An internet-connected garage door control system is disclosed that includes a garage door opener for opening and closing a garage door in response to signals received through the internet, and an in-vehicle remote garage door opener integrated into a vehicle for transmitting the signals through the internet to the garage door opener. The in-vehicle remote garage door opener includes an interface configured to communicate with an internet-connected device, a trainable RF transceiver for transmitting an RF signal to the garage door opener, a user-actuated input, an interface configured to communicate with an internet-connected device, and a controller, wherein, upon actuation of the user-actuated input, the controller is configured to at least one of (a) request a signal to be transmitted by the internet-connected device through the internet to the garage door opener, and (b) cause the trainable RF transceiver to transmit the RF signal to the garage door opener.

A method of implementing use cases includes associating a use case with each of a plurality of devices capable of being used or accessed by a user. The method also includes providing a plurality of stackable blades, each providing a standard physical interface and being configured to implement a solution to the use case associated with each of the plurality of devices. The method further includes stacking the plurality of stackable blades to form an interconnected stack. Each of the plurality of stackable blades are coupled using the standard physical interface. The method also includes executing a first purpose corresponding to a first use case and executing a second purpose corresponding to a second use case. Embodiments provide an electronic ecosystem featuring ubiquitous connectivity in which a standard contact array in each component of the ecosystem assures interoperability between heterogeneous devices.

A device includes a device body having an attachment face defined by an attachment area and a contact array disposed in the device body and exposed at a coupling face. The contact array comprises one or more magnets disposed on the coupling face and a plurality of terminals disposed on the coupling face. A periphery of the one or more magnets and the plurality of terminals defines a coupling area. The attachment area is greater than and independent of the coupling area.

An internet-connected garage door control system is disclosed that includes a garage door opener for opening and closing a garage door in response to signals received through the internet, and an in-vehicle remote garage door opener integrated into a vehicle for transmitting the signals through the internet to the garage door opener. The in-vehicle remote garage door opener includes an interface configured to communicate with an internet-connected device, a trainable RF transceiver for transmitting an RF signal to the garage door opener, a user-actuated input, an interface configured to communicate with an internet-connected device, and a controller, wherein, upon actuation of the user-actuated input, the controller is configured to at least one of (a) request a signal to be transmitted by the internet-connected device through the internet to the garage door opener, and (b) cause the trainable RF transceiver to transmit the RF signal to the garage door opener.

A vehicle comprising a keyless go system, and at least one key fob, said keyless go system being operatively connected to a locking/unlocking subsystem and an engine start subsystem, said vehicle further comprising at least one LF transmitter, at least one LF receiver, at least one HF transmitter and at least one HF receiver, said vehicle further comprising an aftermarket keyless go system interfacing with said keyless go system, wherein at least one of said at least one key fob is embedded into said vehicle, and wherein when a user sends a lock/unlock command, or a start command with a portable device, said aftermarket keyless go system interacts with said embedded key fob to selectively enable and disable low frequency communication between said embedded key fob and said keyless go system.

A server may communicate with a mobile device and/or a reader device via an Internet connection. The server may be configured to generate a credential and transmit the credential to the mobile device. The mobile device may use the credential in an access control system, a payment system, a transit system, a vending system, or the like.

A device includes a device body having an attachment face defined by an attachment area and a contact array disposed in the device body and exposed at a coupling face. The contact array comprises one or more magnets disposed on the coupling face and a plurality of terminals disposed on the coupling face. A periphery of the one or more magnets and the plurality of terminals defines a coupling area. The attachment area is greater than and independent of the coupling area.

A vehicle comprising a keyless go system, and at least one key fob, said keyless go system being operatively connected to a locking/unlocking subsystem and an engine start subsystem, said vehicle further comprising at least one LF transmitter, at least one LF receiver, at least one HF transmitter and at least one HF receiver, said vehicle further comprising an aftermarket keyless go system interfacing with said keyless go system, wherein at least one of said at least one key fob is embedded into said vehicle, and wherein when a user sends a lock/unlock command, or a start command with a portable device, said aftermarket keyless go system interacts with said embedded key fob to selectively enable and disable low frequency communication between said embedded key fob and said keyless go system.

Exemplary hand-held sprayer systems are shown and described herein. An exemplary hand-held sprayer system includes a container for holding fluid. The container has a neck. A closure connects to the neck. A fluid conduit extends from the closure to a dispensing wand. The dispensing wand is configured to be held in a hand and to be moved about while dispensing fluid. A data tag is secured to the container. The dispensing wand has a trigger, a data tag reader, a pump, a motor, a power source, a processor and memory. The hand-held sprayer also includes logic for causing the processor to determine whether a data read from the data tag meets a criteria for allowing the dispensing of fluid from the container. If the data read from the data tag meets the criteria, fluid is dispensed from the container when the trigger is activated.