Abstract: Information of a plurality of locations on a route for a vehicle is received. A plurality of segments of the route is identified based at least in part on the information. A specified state of charge of a vehicle battery and a specified power output of an engine are determined for each of the segments based at least in part on the information. One or more vehicle subsystems is actuated to navigate each of the segments to change a current state of charge of the vehicle battery to the specified state of charge.

Abstract: A computer in a vehicle can determine a first distance from a vehicle to a traffic object and receive, via a network interface, a second distance from a second vehicle to the traffic object and a third distance from the second vehicle to the vehicle. The computer can determine a fourth distance by triangulation based on the second distance and the third distance and pilot the vehicle based on combining the first distance and the fourth distance.

Abstract: Signals are from a plurality of sources representing aspects of the vehicle and an environment surrounding the vehicle. An autonomous confidence factor is developed based on component confidence levels for at least one of the signals. Control of the vehicle is transitioned between levels of autonomous control based at least in part on the autonomous confidence factor.

Abstract: A system includes a processor programmed to send first and second recommended routes to a wireless device in response receiving a present vehicle location stored when the vehicle was parked and also a received destination and departure time. The first recommended route is based on travel-time factors corresponding to the destination and departure time and specified routing and timing preferences. The second recommended route is based on a calculated alternative departure time using the specified preferences.

Abstract: Methods and systems are provided for adjusting grille shutters based on engine coolant temperature and a difference in aerodynamic drag between the grille shutter positions. In one example, the grille shutters may be adjusted into a position closer to a first smaller opening when a difference in aerodynamic drag between the first and second positions is large. In other examples, the grille shutters may be adjusted into a position closer to the second larger opening when a difference in aerodynamic drag between the first and second positions is small thus maintaining the engine at lower temperatures.

Abstract: A heating, ventilating, and air conditioning (HVAC) system has a steerable outlet for directing a stream of treated air into a passenger compartment of a vehicle. A thermographic imager is configured to capture thermographic images covering a fixed region within the passenger compartment in which an occupant is potentially located. The HVAC control circuit is configured to a) compress a thermographic image to a temperature map representing pixels of the thermographic image falling within a predetermined temperature range corresponding to the occupant, b) filter the temperature map according to a sliding window to coalesce continuous regions of pixels on average falling within the predetermined temperature range, c) quantify an area for each continuous region, d) locate a centroid of a continuous region having a largest area, and e) aim the steerable outlet toward the centroid.

Abstract: A heating, ventilating, and air conditioning (HVAC) system has a steerable outlet for directing a stream of treated air into a passenger compartment of a vehicle. A thermographic imager is configured to capture thermographic images covering a fixed region within the passenger compartment in which an occupant is potentially located. The HVAC control circuit is configured to a) compress a thermographic image to a temperature map representing pixels of the thermographic image falling within a predetermined temperature range corresponding to the occupant, b) filter the temperature map according to a sliding window to coalesce continuous regions of pixels on average falling within the predetermined temperature range, c) quantify an area for each continuous region, d) locate a centroid of a continuous region having a largest area, and e) aim the steerable outlet toward the centroid.

Abstract: A hybrid powertrain system for a vehicle includes an electric machine, a gear set mechanically connected with the electric machine, and a clutch mechanically coupled with at least one of a primary and secondary driveline assembly. The electric machine is configured to selectively provide motive power to at least one of the primary and secondary driveline assemblies. The gear set is configured to permit differential rotation between the primary and secondary driveline assemblies. The clutch is configured to selectively transfer torque between the primary and secondary driveline assemblies.

Abstract: A driver of a vehicle is alerted if an air passage from an air source to a battery becomes blocked. The determination as to whether the air passage is blocked may be based on the temperature of the battery, the airflow through the air passage, and the power to a fan used to move air through the air passage.

Abstract: A heating, ventilating, and air conditioning (HVAC) system has a steerable outlet for directing a stream of treated air into a passenger compartment of a vehicle. A thermographic imager is configured to capture thermographic images covering a fixed region within the passenger compartment in which an occupant is potentially located. The HVAC control circuit is configured to a) compress a thermographic image to a temperature map representing pixels of the thermographic image falling within a predetermined temperature range corresponding to the occupant, b) filter the temperature map according to a sliding window to coalesce continuous regions of pixels on average falling within the predetermined temperature range, c) quantify an area for each continuous region, d) locate a centroid of a continuous region having a largest area, and e) aim the steerable outlet toward the centroid.

Abstract: A method according to an exemplary aspect of the present disclosure includes, among other things, controlling an electrified vehicle by adjusting a deceleration rate based on a closing rate of the electrified vehicle to an oncoming object.

Abstract: A vehicle system includes a processor and a memory accessible to the processor and storing instructions executable by the processor. The instructions include detecting a handoff request indicating a transition of a host vehicle from an autonomous mode of operation to a non-autonomous mode of operation and assessing driver competency. The handoff request is approved if the driver competency exceeds a predetermined threshold. Likewise, the handoff request is denied if the driver competency fails to exceed the predetermined threshold.

Abstract: A method for controlling a vehicle includes automatically controlling vehicle brakes to decelerate the vehicle at a braking deceleration rate in response to an anticipated stop at a traffic signal and an adaptive cruise control system being active. The method further includes, in response to the vehicle decelerating to an intermediate speed, releasing the vehicle brakes. The intermediate speed is determined such that, at the intermediate speed, a coasting distance to a full stop is approximately equal to a distance to the traffic signal.

Abstract: A hybrid vehicle includes an engine; a traction battery; and a controller or a vehicle control system having a controller. The controller is programmed to respond to a state of charge (SOC) of the traction battery. When the SOC is greater than a predicted SOC the controller is programmed to decrease a SOC threshold at which the engine is shut down to reduce the SOC. The SOC threshold is defined by a difference between a maximum SOC and an expected change in the SOC associated with predicted regenerative energy for a drive cycle.

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: Signals are received from a plurality of sources, representing aspects of the vehicle, a vehicle operator, and an environment surrounding the vehicle. An alertness factor and a readiness factor are developed based at least in part on the signals. Control of the vehicle is transitioned between levels of autonomous control based at least in part on the alertness factor and the readiness factor.

Abstract: An action probability factor is developed based at least in part on a plurality of probability arrays predicting one or more probabilities of a deviation from at least one of a planned vehicle direction, position, speed, and acceleration. Levels of autonomous control are transitioned based at least in part on the action probability factor.

Abstract: Signals are received from a plurality of sources, representing operating characteristics of a vehicle and an environment surrounding the vehicle. A plurality of operational factors are developed based on the signals. The vehicle is controlled according to one of at least three levels of control, including an autonomous, a semi-autonomous, and a manual level of control, based on the operational factors.

Abstract: At least one object having a risk of collision with the vehicle is detected. Levels of autonomous control are transitioned in response to detection of a potential collision based at least in part on an autonomous peril factor which includes a probability of collision and a magnitude of possible damage in the event of a collision.