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 touchless stall door opening and closing system includes a motor, a door pivot for pivoting a door between an open position and a closed position, a locking mechanism for locking the door when the door is in the closed position, and a microcontroller for receiving a signal from a first sensor to drive the motor for opening the door and for receiving a signal from a second sensor for actuating the locking mechanism for unlocking the door. A method for touchless operation of the door includes touchless opening of the door, touchless closing of the door, and touchless locking and unlocking of the door.

A terminal device that is connected via a cable to a port of a switching device and performs data communication with a master device includes: a plurality of controllers configured to control, in accordance with a control command transmitted from the master device, a plurality of objects to be controlled; and a data transmitter configured to integrate data, transmitted from the plurality of respective controllers, in a transmission format for transmitting data to the master device to transmit the integrated data to the switching device.

A method for operating a system of a motor vehicle including a first electromotive door adjusting device having a first door, and a second electromotive door adjusting device having a second door. A request for carrying out a closing movement of the first door and for carrying out a closing movement of the second door is detected, and a priority rule is ascertained for activating the first electromotive door adjusting device and the second electromotive door adjusting device. The first electromotive door adjusting device and the second electromotive door adjusting device are activated on the basis of the priority rule. A system for a motor vehicle is also provided.

A barrier operator feature enhancement device is designed to provide one or more features found in modern barrier operator devices and to incorporate those features into a previously installed barrier operator system. To facilitate ease of use, the barrier operator feature enhancement device can communicate with a large variety of barrier operators. Such communication may be wireless or wired, depending on the communication protocol implemented by a particular previously installed barrier operator. To facilitate the ease of installation, the device is designed to configure itself to operate with the communication protocol of the previously installed barrier operator. Once configured to be able to communicate with the previously installed barrier operator, the feature enhancement device works with the barrier operator to provide one or more additional features to enhance the capabilities of the previously installed barrier operator.

An example window operator assembly comprises a motor, communication circuitry, and processor circuitry. The communication circuitry being configured to provide a first type of wireless communications and a second type of wireless communication with a first wireless communication system and a second wireless communication system. And, the processor circuitry being configured to identify connection loss between the communication circuitry and the first wireless communication system, and in response, cause the communication circuitry to switch to the second wireless communication system and cause the window operator assembly to perform an action.

In example implementations, an apparatus is provided. The apparatus includes a connection interface, a local area network (LAN) interface, a wide area network (WAN) interface, and a processor. The connection interface is to connect to a printed circuit board (PCB) of a door controller. The LAN interface is to communicate with a plurality of door sensors, wherein each one of the plurality door sensors is to monitor operation of a respective door of a plurality of doors. The WAN interface is to communicate with a remote server of a service provider. The processor is communicatively coupled to the connection interface, the LAN interface, and the WAN interface. The processor is to receive door data from the plurality of door sensors via the LAN interface, transmit the door data to the remote server for analysis via the WAN interface, receive a correction action from the remote server over the WAN interface in response to the door data, and execute the corrective action on a door of the plurality of doors via the LAN interface.

A passive ventilation control system and method. The system includes passive vents throughout a building. The vents may be arranged in multiple sets, with each set being substantially vertically aligned through multiple floors or the entire height of the building. Sensors are positioned inside and/or outside the building for sensing different environmental parameters or atmospheric conditions. The sensors send signals to a controller, which automatically adjusts airflow through the vents in response to the signals from the sensors.

A non-contact obstacle and gesture detection system and method are disclosed. The system includes first and second electronic control units in communication with one another and obstacle and gesture sensors coupled to the first electronic control unit. First and second power actuators are coupled to the first and second electronic control units for moving first and second closure members, respectively. The first electronic control unit detects the obstacle or gesture using the obstacle and gesture sensors, communicates the detection of the obstacle or gesture to the second electronic control unit, and controls movement of the first closure member using the first power actuator. The second electronic control unit is configured to request the detection of the obstacle or gesture adjacent the motor vehicle from the first electronic control unit and control movement of the second closure member using the second power actuator accordingly.

Embodiments include methods, systems and computer readable storage medium for a method for operating one or more doors of a vehicle is disclosed. The method includes receiving, by at least one radar sensor on the vehicle, input data related to one or more objects. The method further includes filtering, by the at least one radar sensor, vehicle environment noise from the received input. The method further includes identifying, by the at least one radar sensor, an external environment for the vehicle based on the filtered input. The method further includes operating, by a processor, one or more doors of the vehicle based on the external environment for the vehicle.