A modular electronic damping control system is described and includes a damping component located at a vehicle suspension location. The modular electronic damping control system also includes a control system configured to control the damping component, and determine the type of damping component present. Also, the control system is configured to automatically tune a vehicle's suspension based on the type of damping component present, and automatically monitor the damping component and determine when a change has been made to the damping component so that the control system can then automatically re-tune the vehicle's suspension based on the change to the damping component.

A modular electronic damping control system is described and includes a damping component located at a vehicle suspension location. The modular electronic damping control system also includes a control system configured to control the damping component, and determine the type of damping component present. Also, the control system is configured to automatically tune a vehicle's suspension based on the type of damping component present, and automatically monitor the damping component and determine when a change has been made to the damping component so that the control system can then automatically re-tune the vehicle's suspension based on the change to the damping component.

A method of setting the rides height of the air springs and air pressures of the tires, including receiving a user selected setting or preprogrammed ride height settings; sensing a ride height of, and air pressure within, each of the air springs; determining the weight of the vehicle based on the sensed ride height and air pressure within each of the air springs; providing specified ride heights for the left and right front and rear air springs; determining specified air pressures for the left and right front and rear tire inflators, based upon the determined weight of the vehicle and selected setting; inflating the left and right front and rear air springs to the specified ride heights; and inflating the left and right front and rear tires to the specified air pressures.

A system includes multiple drive modules, each for at least one actuator of a wheel or an axle of a vehicle. Each drive module has a bus interface for connecting to a bus, a switching signal input and a switching signal output. The drive module is configured to operate in an operating mode and a learning mode. The drive module has a switch and is configured to use the switch in the operating mode to conductively connect the switching signal input to the switching signal output and, after a transition from the operating mode to the learning mode, to interrupt the connection between the switching signal input and the switching signal output. The drive modules are connected in series via the switching signal inputs and switching signal outputs.

Methods and systems are provided for controlling a suspension system of a vehicle. In one embodiment, the method includes: receiving, by a processor, sensor data indicative of conditions of a roadway in a path of the vehicle; determining, by a processor, a continuous road profile based on the sensor data; and selectively controlling, by a processor, at least one suspension element of the vehicle based on the continuous road profile.

A method for operating an actuator of a torsion bar system of a wheel suspension of a motor vehicle is disclosed. The actuator is mounted on a carrier structure of the vehicle and actuation of the actuator changes a pre-tension acting on a wheel guide element of the wheel suspension. The method includes controlling an active aggregate support so as to reduce a vibration of a drive aggregate supported on the carrier structure via the active aggregate support adjacent to the actuator; and controlling the active aggregate support for reducing an operational vibration of the actuator.

A method for adapting a transfer function of an active suspension of a vehicle comprises the vehicle driving along a section of road for which a surface profile is stored in a control unit of the vehicle. The active suspension is activated according to a predetermined transfer function for adaptation to the surface profile by means of adjustment values in order to compensate for unevenness of the surface profile. A shock absorber sensor system and/or a tire sensor system of the vehicle is used to record vertical accelerations while driving along the section of road and transfer them to the control unit. The invention provides that the adjustment values and the vertical accelerations are transferred by the vehicle to an external central computer.

A snowmobile including a chassis including a tunnel; a motor; at least one ski; an endless drive track; a rear suspension assembly including: a front suspension arm; a rear suspension arm; a pair of slide rails; a first rear shock absorber connected between the front suspension arm and the slide rails; and a second rear shock absorber connected between the rear suspension arm and the front suspension arm or the slide rails; at least one sensor for sensing an angular position of the front suspension arm or the rear suspension arm relative to one of the tunnel and a component of the rear suspension assembly near at least one of the front suspension arm and the rear suspension arm; and a controller communicatively connected to the sensor to receive electronic signals therefrom representative of the angular position.

A snowmobile including a right front suspension assembly and a left front suspension assembly, each of the left and right front suspension assembly including: a ski leg; an upper A-arm and a lower A-arm, the upper and lower A-arms being connected between the ski leg and the chassis; and a shock absorber connected between one of the upper and lower A-arms and the chassis; a first sensor connected between one of the upper and lower A-arms of the right front suspension assembly and the chassis to measure the angle therebetween; a second sensor connected between one of the upper and lower A-arms of the left front suspension assembly and the chassis to measure the angle therebetween; and a controller communicatively connected to the first sensor and the second sensor, the electronic signals representing angular position between the A-arms of the right and left front suspension assembly and the chassis.

A control system for a vehicle suspension system comprises one or more controllers and is configured to: receive a total roll signal indicative of a total roll moment of the vehicle, the roll moment determined in dependence on a lateral acceleration of the vehicle; receive a spring stiffness signal indicative of a non-active roll moment component of the vehicle, the non-active roll moment component dependent on a current spring stiffness mode of plural available spring stiffness modes of the variable stiffness spring system; determine a target active roll moment component of the vehicle, in dependence on the total roll moment and the non-active roll moment component; and output an active roll control signal indicative of the target active roll moment component to the active roll control system to control the roll moment of the vehicle.