A weight sensing assembly for a semi-trailer truck enabling balancing of a load includes a sensing module, which is one of a plurality thereof. The sensing modules are mountable to wheels of the semi-trailer truck so that each axle has a sensing module engaged to outside wheels thereof. The sensing module obtains a pressure measurement of a tire engaged to the wheel and transmits it to an electronic device. Programming code on the electronic device enables it to utilize a pressure changes, upon positioning of a load upon the semi-trailer truck, to determine a weight that is positioned upon an associated axle. The electronic device calculates adjustments to positions of a sliding fifth wheel and of sliding tandems of the semi-trailer truck to obtain positions thereof that will achieve a legal weight distribution of the load. The electronic device presents, upon a screen thereof, the adjustments to a user.

A mobile device intermediary for vehicle adaptation is disclosed. A mobile device intermediary can access driver profile information and vehicle profile information from a remotely located device, determine vehicle adaptation information based on the driver profile information and vehicle profile information, and facilitate access to the vehicle adaptation information to facilitate adapting an aspect of a first vehicle. The mobile device intermediary can further receive other vehicle profile information related to a second vehicle associated with a driver profile and include the other vehicle profile information in determining the vehicle adaptation information. The vehicle adaptation information can be related to adapting a performance aspect of the first vehicle. The vehicle adaptation information can also be related to adapting an amenity aspect of the first vehicle. Vehicle adaption information can provide improved safety and driver comfort as a driver uses different vehicles, can be portable, and can be device independent.

A vehicle suspension management via an IVI system is disclosed. The system includes an in-vehicle infotainment (IVI) system and a vehicle suspension system communicatively coupled with the IVI system. The vehicle suspension system includes at least one active shock assembly. A suspension control application on the IVI system, the suspension control application to cause the IVI system to send a signal to the at least one active shock assembly, the signal used to modify a damping characteristic of the at least one active shock assembly.

A vehicle suspension management via an IVI system is disclosed. The system includes an in-vehicle infotainment (IVI) system and a vehicle suspension system communicatively coupled with the IVI system. The vehicle suspension system includes at least one active shock assembly. A suspension control application on the IVI system, the suspension control application to cause the IVI system to send a signal to the at least one active shock assembly, the signal used to modify a damping characteristic of the at least one active shock assembly.

High-performance road vehicle having: a plurality of replaceable or removable components; a control unit that supervises the operation of the road vehicle; at least one electronic identification device, which is fitted on a corresponding component, has a memory designed to contain at least one unique identifying code of the component and has a first transmission organ designed to send the data contained in the memory; and a second transmission organ designed to communicate with the first transmission organ and connected to the control unit to allow the control unit to interact with the electronic identification device.

A suspension monitoring and adjustment system for an off-road vehicle includes a distance sensor arranged to measure shock displacement of a suspension of the vehicle. The system may include an output device configured to output shock displacement data generated by the distance sensor and a processor or programmable circuit operable to produce a visual representation of the shock displacement data output by the output device. The system may include a processor or programmable circuit operable to generate an adjustment signal based on shock displacement data generated by the distance sensor and a suspension adjuster arranged to adjust the suspension of the vehicle in response to the adjustment signal.

Exemplary embodiments described in this disclosure are generally directed to a collaborative relationship between a vehicle and a UAV. In one exemplary implementation, a computer that is provided in the vehicle uses images captured by an imaging system in the UAV together with images captured by an imaging system in the vehicle, to modify a suspension system of the vehicle based on a nature of the terrain located below, or ahead, of the vehicle. The computer may, for example, modify a suspension system before the vehicle reaches a rock or a pothole on the ground ahead. In another exemplary implementation, the computer may generate an augmented reality image that includes a 3D model of the vehicle rendered on an image of a terrain located below, or ahead of, the vehicle. The augmented reality image may be used by a driver of the vehicle to drive the vehicle over such terrain.

A damping control device and a damping control method for controlling damping of a vehicle are provided. Damping control of the vehicle is performed by adaptively switching a damping mode while considering energy consumption (fuel economy, a consumption amount of a battery, and the like) according to a state of the vehicle such as a state of an interior of the vehicle, a driving state of the vehicle, and an ambient environment. That is, the state of an interior of the vehicle, the driving state of the vehicle, and the ambient environment are constantly monitored, and the damping mode is switched to a weak damping mode in the case where unnecessity of damping as strong as a current state is determined whereas the damping mode is switched to a strong damping mode in the case where necessity of stronger damping is determined.

A suspension monitoring and adjustment system for an off-road vehicle includes a distance sensor arranged to measure shock displacement of a suspension of the vehicle. The system may include an output device configured to output shock displacement data generated by the distance sensor and a processor or programmable circuit operable to produce a visual representation of the shock displacement data output by the output device. The system may include a processor or programmable circuit operable to generate an adjustment signal based on shock displacement data generated by the distance sensor and a suspension adjuster arranged to adjust the suspension of the vehicle in response to the adjustment signal.

Disclosed is a low cost air suspension adjustment system that employs a visible height indicator. The combination of an externally-viewable suspension height green zone or desired height indicator and automatic pressure control enables a low-cost simple height adjustment system. The height adjustment system of the present invention includes a PCU which can be a module that houses an ECU (electronic control unit with a microprocessor), at least one solenoid valve 16, a pressure sensor 18 and a remote control device to instruct the ECU.