In one embodiment, a label stability analyzer service receives classification data indicative of device type labels assigned to endpoints in a network by a device classification service. The label stability analyzer service counts device type label changes made by the device classification service to the endpoints. The label stability analyzer service computes variability metrics for the device type labels, wherein the variability metric for a device type label is based on a count of the device type label changes associated with that label. The label stability analyzer service determines, based on one of the variability metrics for a particular one of the device type labels exceeding a threshold value, a configuration change for the device classification service that adjusts how the device classification service applies the particular label to endpoints. The label stability analyzer service provides the configuration change to the device classification service.

A method for mapping underground sensors onto a network map may include obtaining a plurality of magnetic measurements from a plurality of sensors. The method may include using the plurality of magnetic measurements for determining a plurality of sensor locations in an initial network map. The method may include generating updated network maps from the perspective of each localized sensor. The method may include merging the updated network maps into a final network map, the final network map comprising a most accurate location for each sensor. The method may include determining inner localized sensors out of the plurality of sensors in the final network map. The method may include identifying the inner localized sensors as new base station anchors. The method may include mapping the inner localized sensors onto the final network map as new base station anchors.

A device, method and system for assigning alerts to sensor analytics engines is provided. A device one or more of generates and receives an alert to perform a search for a target object. The device determines a geographic area in which to perform the search for the target object. The device determines sensors available in the geographic area for use in the search for the target object. The device, in response to the sensors meeting a threshold condition, assigns the alert to a sensor analytics engine to search for the target object using the sensors. The device, in response to the sensors not meeting the threshold condition, provides the alert to one or more communication devices to initiate a human-based search for the target object.

Embodiments disclosed herein generally relate to line-powered wireless communications systems, and more specifically to methods and apparatus for providing persistent and ubiquitous wireless communications and sensor networks in physical premises to enable a wide variety of different applications and use cases.

The present invention relates to an intelligent rodent management system which provide efficient, reliable, and effective system which traps the rodents or animals and manages disposal process from a remote location. The intelligent rodent management system is water resistant, which can effectively catch water borne rodents as well. The bait is placed on top part of the main body and the bait station is closed with a bait cap, the smell of the bait lures the animals from the entrance of the main body. The animals enter through the main body of the device wherein the door is operated through spring loaded mechanism. The intelligent rodent management system of present invention provides a collecting, communicating and analyzing system for received information about entry of animals and the data is stored on a cloud server through electronics hardware which consist of a modem and a processor.

The present invention relates to an intelligent rodent management system which provide efficient, reliable, and effective system which traps the rodents or animals and manages disposal process from a remote location. The intelligent rodent management system is water resistant, which can effectively catch water borne rodents as well. The bait is placed on top part of the main body and the bait station is closed with a bait cap, the smell of the bait lures the animals from the entrance of the main body. The animals enter through the main body of the device wherein the door is operated through spring loaded mechanism. The intelligent rodent management system of present invention provides a collecting, communicating and analyzing system for received information about entry of animals and the data is stored on a cloud server through electronics hardware which consist of a modem and a processor.

A smart ring includes a battery, memory, processing circuitry, a plurality of sensors, a plurality of antennas, and a battery, each coupled to one another and all enclosed in a casing, wherein the processing circuitry is configured to conserve the battery by any of sending data to the cloud service when an application is open on the user device, sending data to the cloud service when a threshold is crossed, waking up processing or communicating when there is a change in motion detected by the accelerometer.

A smart ring includes a battery, memory, processing circuitry, a plurality of sensors, a plurality of antennas, and a battery, each coupled to one another and all enclosed in a casing, wherein the processing circuitry is configured to conserve the battery by any of sending data to the cloud service when an application is open on the user device, sending data to the cloud service when a threshold is crossed, waking up processing or communicating when there is a change in motion detected by the accelerometer.

A sensor node system for mapping hydraulic fractures may include a localization system that identifies location information of the sensor node device with respect to an area of interest in a rock formation. The location information may include various magnetization parameters indicative of various signal strengths surrounding the sensor node device. The sensor node device may include a transceiver that exchanges signals with a base station and at least one other sensor node device. The transceiver establishes a communication link between the base station and the sensor node device. The transceiver may monitor at least one other communication link between the at least one other sensor node device and the base station. The sensor node device may include a processor that identifies distance information based on the location information and a predetermined number of signals associated to the various signal strengths surrounding the sensor node device.

A method for managing restoration assets, a restoration sensor, a system, and a controller for use in a mitigation environment are provided. An illustrative method may include receiving first sensor data describing an environmental condition in proximity to a first restoration asset, receiving second sensor data describing an environmental condition in proximity to a second restoration asset, comparing the first sensor data with the second sensor data, and determining a drying condition for a building in which the first restoration asset and the second restoration asset are provided based on the comparison of the first sensor data with the second sensor data.