A method of brake control of a vehicle combination (2) composed of a tractor vehicle (4) with an electronically controlled braking system (5) and a trailer vehicle (6, 8) with a pneumatically controlled pneumatic braking system (7, 9), involves introducing the brake control pressure (p.sub.BC) of the trailer vehicle (6, 8) into a tractor brake control line (19) extending to a tractor vehicle-side brake coupling head (26) via an electronically controlled trailer control valve (13) of the tractor vehicle (4). At the beginning of a braking operation, a pressure pulse (34) exceeding a target brake control pressure (p.sub.BC_soll) is introduced into the tractor brake control line (19). The volume of a trailer brake control line (28, 29, 32) coupled to the brake coupling head (26) is ascertained, and the absolute value (p.sub.PI) and/or the duration (t.sub.PI) of the pressure pulse (34) introduced are/is established depending on the ascertained volume.

A digital autonomous hardware based FPGA (Field Programmable Gate Array) device and method for preventing the initial onset of trailer oscillations and swaying (Snaking) movements and subsequent control thereof. The device being a detection and control method for any wheeled trailer which is detachable from the towing vehicle. The system uses a Kalman Filter to processes digital data from a number of wireless IMUs (Inertial Measurement Units) located on the trailer and towing vehicle and then subsequently digitally controls the application and monitoring of simultaneous braking to the trailer whilst accelerating the towing vehicle in a safe manner in an attempt to quickly alleviate and stop all oscillations and swaying (Snaking) movements. The system includes a number of other ancillary safety related features.

A brake control unit includes a processor, a first high side driver and a second high side driver. The processor sends signals to the first high side driver and the second high side driver. The first and second high side drivers process the signals independent of each other. The processor diagnoses faults and locations of faults based on feedback from the high side drivers. The first high side driver controls the braking of a first trailer brake. The second high side driver controls the braking of a second trailer brake.

A trailer brake controller and system detects absolute deceleration of a trailer by incorporating an electronic gyroscope/accelerometer combination in order to accurately calculate the deceleration subtracting out the component which is due to the force of gravity. The controller and system also receives and reads information from the towing vehicle's speed sensor. The system detects the deceleration of the trailer and sends a signal to a trailer brake activation circuit based upon an acceleration status of the trailer. In some embodiments, the system detects that the trailer is decelerating and the trailer control device sends a signal to the trailer braking system activation circuit to activate the trailer brakes. Particularly, the system is able to detect that the trailer is decelerating at an unsafe rate and to activate the trailer brakes and slow the trailer to a safe speed.

Embodiments of the invention provide a device and method for controlling sway of a trailer utilizing a global positioning system (GPS) device to detect a speed of a vehicle, a rate gyro to detect a sway angle of the vehicle, and a controller coupled to the GPS device and the rate gyro. The GPS and the rate gyro provide the speed and the sway angle to the controller and the controller outputs a brake command if either a first condition is satisfied or a second condition is satisfied.

A vehicle includes friction brakes, an axle, and a controller. The axle has an electronic limited-slip differential that includes a variable torque capacity lockup clutch. The controller is programmed to, in response to a difference between desired and actual yaw rates exceeding a first threshold, increase the torque of the lockup clutch to decrease the difference between the desired and actual yaw rates. The controller is further programmed to, in response the difference between desired and actual yaw rates exceeding a second threshold that is greater than the first threshold, increase the torque of the friction brakes to decrease the difference between the desired and actual yaw rates.

A control apparatus and a method of a brake system include an input unit receiving a connection signal on a connection between a vehicle and a trailer sensed by a sensing apparatus and receives current yaw rate error information of the vehicle according to current oscillation information of the trailer, a determination unit determining whether the vehicle and the trailer are mutually connected based on the connection signal, and a control unit selecting target yaw rate information preset while being divided for each type and weight of the trailer depending on the connection of the trailer to reduce a yaw rate error rate with respect to the current yaw rate error information of the vehicle according to the current oscillation information and transmitting a brake command to the brake system to brake the vehicle according to the selected corresponding target yaw rate information.

A trailer braking system comprises a vehicles having a continuously-variable hydrostatic transmission, and a trailer coupled for towing by the vehicle and having an associated braking system operable from the vehicle. The vehicle transmission includes a first pressure sensor arranged to measure a fluid pressure at a predetermined point within the transmission, and a rotation sensor arranged to determine a rotation direction of a predetermined component in a driveline of the vehicle. A control unit coupled to the first pressure sensor and rotation sensor determines when a PUSH condition exists based on a particular combination of pressure and rotational direction, and operates the trailer brakes in response. One or more back-up systems to confirm the existence of a PUSH condition may be provided.

A method and device for determining a target curve incline of a motor vehicle during traveling of a curved roadway section is disclosed. A momentary transverse acceleration of the motor vehicle is determined depending on a momentary speed of the motor vehicle and a momentary roadway curvature of the curved roadway section determined by an optical detection system. A momentary target curve incline for the motor vehicle is calculated from the determined momentary transverse acceleration. A modified momentary target curve incline is calculated by weighting of the calculated target curve incline with a speed-dependent target curve incline weighting factor. The momentary roadway curvature is determined by additionally using a vehicle navigation system of the motor vehicle.

A method is provided for the detection of a critical snaking motion of a trailer of a vehicle combination, in which a setpoint yaw rate of the trailer is ascertained from the transverse acceleration of the trailer and the longitudinal speed of the vehicle combination, the actual yaw rate of the trailer is ascertained using a yaw rate sensor, and by a comparison of the curve over time of the setpoint yaw rate and the actual yaw rate, the presence of a critical snaking motion of the trailer is ascertained.