A tool assembly for mounting a tailgate to a car body is provided. The tool assembly includes a bracket adapted to engage with an overhead structure and a frame movably coupled to the bracket and configured to move in a vertical direction relative to the bracket. The tool assembly also includes a linkage mechanism movably coupling the frame with the bracket and configured to maintain the frame parallel to the bracket during the vertical movement of the frame. Further, a pair of torque guns is coupled to the frame and is configured to hold a pair of fasteners. The pair of torque guns engages and tightens the pair of fasteners to the car body and a hinge attached to the tailgate.

A display system for a vehicle to display vehicle information includes a meter panel, a heads-up display system, and a controller. The meter panel has at least one display section and the heads-up display system includes a projector mounted on the meter panel and arranged at a front of the meter panel opposite to the at least one display section. The projector is configured to project a light to display the vehicle information on the front windshield. The heads-up display system also includes a curve mirror arranged spaced apart from the projector and is adapted to reflect and focus the light on the front windshield to display the vehicle information on the front windshield. The controller is configured to control the meter panel and heads-up display system to display the vehicle information on the meter panel and the front windshield.

Aspects of the disclosure include a light feeding system for a display that uses micro light-emitting diodes (LEDs) laminated into glass for light guide applications. An exemplary display can include a light feeding system having one or more micro LEDs on a surface of a backplane. An optical bonding collimator is positioned over and in direct contact with a surface of the micro LEDs. The optical bonding collimator is on the surface of the backplane. A light guide is coupled to an end of the optical bonding collimator such that the optical bonding collimator is between the light guide and the backplane. One or more inner reinforcing layers are in direct contact with the light feeding system and one or more outer layers are in direct contact with the inner reinforcing layers. The light feeding system is laminated with the inner reinforcing layers and the outer layers.

A display control device for controlling a display position of a virtual image displayed and superimposed on a foreground in a vehicle (A), includes: an information acquisition unit for acquiring state information of the vehicle and extracting attitude change information and vibration information of the vehicle from the state information; a position correction unit for correcting a displacement of the display position of the virtual image with respect to the foreground caused by the attitude change of the vehicle, based on the attitude change information; a rough road determination unit for determining whether a road is a rough road, the road on which the vehicle is traveling or scheduled to travel, based on the vibration information; and a correction suppression unit for suppressing a correction control of the display position executed by the position correction unit and continuing to display the virtual image, based on a rough road determination.

A fastener is adapted to fasten a wheel rim to a wheel hub. The wheel rim has multiple hole-defining walls respectively defining multiple installation holes. The fastener includes a main body and a sleeve. The main body extends along a central axis thereof, is adapted to engage the wheel hub, and has an abutting portion corresponding in shape to a corresponding one of the installation holes and extending into the corresponding installation hole. The sleeve is sleeved and retained on the abutting portion, and has a contacting surface, which abuts against corresponding one of the installation holes.

A following cruise control method is provided for controlling a control vehicle to follow a target vehicle, the following cruise control method including: determining one of a plurality of vehicles cruising in a group as the target vehicle based on preset priorities of the plurality of vehicles; receiving following-target information comprising at least one of driving information, position information, and state information from the target vehicle; controlling follow-cruising of the control vehicle to follow the target vehicle with a preset following distance from the target vehicle by generating a driving command based on the following-target information; determining whether the target vehicle is abnormal based on the following-target information; and in response to the target vehicle being determined to be abnormal, stopping the follow-cruising of the control vehicle.

A personal transportation vehicle. The personal transportation vehicle provides an outer and inner shell having a rotor assembly supported between. The inner shell defines a compartment, which in turn houses an input system that controls an electromagnetic drive system. The electromagnetic drive system includes electromagnets that can generate a magnetic field. A sensor detects motion of the rotor assembly and stabilizes the inner shell. A controller controls states of each electromagnet depending on a position of the rotor assembly and an input from the input system. The electromagnets of the electromagnetic drive system cooperatively cause the personal transportation vehicle to move.

Methods are provided for optimizing generation of water on-board a vehicle with reduced impact on fuel economy. Regenerative braking energy, and/or solar energy, in excess of what is required for charging a system battery, is used to operate a water extractor and save the captured energy as stored water. A proportion of the braking energy used to charge the battery versus operate the water extractor is adjusted as a function of operating conditions including a water level in a water reservoir on-board the vehicle.

Vehicle systems and methods for assisting a driver making a turn at an intersection are disclosed. In one embodiment, a vehicle includes a plurality of sensors configured to output a plurality of operational signals, one or more processors, and one or more non-transitory memory modules communicatively coupled to the one or more processors. The processors store machine-readable instructions that, when executed, cause the one or more processors to receive a signal indicating a driver of the vehicle is attempting to make a turn at an intersection. The processors are further caused to access a behavioral profile that is representative of the intersection. The processors are also caused to develop a perception as well as a risk associated with the intersection based on the plurality of operational signals from the plurality of sensors and the behavioral profile of the intersection. The processors are further caused to calculate at least one maneuver.

Method for automatically assessing performance of a driver (110) of a vehicle (100) for a particular trip, wherein current driving data sets, comprising basic driving data are repeatedly read from the vehicle, which method comprises the steps a) collecting previous-trip driving data sets, comprising instantaneous vehicle energy consumption, for different previous trips, different drivers and different vehicles; b) for each of said current-trip driving data sets, selecting a corresponding previous-trip data set; c) calculating the value of said second trip performance parameter based upon the respective values of a first trip performance parameter for each of said selected previous-trip driving data sets, which first trip performance parameter is calculated for the previous-trip data set in question as a relative trip performance of the previous-trip data set in question in relation to the trip during which the previous-trip data set was observed. The invention also relates to a system.