A conveyance system (1) according to the present disclosure includes: a conveyance vehicle (10) that conveys an object based on a first traveling path; a sensor (20) that transmits information regarding a position of the conveyance vehicle (10) via a network; a communication unit (32) that can communicate with the conveyance vehicle (10) and the sensor (20); and a control unit (31) that controls the conveyance vehicle (10) via the communication unit (32). The control unit (31) determines a second traveling path based on the information regarding the position of the conveyance vehicle (10) and corrects a traveling trajectory of the conveyance vehicle (10) based on the first traveling path and the second traveling path.

Methods and apparatus for implementing a safety system for a mobile robot are described. The method comprises receiving first sensor data from one or more sensors, the first sensor data being captured at a first time, identifying, based on the first sensor data, a first unobserved portion of a safety field in an environment of a mobile robot, assigning, to each of a plurality of contiguous regions within the first unobserved portion of the safety field, an occupancy state, updating, at a second time after the first time, the occupancy state of one or more of the plurality of contiguous regions, and determining one or more operating parameters for the mobile robot, the one or more operating parameters based, at least in part, on the occupancy state of at least some regions of the plurality of contiguous regions at the second time.

The present invention relates to a technical idea for providing a delivery service on regular and irregular roads using autonomous vehicles. More specifically, the present invention relates to technology in which, on a regular road, a lead vehicle and at least one droid vehicle are coupled to each other and a delivery service is provided based on autonomous driving; and on an irregular road, the coupling between the lead vehicle and the droid vehicle is automatically released and the droid vehicle provides a delivery service by remotely controlling the driving of the droid vehicle by the lead vehicle in the last mile delivery section corresponding to the irregular road. According to one embodiment of the present invention, a system for providing a delivery service using autonomous vehicles may provide a delivery service on an irregular road where entry of normal vehicles is not allowed and a regular road where entry of small and low-speed vehicles is not allowed and may include a droid vehicle for providing a delivery service using limited autonomous driving performance in a last mile delivery section corresponding to the irregular road; and a lead vehicle for providing a delivery service based on autonomous driving on the regular road, transporting the droid vehicle by being coupled to the droid vehicle on the regular road, and remotely controlling driving of the droid vehicle after being separated from the droid vehicle in the last mile delivery section.

Some embodiments include apparatuses providing control over movement of motorized transport units at a retail facility, comprising: multiple self-propelled motorized transport units; a wireless communication network; and a central computer system, wherein the central computer system comprises: a transceiver; a control circuit; and a memory storing computer instructions that when executed cause the control circuit to: receive an override command, from a worker associated with the retail facility, to cause a first motorized transport unit of the multiple motorized transport units to implement one or more actions; confirm a valid authorization of the worker to override one or more operating limits of the first motorized transport unit; and override the one or more operating limits and communicate one or more instructions to the first motorized transport unit configured to cause the first motorized transport unit to implement the one or more actions in accordance with the override command.

A conveyance system according to the present disclosure includes a conveyance vehicle configured to travel along a guide line laid on a traveling road. The conveyance vehicle includes: a guide line detection unit configured to detect the guide line; an object position detection unit configured to detect information on a position of an object around the conveyance vehicle; and a stop position determination unit configured to determine a stop position of the conveyance vehicle based on a result of detection by the object position detection unit.

According to the present disclosure, there is provided a moving body including a holding device configured to hold a cargo, a driving device configured to move the moving body, a detection device configured to detect a parameter relating to a stable degree of the cargo in the holding device when the moving body is moving, and a control device configured to determine whether a state of the cargo is stable using the parameter relating to the stable degree, and to perform stabilization control in which the driving device is controlled such that the state of the cargo is stable when it is determined that the state of the cargo is not stable.

This traveling system includes: a setting processing unit that sets a travel route corresponding to each of the plurality of automatic traveling devices; a calculation processing unit that, when a first automatic traveling device interferes with a travel of other automatic traveling devices, calculates an evaluation value representing an influence level that the first automatic traveling device imposes on the travel of the other automatic traveling devices; and a change processing unit that, when the evaluation value calculated by the calculation processing unit is greater than or equal to a threshold, changes the travel route that is set to the first automatic traveling device by the setting processing unit.

A conveyance system according to the present disclosure includes a host vehicle position estimation unit that detects at least one of a traveled distance of a conveyance vehicle and a position of the host vehicle, and a control switching unit that switches, when the traveled distance or the position of the host vehicle detected by the host vehicle position estimation unit falls within a preset range while the conveyance vehicle is being controlled by an autonomous traveling control unit, a control mode from traveling control by the autonomous traveling control unit to traveling control by a guided traveling control unit.

An autonomous mobile vehicle for loading and unloading goods in an environmental field, and a guidance and obstacle avoidance method are provided. The autonomous mobile vehicle includes a vehicle body, a first Lidar module, and a second Lidar module. The vehicle body is configured to carry goods, the first Lidar module is fixed on the vehicle body and the second Lidar module is selectively assembled on and disassembled from the vehicle body. When the second Lidar module is assembled on the vehicle body, the autonomous mobile vehicle uses the second Lidar module to establish a map of the environmental field. When the second Lidar module is disassembled from the vehicle body, the autonomous mobile vehicle is guided by using the first Lidar module according to the map, so as to perform an obstacle avoidance on a moving path of the autonomous mobile vehicle.

A server apparatus includes a communication interface and a controller configured to communicate, using the communication interface, with a mobile object having a facility for executing one or more processes in a plurality of processes to be executed sequentially to manufacture a product. The controller is configured to transmit an instruction to a first mobile object to travel to a meeting point with a second mobile object for executing a second process that follows a first process to be executed in the first mobile object, the instruction being for delivering the product being manufactured to the second mobile object at the meeting point.