A power management system includes a sensor interface that receives sensor data samples during operation of a vehicle. A storage device stores the sensor data samples for multiple points in time along a route segment traveled by the vehicle. One or more processors analyze the sensor data samples to detect a historical pattern of the vehicle. The one or more processors determine time efficient operational parameters for the vehicle in response to a destination and an estimated travel time to the destination. The estimated travel time may be based on predicted conditions of the vehicle indicated by the historical pattern. The time efficient operational parameters may be selected to decrease the estimated travel time. At least one of the sensor data samples may include telemetry data.

The present invention relates to an electric vehicle charging device and to a method for controlling same. The electric vehicle charging device includes a plurality of charging cables installed in one electric vehicle charger. After battery charging of a vehicle, which has arrived first, is completed using one charging cable, a next vehicle is immediately charged using another charging cable such that even in a state where the vehicle, which has arrived first, does not leave a charging station, the next vehicle can be charged. Accordingly, it is possible to improve convenience of an electric vehicle user, and minimize waiting time for charging. Therefore, it is possible to improve the operational efficiency of the electric vehicle charger.

Systems and methods for facilitating an operation of an electric off-road vehicle are provided. A method includes determining an estimated battery consumption data for a planned trip along a route including an off-road trail with the electric off-road vehicle using past battery consumption data and communicating the estimated battery consumption data for the planned trip to an operator of the electric off-road vehicle. When the electric off-road vehicle is travelling along the off-road trail, the method includes receiving actual battery consumption data associated with the electric off-road vehicle, and revising the estimated battery consumption data for the planned trip based on the actual battery consumption data. The revised estimated battery consumption data is communicated to the operator of the electric off-road vehicle during the planned trip.

Systems and methods for a safety control framework for automated driving systems in which a second controller—with different/diverse hardware and/or software than the first controller—verifies whether a path plan generated by the first controller meets certain safety conditions and preempts the first controller from controlling automated driving of the host vehicle in response to determining that the path plan does not satisfy the safety conditions. In some implementations, the second controller is configured to preempt the first controller by operating the vehicle under automated control using a safety path plan generated by the second controller.

The charging/discharging time of electric vehicle is shortened. The charging/discharging management system includes: a first acquisition controller configured to acquire vehicle information including vehicle capabilities regarding charging/discharging capabilities of multiple electric vehicles; a second acquisition controller configured to acquire device information including device capabilities regarding charging/discharging capabilities of multiple charging/discharging devices capable of charging/discharging the electric vehicles; and an assigning controller configured to compare the vehicle capabilities and assign the charging/discharging device having a high device capability among the charging/discharging devices for which device information has been acquired in the second acquisition controller, to the electric vehicle having a high vehicle capability.

The present disclosure provides a method of providing guidance for use of electric power of an electric vehicle capable of limiting use of electric power in a vehicle-to-load (V2L) mode or providing various pieces of information on use of the electric power. The method includes receiving information on a set travel route to an electric vehicle charging station in the V2L mode, calculating battery energy requirements necessary for the vehicle to move from the current location to a charging station along the travel route, calculating available amount of energy in the V2L mode based on the battery energy requirements and the current amount of energy of a battery, calculating an available usage time of an electronic product based on electric power consumption per unit time of the electronic product and the available amount of energy, and displaying the available usage time of the electronic product through an information-providing device.

The embodiments of the application provide a battery swapping method, a server and a battery installing-and-removing device. The battery swapping method comprising: receiving battery swapping status information of an electric vehicle; sending a battery removing instruction to a battery installing-and-removing device based on the battery swapping status information; sending a battery installation instruction to the battery installing-and-removing device when detecting that the first battery is transported to the first position; receiving the battery installation information sent by the battery installing-and-removing device; sending a battery swapping completion instruction to the electric vehicle based on the battery installation information.

A vehicle controller includes a processing unit which creates a power-supply plan that ensures a first amount of electric power needed for the vehicle to arrive at the destination from the current location along a travel route. The travel route includes a specified section on which wireless power-supply equipment, among a plurality of power-supply equipment, is disposed. Using weather information including the specified section, the processing unit creates the power-supply plan in which a ratio of a second amount of electric power, which is supplied from the at least one wireless power-supply equipment to the vehicle, to the first amount of electric power is less in a first case in which deposition is determined to be present on the specified section than in a second case in which deposition is determined to be not present on the at least one specified section.

Provided is a frequency determination unit that determines whether a prohibition frequency at which a drive source control unit prohibits a vehicle from being put in an EV priority mode is equal to or higher than a second threshold value when the vehicle has traveled between a predetermined location and a destination in the past in a state in which a specific target SOC is set to a value lower than a EV-SW permission SOC. When the frequency determination unit determines that the prohibition frequency is equal to or higher than the second threshold value and when the vehicle travels between the predetermined location and the destination, a low SOC control unit adjusts at least one of the specific target SOC and the EV-SW permission SOC such that the specific target SOC becomes a value that is equal to or higher than the EV-SW permission SOC.

Disclosed are a method of improving fuel efficiency of a fuel cell electric vehicle, and an apparatus and a system therefor. The method includes collecting navigation information and vehicle speed information, calculating a coasting line when a specified event point is detected based on the navigation information, determining whether deceleration is necessary by comparing a current traveling speed with a coasting line speed corresponding to a current location, and changing a criterion for determining whether to enter a fuel cell stop (FC STOP) state when the deceleration is necessary as a determination result.