An apparatus of controlling a safety power window of a vehicle and a method thereof to not injure the body caught in a window frame, as well as to prevent a malfunction of the safety power window, by adaptively setting an operation reference value of the safety power window, may include a learning device that deep-learns a model which predicts an operation reference value of the safety power window provided in the vehicle, based on driving information of the vehicle, a sensor that collects the driving information of the vehicle, and a controller that obtains the operation reference value of the safety power window corresponding to current driving information of the vehicle by use of the model on which the deep learning is completed, and controls the safety power window according to the operation reference value of the safety power window.

An opening-closing member controller includes a control unit that executes an initialization process to store at least a fully closed position of an opening-closing member. In the initialization process, the control unit closes the opening-closing member, executes entrapment reversing control one or more times when entrapment is detected to open the opening-closing member, and closes the opening-closing member after the entrapment reversing control to store a position where the opening-closing member locks as the fully closed position.

A vehicle control device that includes a memory and a processor coupled to the memory, and that controls driving of a vehicle door. The processor being configured to determine multiple times whether or not a communication terminal communicable with the vehicle control device is in a cabin-external region, which is a predetermined region external to a cabin of the vehicle, in a case in which a door switch of the vehicle door has been operated. The processor being configured to perform control to drive the vehicle door in accordance with the operation of the door switch in a case in which it has been determined at least one time or more, based on determination results, that the communication terminal is in the cabin-external region.

In one aspect, a remote server computer is provided for facilitating operation of movable barrier operator systems having imminent motion notification apparatuses. The remote server computer includes a processor, a memory, and a network interface for communicating state change commands to the movable barrier operator systems via a network. The remote server computer is configured to receive a confirmation indicating that a sensor check has been performed to test sensors of those systems. Upon receiving a state change request from a remote control associated with a movable barrier operator system, the processor may determine whether the confirmation has been received for that system, and if so, causes communication of an attended command signal that inhibits operation of an imminent motion notification apparatus of the movable barrier operator system. Otherwise, the remote server computer may communicate an unattended command signal.

A door system includes a controller for controlling the door system. A user computer system transmits information to the controller over a wireless connection to modify operating parameters for controlling the operation of the door system. During installation of the door system sensors may be utilized to determine if the door system has been installed properly. The sensors may be used to identify if the door system is mounted level and plum, and to review the movement, vibration, speed, acceleration, force, or the like of the sensors, and thus, the components to which the sensors are operatively coupled in order to make adjustments to the door assembly. Furthermore, the operating parameters of the installed door system, may be cloned and provided to other door systems in order to quickly clone and distribute the operating parameters of one or more door systems to one or more other door systems.

The present invention concerns a motorized door for closing an area (3) at least partially defined by a frame, said Motorized door comprising: (A) a motorized driving mechanism (10) for moving a shutter between an open position (z=1) and a closed position (z=0) in a first direction (α) to close said area defined within said frame and in a second direction (β) to open said area; (B) a detection cell (5, 6) suitable for detecting an accidental event (eI), during the motion of the shutter. The motorized door further comprises a processing unit programmed to trigger a wind related safety function avoiding the yo-yo effect in case strong winds triggered the erroneous detection of an accidental event by the detection cell, said wind related safety function comprising the following steps: (C) a processing unit (CPU): (a) stop the movement of the shutter in the first direction (α), and reverse said movement into the second direction (β) and, after a brief reverse time, Δt, of the order of 0.8 to 3.0 s, (b) stop said movement in the second direction (β) and reverse the movement back into the first direction (α) towards the closed position (z=0) of the shutter.

A sectional door operator system (1) for opening and closing an opening (2) is provided herein. The sectional door operator system (1) comprises a door (8) arranged to be moved between an open (O) and closed (C) position and comprising a plurality of horizontal and interconnected sections (9a-e), and a door frame (3) comprising a first frame section (4) at a first side (5) of the opening (2) and a second frame section (6) at a second side (7) of the opening (2), wherein the plurality of horizontal and interconnected sections (9a-e) are connected to the door frame (3). The sectional door operator system (1) further comprises a drive unit system (100) mounted on a section (9e) of the plurality of horizontal and interconnected sections (9a-e), wherein the drive unit system (100) is arranged to move the sectional door (8) from the closed position (C) to the open position (O), wherein the drive unit system (100) comprises at least a first drive unit (10a) comprising a first motor (11a) and at least a second drive unit (10b) comprising a second motor (11b), and wherein the first drive unit (10a) and the second drive unit (10b) are mounted at different vertical sides of the horizontal and interconnected section (9e). Further, the sectional door operator system (1) comprises at least one sensor device (40a, 40b) mounted on a section (9e) of the plurality of horizontal and interconnected sections (9a-e), and at least one control unit (20a, 20b) being in operative communication with the drive unit system (100) and configured to control the operation of the drive unit system (100) at least based on sensor data (42) from the at least one sensor device (40a, 40b), wherein the sensor data (42) relates to an angle (φ) of the door (8) in relation to a true horizontal plane of the sectional door operator system (1).

A barrier operator includes a motor, a controller operably connected to the motor, a sensor, and a control module. The motor is couplable to a drive mechanism of a barrier and is configured to move the barrier between open and closed positions. The sensor is configured to monitor an operating parameter of the barrier operator associated with movement of the barrier. The control module includes user input controls. The controller is configured to receive a first user input from the control module; initiate, in response to receipt of the first user input, operation of the motor for a first movement of the barrier to establish a first travel limit of the barrier; receive a first signal indicative of the operating parameter from the sensor; and generate, during the first movement of the barrier, a first force limit based on the first signal from the sensor.

An opening-closing member control device includes a motor that opens and closes an opening-closing member of a vehicle, and a control unit configured to stop the motor when determining that a foreign object has been entrapped by the opening-closing member and reverse the motor when a delay time elapses after stopping the motor. When the control unit determines that entrapment has occurred upon operation of a remote operation switch that is separated from the vehicle, the control unit reverses the motor after the delay time that is shorter than when determining that entrapment has occurred upon operation of a vehicle operation switch that is arranged in the vehicle.

A method for operating a door system, with the door system having a door leaf and with a first sensor unit being configured on a first door side and a second sensor unit on an opposing second door side, and with the approach of a person being detected with the first sensor unit, with the method having at least the following steps: determining a probable approach time of the person after which the person passes through the door system after being first detected; opening the door leaf; storing the approach time; recording an exit time of the person from the second door side using the second sensor unit and holding open the door leaf for an opening period which is determined from the recorded exit time or the approach speed, depending on which time is longer. A door system having a control unit is configured to carry out this method.