A method of operating a powertrain system during coasting operation, wherein the powertrain system includes a driveline component (e.g., a transmission, drive shaft, differential, axle or wheel) having an output torque profile. The method includes: (i) determining a desired output torque transition profile for the driveline component between a first transition point before an end of a first state, and a second transition point after a beginning of a second state; and (ii) in response to a braking torque request, generating a friction braking torque command to operate a friction braking system, and adjusting the friction braking torque command during a transitional state between the first and second transition points by an amount corresponding to a difference between a magnitude of the output torque profile and a magnitude of the desired output torque transition profile.

A braking controller and method in a towing vehicle towing one or more towed vehicles as a combination vehicle provides brake control of the one or more towed vehicles based on a level of braking force applied to the towing vehicle. A non-enhanced braking mode applies a first level of braking force to the towed vehicles in a predetermined reduced proportion relative to the level of braking force applied to the towing vehicle, and an enhanced braking mode applies a second level of braking force to the towed vehicles greater than the first level of braking force. The enhanced braking mode strategy is used unless trailer capability information reported by one or more the trailers fails to match against expected trailer capability information.

A method for defining at least one characteristic curve which, in a pressure-actuated brake system of a vehicle, represents a relationship between a brake pressure and a brake demand), and for operating a pressure-actuated brake system of a vehicle, in which at least one brake cylinder can be supplied with a pressurized medium under a brake pressure, and in which the brake pressure is formed based on at least one such characteristic curve, and to a pressure-actuated brake system of a vehicle in which at least one brake cylinder can be supplied with a pressurized medium under a brake pressure.

A braking system having expanded functionality, which provides the driver of a vehicle the option to manually control the clamping force of the rear brakes as desired, while keeping existing braking system functionalities. The braking system includes a manual control device, such as a hand lever assembly, and the driver is able to move the hand lever to various positions. The position of the lever corresponds to an equivalent rear hydraulic brake clamping force request. A fully retracted lever corresponds to a complete release action of the rear hydraulic brakes, and a fully actuated lever corresponds to a complete clamping of the rear hydraulic brakes. Any position in between the fully retracted and fully actuated positions corresponds to a partial apply of the rear hydraulic brakes using a predefined ratio of force to lever position.

A brake system includes a master cylinder configured to generate a hydraulic pressure, a primary brake actuator configured to increase and decrease the hydraulic pressure generated in the master cylinder, a secondary brake actuator connected in series with and downstream of the master cylinder and in series with and upstream of the primary brake actuator, and configured to increase and decrease the hydraulic pressure generated in the master cylinder, and at least one wheel cylinder configured to apply brake torque to a wheel of a vehicle based on the hydraulic pressure generated by the master cylinder and increased or decreased by the primary actuator or the secondary actuator. An automatic brake hold control method includes sequential performing an automatic brake hold control on at least one wheel cylinder by the primary brake actuator and then the secondary brake actuator.

A braking controller and method in a towing vehicle towing one or more towed vehicles as a combination vehicle provides brake control of the one or more towed vehicles based on a level of braking force applied to the towing vehicle. A non-enhanced braking mode applies a first level of braking force to the towed vehicles in a predetermined reduced proportion relative to the level of braking force applied to the towing vehicle, and an enhanced braking mode applies a second level of braking force to the towed vehicles greater than the first level of braking force. The enhanced braking mode strategy is used unless trailer capability information reported by one or more the trailers fails to match against expected trailer capability information.

Provided is a high-performance brake control device capable of effectively suppressing a vehicle body vibration generated during traveling on a road with a step or roughness. The brake control device includes a traveling environment estimation unit that estimates a traveling environment from a behavior of a first wheel that is any one of a plurality of wheels provided in a vehicle, and a timing calculation unit that calculates a timing at which a second wheel different from the first wheel is affected by the traveling environment, based on a vehicle speed. The plurality of wheels includes any one wheel that is controlled as for braking based on an estimation result of the traveling environment estimation unit and a calculation result of the timing calculation unit.

A control system for remotely configuring a locomotive may include an operational control device located on-board the locomotive, wherein the operational control device may be configured in a run configuration when the locomotive is ready for travel. An on-board controller located on-board the locomotive may be configured to switch the operational control device to the run configuration upon receipt of a configuration command signal. An off-board remote controller interface located remotely from the locomotive may be configured to receive a configuration failure signal, wherein the configuration failure signal may be indicative of the operational control device being in a configuration other than the run configuration. The off-board remote controller interface may selectively send the configuration command signal to the on-board controller to switch the operational control device to the run configuration.

A vehicle includes: a brake mechanism configured to brake a wheel in accordance with a pressure of a brake fluid; a hydraulic circuit configured to adjust the pressure of the brake fluid and transfer the brake fluid to the brake mechanism; and a controller. The controller includes one or more processors to execute: a torque adjustment process of giving an offset to increase a required driving torque determined based on an operation amount of accelerator of the vehicle in a case where it is determined that the vehicle is in a stolen state; and a brake fluid pressure adjustment process of applying control to the hydraulic circuit to pressurize the brake fluid so as to compensate for an increase in the required driving torque due to the offset.

This disclosure provides systems and methods for deceleration control during emergency braking using control algorithm override. An embodiment of the present disclosure provides a computer-implemented method for deceleration by a controlling device of an autonomous driving vehicle (ADV). The method includes engaging a braking system of the ADV to decelerate the ADV using a first deceleration algorithm. When an onset of discrepancy between a velocity of the ADV and a corresponding wheel speed of the ADV is detected, a processing device, based on the discrepancy, overrides an output of the first deceleration algorithm using a second deceleration algorithm that prioritizes in reducing the discrepancy between the velocity of the ADV and the corresponding wheel speed of the ADV over a target rate of deceleration computed by the first deceleration algorithm.