A system for making sure that two wireless devices (a perimeter-anchoring device and a constrained device) are not separated too far apart by having a dynamic perimeter that follows the perimeter-anchoring device as it moves. In some embodiments, the size and/or shape of the perimeter is controlled by machine logic based rules, based at least in part, upon a set of environmental factor(s). Some possible environmental factors include: line of sight, pollution, noise level, presence of stranger(s), streets, traffic, body(ies) of water, contamination, allergen, or blocking obstruction(s).

In some implementations, a first computing device can send notifications at times that the first computing device is not in an expected location. A user of a second computing device can remotely configure an expected location for the first computing device, which may be a particular location for a certain period of time. During that time, the first computing device can monitor its own location and check whether it is within the expected location. If the first computing device unexpectedly leaves or fails to enter the expected location, the first computing device may transmit a notification to the second computing device. Similarly, if the first computing device loses connectivity with other devices, a server device may notify the second computing device that the location of the first computing device cannot be determined.

A vehicular child monitoring system includes a child monitoring device having a connector for securing the device within a motor vehicle and oriented toward a child seat. The device includes a mirror, a seat connector, a camera, and a control system having a wireless communication unit and a plurality of sensors. The sensors include a temperature sensor, a humidity sensor, a proximity sensor, and a child detection sensor. A child monitoring application is communicatively linked to the communication unit and includes functionality for displaying the information received from the camera and each of the sensors, and for determining a separation distance with the child monitoring device. The system including functionality for determining that a child is in the car seat and sending an alarm to an external device if the vehicle temperature is above a set threshold.

Methods and systems are described for tracking location using a home automation system. One method includes receiving sensor data indicating presence of a wearable tracking device in a predetermined area of a property monitored by the home automation system, confirming an identity of the tracking device, and generating a notice indicating a location of the tracking device.

In a lost child search system including a parent terminal and a child terminal, the child terminal is provided with: a gyro sensor that measures the angular velocity for identifying the posture of that child terminal; an acceleration sensor that measures the acceleration of that child terminal; a positioning control unit that performs relative positioning of that child terminal based on the identified posture and the measured acceleration; a communication unit that performs data communication via near-field wireless communication using radio waves; an intensity detection unit that detects the radio wave intensity in the near-field wireless communication with the parent terminal; and an intensity decision unit that decides whether or not search for the child terminal is necessary in accordance with the detected intensity information. The acceleration sensor is made to start measuring the acceleration in accordance with the decision result (decision information) by the intensity decision unit.

Disclosed herein is a method for facilitating supervision of individuals based on geofencing. Accordingly, the method may include receiving, using a communication device, a parameter from a supervisor device associated with a supervisor and a geographical location from the supervisor device. Further, the method may include analyzing, using a processing device, the geographical location based on a security parameter and generating a geofence corresponding to a geographical area based on the analyzing. Further, the method may include receiving, using the communication device, supervisee data associated with a supervisee from a supervisee device, including supervisee emergency input or nearby audio and video sensor data. Further, the method may include analyzing, using the processing device, the supervisee data based on the geofence and generating a supervision notification based on the analyzing of the supervisee data. Further, the method may include transmitting, using the communication device, the supervision notification to the supervisor device.

An electronic patient monitoring system and method of operation that includes one or more generally non-metal, tamper-resistant patient identification and monitoring devices, an observer transmitter/receiver device configured to receive and detect one or more beacon signals that exceed a predetermined threshold from at least one of the not easily removable patient identification and monitoring devices, set a time to hold open a window for a response on the transmitter/receiver device, and send a request for information to the observer with the transmitter/receiver device, and a central computer system. Each of the transmitter/receiver device and the central computer system, including, at least, a computer processor, communications components and system software to communicate with the observer transmitter/receiver device at specified/predetermined time intervals to receive observer- and patient-specific information.

Techniques are described for processing sensor data associated with product dispensers at an establishment. The system is configured to monitor the location of product dispensers at an establishment and the system detects an alarm event related to the monitoring system based on the monitoring.

A system for making sure that two wireless devices (a perimeter-anchoring device and a constrained device) are not separated too far apart by having a dynamic perimeter that follows the perimeter-anchoring device as it moves. In some embodiments, the size and/or shape of the perimeter is controlled by machine logic based rules, based at least in part, upon a set of environmental factor(s). Some possible environmental factors include: line of sight, pollution, noise level, presence of stranger(s), streets, traffic, body(ies) of water, contamination, allergen, or blocking obstruction(s).

Techniques are described for distributing, to a distributed network of central stations, alarm events detected in monitoring system data collected by sensors included in monitoring systems located at monitored properties. A system receives monitoring system data collected by sensors included in monitoring systems located at monitored properties, tracks alarm events detected within the monitoring system data, and generates, for central station servers in a distributed network of central stations, load profiles that reflect a volume of alarm events being handled at each of the central station servers at a particular period of time. The system determines capacities to handle additional alarm events for the central station servers, determines relative priorities for the central station remote servers based on the determined capacities, and directs subsequent alarm events to the central station servers based on the relative priorities.