A rearview monitor apparatus includes: a display provided on an instrument panel; and a housing formed to surround a periphery of the display, wherein the housing includes an upper surface arranged above the display, a side surface arranged at the outside in a vehicle width direction of the display, and a visor that extends in a vehicle rearward direction beyond the display from vehicle rearward positions of the upper surface and the side surface and that forms an opening part in a vehicle rearward direction, and a first recess part of which a depth gradually increases toward a vehicle frontward direction towards the inside in the vehicle width direction from an outer end in the vehicle width direction is formed on the upper surface side of the visor.

A rear view monitoring device includes: a display unit which is provided on both sides of an instrument panel in a vehicle width direction; and a housing formed to surround a periphery of the display unit, wherein the housing includes an opening portion formed on a display surface side of the display unit, an upper surface disposed above the display unit, a side surface disposed outside the display unit in the vehicle width direction, and an overhanging portion which straddles the upper surface and the side surface and overhangs outward in the vehicle width direction from a range in which a pillar projects in a vertical direction, and at least the overhanging portion is formed to have a downward gradient toward an outside in the vehicle width direction.

A drive arrangement having combustion and electric engines and a transmission with input shafts (4, 5). The drive arrangement includes first and second planetary gearsets (PG1, PG2), each having a carrier, and sun and ring gears. One element of gearset (PG1) is rotationally fixed to shaft (5). Another element of gearset (PG1) is fixed to a housing. One element of gearset (PG2) is connected to the electric engine. Another element of gearset (PG2) is rotationally fixable to shaft (4). When a first switching element is engaged, a further element of gearset (PG2) is fixed to the housing. When a second switching element is engaged, the further element of gearset (PG2) is rotationally fixed to shaft (5), to which the element of gearset (PG1) is also rotationally fixed. When a third switching element is engaged, the further element of gearset (PG2) is rotationally fixed to a further element of gearset (PG1).

The invention relates to a method for operating a motor vehicle, in which by at least one ultrasonic sensor, operated in the active operation mode, of an ultrasonic sensor device of the motor vehicle ultrasonic waves are emitted into an environmental region of the motor vehicle, wherein the motor vehicle as hybrid vehicle is equipped with an internal combustion engine (and an electric drive machine and in the active operation mode of the ultrasonic sensor arranged on a rear part of the motor vehicle the motor vehicle at least temporarily is operated by means of the electric drive machine. The invention also relates to a motor vehicle.

The invention relates to a method for assisting a driver of a motor vehicle (1) in maneuvering the motor vehicle (1) with a trailer (3), wherein image data is captured from an environmental region (12) of the motor vehicle (1) by means of at least one vehicle-side camera (5) and by means of at least one trailer-side camera (10) and an image (B) of the environmental region (12) is created for displaying on a vehicle-side display device (14) depending on the captured image data, wherein a perspective (P1, P2), from which the environmental region (12) is displayed in the image (B), is determined depending on a pivot angle (17) between the trailer (3) and the motor vehicle (1). The invention additionally relates to a driver assistance system (2) as well as to a vehicle/trailer combination with a motor vehicle (1), a trailer (3) and a driver assistance system (2).

Methods and systems for monitoring a load in a trailer coupled to a vehicle. One method includes determining, with an electronic processor, an initial weight on a rear axle of the vehicle when the load is engaged with the trailer coupled to the vehicle. The method also includes monitoring, with the electronic processor, a current weight on the rear axle of the vehicle based on data collected by a sensor. The method also includes comparing, with the electronic processor, the initial weight and the current weight. The method also includes automatically generating, with the electronic processor, a notification when the current weight is different than the initial weight by a predetermined threshold.

A method for controlling an electric rear axle drive (eRAD) includes, responsive to a vehicle being in DRIVE, operating the eRAD such that any torque output by the eRAD to drive rear wheels forward is less than torque output to drive front wheels forward. The method further includes, responsive to the vehicle being in REVERSE, operating the eRAD such that torque output by the eRAD to drive the rear wheels backwards is more than any torque output to drive the front wheels backwards.

A method includes controlling an electrified vehicle by modifying a state of charge (SOC) window associated with an energy storage device of the electrified vehicle in response to a reverse driving event or a trailer towing event.

An engine starting control system for hybrid vehicles is provided to prevent a temporal drop in drive force when starting an engine. The control system maintains an operating mode of a switching mechanism when starting the engine by the first motor, in a case that the vehicle is propelled in the forward direction by the first motor and that the switching mechanism is in a second mode, or in a case that the vehicle is propelled in the reverse direction by the first motor and that the switching mechanism is in the first mode. Thereafter, the control system increases a rotational speed of the engine to a self-sustaining speed, switches the operating mode of the switching mechanism, and increases torque of the engine.

A drive arrangement having combustion and electric engines and a transmission with input shafts (4, 5). The drive arrangement includes first and second planetary gearsets (PG1, PG2), each having a carrier, and sun and ring gears. One element of gearset (PG1) is rotationally fixed to shaft (5). Another element of gearset (PG1) is fixed to a housing. One element of gearset (PG2) is connected to the electric engine. Another element of gearset (PG2) is rotationally fixable to shaft (4). When a first switching element is engaged, a further element of gearset (PG2) is fixed to the housing. When a second switching element is engaged, the further element of gearset (PG2) is rotationally fixed to shaft (5), to which the element of gearset (PG1) is also rotationally fixed. When a third switching element is engaged, the further element of gearset (PG2) is rotationally fixed to a further element of gearset (PG1).