A server comprises: a communication unit configured to receive, from an ordering terminal, work request information entered by an orderer of work and indicating a specific piece of the work and working time required for the specific work content; a required skill level determination unit configured to determine, based on the work request information received by the communication unit, a required skill level indicating a skill for remote control required for an operator by the orderer; an operator database storing respective skill levels of a plurality of operators; and an information list generation unit configured to extract from the operator database an operator having a skill level equal to or higher than the required skill level and generate an operator information list for presenting the extracted operator to the orderer, and the communication unit transmits the operator information list to the ordering terminal.

Methods and systems are disclosed for providing vehicular driver alerts. In various aspects a vehicle operating environment may be monitored by one or more sensors associated with a first vehicle operating within the vehicle operating environment. The first vehicle may be determined to be in proximity to a second vehicle based upon sensor data obtained from the one or more sensors. An identifier associated with the second vehicle may be determined based upon the sensor data and the identifier may be used to receive evaluation data associated with the second vehicle. The evaluation data may indicate a quality level associated with operation of the second vehicle. Based upon the evaluation data, it may be determined that the second vehicle is associated with a heightened risk of a vehicle accident. A warning regarding the heighted risk may be generated and presented, by an output device, to a vehicle operator of the first vehicle.

Systems and methods for providing driver training in a virtual reality environment are disclosed. According to some aspects, an appropriate virtual reality driving simulation may be determined based on one or more input parameters provided by a user. The virtual reality driving simulation may include: (i) an instructional lesson, to be rendered in virtual reality, for teaching driving-related rules and/or skills to a user, and (ii) a driving scenario, to be rendered in virtual reality, for the user to practice the driving-related rules and/or skills taught by the instructional lesson. While the virtual reality driving simulation is rendered, user performance data may be recorded. Based on an analysis of the user performance data, a driving competency score and/or user feedback may be determined.

Systems and methods for providing driver training in a virtual reality environment are disclosed. According to some aspects, an appropriate virtual reality driving simulation may be determined based on one or more input parameters provided by a user. The virtual reality driving simulation may include: (i) an instructional lesson, to be rendered in virtual reality, for teaching driving-related rules and/or skills to a user, and (ii) a driving scenario, to be rendered in virtual reality, for the user to practice the driving-related rules and/or skills taught by the instructional lesson. While the virtual reality driving simulation is rendered, user performance data may be recorded. Based on an analysis of the user performance data, a driving competency score and/or user feedback may be determined.

Systems and methods for monitoring the use of a shared vehicle are described. In various aspects, telematics data regarding operation of a shared vehicle is collected from one or more sensors, where the shared vehicle is associated with a shared vehicle operator and a shared vehicle stakeholder. One or more processors determine whether a driving event has occurred based upon the telematics data, where the driving event is indicative of improper usage of the shared vehicle by the shared vehicle operator. The one or more processors generate a notification regarding the driving event. The notification includes a driver rating determined from the telematics data regarding operation of the shared vehicle by the shared vehicle operator. The notification is transmitted, via a network, to the shared vehicle stakeholder for presentation to the shared vehicle stakeholder.

Approaches for analyzing driver pattern deviations and reproducing the pattern deviations in a user interface or a driving simulator are provided. A computer-implemented method includes: collecting, by a server, data from plural vehicles; determining, by the server, a baseline for a driving action based on the data from the plural vehicles; identifying, by the server, a problem action for a driver based on the baseline; and generating, by the server, an interface to display the problem action.

Approaches for analyzing driver pattern deviations and reproducing the pattern deviations in a user interface or a driving simulator are provided. A computer-implemented method includes: collecting, by a server, data from plural vehicles; determining, by the server, a baseline for a driving action based on the data from the plural vehicles; identifying, by the server, a problem action for a driver based on the baseline; and generating, by the server, an interface to display the problem action.

A vehicle remote instruction training device that trains a remote commander who issues a remote instruction to an actual autonomous vehicle includes: a commander interface including an information output unit that shows a situation of the actual autonomous vehicle to the remote commander and an instruction input unit for the remote commander to input the remote instruction to the actual autonomous vehicle; a virtual situation display unit that shows a virtual situation of a virtual vehicle with time variation to a remote commander who is a trainee through the information output unit; a remote instruction input recognition unit that recognizes an input of the remote instruction input into the instruction input unit; and an evaluation unit that evaluates the remote commander based on timing at which they issue the remote instruction with respect to the virtual situation of the virtual vehicle or on a content of the remote instruction.

A vehicle remote instruction training device that trains a remote commander who issues a remote instruction to an actual autonomous vehicle includes: a commander interface including an information output unit that shows a situation of the actual autonomous vehicle to the remote commander and an instruction input unit for the remote commander to input the remote instruction to the actual autonomous vehicle; a virtual situation display unit that shows a virtual situation of a virtual vehicle with time variation to a remote commander who is a trainee through the information output unit; a remote instruction input recognition unit that recognizes an input of the remote instruction input into the instruction input unit; and an evaluation unit that evaluates the remote commander based on timing at which they issue the remote instruction with respect to the virtual situation of the virtual vehicle or on a content of the remote instruction.

An interactive vehicle simulation system having a virtual reality engine that generates a virtual operating environment that includes a user operated vehicle having a plurality of wheel types, a vehicle position, vehicle orientation, vehicle velocity and vehicle acceleration.