A bicycle component for an at least partially human-powered bicycle has a shock absorber device. The shock absorber device includes a damper device which can be controlled by a control device. A detection device is provided with a sensor device for receiving a signal. The sensor device is arranged on at least one component of the bicycle which is pivoted in the case of a steering movement. The detection device is suitable for detecting, and is designed to detect, the difficulty in the terrain as a function of the acquired signal, and is configured to control the damper device as a function of the detected difficulty in the terrain, with the result that a damping property of the damper device can be adjusted by way of a signal of the detection device.

The present invention discloses a dynamically adjustable suspension device including one or more springs having similar or different spring rates, where said one or more springs are arranged in a pre-defined configuration, and a dynamically adjustable damper. The dynamically adjustable damper, includes a rotatable knob coupled to the dynamically adjustable damper to change the damping coefficient dynamically in real-time, means to rotate the knob so as to adjust damping coefficient in real-time while the dynamically adjustable suspension device being used, means to identify compression of the one or more springs by sensing one or more positions of the springs, between a fully elongated state and a fully compressed state in real-time.

A method for a vehicle comprising at least one wheel suspension with at least one damper, wherein the at least one damper is such that it can adjust its damping resistance between a first damping mode and at least a second damping mode, wherein the second damping mode presents a larger damping resistance than a damping resistance of the first damping mode. The method comprises the steps: S1) identifying if the vehicle is in a first situation during driving of said vehicle which may lead to a subsequent impact force (F) on the at least one wheel suspension which is of a magnitude such that the at least one damper, when in its first damping mode, will reach a position where no further damping can be performed; and, if this is the case, S2) adjusting the damping resistance from the first damping mode to the at least second damping mode.

An exemplary method to detect a wear condition of a suspension system component of a vehicle includes the steps of receiving suspension system component data from a vehicle sensor, calculating an amplitude of the suspension system component data as a function of frequency, monitoring the amplitude of the suspension system component data within a predetermined frequency range, determining whether the amplitude of the suspension system component data is greater than a predetermined threshold, and, if the amplitude is greater than the predetermined threshold, transmitting a diagnostic notification.

A method for improving the safety and comfort of a vehicle driving over a railroad track, cattle guard, or the like. The method may include receiving, by a computer system, one or more inputs corresponding to one or more forward looking sensors. The computer system may also receive data characterizing a motion of the vehicle. The computer system may estimate, based on the one or more inputs and the data, a motion of a vehicle with respect to a railroad track, cattle guard, or the like extending across a road ahead of the vehicle. Accordingly, the computer system may change a suspension setting, steering setting, or the like of the vehicle to more safely or comfortably drive over the railroad track, cattle guard, or the like.

A suspension device (S) which is a means for solving the problem of the present invention includes an actuator (AC) movable in a telescopic manner, a pump (4), a liquid pressure circuit (FC) provided between the actuator (AC) and the pump (4) and supplying a liquid discharged from the pump (4) to the actuator (AC) so that the actuator (AC) expands and contracts, and a controller (C) controlling the driving of the pump (4), in which the pump (4) is controlled by obtaining a target rotation number of the pump (4) on the basis of road surface displacement detected by a preview sensor (41).

Disclosed is a method for measuring height in a vehicle by determining a distance between a vehicle chassis and a vehicle axle or parts connected thereto. In the method, a first device (12) with a first transmitter (13) and a first receiver (14) and a second device (15) with a second transmitter (16) and a second receiver (17) interact. In particular, the first transmitter (13) produces an electromagnetic field, and the second receiver (17) detects the electromagnetic field. The second device (15) with the second transmitter (16) produces a signal from the detected field and transmits the signal, which correlates with the distance from the first transmitter (13) to the second receiver (17). The first device (12) with the first receiver (14) receives the signal. A system, an electronically controlled pneumatic suspension, an electronic control unit, and a vehicle are also disclosed.

The invention relates to a method for providing a manipulated variable for an actuator (4) of an active chassis of a motor vehicle (2), wherein the manipulated variable in the event that a value for a projected variable, which is dependent upon a height profile of the terrain to be travelled by the motor vehicle (2), is available, is configured from a combination of a Skyhook variable, which is dependent upon a movement of a structure of the motor vehicle (2), and the projected variable, and wherein the manipulated variable is configured from a combination of a soft-spring variable, which is dependent upon a wheel-suspension of the motor vehicle (2), and the Skyhook variable, if no value for the projected variable is available.

A method for improving the safety and comfort of a vehicle driving over a railroad track, cattle guard, or the like. The method may include receiving, by a computer system, one or more inputs corresponding to one or more forward looking sensors. The computer system may also receive data characterizing a motion of the vehicle. The computer system may estimate, based on the one or more inputs and the data, a motion of a vehicle with respect to a railroad track, cattle guard, or the like extending across a road ahead of the vehicle. Accordingly, the computer system may change a suspension setting, steering setting, or the like of the vehicle to more safely or comfortably drive over the railroad track, cattle guard, or the like.

A system for controlling an active stabilizer bar in a vehicle includes a stabilizer bar associated with one or more wheels of the vehicle and a control module in communication with the stabilizer bar. The stabilizer bar is configured to be controlled according to a plurality of stiffness modes. Each stiffness mode is associated with a different amount of torque for the stabilizer bar. The control module is configured to control the stabilizer bar to operate according to a first stiffness mode of the plurality of stiffness modes, detect an anomaly in a path of the vehicle, and in response to detecting the anomaly, control the stabilizer bar to operate according to a second stiffness mode of the plurality of stiffness modes, the second stiffness mode being different than the first stiffness mode. Other examples systems and methods for controlling active stabilizer bars in vehicles are also disclosed.