A system for identifying fatigue sources includes a processor and at least one computer program residing on the processor. The computer program is stored on a non-transitory computer readable medium having computer executable code embodied thereon. The computer executable code is configured to detect a fatigue level. The computer executable code is further configured to receive fatigue contribution data. In addition, the computer executable code is configured to identify a fatigue source based on the fatigue level and the fatigue contribution data.

A patient communication system having a medical sensing device operable to collect medical data, a network communication module operable to transmit the medical data onto a data network, a controller operable route the first medical sensing data to the network communication module, and a power source operable to provide power to the first medical sensing device, the controller, and the network communication module.

A patient communication system having a medical sensing device operable to collect medical data, a network communication module operable to transmit the medical data onto a data network, a controller operable route the first medical sensing data to the network communication module, and a power source operable to provide power to the first medical sensing device, the controller, and the network communication module.

In one example of smart appliance registration, a system comprises an electric device that is configured to transmit a unique identifier upon activation, a smart meter that is configured to receive the unique identifier and to further transmit the unique identifier, and a monitoring entity configured to receive the unique identifier from the smart meter for device-specific profiling.

A mobile terminal and controlling method thereof are disclosed. The present invention includes a touchscreen; a memory configured to store access point (AP) information; a 1.sup.st wireless communication unit configured to perform a communication with an AP (access point); and a controller configured to control a user interface for remotely controlling an external device to be displayed on the touchscreen or to be in a displayable state when the AP connected to the 1.sup.st wireless communication unit matches the stored AP information.

In response to a detected presence of an intended target appliance within a logical topography of controllable appliances identity information associated with the intended target appliance is used to automatically add to a graphical user interface of a controlling device an icon representative of the intended target appliance and to create at a Universal Control Engine a listing of communication methods for use in controlling corresponding functional operations of the intended target appliance. When the icon is later activated, the controlling device is placed into an operating state appropriate for controlling functional operations of the intended target appliance while the Universal Control Engine uses at least one of the communication methods to transmit at least one command to place the intended target appliance into a predetermined operating state.

A trainable transceiver is provided for a vehicle for transmitting signals to a device remote from the vehicle. The trainable transceiver includes an RF transceiver configured to receive an RF signal during a training mode in order to learn characteristics of the received RF signal, and to transmit an RF signal to the remote device in an operating mode where the transmitted RF signal includes the learned characteristics of the received RF signal; a local memory device for storing channel data representing the learned characteristics of the received RF signal; an interface configured to communicate with an Internet-connected device; and a controller coupled to the local memory device and the interface, the controller configured to retrieve the channel data from the local memory device and transfer the channel data for storage remote from the vehicle using the interface. The controller may also receive channel data from the remote memory device.

A trainable transceiver is provided for a vehicle for transmitting signals to a device remote from the vehicle. The trainable transceiver includes an RF transceiver configured to receive an RF signal during a training mode in order to learn characteristics of the received RF signal, and to transmit an RF signal to the remote device in an operating mode where the transmitted RF signal includes the learned characteristics of the received RF signal; a local memory device for storing channel data representing the learned characteristics of the received RF signal; an interface configured to communicate with an Internet-connected device; and a controller coupled to the local memory device and the interface, the controller configured to retrieve the channel data from the local memory device and transfer the channel data for storage remote from the vehicle using the interface. The controller may also receive channel data from the remote memory device.

The disclosed method uses a dongle to program a replacement key fob transmitter to a vehicle. The dongle mates to the vehicle's on-board electronics through the vehicle's existing data link. A diagnostic circuit in the dongle determines a communications protocol for programming the key fob transmitter to the vehicle. Audio and visual indicators indicate that communications are established and the successful programming of the key fob transmitter to the vehicle.

Disclosed are various embodiments of systems and methods related to measuring one or more ambient conditions within a confined environment. A telemetry monitoring system comprises a magnetic resonator disposed within a confined environment. The magnetic resonator may be passively energized by an interrogating antenna situated outside the confined environment. Resonant signal responses emitted from the magnetic resonator may be analyzed to determine one or more ambient conditions within the confined environment.