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 trailer oscillation and stability control device including an accelerometer and an angular rate sensor. An oscillation detection discriminator detects oscillatory lateral trailer motion in response to trailer displacement data derived from inputs from the angular rate sensor and acceleration signals received from the accelerometer, and then generates corresponding oscillatory event data. A brake controller generates a braking control signal in response to oscillatory event data received from the oscillation detection discriminator.

Embodiments are presented herein for trailer sway detection and mitigation using a camera mirror system. In one embodiment, a vehicle controller is provided comprising: one or more processors; a non-transitory computer-readable medium; and program instructions stored on the non-transitory computer-readable medium. When executed by the one or more processors, the program instructions cause the one or more processors to: monitor images captured by at least one image capture device to detect sway of a trailer being towed by a tractor; and in response to detecting sway of the trailer, cause a braking system to apply a brake to attempt to reduce to the sway of the trailer.

Embodiments are presented for trailer sway detection and braking distribution using a camera mirror system. In one embodiment, a vehicle controller is provided comprising: one or more processors; a non-transitory computer-readable medium; and program instructions stored on the non-transitory computer-readable medium. The program instructions, when executed by the one or more processors, cause the one or more processors to: monitor images captured by at least one image capture device to detect sway of a plurality of trailers being towed by a tractor; estimate a relative weight of each of the plurality of trailers based on the detected sway; determine braking force to apply to each of the plurality of trailers based on the estimated relative weight of each of the plurality of trailers; and send an electronic signal to a braking system of each of the plurality of trailers to apply the determined braking force to each of the plurality of trailers.

A braking control system associated with a towed apparatus is provided. The braking control system includes an intelligent control, an accelerometer electrically coupled to the intelligent control, a global positioning receiver electrically coupled to the intelligent control, and a visual indicator operatively coupled to the intelligent control. The braking control system may also include a wireless RF receiver operatively coupled to the intelligent control.

An arrangement for improving stability of a vehicle combination includes a towing vehicle and at least one towed vehicle, where the at least one towed vehicle includes an actively steered axle and/or individual brake on at least one axle, where the towing vehicle and the at least one towed vehicle each includes a lateral acceleration determining arrangement. A vehicle combination model is adapted for determining a desired delay value between the lateral acceleration of the towing vehicle and the lateral acceleration of the at least one towed vehicle, where the arrangement is adapted to stabilize the at least one towed vehicle by using the determined lateral acceleration of the towing vehicle and the desired delay value for the at least one towed vehicle to establish a desired lateral acceleration for the at least one towed vehicle, and to control the steered axle and/or the individual brake of the at least one towed vehicle such that the determined lateral acceleration of the at least one towed vehicle corresponds to the desired lateral acceleration of the at least one towed vehicle.

An arrangement for improving stability of a vehicle combination including a towing vehicle and at least one towed vehicle, where the at least one towed vehicle includes at least one actively steered axle and/or individual brake on at least one axle, where the towing vehicle and the at least one towed vehicle each includes an arrangement for determining yaw rate for determining the yaw rate of the vehicle and the at least one towed vehicle, where the arrangement further includes a vehicle combination model adapted for determining a desired delay value between the yaw rate of the towing vehicle and the yaw rate of the at least one towed vehicle, where the arrangement is adapted to stabilize the at least one towed vehicle by using the determined yaw rate of the towing vehicle and the desired delay value for the at least one towed vehicle to establish a desired yaw rate for the at least one towed vehicle, and to control the steered axle and/or the individual brake of the at least one towed vehicle such that the determined yaw rate of the at least one towed vehicle corresponds to the desired yaw rate of the at least one towed vehicle. The yaw rate may be estimated or measured. The advantage of the invention is that the stability of a vehicle combination can be improved, which in turn improves the road safety.

The present invention relates to a trailer with a trailer brake control device therein. The trailer brake control device of the present invention comprises: a sway detecting sensor arranged in the trailer for detecting the sway of the trailer; a signal sensor for detecting a brake signal generated by a brake switch of a vehicle which tows the trailer; and a processor, electrically connected to the sway detecting sensor, the signal sensor and the brake, for controlling the brake based on an output of the sway detecting sensor and/or an output of the signal sensor. According to the present invention, the trailer brake control device can independently control the brakes and/or diagnose the malfunction of a brake controller arranged in the vehicle.

A method for braking one or more trailers in a tractor-trailer combination. The method comprises establishing a maximum continuous brake pressure for trailer brakes of wheels of the one or more trailers of the tractor-trailer combination. The method further comprises establishing an on-off cycling frequency for pulsing of the brakes of the one or more trailers of the tractor-trailer combination at brake pressures above the maximum continuous brake pressure. The method further comprises establishing applying the brakes of the one or more trailers continuously at brake pressures up to the established maximum continuous brake pressure and by pulsing according to the established on-off cycling frequency at brake pressures above the established maximum continuous brake pressure.

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.