A lock that includes a motor driven pin, a first motor connected to the motor driven pin, and a body housing the first motor and the motor driven pin. The motor driven pin is moveable from an open position where it is inside the body to a closed position where it is at least partially outside the body. The body includes a hook member. When the motor driven pin is in the closed position, the hook member and the motor driven pin create a closed loop.

A method includes determining, by a field instrument in an industrial process and control system, a Highway Addressable Remote Transducer (HART) mode of the field instrument. The method also includes, upon a determination, by the field instrument, that the HART mode is a HART On Demand mode, listening for a HART data signal from a HART master device; when the HART data signal is detected, communicating with the HART master device according to a HART protocol; and when the HART data signal is not detected, diverting a current supply allocated for HART communication to a BLUETOOTH Low Energy (BLE) transceiver for use in BLE communication, and communicating according to a BLE protocol.

Methods, apparatus, and articles of manufacture are disclosed to control communication data rates of low-energy devices. An example apparatus includes a Bluetooth Low Energy (BLE) radio, and a power manager to determine whether to divide a first computation task into at least a second and a third computation task based on (1) energy stored in a power supply associated with the BLE radio and (2) a charging rate of the power supply, and when the first computation task is to be executed by the BLE radio and the first computation task is divided based on the determination, instruct the BLE radio to enter a sleep mode after the second computation task is executed, and invoke the BLE radio to transition from the sleep mode to an operating mode to execute the third computation task, the invoking in response to a measurement associated with the power supply satisfying an energy threshold.

Apparatus for automation technology, comprising: a housing, a radio antenna externally mounted on the housing, a communication electronics arranged within the housing and data conductively connected with the antenna and adapted to communicate data, preferably process data, bidirectionally according to a first radio standard wirelessly via the antenna to and from a superordinated unit, which communication electronics is, furthermore, adapted to communicate data, preferably parameter data, bidirectionally according to a second radio standard wirelessly via the antenna to and from a service unit.

Methods, apparatus, and articles of manufacture are disclosed. An example apparatus includes a field device including a network bridge, the network bridge to convert first data received at a first Bluetooth Low Energy (BLE) radio of the network bridge, over a BLE network, from a second BLE radio of a remote device, and formatted according to a BLE communication protocol, into second data formatted according to an industrial communication protocol.

An apparatus includes a BLUETOOTH low energy (BLE) based emergency backup and recovery tool. The tool includes a backup power source that stores electric energy and outputs electric energy when a main power source is off. The tool includes a shared memory accessible by a processor and a BLE module. The shared memory stores information written by the processor, and operates using at least some of the electric energy output from the backup power source when the main power source is off. The tool includes the BLE module coupled to the backup power source. The BLE module operates using at least some of the electric energy output from the backup power source when the main power source is off, reads the information stored in the shared memory, and transmits the information to an external device through a wireless communication channel using a BLUETOOTH communication protocol.

Implementations are described herein for provisioning a device such as a DCN with configuration data for operation on a process automation network using an out-of-band communication channel. In various implementations, a temporary out-of-band communication channel may be established between a first and second DCNs. The out-of-band communication channel may be distinct from a process automation network through which the first DCN is to be communicatively coupled with other process automation nodes of a process automation system. Provisioning data may be transmitted from the second DCN to the first DCN over the temporary out-of-band communication channel. The provisioning data may include: information technology (IT) configuration data and operational technology (OT) configuration data. Subsequent to the transmitting, the temporary out-of-band communication channel may be closed.

A destination call, as an example of an action, is automatically generated in an elevator system when detected current connection data correspond to a stored behavior pattern for the usage of the elevator system. A communicative link between a sensor in a sensor system that comprises a multitude of sensors and the mobile electronic device of a passenger is detected, and connection data about the communicative link are recorded. The connection data are compared with data stored in a memory device containing at least one behavior pattern in order to determine whether the connection data correspond to a stored behavior pattern.

A method for connecting a field device (1) to an operating unit (2), and a field device (1) for use therewith, via which a connection between a field device and an operating unit can be implemented when the field device is mounted at a location that is difficult to access is achieved in that a query signal is transmitted to the field device (1) by the operating unit (2) and that a response signal is generated by the field device (1) as a reaction to the query signal, in that the field device (1) generates a blinking display and/or a change in color of the display and/or an acoustic signal and/or a change in an acoustic signal.

A method includes communicating using a BLUETOOTH Low Energy (BLE) communication link with a plurality of field instruments in an industrial process and control system. The method also includes receiving operating parameters from each of the field instruments. The method further includes displaying an identifier of each field instrument and at least one operating parameter from each field instrument on a single screen or window of a wireless mobile device. The method also includes receiving a user input associated one or more operating parameters. In addition, the method includes transmitting data to or receiving information from a first field instrument based on the user input. In some embodiments, the method can also include receiving one or more voice or gesture commands related to operation of the field instruments, translating the voice or gesture commands to command data, and sending the command data to the field instruments.