Abstract: A vehicle system includes a controller that is programmed to, in response to a speed differential between the vehicle and a forward detected object, decelerate the vehicle at a first rate during a first period via regenerative braking alone and decelerate the vehicle at a second rate during a second period, following the first period, to reduce a distance to the forward detected object from an initial distance to a minimum distance.

Abstract: Example systems and methods to determine electric vehicle range based on environmental factors are disclosed. An example disclosed vehicle includes a battery pack, a HVAC control module, and an electronic control unit that includes a range calculator. The example range calculator determine a base power load, determines an auxiliary power load based on a sun load, an ambient temperature, a cabin temperature, and a temperature setting, and calculates a range of the vehicle based on the base power load, the auxiliary power load and a charge of the battery pack.

Abstract: Systems and methods for operating a vehicle in an electric idle mode are presented. The vehicle electrical idle mode may be characterized as a mode where the vehicle's engine is off; the vehicle increases torque to vehicle wheels responsive to an application of an accelerator pedal, release of a brake pedal, or a vehicle occupant shifting a transmission; and the vehicle's battery supplies electrical energy to devices of the vehicle being operated by a vehicle occupant.

Abstract: A method for balancing electrical grid production with electrical grid demand, according to an exemplary aspect of the present disclosure includes, among other things, adjusting operation of an engine of an electrified vehicle during a drive event to either conserve a state of charge of a battery pack in response to a first grid condition of an electrical grid or deplete the state of charge of the battery pack in response to a second grid condition of the electrical grid.

Abstract: A method for balancing electrical grid production with electrical grid demand according to an exemplary aspect of the present disclosure includes, among other things, controlling an electrified vehicle prior to and during an inductive roadway event to either conserve a state of charge of a battery pack in response to a first grid condition of an electrical grid or deplete the state of charge of the battery pack in response to a second grid condition of the electrical grid.

Abstract: A vehicle may require an electric recharge. A request may be sent to obtain identification of charge locations along a route. Along with the request, data may be sent identifying vehicle location, route, and desired safety rating. A response may be obtained from a remote server, and the results may be displayed, which include the user rating of the charge station. The desired user rating may be adjusted based on the battery's state of charge (SOC). The desired user rating may be decreased as the battery state of charge decreases. The user may further set the desired user rating. The desired user rating may further depend on other ratings of the charging station.

Abstract: A vehicle may require an electric recharge. A request may be sent to obtain identification of charge locations along a route. Along with the request, data may be sent identifying vehicle location, route, and desired safety rating. A response may be obtained from a remote server, and the results may be displayed, which include the user rating of the charge station. The desired user rating may be adjusted based on the battery's state of charge (SOC). The desired user rating may be decreased as the battery state of charge decreases. The user may further set the desired user rating. The desired user rating may further depend on other ratings of the charging station.

Abstract: A method according to an exemplary aspect of the present disclosure includes, among other things, controlling charging of a battery pack of an electrified vehicle over a plurality of charging locations of a drive route, the controlling step including scheduling charging based at least on a cost to charge at each of the plurality of charging locations and an amount of charging time available at each of the plurality of charging locations.

Abstract: A vehicle may require an electric recharge. A request may be sent to obtain identification of charge locations along a route. Along with the request, data may be sent identifying vehicle location, route, and desired safety rating. A response may be obtained from a remote server, and the results may be displayed, which include the safety rating of the charge station. The desired safety rating may be adjusted based on the battery's state of charge (SOC). The desired safety rating, for example, may be decreased as the battery state of charge decreases.

Abstract: A vehicle may require an electric recharge. A request may be sent to obtain identification of charge locations along a route. Along with the request, data may be sent identifying vehicle location, route, and desired safety rating. A response may be obtained from a remote server, and the results may be displayed, which include the safety rating of the charge station. The desired safety rating may be adjusted based on the battery's state of charge (SOC). The desired safety rating, for example, may be decreased as the battery state of charge decreases.

Abstract: A system and method for controlling a vehicle includes controlling a vehicle according to a first mode in response to a calculated likelihood exceeding a threshold likelihood, and controlling the vehicle according to a second mode otherwise. The calculated likelihood corresponds to the likelihood that the vehicle is within a threshold distance of a current drive cycle final destination. The calculated likelihood is derived from geolocation data collected from geolocation systems in at least one vehicle across a plurality of vehicle drive cycles.

Abstract: A system for controlling battery charging in a vehicle includes a traction battery and a controller. The controller is configured to charge the traction battery to a SOC that is less than a maximum SOC based on an amount of charge predicted to be received from an anticipated regenerative braking event. The regenerative braking event is anticipated to occur during the next drive cycle. The target SOC may be set such that, upon occurrence of the anticipated regenerative braking event, the traction battery achieves the maximum SOC.

Abstract: A system for controlling battery charging in a vehicle includes a traction battery and a controller. The controller is configured to charge the traction battery to a SOC that is less than a maximum SOC based on an amount of charge predicted to be received from an anticipated regenerative braking event. The regenerative braking event is anticipated to occur during the next drive cycle. The target SOC may be set such that, upon occurrence of the anticipated regenerative braking event, the traction battery achieves the maximum SOC.