A method for adjusting one or more vehicle dynamics systems of a vehicle, the vehicle comprising a road wheel and at least one vehicle sensor configured to provide vehicle condition data, the road wheel comprising a tyre sensor configured to output tyre operation data, the method comprising: receiving tyre operation data from the tyre sensor; receiving vehicle condition data from at least one vehicle sensor; calculating one or more vehicle dynamics parameters based on the vehicle condition data and the tyre operation data; and adjusting one or more vehicle dynamics systems in response to the calculated one or more vehicle dynamics parameters.

This invention pertains to shock absorbers, and a method of controlling their operation. Specifically, this invention relates to use of a user interface allowing to control the sensitivity of various parameters used by a programmed electronic control unit. When in operation, said electronic control unit automatically send calculated and user-adjusted electronic signals to electronic control devices which proportionally regulate flow of fluid within each shock absorbers of a vehicle.

System and method for operating an active suspension system of a vehicle includes actuating a switch on the vehicle, setting the active suspension system for the vehicle to a demonstration mode, setting a timer when the active suspension system is set to the demonstration mode, and setting the active suspension system for the vehicle to a normal operating mode after the timer reaches a predetermined time. Prior to expiration of the timer, the system and method determines a gear in which the vehicle is placed, determines whether an engine of the vehicle is running if the transmission gear of the vehicle is drive, reverse, or neutral, and determines a throttle angle of the vehicle if the engine is running. The active suspension system is set to a normal operating mode if the throttle angle is greater than a predetermined angle. An iterative process determines the status of the timer.

A cooperative control module, an adaptive cruise system and a control method thereof, and a vehicle are provided. The adaptive cruise system comprises a vehicle sensor module, a driving environment intelligent sensing module, a vehicle state response estimation module, an adaptive cruise and controllable suspension cooperative control module, and a power control module. The control method of adaptive cruise is optional, one is according to the cruise speed set by the driver, and the other one is according to the cruise comfort set by the driver. In the case of adaptive cruising according to cruise comfort, the optimal cruise speed is intelligently calculated by the adaptive cruise and controllable suspension system based on driving conditions and driver's demands. The controllable suspension is controlled cooperatively during cruising, and the suspension control parameters are adaptively switched according to the performance requirements of the vehicle under different driving conditions.

The present invention field relates to a braking device of the tilting system of vehicles that have at least three wheels and can lean sideways by virtue of the presence a so-called wheel tilting system. The device is characterized in that it comprises an electronic control unit adapted to receive and process a plurality of signals coming from devices capable of detecting parameters related to the instantaneous dynamic behavior of the vehicle and to selectively actuate said braking means.

A two-wheel suspension mechanism includes a control frame having therein a left channel and a right channel; a control valve disposed at the control frame and connected between the left and right channels; a left retractable cylinder having a left external-cylinder and a left internal-cylinder, with the left external-cylinder pivotally connected to the control frame, and the left internal-cylinder retractable into the left external-cylinder, defining a left retractable space between the left external-cylinder and the left internal-cylinder, allowing the left retractable space to communicate with the left channel; a right retractable cylinder having a right external-cylinder and a right internal-cylinder, with the right external-cylinder pivotally connected to the control frame, and the right internal-cylinder retractable into the right external-cylinder, defining a right retractable space between the right external-cylinder and the right internal-cylinder, allowing the right retractable space to communicate with the right channel.

An ECU controls the damping force at the time of the expansion movement and contraction movement of the front fork. When detecting at least that the motorcycle is in a state of making a stop and the brake hydraulic sensor shows an output of more than or equal to a predetermined value, the ECU carries out a damping force reducing control for minimizing the damping force of the front fork. The ECU takes the following sequential steps of: sensing a start of an expansion movement of the front suspension after starting the damping force reducing control, sensing a termination of the expansion movement of the front suspension, and terminating the damping force reducing control.

In a suspension controlling apparatus for a vehicle which includes a suspension whose damping force is variably settable and a control unit for calculating acceleration of the vehicle in a forward and rearward direction on the basis of brake hydraulic pressure detected by a hydraulic pressure sensor for detecting brake hydraulic pressure and is capable of controlling the damping force of the suspension with target damping force determined on the basis of the acceleration. In addition, appropriate control is also possible upon antilock braking control. A control unit includes an acceleration calculation device for calculating, upon ordinary braking, acceleration on the basis of ordinary braking force corresponding to a detection value of a hydraulic pressure sensor but calculating, upon antilock braking control, the acceleration on the basis of given antilock brake controlling braking force.

The present invention achieves suspension control that allows for synchronization of the roll and the pitch of a vehicle. This suspension control device that controls the damping force of a suspension comprises: a target pitch angle calculation unit that calculates a target pitch angle with reference to a roll angle signal; and a target control amount computation unit that calculates the roll posture target control amount referred to for controlling the damping force of the suspension by referring to a steering torque signal and the target pitch angle.

A technology can be realized which increases the sense of unity with a vehicle that is felt by a driver. A suspension control device, which controls the damping force of the suspension of a vehicle, comprises a target control amount calculation unit which sets a target control amount, that is referenced when controlling the damping force of the suspension, such that the period of the phase of the roll angle and the period of the phase of the pitch angle of the vehicle approach a synchronized state, such that the magnitude of the expansion-side damping force is greater than the magnitude of the contraction-side damping force on the front-wheel-side of the vehicle, and such that the contraction-side damping force is greater than or equal to the expansion-side damping force on the rear-wheel-side of the vehicle.