A parking assistance device includes a processor and a memory having instructions. The instructions, when executed by the processor, cause the parking assistance device to perform operations. The operations include: calculating a parking route to generate parking route information; and changing a stop determination distance parameter included in an automatic parking parameter based on obstacle information input to the parking assistance device and the parking route information.

The disclosure relates to a method for driver assistance, wherein a vehicle automatically performs a driving maneuver. In the method, a service brake of the vehicle is first actuated. Then a parking brake of the vehicle is controlled in such a way that the parking brake exerts no braking influence and that the free travel to be overcome for actuation of the parking brake is minimized. In subsequent steps, the service brake of the vehicle is released and an automatic driving maneuver is performed, wherein, if a fault or a specified event occurs, the parking brake is actuated such that the vehicle is braked to a standstill and is kept at a standstill. The disclosure further relates to a driver assistance system that is designed to perform the method.

A method for operating a parking brake system includes establishing a parking brake request for a first automated parking brake constructed on a first wheel located on a first side of an axle of a motor vehicle, producing a braking force at the first wheel by activating, in response to the establishing of the parking brake request, the first automated parking brake, and activating a compensation device connecting the first wheel and a second wheel located on a second side of the axle to apply a braking force to the second wheel via the first wheel.

System and techniques for vehicle operation safety model (VOSM) compliance measurement are described herein. A subject vehicle is tested in a vehicle following scenario against VOSM parameter compliance. The test measures the subject vehicle activity during phases of the following scenario in which a lead vehicle slows and produces log data and calculations that form the basis of a VOSM compliance measurement.

A platooning controller includes a processor configured to share information about a first platooning vehicle of a group of platooning vehicles with other platooning vehicles of the group of platooning vehicles when a brake of the first platooning vehicle breaks down during platooning and to perform braking control, and a storage configured to store data and an algorithm for platooning and braking control by the processor. The processor is configured to rearrange the group of platooning vehicles depending on a location where the first platooning vehicle is arranged in a platoon line, to decelerate the first platooning vehicle and a second platooning vehicle in front of the first platooning vehicle, and to center the first platooning vehicle and the second platooning vehicle to perform the braking control.

Systems and methods for controlling a vehicle. One example system includes a deceleration actuator coupled to a first wheel of the vehicle and an electronic processor communicatively coupled to the deceleration actuator. The electronic processor is configured to receive a vehicle park command. The electronic processor is configured to, responsive to receiving the vehicle park command, determine a maximum holding pressure threshold. The electronic processor is configured to determine a requested braking pressure for the deceleration actuator. The electronic processor is configured to determine whether the requested braking pressure exceeds the maximum holding pressure threshold. The electronic processor is configured to, responsive to determining that the requested braking pressure does not exceed the maximum holding pressure threshold, control the deceleration actuator to apply, to the first wheel during a hold time, a holding braking pressure equivalent to the requested braking pressure.

The present disclosure relates to an electrical parking control method and device, a readable storage medium and a computer device. The method includes that: when it is detected that a vehicle is in a self-piloting mode and a preset parking control condition is satisfied, a parking switching request message is generated, and sent to a VCU; a parking switching message fed back by the VCU is received, the parking switching message being a message generated when the VCU detects that a vehicle state is executable parking switching; a parking switching signal corresponding to the parking switching message is generated; and the parking switching signal is pushed to an external Electrical Park Brake (EPB) system, the parking switching signal being used to switch a state of the external EPB system, the state including a tightening state and a releasing state.

The present disclosure relates to a resource allocation procedure for allocating time-frequency radio resources by a scheduler in a mobile communication system. A plurality of numerology schemes are defined, each partitioning a plurality of radio resources of the mobile communication system into resource scheduling units in a different manner. A reference resource set is defined per numerology scheme, each being associated to a set of radio resources usable for being allocated according to the respective numerology scheme. The reference resource set of at least one numerology scheme overlaps with the reference resource set of at least another numerology scheme in the frequency and/or time domain. The resource allocation procedure is performed for allocating radio resources to one or more user terminals according to the numerology schemes. The resource allocation procedure is performed for each numerology scheme based on a scheduling time interval defined for the respective numerology scheme.

A parking assist system is configured to autonomously move a vehicle to a target parking position. The parking assist system includes: a distance acquiring unit configured to acquire a distance between the vehicle and a vehicle stopper provided in the target parking position; and a control unit configured to control a movement of the vehicle to the target parking position based on the distance acquired by the distance acquiring unit.

The vehicle stop position accuracy is improved. A parking assist device, which assists parking of a vehicle at a target stop position, includes: a traveling distance calculation unit that calculates a traveling distance of the vehicle based on a wheel speed pulse; and a braking/driving force calculation unit that determines a remaining distance to the target stop position based on the traveling distance, and switches control of the braking force of the vehicle from feedback control to feedforward control when the remaining distance becomes a value equal to or less than a predetermined value.