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: A vehicle includes an engine; a fraction battery; and a controller or a battery control system having a controller. The controller is programed to respond to a predicted duration of charge sustaining operation for a drive cycle and a speed of the vehicle. When the predicted duration is greater than a predetermined duration and the speed is less than a speed threshold, the controller increases a state of charge threshold of the traction battery associated with triggering shut offs of the engine to reduce cycling of the engine during the drive cycle.

Abstract: A bicycle having a drive-shaft connecting a crank to an internal hub gearbox on a rear wheel. The bicycle having a suspension system and a cantilevered rear stay that connects the rear wheel to the frame and maintains the hub in a relative radial distance from the crank to maintain contact of the drive-shaft with the crank and gearbox. The suspension system having a linearly moveable damping device disposed within the frame. A swing arm pivotally extends from the rear stay to the damping device. The pivotal connection of the rear stay to the frame, the linear connection of the damping device to the frame, and the pivotal connection of the swing-arm to both the rear stay and damping device provide a four-bar sliding mechanism to provide suspension for the rear wheel on the bicycle.

Abstract: A bicycle having a drive-shaft connecting a crank to an internal hub gearbox on a rear wheel. The bicycle having a suspension system and a cantilevered rear stay that connects the rear wheel to the frame and maintains the hub in a relative radial distance from the crank to maintain contact of the drive-shaft with the crank and gearbox. The suspension system having a linearly moveable damping device disposed within the frame. A swing arm pivotally extends from the rear stay to the damping device. The pivotal connection of the rear stay to the frame, the linear connection of the damping device to the frame, and the pivotal connection of the swing-arm to both the rear stay and damping device provide a four-bar sliding mechanism to provide suspension for the rear wheel on the bicycle.

Abstract: A method according to an exemplary aspect of the present disclosure includes, among other things, monitoring a root mean square (RMS) current of a component for a time window, and adjusting a flow of current relative to a battery such that a slope of the RMS current gradually approaches zero as the RMS current approaches an RMS current limit for the time window.

Abstract: An example vehicle system includes a sensor and a processing device. The sensor is configured to identify a first location and a second location. The processing device is programmed to estimate a plurality of energy usages. Each energy usage is based at least in part on a speed of a host vehicle at the first location. The processing device is further programmed to select one of the plurality of energy usages as a target useable energy and control the host vehicle in accordance with the speed associated with the target useable energy.

Abstract: An exemplary method includes adjusting a proportion of engine braking used to achieve a target deceleration of a vehicle to change an amount of thermal energy generated from engine braking. An exemplary assembly includes a friction brake to selectively provide friction braking to a vehicle, an engine brake to selectively provide engine braking to the vehicle, and a controller configured to adjust a proportion of the engine braking used to achieve a target deceleration of the vehicle to change an amount of thermal energy generated from engine braking.

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 increasing lift pedal regeneration in response to exceeding a system regeneration limit.

Abstract: A system and method for improving vehicle performance on a grade comprises an engine, an acceleration sensor, a global positioning system, a controller and a torque transfer device. The controller determines the grade from information obtained from the global positioning system and the acceleration sensor. The controller calculates a dynamic weight shift of the vehicle from a first wheel to a second wheel due to acceleration and a static weight shift of the vehicle from the first wheel to the second wheel due to gravity and the grade. The controller then determines the maximum amount of torque that can be transmitted to the first wheel before the first wheel slips and avoids slipping by preemptively diverting torque from the first wheel to the second wheel before the first wheel slips.

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 total power demand including a wheel power demand may be observed. The wheel power demand may be modified to determine a modified total power demand including a modified wheel power demand if the total power demand falls within a target range of power values defined by upper and lower threshold power values such that the modified total power demand is generally equal to the lower threshold power value.

Abstract: A vehicle includes a first disconnect disposed between a prime mover of the vehicle and a certain one of the vehicle drive wheels. The first disconnect is operable to connect and disconnect the prime mover to and from the certain one of the drive wheels. A second disconnect is disposed between the powertrain and the certain one of the drive wheels, and is operable to connect and disconnect the certain one of the drive wheels to and from the powertrain when the first disconnect is engaged. A control system and method are configured to control operation of at least the first and second disconnects. Through selective control of the disconnects, the system can be automatically placed in a four-wheel-drive mode based on predetermined criteria, or the desirability of the four-wheel-drive mode can be indicated to the vehicle operator in a passive version of the control system and method.

Abstract: A regenerative brake control system for a vehicle includes a vehicle controller, a driveline torque distribution device interfacing with the vehicle controller, an electric machine interfacing with the driveline torque distribution device, a plurality of wheels coupled to the electric machine and at least one traction condition input indicating traction of the plurality of wheels provided to the vehicle controller. The vehicle controller engages the driveline torque distribution device and the electric machine apportions regenerative brake torque to the wheels in proportion to the traction of the wheels. A regenerative brake control method for a vehicle is also disclosed.

Abstract: A user interface for conveying tips on driving behaviors or vehicle settings that will improve vehicle efficiency may be provided. The tips may be listed on an information display along with an efficiency impact value associated with each tip. The efficiency impact values may be conveyed in terms of fuel economy, vehicle range, emissions or some other value. Accordingly, the user interface may communicate ways to improve a vehicle's efficiency, as well as quantify the potential improvement in meaningful terms.

Abstract: A user interface for conveying tips on driving behaviors or vehicle settings that will improve vehicle efficiency may be provided. The tips may be listed on an information display along with an efficiency impact value associated with each tip. The efficiency impact values may be conveyed in terms of fuel economy, vehicle range, emissions or some other value. Accordingly, the user interface may communicate ways to improve a vehicle's efficiency, as well as quantify the potential improvement in meaningful terms.

Abstract: Methods and systems are provided for raising the speed of a hybrid electric vehicle operating in an electric-only mode. During conditions when the vehicle is driven only by an electric motor, vehicle speed may be raised by spinning the engine unfueled using power from a system battery, while adjusting valve operation to reduce engine pumping losses. In this way, vehicle speed may be raised more efficiently and without damaging rotating transmission components.

Abstract: An automotive electric drive system may include an electric power source, an electric machine, and a DC-DC power converter electrically connected between the electric power source and the electric machine. The DC-DC power converter may include an inductor and a first switch each disposed in a different current path connecting the electric power source and the electric machine. The currents paths may be electrically in parallel.

Abstract: An automotive vehicle may include one or more controllers, a braking system and an electric machine. The one or more controllers may be configured to determine whether the vehicle is about to roll over. The braking system may be configured to apply a braking torque for a time period, under the command of the one or more controllers, to a front traction wheel to cause the front traction wheel to skid or slide relative to a road if the vehicle is about to roll over. The electric machine may be configured to generate a propulsion torque, under the command of the one or more controllers, during the time period.

Abstract: Methods and systems are provided for raising the speed of a hybrid electric vehicle operating in an electric-only mode. During conditions when the vehicle is driven only by an electric motor, vehicle speed may be raised by spinning the engine unfueled using power from a system battery, while adjusting valve operation to reduce engine pumping losses. In this way, vehicle speed may be raised more efficiently and without damaging rotating transmission components.