Methods, systems, devices and apparatuses for an air management system that circulates air to reduce the cabin temperature within a vehicle. The air management system includes a window configured to allow air circulation within the vehicle. The air management system includes an actuator coupled to the window and configured to open or close the window to control an amount of air circulation. The air management system includes a sensor. The sensor is configured to measure or determine a cabin temperature within the vehicle. The air management system includes an electronic control unit. The electronic control unit is coupled to the actuator and the sensor and configured to determine, using the sensor, that the cabin temperature is greater than or equal to a first temperature and control the actuator to open the window and allow air circulation within the vehicle.

A vehicle control device includes: an on-vehicle-user-number recognizing unit that performs recognition of an on-vehicle-user-number, and stores the on-vehicle-user-number in a storage unit, the on-vehicle-user-number being a number of users who have got on a vehicle; an off-vehicle-user-number recognizing unit that recognizes an off-vehicle-user-number, the off-vehicle-user-number being a number of the users who have got off the vehicle after the recognition of the on-vehicle-user-number by the on-vehicle-user-number recognizing unit; and a power door control unit that causes at least one power door to perform closing operation when the on-vehicle-user-number stored in the storage unit equals the off-vehicle-user-number recognized by the off-vehicle-user-number recognizing unit, the at least one power door being a power door that the user has used at a time of getting off the vehicle.

A method for state-based maintenance of an access device of a vehicle, in particular of a public transport vehicle, wherein the access device includes a moveable element and an electric drive for moving the moveable element and is attached to the vehicle. The drive is controlled with control signals, wherein actual state signals for describing the state are generated based on a detected state of the access device. The control signals are applied to a physical simulation model for computationally simulating the access device and determining expected target state signals and wherein based on a comparison between the actual state signals and associated target state signals, a maintenance state of the access device is determined. The simulation model is adjusted based on the comparison between the actual state signals and the associated target state signals.

A bidirectional door opening module includes a vehicle body panel located between a first door configured to be rotated to open one end of a vehicle and a second door configured to be rotated to open a remaining end of the vehicle, and a drive unit coupled to the vehicle body panel and configured to apply opening force to the first door and the second door, wherein the drive unit includes a driver configured to apply driving force so as to open the first door or the second door, rail units configured to receive the driving force of the driver and then to apply opening force to the first door or the second door, and hinge units coupled to the rail units and configured to perform rotary opening of the first door or the second door.

A train door control method and system are provided. The train door control method includes: acquiring a first train identifier and a second train identifier when multiple trains park in a platform at the same time, a door of a first train to which the first train identifier belongs being to be opened at a current time point, and a second train to which the second train identifier belongs being a train arranged behind the first train, which enters the platform and parks in the platform; and controlling the opening and closing of the door of the first train and a door of the second train at different time points respectively according to the first train identifier and the second train identifier.

Methods and apparatus to wirelessly interlock doors are disclosed. A door system includes a user interface to receive interlock configuration data input from a user, the interlock configuration data to define an interlock condition to be satisfied before a first door is to undergo an operation, the interlock condition associated with a current state of a second door. The door system includes a first wireless transceiver to receive a signal from a second wireless transceiver associated with a second door. The method includes a door operation controller to at least one of (1) implement the operation of the first door in response to a request when the current state of the second door satisfies the interlock condition, (2) ignore the request, or (3) not execute the operation of the first door in response to the request when the current state of the second door does not satisfy the interlock condition.

The invention relates to a circuit for selectively actuating drive elements (1, 2), which are operated on direct current, in a motor vehicle by means of half-bridges (4, 5). According to the invention, the circuit is designed for selectively actuating eight drive elements (1, 2) for locking and, respectively, unlocking four doors of the motor vehicle from the outside and/or from the inside. The circuit contains nine half-bridges (4, 5), wherein the outputs of eight of the nine half-bridges (4) are each connected to a first pole of one of the eight drive elements (1, 2) and the output of the ninth half-bridge (5) is connected to all second poles of the eight drive elements (1, 2).

A computer implemented method, comprising: detecting presence of an object of interest within a plurality of image frames received from a sensor; determining that the object of interest is moving towards an automatic door that is configured to close within a predetermined time period; determining, based on position, speed and direction of the object of interest, a likelihood that the object of interest may impede closing of the automatic door; and when the likelihood exceeds a threshold value, maintaining the automatic door in an open position for a longer period of time than the predetermined time period.

An automated sliding panel mechanism is disclosed. An automated sliding panel mechanism including a motor is configured to move a sliding window between a closed position and an open position, and includes a power source providing power to the motor, a rack consisting of rack teeth wherein a portion of the surface of the rack teeth are generally perpendicular to a plane, and a gear rotated by the motor and consisting of gear teeth, wherein the gear teeth are shaped to mesh with the rack teeth.

In one aspect, a method is provided for controlling access to a facility including a movable barrier and a plurality of loading docks. The method includes receiving, from a user device associated with a vehicle, a check-in communication that includes a check-in identifier. The method includes receiving a verification communication that verifies a presence of the vehicle relative to a sensor associated with the movable barrier. The method further includes causing a movable barrier operator associated with the movable barrier to move the movable barrier between closed and open positions in response to the check-in identifier indicating authorization to access the facility and in response to receiving the verification communication. Further, the method includes selecting a particular loading dock from the plurality of loading docks and communicating a loading dock identification representative of the particular loading dock to the user device to direct the vehicle to the particular loading dock.