Abstract: A vehicle includes a powertrain and an electric parking brake. A controller activates the electric parking brake in response to the powertrain transitioning to an off state that inhibits production of propulsive torque during an ignition cycle when a vehicle speed is less than a predetermined speed and in a presence of conditions that inhibit the powertrain from transitioning to an on state that permits production of propulsive torque.

Abstract: A vehicle includes an engine configured for autostop and autostart. The vehicle further includes an electric actuator for an active front steering system. Before the engine is autostopped, a controlled decrease in demand current for the electric actuator is initiated. After the engine is autostarted, a controlled increase in demand current for the electric actuator is initiated.

Abstract: A vehicle includes an engine with auto-stop and auto-start functions. The vehicle additionally includes a braking system configured to apply braking torque to vehicle wheels. The vehicle further includes a controller configured to control the engine and braking system via an ACC system in response to a detected forward object. The controller is configured to automatically control the braking system in response to a distance to the detected forward object falling below a first predefined threshold and a vehicle speed falling below a second predefined threshold. In response to these inputs, the controller automatically controls the braking system to apply a braking torque to hold the vehicle stationary in the absence of powertrain torque based on a current road grade. The controller additionally controls the engine to auto-stop in response to these inputs.

Abstract: A vehicle climate control system includes a heat exchanger to heat ambient air using engine waste heat, and a plurality of positive temperature coefficient (PTC) heating elements to heat air passed through the heat exchanger. The vehicle also includes a controller programmed to, while the vehicle is driven without engine propulsion, issue a command to sequentially de-energize the PTC heating elements before an upcoming engine activation. The sequential de-energization of the PTC heating elements is performed according to a schedule that is based upon a power surge dissipation time.

Abstract: A controller may be configured to respond to an engine start condition that occurs while an SOC of the battery is within a first predetermined range by running an engine until first occurrence of the start condition ceasing or the SOC achieving a target. The controller may further be configured to respond to an engine start condition that occurs while the SOC is within a second predetermined range less than the first by running the engine until the SOC achieves the target.

Abstract: Methods for improving operation of a stop-start system of a vehicle include controlling an electrical load delivered to an electrically heated windshield (HWS) subsystem of the vehicle prior to a stop cycle or a start cycle of the stop-start system. The methods include steps of discontinuing the electrical load delivered to the HWS subsystem for a predetermined time period prior to a determined predicted stop cycle of the stop-start system. The methods further include differently apportioning the electrical load delivered to a passenger's side and a driver's side of the HWS subsystem. The differently apportioning may be according to a determined ambient temperature value, and further may include steps of differently apportioning the electrical load for predetermined time periods determined according to the ambient temperature value. Vehicle stop-start systems and vehicles implementing the methods are described.

Abstract: A vehicle includes an engine with auto-stop and auto-start functions. The vehicle additionally includes a braking system configured to apply braking torque to vehicle wheels. The vehicle further includes a controller configured to control the engine and braking system via an ACC system in response to a detected forward object. The controller is configured to automatically control the braking system in response to a distance to the detected forward object falling below a first predefined threshold and a vehicle speed falling below a second predefined threshold. In response to these inputs, the controller automatically controls the braking system to apply a braking torque to hold the vehicle stationary in the absence of powertrain torque based on a current road grade. The controller additionally controls the engine to auto-stop in response to these inputs.

Abstract: A vehicle includes a rear visibility component having a heating element. The vehicle further includes an engine and at least one controller programmed to auto-start and auto-stop the engine. The at least one controller is programmed to inhibit the auto-stop of the engine in response to receiving an auto-stop request while the engine is on and the heating element has been operating less than a predetermined time. In some configurations, the at least one controller is programmed to auto-start the engine and operate the heating element at a full power level in response to expiration of a time period that began with an auto-stop of the engine that occurred after the engine auto-stop was inhibited.

Abstract: A vehicle includes an engine having auto-stop and auto-start conditions. The vehicle additionally includes a braking system having an auto-hold function. The auto-hold function is configured to, after braking the vehicle to a full stop, automatically apply braking torque independent of a brake pedal position. The vehicle further includes a controller configured to, in response to the engine being in the auto-stop condition, the auto-hold function automatically applying braking torque, and a gear shifter being moved out of a gear other than PARK, maintain the engine in the auto-stop condition.

Abstract: A method of operating a heating, ventilation and air-conditioning system of a plug-in hybrid electric vehicle, comprising during a first engine-running condition, where a vehicle window or vent is in a more closed position, operating a climate control system to provide a user requested level of thermal comfort, and during a second engine-running condition, wherein the vehicle window or vent is in a less closed position, limiting the performance of the climate control system and biasing shared vehicle resources to provide additional fuel economy. In this manner, thermal comfort of the vehicle passengers can be maintained while providing additional fuel economy.

Abstract: A method of operating a heating, ventilation and air-conditioning system of a plug-in hybrid electric vehicle, comprising during a first engine-running condition, where a vehicle window or vent is in a more closed position, operating a climate control system to provide a user requested level of thermal comfort, and during a second engine-running condition, wherein the vehicle window or vent is in a less closed position, limiting the performance of the climate control system and biasing shared vehicle resources to provide additional fuel economy. In this manner, thermal comfort of the vehicle passengers can be maintained while providing additional fuel economy.