A method for controlling a hybrid electric vehicle includes selecting a first target engine speed in response to a driver power request, calculating an available engine torque at the first target engine speed, adjusting the target engine speed if the available engine torque is insufficient to satisfy the driver power request, and commanding an engine to run at the target engine speed. The first target engine speed is optimized for fuel economy. The calculated available engine torque is less than a calculated maximum engine torque at the target engine speed, such that a torque reserve is maintained for engine vacuum.

A system for adaptive in-drive updating, for a vehicle travelling on a route, includes a controller having a processor and tangible, non-transitory memory. The vehicle is carrying a load. The controller is adapted to obtain one or more dynamic parameters pertaining to the load. A plurality of adaptive predictors is selectively executable by the controller at a timepoint during the route at which a completed portion of the route has been traversed by the vehicle and a remaining portion remains untraversed. The plurality of adaptive predictors includes a speed predictor configured to generate a global speed profile. The plurality of adaptive predictors includes a driving consumption predictor is configured to predict a driving consumption profile for the remaining portion of the route based in part on the dynamic parameter, the route features, the global speed profile, and a past drive consumption.

A system and a method of controlling a hybrid electric vehicle shift are disclosed. The system includes an engine and a drive motor operating as power sources and a transmission receiving driving torque from one of the engine and the drive motor. A data detector detects a state data for operating the transmission. A vehicle controller calculates a creep torque and an engine setting torque using the state data, determines whether a shift control condition is satisfied based on a position value of an accelerator pedal, calculates an available motor torque using a motor speed at an actual shift start point and a target motor speed when the shift control condition is satisfied, and calculates a first shift input torque using the creep torque, the engine setting torque, the available motor torque, and a first torque apply ratio. The transmission is operated based on the first shift input torque.

A system includes a power source to generate power to propel the vehicle, and a speed sensor to detect a current speed. The system also includes a camera to detect image data corresponding to a current roadway, and a GPS sensor to detect location data corresponding to a current location of the vehicle. The system also includes an ECU. The ECU is designed to determine a target vehicle speed based on at least one of the image data or the location data. The ECU is also designed to calculate an energy-efficient acceleration pattern to accelerate the vehicle from the current speed to the target vehicle speed based on a goal to minimize energy usage of the power source. The ECU is also designed to control the power source to accelerate the vehicle from the current speed to the target vehicle speed using the energy-efficient acceleration pattern.

A system includes a speed sensor to detect a current speed, a camera to detect image data, and a GPS sensor to detect location data. The system also includes a memory to store a lookup table that maps efficient vehicle speeds to roadway speed limits. The system also includes an output device and an electronic control unit (ECU). The ECU determines a current speed limit of the current roadway and determines that the vehicle is within a steady speed range when the current speed of the vehicle fluctuates less than a predetermined speed threshold over a predetermined time period. The ECU also compares the current speed limit to the lookup table to determine at least one efficient vehicle speed that corresponds to the current speed limit and controls the output device to output the at least one efficient vehicle speed when the vehicle is within the steady speed range.

The disclosure relates to a system for controlling a hybrid vehicle having a primary power source such as an electric motor and a secondary power source such as an internal combustion engine, the electric motor and internal combustion engine each being connectable to a driveline of the vehicle. The system comprises a control unit operable to cause the internal combustion engine to be pre-emptively initiated and subsequently connected to the driveline. The control unit is configured and arranged to determine when the vehicle is in a first driving mode (wherein the internal combustion engine is not initiated and is disconnected from the driveline of the vehicle and wherein the electric motor and battery pack are delivering a torque to the driveline in response to a driver demanded torque). The control unit is further configured and arranged to determine that a steering angle of the vehicle and a situational status of the vehicle are indicative of a driving situation in which an expected driver demanded torque will not be met by the primary power source alone. In response thereto, the control unit is configured and arranged to automatically and pre-emptively cause the internal combustion engine to be initiated and connected to the driveline at a time before the actual driver demanded torque reaches or exceeds said expected driver demanded torque.

Example ice and snow detection systems and methods are described. In one implementation, a method activates an ice and snow detection system in response to receiving weather data indicating a likelihood of ice or snow on a roadway near a vehicle. The method receives data from multiple vehicle sensors and analyzes the received data to identify ice or snow on the roadway. If ice or snow is identified on the roadway, the method adjusts vehicle operations and reports the ice or snow condition to a shared database.

A method for operating a hybrid drive system for a motor vehicle having an internal combustion engine and an electrical drive, which is supplied by an electrical energy store, the required powers of the internal combustion engine and/or of the electrical drive being set in accordance with a specified load distribution, including: regulating the load distribution between the electrical drive and the internal combustion engine based on a current setpoint state of charge of the electrical energy store; and determining the current setpoint state of charge from a specified linear setpoint state of charge curve between a current position of the motor vehicle and a destination.

A vehicle includes a fuel tank, a jet pump and a controller. The fuel tank has a passive side and an active side. Each of the sides includes a fuel level indicator. The jet pump is disposed within the active side and is configured to maintain a fuel level above a first threshold, based on each of the indicators, on the active side by siphoning fuel from the passive side during operation in a combustion mode. The controller is configured to, in response a battery charge level being below a second threshold during operation in an electric mode and a detected hill climb via a route guidance system, activate the jet pump to siphon fuel such that a fuel level within the active side rises above the first threshold.

In some examples, a controller receives measurement data from a sensor on a vehicle, determines, based on the measurement data, a condition of usage of the vehicle, and selects a parameter set from among a plurality of parameter sets based on the determined condition of usage of the vehicle, the plurality of parameter sets corresponding to different conditions of usage of the vehicle, where each parameter set of the plurality of parameter sets includes one or more parameters that control adjustment of one or more respective adjustable elements of the vehicle. The controller causes application of the selected parameter set on the vehicle.