A distributed sensor network that utilizes the cabling infrastructure installed for a Distributed Antenna System (DAS) to collect environmental data about a building. In this sensor network, an array of sensors are placed in line with the DAS communication cabling so that additional cabling is not required. The sensors use out of band frequencies or low level signaling so as to not interfere with the DAS signals to communicate the sensor data to the DAS head-unit.

Methods, systems, and apparatus, including computer programs encoded on a computer storage medium for communicating between an operational asset and a backend network that include the actions of receiving first data from an operational asset through a first communication interface that is configured to communicate with an operational asset, and where the first data is formatted according to a first data format that is specific to the operational asset. Processing the first data according to an asset template to generate second data, where the second data includes the first data and being formatted according to a second data format that is specific to the backend network. Causing the second data to be transmitted to the backend network by a second communication interface that is configured to communicate with a backend network.

The present invention is related with a modem device in conjunction with a Low Power Controller, which provides the capability of local control and remote management of electromechanical appliances in cases, where the locally available electric power is very low, and it is specially designed to be electrically powered and to communicate via a single PSTN telephone line The device has a wide application range to institutions, which own and use areas containing both passive and active equipment, and provides the capability of a single uniform solution for all such cases. It provides the ability to connect various digital and analog sensors, the transmission of various commands, the process automation, the data and information collection and the remote control (management).

A device and a non-transitory storage medium are described in which a collector device comprises a first wireless communication interface of a first wireless network configured to receive messages from and transmit messages to a meter interface unit of a utility meter; and a second wireless communication interface of a second wireless network configured to receive messages from and transmit messages to the meter interface unit, wherein the second wireless network is a third party wireless network and the first wireless network is not, and wherein the first wireless communication interface and the second wireless communication interface are configured to operate in a simultaneous mode of communication that provides for a simultaneous transmission to or simultaneous reception of messages from the meter interface unit.

A device and a non-transitory storage medium are described in which a collector device comprises a first wireless communication interface of a first wireless network configured to receive messages from and transmit messages to a meter interface unit of a utility meter; and a second wireless communication interface of a second wireless network configured to receive messages from and transmit messages to the meter interface unit, wherein the second wireless network is a third party wireless network and the first wireless network is not, and wherein the first wireless communication interface and the second wireless communication interface are configured to operate in a simultaneous mode of communication that provides for a simultaneous transmission to or simultaneous reception of messages from the meter interface unit.

A detection device coupled to an item includes a sensor configured to detect user interaction with the item and transmit a signal related to the user interaction and the item. A processor of the detection device receives the signal and determines a type of the user interaction and information about the item based on the signal. The detection device is configured to transmit a signal indicating the type of the user interaction and the information about the item. A server is configured to receive the signal (e.g., from the detection device or a HUB) and determine a user interaction profile associated with the item. The user interaction profile can indicate data about one or more users' interaction with the item or data about the item. The server is also configured to output data indicating the user interaction profile via a graphical user interface or store the data.

A method and system for flow tracing for use in a packet-optical network is disclosed herein. A device in the packet-optical network may receive a packet including a header and payload. The device may read intent information from the header, and translate the intent information to generate a device-specific action in an optical layer to provide one or more globally unique identifiers (IDs) associated with the device. The device may execute the device-specific action in the optical layer to generate a response including the globally unique IDs corresponding to the intent, where the response forms part of the flow trace. The device may associate the response with the intent, and encode the response for downstream data forwarding. The device may further add multi-layer proof-of-transit (POT) information to the response that may be used to securely verify the path indicated in the SmartFlow flow trace.

Methods, systems, and apparatus, including computer programs encoded on a computer storage medium for communicating between an operational asset and a backend network that include the actions of receiving first data from an operational asset through a first communication interface that is configured to communicate with an operational asset, and where the first data is formatted according to a first data format that is specific to the operational asset. Processing the first data according to an asset template to generate second data, where the second data includes the first data and being formatted according to a second data format that is specific to the backend network. Causing the second data to be transmitted to the backend network by a second communication interface that is configured to communicate with a backend network.

Methods, systems, and apparatus, including computer programs encoded on a computer storage medium for communicating between an operational asset and a backend network that include the actions of receiving first data from an operational asset through a first communication interface that is configured to communicate with an operational asset, and where the first data is formatted according to a first data format that is specific to the operational asset. Processing the first data according to an asset template to generate second data, where the second data includes the first data and being formatted according to a second data format that is specific to the backend network. Causing the second data to be transmitted to the backend network by a second communication interface that is configured to communicate with a backend network.

A method and system for packet-optical in-band telemetry (POINT) that may be used in a packet-optical network is disclosed herein. An intermediate POINT device may receive a packet including at least a header and a payload at a packet layer. The POINT device may read intent information from the header, and the intent information may indicate a type of telemetry data to be collected. The POINT device may translate the intent information from the packet layer to generate a device-specific action in an optical layer to the type of telemetry data indicated by the intent. The POINT device may execute the device-specific action in the optical layer to generate a response corresponding to the intent, associate the response with the intent, and encode the response in the packet layer for downstream data forwarding.