robots based on the loaded parameter set to execute the task batch.

Autonomous mobile robots include transfer systems that may receive multiple items for delivery to one or more destinations. The transfer systems may be specifically configured to detect and identify items that are placed on loading surfaces, and to independently discharge specific items at selected destinations or to selected recipients. The transfer systems feature loading surfaces that may be defined by a plurality of independently operable conveyors to receive or discharge items, by independently operable floors that allow items to pass therethrough, or by independently operable diverters for detecting and expelling items therefrom. The transfer systems may receive items from, or discharge items to, one or more humans, other robots, or other systems such as conveyors, chutes, robotic arms or other mechanical implements or effectors, and be aligned at any angle or provided at any height, as desired.

The present invention relates to a driverless transport system (81), comprising a plurality of driverless transport devices (10) having a support structure (12) with an outer contour (14); an undercarriage (16) which is secured to the support structure (12) and has at least one first wheel (18) and a second wheel (20), wherein the first wheel (18) is mounted in the undercarriage (16) so as to rotate about a first axis of rotation (D1) and the second wheel (20) is mounted in the undercarriage (16) so as to rotate about a second axis of rotation (D1); a drive unit (22) by means of which the first wheel (18) and the second wheel (20) can be driven independently of each other; a control unit (94) for controlling or regulating the driverless transport devices (10); and a communication device (76) by means of which information can be exchanged between the control unit (94) and the driverless transport devices (10), wherein one of the driverless transport devices (10) is designed as a master (86) and the other driverless transport devices (10) are designed as slaves (88).

A remotely operated vehicle for moving on a rail system includes a first set of wheels, a second set of wheels, a wheel displacement assembly, and a wheel drive assembly. The rail system includes a first set of parallel rails and a second set of parallel rails arranged perpendicular to the first set of rails. The first set of wheels includes a first pair of wheels and a second pair of wheels, the first and second pairs of wheels arranged on opposite sides of a vehicle frame, allowing movement of the vehicle along a first direction on the rail system during use. The second set of wheels includes a third pair of wheels and a fourth pair of wheels, the third and fourth pairs of wheels arranged on opposite sides of the vehicle frame, allowing movement of the vehicle along a second direction on the rail system during use. The second direction is perpendicular to the first direction. The wheel displacement assembly is mounted to the vehicle frame and arranged to move the second set of wheels in a vertical direction relative to the vehicle frame between a first position. The first set of wheels allows movement of the vehicle along the first direction, and a second position. The second set of wheels allows movement of the vehicle along the second direction. The wheel drive assembly includes a first motor, a drive band, and a band drive wheel. The first motor is operatively connected to rotate the band drive wheel. The drive band interconnects the band drive wheel and the third pair of wheels. The third pair of wheels and the first motor are mounted to a cross-plate which extends horizontally and is arranged to move vertically as part of the wheel displacement assembly. The third pair of wheels and the band drive wheel are attached to the cross-plate such that the cross-plate supports the third pair of wheels and the band drive wheel are in a fixed spatial configuration where each wheel of the third pair of wheels is located at an end portion of the cross-plate and the band drive wheel is positioned at a central portion of the cross-plate.

A remotely operated vehicle includes an arrangement to provide a pre-alert and tracking of a position of the vehicle following a travelling route relative to tracks laid out on rails in x-, y-directions on a rail system. The vehicle has first and seconds sets of wheels connected to drives for moving the vehicle in corresponding x-, y-directions on the rail system. The arrangement includes at least one sensor module provided with at least four sensors. A first sensor is directed vertically downwards to detect the rails in the x-direction on the sensor module. A second sensor is directed vertically downwards to detect the rails in the y-direction on the sensor module. A third sensor is positioned on the sensor module to detect a corner of an intersection between the rails in the x-direction and y-direction. A fourth sensor is configured to detect a remaining distance to the arrival of the vehicle at a set position, by detecting the rails in the x direction when travelling in the y direction, and detecting the rail in the y direction when travelling in the x direction. The fourth sensor is placed at a predefined position on the sensor module. A controller is provided on the vehicle to receive the output from at least one of the sensors and to pre-alert the remaining distance of the arrival of the vehicle at the position.

An own-position estimating device for estimating an own-position of a moving body by matching a feature extracted from an acquired image with a database in which position information and the feature are associated with each other in advance, includes an evaluation result acquiring unit acquiring an evaluation result obtained by evaluating matching eligibility of the feature in the database, and a processing unit processing the database on the basis of the evaluation result acquired by the evaluation result acquiring unit.

An autonomous traveling body includes a vehicle body, a mover, an obstacle detector, a traveling controller, and a storage. The mover causes the vehicle body to travel. The traveling controller controls the mover based on a detection result of the obstacle by the obstacle detector. The storage stores an obstacle detection area around the vehicle body. The obstacle detection area includes a stop area having a predetermined width with the traveling direction of the vehicle body as an axis, and first and second deceleration areas excluding the stop area. When at least a portion of the obstacle is included in the stop area, the traveling controller stops the vehicle body. When at least a portion of the obstacle is included in the first deceleration area or the second deceleration area, the traveling controller reduces the traveling speed of the vehicle body.

A vehicle control system including: a vehicle configured to be movable along a predetermined route, the vehicle including at least an image capturing apparatus; a display apparatus configured to display a video image captured by the image capturing apparatus, the display apparatus being installed in a remote place that is remote from the vehicle; a first operation terminal installed in the remote place; a control apparatus configured to control movement of the vehicle based on first operation information input through the first operation terminal; and a second operation terminal installed in a place that is closer to the vehicle than to the remote place, in which the control apparatus is configured to assist, based on second operation information input through the second operation terminal, the control of the movement of the vehicle that is based on the first operation information.