Systems, methods, and apparatus for managing and controlling network-enabled movable barrier operators is provided. A method for managing network-enabled movable barrier operator includes receiving a user account identifier and a movable barrier operator identifier from a user device, providing an instruction to perform a specified action with a movable barrier operator associated with the movable barrier operator identifier to the user device, determining a registration condition is met upon detecting that the specified action has been performed, and, upon the registration condition being met, associating the movable barrier operator identifier with the user account identifier to allow a user account associated with the user account identifier to control the movable barrier operator over a network.

A secure cabinet that can secure and distribute products. The cabinet can have a user interface that receives information about a user and the user's identity can then be authenticated. The cabinet can accept a user's request to dispense a product and, if the user is approved, the cabinet can dispense a quantity of product to the approved user.

The disclosed computer-implemented method may include receiving sensor data associated with a mobile device associated with a vehicle, wherein the sensor data includes at least one of an angular velocity vector, a linear acceleration vector, and a rotational acceleration vector recorded over a period of time, determining an event signature based on the sensor data, and detecting a door closing event associated with the vehicle based at least in part on the event signature. Other methods, systems, and computer-readable media are disclosed.

A system for enabling both the remote monitoring and receipt of remote change-of-door status commands, via the Internet, of the open or closed status of the garage door. The system includes an encoder generating signal pulses as a function of the motor and garage door movement. A microprocessor processes the signal pulses to generate digital pulses indicative of the open or closed status of the garage door, which status is wirelessly transmitted, via the Internet, for remote monitoring. Change-of-door status commands remotely transmitted, via the Internet, are received by the system to activate a warning and delayed change of door status.

Monitoring systems for automatic doors comprise at least one input device configured for sensing at least one characteristic of at least one operational parameter of an automatic door system, a door system controller coupled to the at least one input device, at least one monitor display comprising a first interface operatively coupled to the door system controller, and at least another interface operatively coupled to the at least one monitor display and configured to be operatively coupled to at least one remote display device. The at least one monitor display is configured to continuously request information representative of the at least one operational parameter characteristic from the door system controller and display the information. Methods of monitoring an automatic door system comprise transmitting data representative of an operational parameter characteristic from an input device to at least one door system controller; sending a description of the operational parameter to a monitor display continuously; and displaying indicia representative of the description of the operational parameter.

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.

A garage door security system includes a camera configured to capture images of vehicles that are in proximity of a garage door of a garage. A database stores identification information for a plurality of vehicles. The identification information includes at least one of make, model, color, license plate number. An image and data analytic controller analyzes the images of vehicles captured by the camera using the identification information for the plurality of vehicles stored in the local database in order to identify vehicles authorized to enter the garage. A motor control opens the garage door for vehicles authorized to enter the garage.

A universal smart key (USK) provides advanced proximity, location, distance or ranging capabilities and communicates with vehicles and smart phones to perform a set of vehicle-related operations and replicates OEM key and may include one or more of Bluetooth, BLE, UWB, NFC and other communications capabilities for determining location, proximity, range, distance of a user possessing the USK relative to vehicle location.

A mobile (key) fob bridge (MFB) connected with vehicle communications/immobilizer control system and provides proximity, location, distance or ranging capabilities and communicates with vehicle and smart phones to perform a set of operations and may be located within a vehicle and communicate with smart key to provide a passive keyless entry system. The MFB may include Bluetooth, BLE, UWB, NFC and other communications capabilities for determining one or more of location, proximity, range, distance of a user possessing a smart key relative to the MFB device and one or more vehicle location(s).

A control module for a remote device comprises a trainable transmitter configured to communicate a radio frequency signal configured to control the remote device via a first communication protocol. The control module further comprises a communication circuit configured to communicate with a mobile device via a second communication protocol and a user interface comprising at least one user input. The control module comprises a controller configured to communicate the programming information for the remote device with the remote server via the second communication interface and assign the programming information to the at least one user input. The controller is further configured to control the trainable transmitter to output a control signal based on the programming information in response to the at least one user input. The control signal is configured to control the remote device.

A cabinet that can control the distribution of products that can optionally include medications. The cabinet can have a user interface that receives information about a user and the user's identity can then be authenticated. The cabinet can accept a user's request to dispense a product and, if the user is approved, the cabinet can dispense a quantity of product to the approved user.