A management device includes: a processor, and the processor specifies a first mobile machine that is not scheduled to operate during a predetermined period, based on data of operation plans of a plurality of mobile machines that are autonomously movable and have a function of a positioning base station, and transmits, to the first mobile machine, an instruction to operate the first mobile machine as the base station during the predetermined period.

A control system configured to control a system including a mobile robot configured to move autonomously and a server configured to be connected to the mobile robot by wireless communication includes one or more processors configured to, when the mobile robot is unable to communicate with the server, determine a state of the mobile robot, including whether the mobile robot has an abnormality, based on information acquired by sensors around the mobile robot.

A mobile carrier includes a controller, the controller executing program instructions to implement operations including moving the mobile carrier to move toward a target, wherein a first mobile vehicle and a second mobile vehicle are stacked on the mobile carrier; lifting the second mobile vehicle away from the first mobile vehicle; and placing the second mobile vehicle down to a predetermined location after the first mobile vehicle moves away from the mobile carrier.

A robot fleet management platform includes datastores configured to store a governance library defining governance standards. Processors execute computer-readable instructions to implement a governance-enabling intelligence layer that receives and responds to intelligence requests received from intelligence service clients. The intelligence layer includes artificial intelligence services including machine learning, rules-based intelligence, digital twin, robot process automation, and machine vision. The set of governance standards is applied to decisions made by one or more of the set of artificial intelligence services. An intelligence layer controller coordinates performance of the artificial intelligence services on behalf of the intelligence service clients and performance of analyses corresponding to the artificial intelligence services based on the set of governance standards. The intelligence layer returns decisions determined by the artificial intelligence services in response to the intelligence requests. The decisions are determined based on intelligence service data sources and the set of analyses.

A moving object manufactured in a factory comprises: a driving controller that implements driving control over the moving object by unmanned driving during a course of manufacture of the moving object in the factory; a process completion detector that detects completion of a process by at least one step included in the course of manufacture; and a control content change unit that changes a content in control over the moving object when the completion of the process is detected.

A control method includes the following. First information indicating a group control level is determined based on operation skills of operators who each perform remote monitoring or remote operation on a moving body. Second information indicating an attribute-dependent control level is determined based on attribute information on the operators. Third information indicating individual control levels of the operators is determined based on the first and second information. Moving bodies present within a predetermined range from a predetermined notification device are identified. Fourth information indicating a device control level is determined based on the third information determined for operators of the moving bodies identified. A detail of notification to be output from the predetermined notification device is determined based on the fourth information. A control command for notifying of the detail is output.

A method and device for remotely controlling a motor vehicle. A remote control device is provided. A transceiver device is located in the vehicle and is configured to exchange signals with the remote control device. A signal from the remote control device to the transceiver device activates a first operating mode in the vehicle, in which operating mode the vehicle moves autonomously, while maintaining specifiable surrounding conditions. The first operating mode is left if the specifiable surrounding conditions can no longer be maintained. After leaving the first operating mode, a second operating mode can be activated by a further signal to the transceiver device. In the second operating mode, the vehicle also moves autonomously but while maintaining further surrounding conditions which are at least partially changed in comparison to the surrounding conditions that can be specified in the first operating mode.

A vehicular system includes a measuring unit attached to a vehicle to detect a magnetic marker laid along a traveling road, a database storing position information of the magnetic marker, and a control unit that acquires the position information of the magnetic marker by referring to a storage area of the database. The database has stored therein position information of each magnetic marker to which a distance from a reference point on the traveling road as a starting point to each magnetic marker is linked. By referring to the database by using a distance traveled until the magnetic marker is detected after the vehicle passes over the reference point, position information of newly detected magnetic marker is acquired.

Planning driving sequences of mobile robots and other devices. In one aspect, a method includes receiving an instruction for movement of a device along a supporting surface. The device includes at least one drive wheel and at least one caster that is rotatable about a generally vertical axis. During motion, the caster is configured to reorient so that an swivel joint of the caster to the device leads a wheel of the caster. The method also includes planning a drive instruction for the device to implement the instruction for movement based on an orientation or expected orientation of the at least one caster upon beginning of the movement. The drive instruction is tailored to the drive wheel and the caster of the device and configured to limit reorientation of the caster during motion in accordance with the drive instruction.

Systems and methods for providing opportunities for interactions and communication between vehicles and passengers. In particular, a vehicle socialization platform is provided for facilitating a wide range of social and utilitarian exchanges between vehicles and their occupants, thus providing a community of interconnected vehicles. Vehicle interactions can include passive communication, including vehicles from a particular fleet acknowledging other fleet vehicles without intervention from a passenger or user. Vehicle interactions can include active communication, in which passengers are engaged with and have some control over vehicle communications through dedicated experiences provided in a ridehail application or on an in-vehicle tablet. In particular, some experiences can become dynamically available based on the fleet vehicle's proximity to another fleet vehicle. The vehicle socialization platform is a smart socialization platform that enables two-way communication between vehicles and passengers, facilitating a wide range of social and utilitarian exchanges between vehicles and vehicle occupants.