Abstract: Systems and methods are provided for routing one or more electrified vehicles in a manner that improves battery life. The proposed systems and methods may utilize a multi-objective approach to route planning. The multi-objective approach may account for factors such as time, energy consumption, and battery life. Origin-destination matrices may be leveraged for providing the multi-objective route planning approaches.

Abstract: The disclosure describes systems and methods that are configured to measure and generate parking environment data including locations of parking spaces and their occupancy status, and to use the parking environment data to find an unoccupied parking space for a vehicle. In particular, a system is configured to determine the location and occupancy status of parking spaces based on parking environment data received from a vehicle, and to determine a location of an unoccupied parking space based on a database of parking environment data.

Abstract: A transportation vehicle provides a workspace in a passenger cabin to support a teleconference with a remote party. External sensors are configured to scan the exterior of the vehicle and detect a pedestrian. A sound exciter is configured to generate a masking noise directed to the exterior. A control circuit which enhances privacy of the teleconference is configured to A) detect the audio content of the teleconference being present in the interior of the vehicle, B) quantify an interior sound level of the audio content, C) estimate a discernability of the audio content at an external location corresponding to the detected pedestrian, and D) activate the sound exciter such that the masking noise is adapted to mask the audio content at the external location.

Abstract: A transportation vehicle provides a workspace in a passenger cabin to support a teleconference with a remote party. External sensors are configured to scan the exterior of the vehicle and detect a pedestrian. A sound exciter is configured to generate a masking noise directed to the exterior. A control circuit which enhances privacy of the teleconference is configured to A) detect the audio content of the teleconference being present in the interior of the vehicle, B) quantify an interior sound level of the audio content, C) estimate a discernibility of the audio content at an external location corresponding to the detected pedestrian, and D) activate the sound exciter such that the masking noise is adapted to mask the audio content at the external location.

Abstract: Responsive to indication that a predicted amount of solar or wind power from a power generating event will exceed a power storage capability of one or more power storage devices configured to receive the solar or wind power, controllers may command the one or more power storage devices to discharge energy to a power grid before the power generating event such that the power storage capability of the one or more power storage devices increases.

Abstract: Systems and methods may coordinate and execute bidirectional energy transfer events between electrified vehicles and one or more participating electrified recreational vehicles. The proposed systems and methods may be configured to provide charging alert notifications from the electrified vehicle to the one or more electrified recreational vehicles during group off-roading events. The charging alert notifications indicate the need for the one or more electrified recreational vehicles to return to the electrified vehicle for charging during the off-roading event in order to avoid a no start/stranded condition.

Abstract: A computer is programmed to allocate a plurality of electric vehicles with associated electric machines to locations to perform tasks based on the charges of the electric vehicles and electric machines and expected energy consumptions of the electric vehicles traveling to the locations and of the electric machines performing the tasks at the locations; and in response to a sum of the charges of a first electric vehicle and the electric machines associated with the first electric vehicle being less than a sum of the expected energy consumptions of the first electric vehicle traveling to a first location and of the electric machines associated with the first electric vehicle performing the tasks at the first location, instruct a second electric vehicle to travel to a second location at which the first electric vehicle will be located.

Abstract: In some aspects, the techniques described herein relate to an outdoor heating system for a motor vehicle, including: a heater electrically connected to a power source of the motor vehicle and to a controller of the motor vehicle, wherein the heater is at least partially outside the motor vehicle, and wherein the controller is configured to issue commands to the heater to selectively adjust an output level of the heater and to selectively adjust an orientation of the heater.

Abstract: A fleet charging method and system include a plurality of chargers and a controller programmed to predict charge demand for fleet vehicles over a predetermined time interval and generate a charging strategy for the predetermined time interval including selecting at least one of a plurality of power sources for the plurality of chargers from at least a utility grid and a subset of fleet vehicles having stored charge capacity exceeding an associated threshold in response to: a predicted power factor of the utility grid during the predetermined time interval; meeting the predicted charge demand for the fleet vehicles; and minimizing a total energy expense for meeting the predicted charge demand.

Abstract: Systems and methods are provided for coordinating and controlling power flow during bidirectional energy transfer events between an electrified vehicle and one or more charging trailers. The systems and methods may prioritize energy transfers between each connected energy unit based on various parameters, including but not limited to battery prognostic information, driving habits/predicted behavior, user preferences, etc. Charge energy may be transferred to the appropriate energy unit using a semi-automated approach to meet customer needs with varying levels of priority according to an energy transfer prioritization control strategy that is derived from the various inputs that are considered.

Abstract: Systems and methods are provided for coordinating and controlling power flow during bidirectional energy transfer events between an electrified vehicle and one or more charging trailers. The systems and methods may prioritize energy transfers between each connected energy based on a charge priority selection that may be manually input by a user of the system. Charge energy may be transferred to the appropriate energy unit using such a manual approach to meet customer needs with varying levels of priority according to an energy transfer prioritization control strategy that is derived from various inputs that are considered.

Abstract: Charge adaptors may be provided as part of a bidirectional energy transfer system for charging multiple vehicles from a single power source. An exemplary charge adaptor may enable intelligent charging of multiple vehicles from the power source through various configurations (e.g., daisy-chain, multiplex, etc.) and strategies (e.g. sequential, parallel, staged, etc.). A microcontroller of the charge adaptor may serve as the primary controller of energy flow through a bidirectional energy transfer system, with other connected devices such as the charge source, vehicles, and other charge adaptors configured to function as periphery control devices. The charge adaptor may implement an AC coupled design in which a common voltage bus is utilized to splice energy to other charge adaptors for enabling bidirectional energy transfers.

Abstract: Responsive to indication that a predicted amount of solar or wind power from a power generating event will exceed a power storage capability of one or more power storage devices configured to receive the solar or wind power, controllers may command the one or more power storage devices to discharge energy to a power grid before the power generating event such that the power storage capability of the one or more power storage devices increases.

Abstract: Systems and methods are provided for coordinating and providing bidirectional energy transfer events between electrified vehicles and households or other structures, such as for supporting household loads associated with the structures during power outage conditions. In some implementations, available energy may be rationed from the vehicle to the structure based on a power outage restoration estimate. Rather than supporting household loads with constant energy during power outage conditions, the disclosed systems/methods may provide strategic rationing of bidirectional energy transfer in order to extend appliance operation for the duration of power outage conditions.

Abstract: A controller may, after receiving indication that an electric utility provider will reduce power supplied during an upcoming period of time, increase a cost of charge energy for vehicles that charge at a rate at least equal to a threshold rate during the upcoming period of time. The controller may also decrease the cost of charge energy for vehicles that avoid charging or charge at a rate less than the threshold rate during the upcoming period of time.

Abstract: Systems and methods are provided for coordinating and controlling power flow during in-flight bidirectional energy transfer events between an electrified vehicle, one or more charging trailers, and optionally, one or more electrified recreational vehicles. The systems and methods may prioritize energy transfers between each connected energy unit based on various parameters, including but not limited to in-transit travel logistics, environmental information, time of day, etc. Charge energy may be transferred to the appropriate power source to meet customer needs with varying levels of priority according to an energy transfer prioritization control strategy that is derived from the various inputs that are considered.

Abstract: The disclosure generally pertains to systems and methods for providing a monitoring service for a pedestrian. In an example method, a request for activation of a monitoring service can be received. The request can include a present location and a destination. Upon receiving the request for activation of the monitoring service, a travel route can be determined from the present location to the destination. As a traveler travels along the travel route, each of one or more vehicles along the travel route may be activated. Each of the one or more vehicles can be configured to stream at least one video feed when the traveler is proximate to the each of the one or more vehicles. The monitoring service can be terminated when the traveler has reached the destination.

Abstract: A power system includes a bidirectional power transfer inverter that receives grid power, and an auxiliary battery electrically connected with the bidirectional power transfer inverter. The auxiliary battery supplies power to the bidirectional power transfer inverter to activate circuitry of the bidirectional power transfer inverter when the grid power is unavailable.

Abstract: A power system includes a bidirectional power transfer inverter that receives grid power and can be electrically connected with electric vehicle supply equipment, and an auxiliary battery electrically connected with the bidirectional power transfer inverter and that supplies power to the bidirectional power transfer inverter and electric vehicle supply equipment while the grid power is unavailable.

Abstract: A driver assistance system aids a driver in charging one or more trailer-mounted batteries in a trailer being towed by an electrified passenger vehicle. Many existing charging facilities for electric vehicles have charging stalls with a layout configured to accommodate single vehicles. Charging facilities having drive-through or elongated charging stalls able to accommodate larger vehicles which are towing an electrified trailer are much scarcer. When attempting to charge a trailer-mounted battery in a charging stall meant for a single vehicle, it may be necessary to unhitch (i.e., decouple) the trailer while in the charging stall so that the passenger vehicle does not block the aisles of a charging station. Sensors in the vehicle perform a sensor sweep of a selected charging stall, and after unhitching, the trailer uses an independent drive system to park itself in the selected charging stall using driving commands which are calculated from the sensor sweep.