The disclosure relates to a method for operating a braking system of a vehicle during autonomous parking processes, including a first electronic control unit, a service brake system, and a partial braking system. The first control unit is designed for activating the service brake system and the partial braking system, in which an autonomous parking process is initiated, followed by an activation of the service brake system by the first control unit to generate a braking force. In the event of a failure of the service brake system, the partial braking system is activated by the first control unit to generate a braking force while the autonomous parking process is continued by utilising the partial braking system. The disclosure also relates to a vehicle control system for controlling autonomous parking processes.

The present disclosure relates to a wheel speed sensor system (1), comprising: one or more first wheel speed sensors (2a, 2b), a first application specific integrated circuit (ASIC) (4) configured to receive one or more first wheel speed signals from the one or more first wheel speed sensors (2a, 2b) and to convert the one or more first wheel speed signals to first wheel speed data, and a first electronic control unit (ECU) (6) configured to receive the first wheel speed data from the first ASIC (4) via a data link (8) between the first ECU (6) and the first ASIC (4); and one or more second wheel speed sensors (3a, 3b), a second ASIC (5) configured to receive one or more second wheel speed signals from the one or more second wheel speed sensors (3a, 3b) and to convert the one or more second wheel speed signals to second wheel speed data, and a second ECU (7) configured to receive the second wheel speed data from the second ASIC (5) via a data link (9) between the second ECU (7) and the second ASIC (5). The first ECU (6) is further configured to receive the second wheel speed data from the second ASIC (5) via a data link (13) between the first ECU (6) and the second ASIC (5), and the second ECU (7) is further configured to receive the first wheel speed data from the first ASIC (4) via a data link (14) between the second ECU (7) and the first ASIC (4). The present disclosure further relates to a vehicle including said wheel speed sensor system and to a method of processing wheel speed signals.

A method, an apparatus, and a computer-readable storage medium having instructions for cancelling a redundancy of two or more redundant modules. Results of the two or more redundant modules are received; reliabilities of the results are ascertained; and, based on the ascertained reliabilities, an overall result is determined from the results. The overall result is output for further processing.

Disclosed are an apparatus and a method for controlling a vehicle based on redundant architecture, and more particularly, a technology for monitoring breakdown of communication paths of a vehicle control device based on redundant architecture. The apparatus includes: a plurality of electronic controllers configured to control driving of the vehicle based on sensing information of the vehicle; and a plurality of communication paths configured to exchange data between the plurality of electronic controllers, wherein the plurality of electronic controllers are configured to generate a vehicle control instruction for controlling driving of the vehicle based on vehicle information and are configured to monitor an operational status of at least one of the plurality of electronic controllers through the plurality of communication paths.

The reliability of path planning calculation can be evaluated with low load without using multiplexing of calculation or an additional sensor. The electronic control device includes an integration unit that acquires information around a vehicle as sensor information from a plurality of sensors for each processing cycle, and integrates the acquired sensor information to create vehicle peripheral information for each processing cycle, a path planning unit that calculates a planned path on which the vehicle will travel in the future using the vehicle peripheral information for each processing cycle, and a path evaluation unit that evaluates reliability of the path planning unit, in which the path evaluation unit that uses, in the planned path calculated by the path planning unit in a first processing cycle, a position of the vehicle in a second processing cycle, which is a processing cycle after the first processing cycle, and the vehicle peripheral information created by the integration unit in the second processing cycle to evaluate the reliability of the path planning unit in the first processing cycle.

The reliability of path planning calculation can be evaluated with low load without using multiplexing of calculation or an additional sensor. The electronic control device includes an integration unit that acquires information around a vehicle as sensor information from a plurality of sensors for each processing cycle, and integrates the acquired sensor information to create vehicle peripheral information for each processing cycle, a path planning unit that calculates a planned path on which the vehicle will travel in the future using the vehicle peripheral information for each processing cycle, and a path evaluation unit that evaluates reliability of the path planning unit, in which the path evaluation unit that uses, in the planned path calculated by the path planning unit in a first processing cycle, a position of the vehicle in a second processing cycle, which is a processing cycle after the first processing cycle, and the vehicle peripheral information created by the integration unit in the second processing cycle to evaluate the reliability of the path planning unit in the first processing cycle.

A control architecture for a vehicle connects a first control unit to a first vehicle communication network. A second control unit is connected to a second vehicle communication network. Commands are received by a plurality of commanded units from the first control unit and/or the second control unit over communication lines. An interlink communication line is connected between the first control unit to the second control unit.

A control architecture for a vehicle connects a first control unit to a first vehicle communication network. A second control unit is connected to a second vehicle communication network. Commands are received by a plurality of commanded units from the first control unit and/or the second control unit over communication lines. An interlink communication line is connected between the first control unit to the second control unit.

A redundant processing fabric in an autonomous vehicle may include processing, by a first processing unit of a plurality of processing units, sensor data from a first sensor of a plurality of sensors, where the plurality of processing units are coupled to the plurality of sensors via a switched fabric, wherein the plurality of processing units and plurality of sensors are included in the autonomous vehicle; determining a failure in processing the sensor data by the first processing unit; and redirecting, via the switched fabric, sensor data from the first sensor a redundant processing unit.

A vehicle control system has a first communication network, a first operation component, a first vehicle control unit connected to the communication network and to the first operation component, wherein the first vehicle control unit is configured to control a first data connection between the first operation component and the first vehicle control unit by a first signal to the first operation component, and a second vehicle control unit connected to the first operation component, wherein the second vehicle control unit is configured to control a second data connection between the first operation component and the second vehicle control unit by a second signal to the first operation component. The first data connection and the second data connection can be controlled so that at least one of the first data connection and the second data connection is enabled or disabled.