Abstract: Customizable electric vehicle supply equipment (EVSE) systems may be utilized for charging electrified vehicles. Exemplary EVSE systems may include a charging cord assembly having a cable that includes an outer sheath and a lighting module housed within the outer sheath. The lighting module may be controlled to emit lighting effects for providing visual indications of various electrified vehicle charging statuses. Settings associated with the lighting effects may be customized within a human machine interface (HMI) of the EVSE system.

Abstract: A vehicle is provided that includes a sensor arrangement configured to sense one or more regions proximate to an exterior of the vehicle, and a controller configured to process signals generated by the sensor arrangement and to detect and generate a geometric profile of a trailer in the one or more regions proximate to the exterior of the vehicle, the controller further determining an air resistance of the trailer based on the geometric profile and calculating an expected driving range of the vehicle based on the detected air resistance.

Abstract: This disclosure relates to an energy transfer system and method including fully integrated supply devices. An example system includes a supply device having a vehicle port, a converter, and an isolation transformer. The vehicle port is configured to electrically couple the supply device to an electrified vehicle.

Abstract: Battery-powered electrified vehicles towing one or more trailers carrying additional rechargeable batteries results in a multi-battery system for which the act of charging the batteries becomes more challenging. A vehicle driver assistance system hereof aids a driver for identifying recharging stations meeting a desired recharging objective for the combined vehicle/trailer having a main battery and a secondary battery to be recharged. The system guides the driver to a parking location and provides instructions for obtaining a hookup to a recharging station.

Abstract: Systems and methods may coordinate and provide bidirectional energy transfer events between electrified vehicles and households or other structures, such as for supporting transient loads associated with the households/structures, for example. Vehicle information, driving habit information, and household information may be leveraged for providing enhanced transient load capability controls that permit increased appliance usage without increasing energy costs. The proposed systems/methods may particularly allow for bidirectional energy transfer support of high load appliances for increasing a user's comfort, pleasure, and convenience.

Abstract: A pop-up charger management method includes assessing an expected charge demand based on communications from a plurality of electrified vehicles, and, in response to the expected charge demand, starting at least one generator of a pop-up charger. A pop-up charger assembly can include at least one generator; at least one battery; a control module configured to, in response to an expected charge demand, start the at least one generator, the expected charge demand based on communications from a plurality of electrified vehicles.

Abstract: A computer includes a processor and a memory storing instructions executable by the processor to receive data indicating a plurality of tasks to be performed at a site by a plurality of electric machines, receive charge statuses of the electric machines and of a plurality of first electric vehicles at the site, and generate an ordered allocation of a plurality of charging operations for the electric machines and first electric vehicles based on the plurality of tasks and on the charge statuses. The charging operations include charging at least one of the electric machines or first electric vehicles from a second electric vehicle with charge ports that is scheduled to visit the site from offsite.

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: Charging cord assemblies for transferring power between electrified vehicles during in-flight bidirectional energy transfer events may include a cable including a wire bundle coated with a conductive foamed plastic shielding to establish a cable subassembly. The conductive foamed plastic shielding is configured to reduce electromagnetic interference (EMI) of the cable. Various cable routing arrangements may be utilized for routing the cable of the charging cord assembly during the in-flight bidirectional energy transfer events.

Abstract: Systems and methods are configured for coordinating and providing passthrough charging during bidirectional energy transfer events between two or more electrified vehicles. The ability to pass charging power from one vehicle to another allows for multiple vehicles to be concurrently charged from a single charge source. Various passthrough charging strategies may be achieved with the proposed systems, including but not limited to, a distributed charging strategy, a waterfall charging strategy, a targeted charging strategy, an automated charging strategy, a pay-for-use charging strategy, etc.

Abstract: Systems and methods may coordinate and provide bidirectional energy transfer events between electrified vehicles and other vehicles, devices, and/or structures. A power outage map can automatically be generated in response to a power outage condition of a grid power source. Both a power outage zone and a predicted power outage zone may be identified within the power outage map. A notification, alternative drive route recommendation, etc. may be sent to users of the bidirectional energy transfer system who are operating their vehicles near the power outage zone or the predicted power outage zone.

Abstract: Systems and methods may coordinate and provide bidirectional energy transfer events between electrified vehicles and other devices or structures, such as for supporting transient loads associated with the devices/structures. Battery life information and driving habit information may be leveraged for selecting an appropriate energy transfer strategy for any given vehicle, traction battery pack, structure, and/or grid power source condition. The proposed systems/methods may thereby align grid demand charge strategies to each vehicle's battery life, thereby preserving the life/warranty and asset utilization of the traction battery pack over the entire usage life of the vehicle.

Abstract: Systems and methods are disclosed for coordinating and executing bidirectional energy transfer events between electrified vehicles and one or more participating electrified recreational vehicles. Energy may be transferred from an electrified vehicle to one or more electrified recreational vehicles, from the one or more electrified recreational vehicles to the electrified vehicle, or both during bidirectional energy transfer events. The proposed systems and methods may further be configured to provide various charging configurations between the electrified vehicle and the one or more electrified recreational vehicles.

Abstract: Systems and methods may coordinate and execute bidirectional energy transfer events between electrified vehicles and other devices or structures. Weather related data and/or grid related data may be leveraged for predicting the likelihood of power outage conditions of a grid power source. When power outage conditions are likely, a charging storage limit of a traction battery pack of the electrified vehicle may be automatically increased. The increased charging storage limit temporarily increases the energy storage capacity of the traction battery pack in anticipation of expected power outage conditions, thereby better preparing the traction battery pack for use as a backup power source during the power outage conditions.

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: 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 vehicle charging system includes a vehicle propelled by an electric machine powered by a chargeable energy storage system. The charging system also includes a controller programmed to predict at least one upcoming plug-in event based on historical charging data, and define a plug-in routine based on a plurality of upcoming plug-in events. The controller is also programmed to set a charging schedule to coincide with the plug-in routine such that a target state of charge (SOC) is achieved at a conclusion of each of the plurality of upcoming plug-in events. Each target SOC corresponding to a plug-in event is based on minimizing a charging energy cost of the plug-in routine and an expected energy depletion ahead of a next subsequent plug-in event.

Abstract: An indicator assembly includes, among other things, a vehicle model that is configured to communicate with a vehicle. The indicator assembly further includes an indicator portion of the vehicle model. The indicator portion is configured to indicate a status of the vehicle based on a communication sent to the vehicle model.

Abstract: Systems and methods for logging images using integrated cameras, lights, and sensors of a vehicle are provided. The system may include a handheld actuator, e.g., a key fob, having a button for initiating the taking of a photo or the start or stop of the recording of a video by the integrated cameras of the vehicle. Moreover, the actuator may select lighting settings such that the integrated lights of the vehicle may illuminate the vicinity of the vehicle to create a flash effect for a photo, or illuminate the vicinity of the vehicle for a video. The image data captured by the cameras may be at least temporarily stored, and transmitted to, e.g., a mobile device within a predetermined range of the vehicle.

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.