A vehicle includes a vehicle subsystem, a user interface, and a controller. The user interface is configured to display a plurality of selectable vehicle models. The controller is programmed to, in response to a selection of a particular vehicle model, adjust a parameter of the subsystem to emulate a corresponding subsystem parameter of the particular vehicle model.

A system for weight monitoring includes a plurality of load sensors that are positioned between a deck floor and a frame mount of a truck, and distributed within a truck bed of the truck to sense a load distribution of a load applied on the truck bed to generate a load distribution data. Each of the load sensors includes a respective through hole load transducer, a respective bolt to fix the through hole load transducer to the truck, and a respective deck cross-member positioned on the load transducer to transfers a mechanical force generated by the load onto the through hole load transducer. The system also includes one or more cameras arranged above the truck bed to monitor a load movement of the load, and a microprocessor configured to receive the load distribution data, determine a vehicle operating parameter accordingly, and transmit the vehicle operating parameter to a vehicle controller.

The present invention provides a method/device to improve braking performance on a wheeled vehicle comprising at least one driving axle, the wheeled vehicle further comprising a collision warning system and an emergency braking system and an air suspension system, the air suspension system comprising at least one air suspension module associated with the at least one driving axle and the air suspension system being configured to control the air pressure in the at least one air suspension module associated with the at least one driving axle, the collision warning system being configured to monitor the environment of the wheeled vehicle, and to determine if and when the emergency braking system may need to be actuated, so that when the collision warning system determines the emergency braking system may need to be actuated, the method being implemented by the collision warning system and comprising one step implemented before eventually actuating the emergency braking system, said step comprising actuating the air suspension system to increase the air pressure on the at least one of air suspension module associated with the at least one driving axle.

In some examples, a controller receives information of a route of a vehicle, and selects a first parameter set from among a plurality of parameter sets based on the route 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 first parameter set to control a setting of the one or more adjustable elements of the vehicle.

A method for preventing a rollover of a vehicle or a tractor-trailer combination in curves, by counteracting a rollover risk of the vehicle by independent regulating interventions, performed without action by a vehicle driver, in a regulation system that actuates the drive and/or the brakes of the vehicle, the method including: capturing the current driving situation and the current load of the vehicle or the tractor-trailer combination as to the current driving position of the vehicle or the tractor-trailer combination, ascertaining a maximum admissible transverse acceleration at the current driving position, at which maximum admissible transverse acceleration the vehicle or the tractor-trailer combination just does not roll over, as to the current driving situation and the current load of the vehicle or the tractor-trailer combination. Also described is a related apparatus for preventing a rollover of a vehicle or a tractor-trailer combination in curves.

A damping control system for a vehicle having a suspension located between a plurality of ground engaging members and a vehicle frame includes at least one adjustable shock absorber having an adjustable damping profile.

Systems and methods for operating an engine and a torque converter are presented. In one example, slip of a torque converter is adjusted via at least partially closing or opening a torque converter clutch in response to vehicle vibration. The vehicle vibration may be based on road surface conditions and an actual total number of operating cylinders of the engine.

Systems and methods for operating an engine and a torque converter are presented. In one example, slip of a torque converter is adjusted via at least partially closing or opening a torque converter clutch in response to vehicle vibration. The vehicle vibration may be based on road surface conditions and an actual total number of operating cylinders of the engine.

A bicycle electric system comprises a first electric component, a second electric component, and a second controller. The first electric component includes a first controller and a sensor. The first controller is configured to control an operating status of the first electric component based on an output of the sensor. The second electric component is different from the first electric component. At least one of the first electric component and the second electric component includes an electric suspension. The second controller is configured to control an operating status of the second electric component based on the output of the sensor of the first electric component.

A lane keeping system includes an absolute pressure sensor located in a door on each of opposing sides of a vehicle. Each sensor generates a signal indicative of a door cavity pressure on that side of the vehicle. A safety restraint system (SRS) controller is in communication with the pressure sensor. The SRS controller is configured to determine a collision event in response to the signal (e.g., increased pressure in the door as it is crushed) and activate a safety restraint component in response to the determined collision event. A lane keeping system (LKS) controller is in communication with the pressure sensors. The LKS controller determines a lateral wind force on the vehicle in response to the signal from each pressure sensor. The LKS controller determines a correction in response to the determined lateral wind force to maintain the vehicle along a desired path.