A vehicle includes an engine, a rotating electric machine, a high-voltage power line, a high-voltage battery, an inverter, a capacitor, an electronic control unit, a low-voltage battery, an alternator, and a low-voltage power line. The capacitor is connected to the high-voltage power line. The electronic control unit is configured to control the engine such that the engine is operated and the alternator supplies electric power to the low-voltage power line in a case where the possibility of the occurrence of a collision of the vehicle is detected. The electronic control unit is configured to perform control such that the capacitor discharges a residual electric charge in a case where the possibility of the occurrence of the collision of the vehicle is detected or in a case where the occurrence of the collision of the vehicle is detected.

A vehicle includes a fuel pump configured to deliver fuel to an internal combustion engine. The vehicle also includes an accelerometer configured to detect acceleration of a vehicle component. A plurality of sensors are provided about the vehicle for detecting conditions that would indicate aggressive driving. At least one controller is provided and is in communication with the fuel pump, the accelerometer, and the sensors. The at least one controller is programmed to adjust a fuel pump shutoff threshold to an adjusted shutoff threshold in response to one or more conditions indicating aggressive driving. The at least one controller then shuts off the fuel pump in response to the acceleration exceeding the adjusted shutoff threshold.

A powertrain system including an engine and transmission is described, and includes a temperature sensor disposed to monitor a hydraulic fluid for the transmission. A method for monitoring the temperature sensor includes monitoring engine operation including engine coolant temperature and monitoring a signal output from the temperature sensor. An indicated temperature slope is determined based upon the signal output from the temperature sensor, and a temperature region associated with the engine coolant temperature is determined. Performance of the temperature sensor is evaluated based upon the indicated temperature slope and minimum and maximum temperature slope thresholds that are associated with the temperature region.

A method for populating a controller for a motor vehicle with data includes providing a controller with a storage device, and generating a projected mathematical model of at least one section of a powertrain, including a transmission. The projected mathematical model describes the section of the powertrain with a gear ratio of 1 and is applicable to different transmissions. The projected mathematical model is stored in the storage device of the controller. A motor vehicle is also provided and operated accordingly.

A control system includes a sensor configured to detect information associated with an area surrounding a vehicle and an electronic control unit configured to control an automated driving of the vehicle. The electronic control unit includes a driving plan generation unit, a driving control unit, a regeneration control unit configured to control a process for regenerating an engine exhaust gas treatment apparatus, and a lane selection unit configured to predict an engine load associated with traveling in each lane of a plurality of lanes. The lane selection unit is also configured to select a lane which would cause an increase in engine load when the control for regenerating the exhaust gas treatment apparatus is being performed by the regeneration control unit. The control system is configured to cause the vehicle to be driven in the lane selected by the lane selection unit.

A lidar system is described herein. The lidar system includes a transmitter that is configured to emit a frequency-modulated lidar signal. The lidar system further includes processing circuitry that is configured to compute a distance between the lidar system and an object based upon the frequency-modulated lidar signal, the processing circuitry configured to compute the distance with a first resolution when the distance is at or beneath a predefined threshold, the processing circuitry configured to compute the distance with a second resolution when the distance is above the predefined threshold, wherein the first resolution is different from the second resolution.

A start-stop vehicle includes an engine configured to automatically stop and start during travel. The vehicle further includes a gear lever, a brake pedal, and a controller. The controller is programmed to restart the engine or inhibit restarting of the engine depending upon one or more sets of conditions of the vehicle. A method is also present for operating the vehicle based upon the one or more sets of conditions.

This disclosure is generally directed to systems and methods for avoiding certain undesirable vehicle operations when a vehicle having a dual vehicle propulsion system is parked inside a confined space. For example, it is desirable to avoid operating an internal combustion engine of a hybrid electric vehicle when the hybrid electric vehicle is parked inside a garage because the internal combustion engine may produce undesirable gaseous emissions, particularly during start up. In an example embodiment, this issue is addressed by a computer of the vehicle defining a geofence that encompasses the garage. The computer disables the operation of the internal combustion engine when the hybrid electric vehicle is located inside the geofence but allows operation of an electric motor of the hybrid electric vehicle for moving the vehicle out of the geofence. The computer enables operation of the internal combustion engine when the vehicle has moved outside the geofence.

An automatic control device for a motorcycle including a control device that automatically controls an automatic cruise control system and a brake system including a front wheel brake and a rear wheel brake includes a brake temperature detection unit that detects a brake temperature. The control device varies operation states of the front wheel brake and the rear wheel brake according to the brake temperature during automatic cruise control. At a time of deceleration in a case where the brake temperature during the automatic cruise control is low, the control device raises the brake temperature by reducing an engine brake of a power unit of a vehicle and increasing operation frequencies of the front wheel brake and the rear wheel brake.

A vehicle includes: an electric motor; a storage battery configured to supply electric power to the electric motor and be charged with electric power from an external power source; an internal combustion engine configured to rotate the electric motor; and a controller configured to perform an electric power generation control and a prohibition control, the internal combustion engine being prohibited in a case where the vehicle is positioned in a predetermined region, wherein the electric power stored in the storage battery is suppliable to an outside, and the controller is configured to permit driving of the internal combustion engine even in the predetermined region in a case where a supply of electric power is insufficient for an electric power demand in the predetermined region or in a case where the supply of the electric power is predicted to be insufficient for the electric power demand in the predetermined region.