A method for determining jumps and/or inflection points in an activation characteristic of an activation unit includes activating the activation unit using an activator, wherein different activation areas, separated from one another by the jumps and/or inflection points, are defined by the activation characteristic. Different activation forces for activating the activator are respectively set in the activation areas. The jumps and/or inflection points are determined by activating the activator by continuously determining activation travel values of the activator, respectively assigning an activation speed characteristic variable to the determined activation travel values, continuously forming value pairs from the determined activation travel value and the assigned activation speed characteristic variable, and checking, based on the value pairs which are formed whether significant changes occur in the activation speed. The jumps and/or inflection points in the activation characteristic are assigned to activation travel values at which significant changes occur in activation speed.

The present invention makes it possible to avoid the risk of a brake operation system for emergency stopping not operating normally during autonomous travel of a work vehicle. A work vehicle is provided with: a foot brake for braking left and right rear wheels; an autonomous travel unit that enables autonomous travel of the vehicle; and an electric actuator for switching the foot brake between a braking state and a release state. The autonomous travel unit comprises a control unit for controlling the operation of the electric actuator. When an autonomous travel mode is selected by human operation of a mode selection unit, the control unit performs operation verification processing in which it is verified by operation control of the electric actuator whether the foot brake is operating normally, and when it is verified that the foot brake is operating normally in the operation verification processing, said control unit transitions to a completed operation verification state and allows the travel mode to transition from a manual travel mode to the autonomous travel mode.

A method, for a trailer brake control device of a vehicle trailer with an electric drive, includes receiving at least one acceleration request signal with a requested positive acceleration or a requested negative acceleration and further receiving a status signal with at least one status variable of the electric drive of the vehicle trailer. The method also includes generating, with a controller of the trailer brake control device, at least one brake actuation signal for at least one friction brake of the vehicle trailer and a torque request signal for the electric drive, each based on the at least one acceleration request signal and the status signal. Furthermore, the method includes outputting the brake actuation signal and the torque request signal via at least one output and/or at least one interface of the trailer brake control device.

The present disclosure provides an emergency braking system, an emergency braking method and a semitrailer, capable of improving the braking effect of the vehicle, thereby achieving improved safety for the vehicle. The system includes: a sensor component configured to collect sensed information on an environment where a semitrailer is located; and a braking controller configured to determine whether there is a risk of collision for the semitrailer based on the sensed information, and if so, calculate a maximum adhesive force that can be provided by a road surface the semitrailer is currently on, determine a first braking pressure corresponding to each wheel based on the maximum adhesive force and axle load information, and transmit to a braking system a first braking instruction carrying the first braking pressure for each wheel.

A control system for a motor vehicle automatically activates or deactivates a parking lock or an automatic roll-away prevention facility. The control system has at least one electronic control unit which is designed such that limited maneuvering operation is possible within set boundary conditions in accordance with predefined embarking conditions and in accordance with predefined disembarking conditions, an identified intentional maneuvering demand of the driver after prior automatic roll-away prevention of the vehicle being defined as a predefined embarking condition. The limited maneuvering operation may be activatable both in the case of an activated motor and in the case of a deactivated motor proceeding from a secured state. Depending on the differently defined disembarking conditions that are satisfied, a transition can be made from the limited maneuvering operation either into the secured state, or driving operation can be permitted if the defined conditions for the automatically secured state are no longer present.

A braking system for a motor vehicle includes a hydraulic service brake for braking the motor vehicle in driving operation, an electric parking brake for holding the motor vehicle at a standstill, and an electronic control system for automatically controlling the parking brake and the service brake. The electronic control system may be adapted to activate the parking brake, with the service brake activated, after the motor vehicle has been braked to the standstill via the activated service brake, and to at least partly deactivate the activated service brake after the parking brake has been activated. The electronic control system may also be adapted to deactivate the activated parking brake following operation of an accelerator pedal of the motor vehicle.

A foldable brake pedal apparatus for an autonomous driving vehicle is provided. In a manual driving mode in which a driver directly operates a vehicle, a lower end of a brake pedal is exposed to an interior of the vehicle to allow engagement of the brake pedal by a driver and, in an autonomous driving mode in which the driver does not directly drive the vehicle, the lower end of the brake pedal is pivoted and moved forward due to an operation of an actuator to switch to a concealed state in which an operation of the brake pedal is blocked.

A method for installing a stroke sensor is provided such that the stroke sensor can be easily adjusted using a simple process.

The method has the steps of; obtaining a relationship between the magnetic field and the indicator value while moving the magnet in the first direction relative to the magnetic field detecting element within a predetermined relative movable range, and writing the relationship in the processor; after the relationship is written in the processor, preventing the predetermined relative movable range from being shifted in the first direction by means of a jig for preventing positional shift, wherein the jig includes an element that fixes relative positions between the magnetic field detecting element and the magnet; attaching the magnet and the magnetic field detecting element, which have been prevented from being shifted, to different structures that are movable in the first direction relative to each other, and removing the jig.

A system for predicting a negative pressure of a brake booster of a vehicle includes: a driving information detector configured to detect driving information according to driving of the vehicle; and a controller configured to calculate a negative pressure of an intake manifold based on a pressure of the intake manifold and an atmospheric pressure that is the driving information and including a booster negative pressure predictor configured to predict the negative pressure of the brake booster by integrating over time a change rate according to a charging rate and a discharging rate of the negative pressure calculated using a previous negative pressure of the brake booster calculated in a previous cycle according to a logic for predicting the negative pressure of the brake booster and the negative pressure of the intake manifold and a brake pedal force of a current cycle.

A system for predicting a negative pressure of a brake booster of a vehicle includes: a driving information detector detecting driving information related to driving of the vehicle; and a controller determining a negative pressure of an intake manifold based on a pressure of the intake manifold and an atmospheric pressure which is the driving information and including a booster negative pressure predictor predicting the negative pressure of the brake booster by integrating over time a change rate according to a charging rate and a discharging rate of the negative pressure determined using a negative pressure of the brake booster determined in a previous cycle according to a logic for predicting the negative pressure of the brake booster and the negative pressure of the intake manifold of a current cycle and an imitated brake pedal force signal of the current cycle imitating an acceleration of the vehicle.