Abstract: A vehicle seating assembly includes a plurality of horizontal members, a plurality of vertical members, and a plurality of corner members, which define a seat frame. The plurality of corner members are configured to snap-fit into the plurality of horizontal and vertical members. A seatback is disposed behind the seat frame. A low-pressure compression mold is disposed over the seat frame and defines at least one open section. A subassembly is disposed over the compression mold, defining a center seat and including at least one cushion attachment support disposed adjacent to the at least one open section. A seat cushion insert is operably coupled to the at least one cushion attachment support and is disposed over the at least one open section and defining a side seat.

Abstract: A front end assembly including a stepped deflector assembly. The stepped deflector assembly includes a first step attached to one end of a bumper. The first step includes an inner front leg and an intermediate leg. The second step includes an outer front leg and a rear leg. The intermediate leg and rear leg have ends that are disposed adjacent a frame rail, but that are not attached to the frame rail. In a collision, the first and second inner ends of the first and second step, respectively, are driven laterally into the frame rail to reduce intrusions into the passenger compartment of the vehicle.

Abstract: A recirculating-ball style gearbox for a vehicle steering system is provided. The gearbox has a rack with rack-teeth that are capable of providing variable ratio steering, where the rack-teeth are in mesh with the involute-teeth of a tapered sector gear. The involute-teeth of the sector gear have arrays of helical meshing lines extending across the meshing surfaces of the teeth, wherein the array of helical meshing lines have leads that decrease in length moving radially outward across the meshing surfaces.

Abstract: A method for an engine, comprising: responsive to a pressure in a fuel tank being below a pressure threshold, injecting only a liquid fuel into an engine cylinder, the fuel tank storing the liquid fuel and a pressurized gaseous fuel partially dissolved in the liquid fuel. In this way, the pressurized gaseous fuel may be conserved, thus maintaining a pressure gradient within the fuel system and allowing for judicious use of the pressurized gaseous fuel, for example during cold start conditions.

Abstract: A method of age hardening a 7xxx series aluminum alloy is provided that includes heat treating the alloy at a first temperature for a first exposure time and heat treating the alloy at a second temperature that is higher than the first temperature for a second exposure time. The age hardening process may be used to form an alloy having a yield strength of at least 490 MPa and the total age hardening time may be 8 hours or less. In one example, the first heat treatment is performed at 100° C. to 150° C. for 0.2 to 3 hours and the second heat treatment is be performed at 150° C. to 185° C. for 0.5 to 5 hours.

Abstract: An aerial image relates to a geographic area. The aerial image is analyzed to identify at least one traffic signal in the geographic area. Based at least in part on analyzing the aerial image, a timing prediction is determined for the at least one traffic signal.

Abstract: A method for controlling a hybrid vehicle having an engine includes automatically stopping the engine in response to vehicle power demand dropping below currently available electrical power while trailering, and automatically starting the engine when vehicle power demand is at a first offset below currently available electrical power. A hybrid vehicle includes an engine, an electric machine, a trailer hitch, and a controller configured to, in response to the vehicle trailering, command the engine to start at a torque offset below an unladen vehicle engine torque pull up schedule, where the torque offset is based on vehicle loading. A method for controlling a hybrid vehicle having a trailer hitch includes detecting the trailer hitch being in use, commanding an engine to stop, and commanding the engine to start in response to a torque to accelerate being within a predetermined offset below an unladen vehicle torque pull up schedule.

Abstract: An aerial image is received. A portion of the aerial image is identified that represents an area of interest that includes a vehicle. The portion of the aerial image is analyzed to generate an identification of one or more objects in the area of interest related to a route of the vehicle.

Abstract: Methods and systems are provided for accurately learning the zero point of an intake gas oxygen sensor during selected idling conditions. The learned zero point is used to infer EGR flow and accordingly adjust EGR valve control. In addition, EGR valve leakage is diagnosed based on the zero point learned during an idle adaptation relative to a zero point learned during a DFSO adaptation.

Abstract: Methods and systems are provided for accurately learning the zero point of an intake gas oxygen sensor in varying ambient humidity conditions. The learned zero point is corrected based on an estimated ambient humidity to calibrate the reading for dry air conditions or standard humidity conditions. EGR control is performed by comparing the output of an intake oxygen sensor during EGR conditions relative to the humidity-corrected zero point.

Abstract: Systems and methods for operating a battery pack supplying power to propel a vehicle are disclosed. One example method includes, increasing a battery pack state of charge window in response to a negative grade of a section of road a vehicle is traveling. The method also includes decreasing the battery pack state of charge window in response to the vehicle transitioning from traveling down a section of road having a negative grade to traveling down a section of road that has a positive or zero grade.

Abstract: Various methods for inferring oil viscosity and/or oil viscosity index in an internal combustion engine are provided. In one example, a new control method comprises cranking the engine during a start mode with an electric motor connected to a substantially constant source of electrical power, inferring engine oil viscosity based at least on engine oil temperature and speed of the engine while being cranked by the electric motor during the start mode, and correcting an operating parameter of the engine based on the inferred engine oil viscosity.

Abstract: A steering system is provided to support a straight running of a vehicle. The steering system included an active steering assistance system, a support torque section, and a correction section. The support torque section is configured to calculate a supporting torque based on a steering torque applied to a steering wheel of the vehicle. The correction section is configured to calculate a correcting torque on a basis of a progressively calculated supporting torque. The active steering assistance is configured to be controlled on the basis of a control torque based upon a superimposition of the supporting torque with the correcting torque.

Abstract: A stop/start vehicle includes an engine and a stop/start system that selectively prevents an auto stop or auto start of the engine in response to a detected vehicle proximity and direction of travel relative to an emergency vehicle. The stop/start system may be programmed to prevent an auto stop of the engine in response to a detected proximity to an emergency vehicle where the emergency vehicle is traveling in the same direction as the stop/start vehicle, or in response to a detected proximity to an emergency vehicle where the stop/start vehicle is located within an intersection. The stop start system may also be programmed to prevent an auto start of the engine in response to the engine being stopped, and further in response to a detected proximity to an emergency vehicle where the emergency vehicle is traveling in cross traffic relative to the stop/start vehicle.

Abstract: Systems and methods for operating a battery pack supplying power to propel a vehicle are disclosed. One example method comprises, adjusting a battery pack state of charge window in response to vehicle mass. Adjusting the battery pack state of charge window in response to vehicle mass may allow the battery pack to provide an increased amount of energy to a motor so that the motor may provide torque to a driveline for a longer period of time and/or absorb more vehicle generator produced power during vehicle operations.

Abstract: An estimated fuel consumption may be determined for a route for a vehicle. At least in part on the estimated fuel consumption, it may be determined that an amount of fuel in the vehicle is insufficient for the vehicle to traverse the route and/or one or more waypoints may be identified within a predetermined distance of the route, e.g., waypoints for refueling the vehicle.

Abstract: A brake pedal assembly for a hybrid electric vehicle having a brake pedal arm and a cam follower extending from the brake pedal arm is provided. The cam follower is configured to cooperate with a stamp bracket having a cam surface to provide brake pedal feel resistance as the brake pedal arm is actuated by a user of the hybrid electric vehicle. This brake pedal feel resistance increases as the cam follower traverses along the cam surface of the stamp bracket.

Abstract: A method for controlling a hybrid vehicle having an engine includes automatically stopping the engine in response to vehicle power demand dropping below currently available electrical power, and automatically starting the engine when vehicle power demand is at a first offset below currently available electrical power to reduce a time delay for starting the engine and increase a currently available vehicle power to move the vehicle up a grade in response to receiving a signal indicating a positive grade. A hybrid vehicle includes an engine, an electric machine, and a controller. The controller is configured to control starting/stopping of the engine in response to a first driver demand when receiving a signal indicative of a road grade angle exceeding a corresponding threshold and in response to a second driver demand otherwise.

Abstract: A vehicle computer system (VCS) configured to communicate with one or more mobile devices, comprising a first processor configured to automatically create a priority list by utilizing one or more factors associated with communication activity between the vehicle computer system and the one or more mobile devices, wherein the priority list includes instructions to pair one or more mobile devices with the VCS and indicates the order of connecting to the one or more mobile devices. The vehicle computer system also includes a wireless transceiver including a second processor configured to receive the priority list from the first processor and establish a wireless connection with one or more mobile devices based on the priority list.

Abstract: A system includes a processor configured to receive remote vehicle identification information and a user-confirmable vehicle variable value from a remote vehicle computing system. The processor is also configured to receive vehicle identification information and user-confirmable variable value user-input, input in conjunction with a remote process remote access request. Further, the processor is configured to compare the user-input variable value to the remotely received variable value. The processor is additionally configured to provide access to the remote process upon a correspondence between the user-input variable value and the remotely received variable value.