Abstract: A system and method for operating an electric heater to determine heater functionality is based on actual heater power consumption relative to expected heater power consumption during operating conditions where electrical power consumption by other system components can be accurately estimated. One or more components, including a second heating source, may be controlled based on the heater functionality. The system may include a hybrid vehicle having an engine, an electric heater and heater core, a valve positioned to route coolant through the engine and/or the electric heater, and a controller configured to store a diagnostic code and/or start the engine when the electric heater is commanded on and when the actual energy consumption of the electric heater is below a corresponding threshold.

Abstract: A vehicle includes a navigation system and a processing device. The navigation system is configured to identify a current location of the vehicle, a destination location, and a distance between the current location and the destination location. The processing device is configured to identify a task, associate the task to the destination location, and schedule the task according to the distance from the destination location.

Abstract: A vehicle is provided with a climate control system and a battery that is connected to the climate control system for supplying power. The vehicle also includes at least one controller that is configured to receive input indicative of a battery power limit and a battery state of charge (BSOC). The at least one controller is also configured to disable the climate control system and reduce the battery power limit to an intermediate power limit, when the BSOC is less than a discharge limit.

Abstract: Methods and systems for controlling a fuel tank isolation valve coupled to a fuel tank in a vehicle are disclosed. In one example approach, a method comprises, in response to a refuel request, actuating a fuel tank isolation valve to vent a fuel tank for refueling; and, in response to a pressure in the fuel tank below a threshold pressure after a predetermined time duration, discontinuing actuation of the fuel tank isolation valve to seal the fuel tank.

Abstract: A vehicle comprises a plurality of control module structures. A first control module structure is configured for determining a current motive mode of the vehicle. A second control module structure is configured for determining information indicating that a driver of the vehicle has left the vehicle unattended while the vehicle is in a motive-enabled mode. A third control module structure is configured for causing a secure idle mode to be implemented as a function of determining the information indicating that the driver of the vehicle has left the vehicle unattended while the vehicle is in the motive-enabled mode. Implementing the secure idle mode can include inhibiting the vehicle from being driveable until a driver access code is successfully received and authenticated by the vehicle.

Abstract: A vehicle, a control system for a vehicle having a user interface, and a method of controlling a vehicle are provided. In response to input selecting an electric-only operating mode, an engine is disabled such that the vehicle is propelled by an electric machine. In response to detecting a predefined vehicle state while the electric-only operating mode is selected, the engine is re-enabled such that the vehicle is propelled by at least one of the engine and electric machine. In response to detecting an absence of the predefined vehicle state while the electric-only operating mode is selected, the engine is disabled such that the vehicle is propelled by the electric machine.

Abstract: Methods and systems for controlling a fuel tank isolation valve coupled to a fuel tank in a vehicle are disclosed. In one example approach, a method comprises, in response to a refuel request, actuating a fuel tank isolation valve to vent a fuel tank for refueling; and, in response to a pressure in the fuel tank below a threshold pressure after a predetermined time duration, discontinuing actuation of the fuel tank isolation valve to seal the fuel tank.

Abstract: A vehicle and a method of controlling the vehicle are provided. The vehicle controller is configured to (i) in response to the user interface receiving input selecting an electric-only operating (EV) mode, disable the engine such that the vehicle is propelled by the electric machine, (ii) in response to the user interface receiving input overriding EV mode, re-enabling the engine for a predetermined time period. A vehicle is provided with a controller. In response to input selecting an electric-only operating (EV) mode, an engine is disabled such that the vehicle is propelled by an electric machine. In response to user power demand being greater than power available during the EV mode, a prompt is generated inquiring whether to override the EV mode. In response to user confirmation to override the EV mode, the engine is re-enabled to satisfy the user power demand.

Abstract: A vehicle comprises a plurality of control module structures. A first control module structure is configured for determining a current motive mode of the vehicle. A second control module structure is configured for determining information indicating that a driver of the vehicle has left the vehicle unattended while the vehicle is in a motive-enabled mode. A third control module structure is configured for causing a secure idle mode to be implemented as a function of determining the information indicating that the driver of the vehicle has left the vehicle unattended while the vehicle is in the motive-enabled mode. Implementing the secure idle mode can include inhibiting the vehicle from being driveable until a driver access code is successfully received and authenticated by the vehicle.

Abstract: A vehicle having an electric machine arrangement, including an electric machine operable to drive the vehicle includes a control system having at least one controller. The control system is configured to implement a method for thermal mitigation of the electric machine arrangement. The thermal mitigation strategy is controlled such that a time between successive implementations of the strategy is inversely related to a temperature of at least a portion of the electric machine arrangement, and the time between two successive implementations of the thermal mitigation strategy may decrease with each successive pair of implementations.

Abstract: A vehicle comprises a plurality of control module structures. A first control module structure is configured for determining a current motive mode of the vehicle. A second control module structure is configured for determining information indicating that a driver of the vehicle has left the vehicle unattended while the vehicle is in a motive-enabled mode. A third control module structure is configured for causing a secure idle mode to be implemented as a function of determining the information indicating that the driver of the vehicle has left the vehicle unattended while the vehicle is in the motive-enabled mode. Implementing the secure idle mode can include inhibiting the vehicle from being driveable until a driver access code is successfully received and authenticated by the vehicle.

Abstract: A vehicle is provided with a motor that is configured to provide drive torque and to facilitate regenerative braking. The vehicle also includes a controller that is configured to receive input that is indicative of a vehicle speed and a battery state of charge (BSOC), and to disable the drive torque when the BSOC is less than a maximum discharge limit. The controller is also configured to activate regenerative braking when the BSOC is less than the maximum discharge limit and the vehicle speed is greater than a predetermined speed.

Abstract: A vehicle guidance system is provided with a controller configured to receive input signals indicative of an instantaneous charging port position relative to an external charging pad and a charging status. The controller is further configured to transmit a vehicle status signal in response to the input signals. An interface communicates with the controller, and is configured to display a vehicle position indicator and a charging status message in response to the vehicle status signal.

Abstract: A vehicle is provided with at least one wheel and a motor that is coupled to the wheel. The motor is configured to provide regenerative brake torque. The vehicle also includes at least one controller that is configured to predict future powertrain oscillation based on input indicative of a wheel speed and a total brake torque. The controller is also configured to control the motor to reduce the regenerative brake torque prior to the powertrain oscillation.

Abstract: A vehicle is disclosed that has multiple coolant paths selected by control of a valve. A valve system is configured to direct coolant from an engine to a heat exchanger according to a difference between a temperature associated with the engine and a temperature associated with the heat exchanger. The valve system is also configured to direct coolant from the engine to an electric heater and to, in response to a heat demanded from the heat exchanger being greater than a heat capability of the electric heater, request the engine to run. A method is disclosed for controlling a valve to change from an isolation position in which the valve isolates coolant circulating through an electric heater and the valve from coolant circulating through an engine to a non-isolation position in which the valve directs coolant from the engine to the electric heater.

Abstract: A vehicle and a method of controlling the vehicle are provided. The vehicle controller is configured to (i) in response to the user interface receiving input selecting an electric-only operating (EV) mode, disable the engine such that the vehicle is propelled by the electric machine, (ii) in response to the user interface receiving input overriding EV mode, re-enabling the engine for a predetermined time period. A vehicle is provided with a controller. In response to input selecting an electric-only operating (EV) mode, an engine is disabled such that the vehicle is propelled by an electric machine. In response to user power demand being greater than power available during the EV mode, a prompt is generated inquiring whether to override the EV mode. In response to user confirmation to override the EV mode, the engine is re-enabled to satisfy the user power demand.

Abstract: A vehicle, a control system for a vehicle having a user interface, and a method of controlling a vehicle are provided. In response to input selecting an electric-only operating mode, an engine is disabled such that the vehicle is propelled by an electric machine. In response to detecting a predefined vehicle state while the electric-only operating mode is selected, the engine is re-enabled such that the vehicle is propelled by at least one of the engine and electric machine. In response to detecting an absence of the predefined vehicle state while the electric-only operating mode is selected, the engine is disabled such that the vehicle is propelled by the electric machine.

Abstract: A vehicle has an engine, a fuel tank, and a controller configured to selectively operate the engine, during one or more drive cycles, until a specified fraction of fuel from the tank has been consumed in response to expiration of a predefined time period to limit fuel degradation. A powertrain system has a traction battery, an engine, a fuel tank, and a controller configured to selectively operate the engine in response to a quality of fuel in the tank being below a threshold until a specified fraction of fuel has been consumed, thereby limiting fuel degradation. A method of controlling a vehicle includes, in response to expiration of a predefined time period, selectively operating an engine, during one or more vehicle drive cycles, such that state of charge of a traction battery is generally maintained until a specified fraction of fuel in a fuel tank has been consumed to limit degradation of the fuel.

Abstract: A vehicle and a method for controlling the vehicle include a controller configured to, in response to a user command to delay electric-only operation of the vehicle, selectively operate an electric machine and an engine to propel the vehicle such that a state of charge of a traction battery electrically connected with the electric machine is generally maintained at a target value within a predefined range of states of charge. A vehicle includes a powertrain and a controller. The controller is configured to (i) operate the powertrain in a charge deplete mode and a charge sustain mode, and (ii) in response to a user request, operate the powertrain in the charge sustain mode if the state of charge is within a predefined range of states of charge when the request is received.

Abstract: A system and method for operating an electric heater to determine heater functionality is based on actual heater power consumption relative to expected heater power consumption during operating conditions where electrical power consumption by other system components can be accurately estimated. One or more components, including a second heating source, may be controlled based on the heater functionality. The system may include a hybrid vehicle having an engine, an electric heater and heater core, a valve positioned to route coolant through the engine and/or the electric heater, and a controller configured to store a diagnostic code and/or start the engine when the electric heater is commanded on and when the actual energy consumption of the electric heater is below a corresponding threshold.