An exemplary system for covering an open bed of a trailer generally includes an armature movable between an open position and a closed position, a cover connected with the armature such that the bed is exposed when the armature is in the open position and is covered by the cover when the armature is in the closed position, an actuator operably connected with the armature, control circuitry operable to control the actuator to move the armature between the open position and the closed position. The control circuitry includes a wireless communication device, is configured to control the actuator to move the armature toward the open position in response to receiving an open command via the wireless communication device, and is configured to control the actuator to move the armature toward the closed position in response to receiving a close command via the wireless communication device.

An embodiment door control method for a vehicle, wherein the vehicle includes a switch for opening or closing a door of the vehicle, includes receiving a first close input of the door of the vehicle from the switch, determining whether a keep-open mode of the door is in an ON state or an OFF state, wherein the keep-open mode is determined based on a user input, and controlling opening or closing of the door based on the ON state or the OFF state of the keep-open mode.

An embodiment door control method for a vehicle, wherein the vehicle includes a switch for opening or closing a door of the vehicle, includes receiving a first close input of the door of the vehicle from the switch, determining whether a keep-open mode of the door is in an ON state or an OFF state, wherein the keep-open mode is determined based on a user input, and controlling opening or closing of the door based on the ON state or the OFF state of the keep-open mode.

A mechanism is disclosed for automating a sliding window having window components comprising a stationary pane component, a sliding pane component and a window frame component. The mechanism includes a telescoping mounting assembly attached to a first of the window components. The telescoping mounting assembly includes a housing and one or two extension arms, selectively extensible from the housing to either one or both sides of the first window component. A motor is disposed within the housing driving a first gear. Either one or two telescoping drive shafts are disposed within the extension arms, each having a gear on one end of the telescoping drive shaft driven by the first gear and having a gear on an opposite end of the telescoping drive shaft that engages a rack mounted on one side of a second of the window components. The telescoping drive shafts are coupled to the extension arms and are therefore selectively extensible with first extension arms. This mechanism is installed by extending the extension arm to fit the first of the window components. The sliding window is opened and closed by rotation of the motor and the telescoping drive.

A mechanism is disclosed for automating a sliding window having window components comprising a stationary pane component, a sliding pane component and a window frame component. The mechanism includes a telescoping mounting assembly attached to a first of the window components. The telescoping mounting assembly includes a housing and one or two extension arms, selectively extensible from the housing to either one or both sides of the first window component. A motor is disposed within the housing driving a first gear. Either one or two telescoping drive shafts are disposed within the extension arms, each having a gear on one end of the telescoping drive shaft driven by the first gear and having a gear on an opposite end of the telescoping drive shaft that engages a rack mounted on one side of a second of the window components. The telescoping drive shafts are coupled to the extension arms and are therefore selectively extensible with first extension arms. This mechanism is installed by extending the extension arm to fit the first of the window components. The sliding window is opened and closed by rotation of the motor and the telescoping drive.

In one aspect, an in-vehicle device is provided that includes a sensor configured to detect a vehicle characteristic indicative of the vehicle being in proximity to a location associated with a movable barrier operator. The in-vehicle device includes communication circuitry to communicate an open command to the movable barrier operator that causes the movable barrier operator to open a movable barrier connected to the movable barrier operator. A memory is configured to store a vehicle arrival condition indicative of whether the vehicle arrived at the location associated with the movable barrier operator. A processor is configured to determine satisfaction of the vehicle arrival condition and, upon the vehicle arrival condition not being satisfied, cause the communication circuitry to communicate a close command to the movable barrier operator that causes the movable barrier operator to close the movable barrier.

In one aspect, an in-vehicle device is provided that includes a sensor configured to detect a vehicle characteristic indicative of the vehicle being in proximity to a location associated with a movable barrier operator. The in-vehicle device includes communication circuitry to communicate an open command to the movable barrier operator that causes the movable barrier operator to open a movable barrier connected to the movable barrier operator. A memory is configured to store a vehicle arrival condition indicative of whether the vehicle arrived at the location associated with the movable barrier operator. A processor is configured to determine satisfaction of the vehicle arrival condition and, upon the vehicle arrival condition not being satisfied, cause the communication circuitry to communicate a close command to the movable barrier operator that causes the movable barrier operator to close the movable barrier.

A device for receiving signals via an electrically driveable or adjustable furniture element includes a receiving device for receiving at least one wirelessly transmitted signal, and the at least one wirelessly transmitted signal that has been received by the receiving device can be transmitted on to a furniture element. The receiving device is designed such that the at least one wirelessly transmitted signal can be received and processed via a first transmission protocol and a second transmission protocol, wherein the first transmission protocol is different from the second transmission protocol.

A device for receiving signals via an electrically driveable or adjustable furniture element includes a receiving device for receiving at least one wirelessly transmitted signal, and the at least one wirelessly transmitted signal that has been received by the receiving device can be transmitted on to a furniture element. The receiving device is designed such that the at least one wirelessly transmitted signal can be received and processed via a first transmission protocol and a second transmission protocol, wherein the first transmission protocol is different from the second transmission protocol.

In one aspect, a garage door opener system includes a battery configured to be charged by a power source, a controller coupled to the battery, the controller configured to operate a motor that is powered only by the battery, at least one sensor coupled to the motor and the controller, the at least one sensor generating sensor data, and a battery monitoring system coupled to the battery, the controller, and the least one sensor, the battery monitoring system configured to monitor a power consumption of the battery and a state of the battery, and to update an operation configuration of the controller based on historical power consumption of the battery, the state of the battery, and the sensor data.