Monitoring a premises may comprise receiving signals from a plurality of devices. One or more spatially static devices of the plurality of devices may be determined based on strengths of the received signals. A user activity pattern may be determined based on changes in strengths of signals received from the spatially static devices. Abnormal user activity may be determined based on the user activity pattern and a strength of at least one signal received from at least one of the spatially static devices.

A detection system for measuring one or more conditions within a predetermined area includes at least one fiber optic cable for transmitting light to and receiving scattered light from one or more nodes and a cover plate having an internal cavity. The cover plate surrounds the one or more nodes such that the one or more nodes are in communication with the internal cavity. A control system is operably coupled to the at least one fiber optic cable so that the scattered light received by the one or more nodes is transmitted to the control system. The control system analyzes the scattered light to evaluate a condition at the one or more nodes.

A detection system for measuring one or more conditions within a predetermined area includes at least one fiber optic cable for transmitting light to and receiving scattered light from one or more nodes and a cover plate having an internal cavity. The cover plate surrounds the one or more nodes such that the one or more nodes are in communication with the internal cavity. A control system is operably coupled to the at least one fiber optic cable so that the scattered light received by the one or more nodes is transmitted to the control system. The control system analyzes the scattered light to evaluate a condition at the one or more nodes.

A home occupant detection and monitoring system has a sensor unit having a radio wave transmitter, a radio wave receiver, and a wireless transmitter configured to detect and receive vital signs of an occupant; a user interface having a microcontroller, a wireless receiver configured to receive the wireless signals transmitted from the sensor unit, a means for user input, and a network card; and a means for alerting occupants and third-parties to a triggering event; wherein the microcontroller, based upon logic, activates the alerting means at the triggering event.

A home occupant detection and monitoring system has a sensor unit having a radio wave transmitter, a radio wave receiver, and a wireless transmitter configured to detect and receive vital signs of an occupant; a user interface having a microcontroller, a wireless receiver configured to receive the wireless signals transmitted from the sensor unit, a means for user input, and a network card; and a means for alerting occupants and third-parties to a triggering event; wherein the microcontroller, based upon logic, activates the alerting means at the triggering event.

Electronic processing systems and methods for collaborating between vehicular threat detection appliances. One system includes a memory, a transceiver, an electronic processor, and a first vehicular 360-degree threat detection appliance that is physically coupled to a first vehicle. The electronic processor is configured to identify a portion of the first vehicular 360-degree threat detection appliance having an obstructed field-of-view. The electronic processor is also configured to detect a second vehicular 360-degree threat detection appliance that is physically coupled to a second vehicle and has an unobstructed field-of-view of the obstructed field-of-view. The electronic processor is further configured to transmit a request to the second vehicular 360-degree threat detection appliance to provide threat detection coverage for the first vehicle in a direction of the obstructed field-of-view. The electronic processor is also configured to temporarily disable the portion of the first vehicular 360-degree threat detection appliance that has the obstructed field-of-view.

Disclosed are systems comprising: a transmitter background; a receiver background; a plurality of transmitter units affixed on the transmitter background, each transmitting an encoded electromagnetic wave (EM), wherein the electromagnetic wave is transmitted as a wide beam; and a plurality of receiver units affixed on the receiver background, wherein each of the plurality of the transmitter units is in electromagnetic communication with at least one of the receiver units. Also disclosed are methods of identifying the presence of an object intersecting a spatial surface, the methods comprising: transmitting a plurality of coded wide beams, optionally non-simultaneously, using a plurality of transmitter units, each wide beam transmitted by a transmitter unit; receiving the plurality of the coded wide beams by a plurality of receiver units, each receiver unit receiving two or more of the plurality of the coded wide beams; determining if at least one receiver unit did not receive at least one coded wide beam; and sending a code identifying that an object is intersecting a spatial surface. Further, a housing for the system is disclosed.

Systems and methods for detecting a presence of a target such as a vehicle, an animal, a person, or another object in a monitored area without the use of sensors, are provided. Multiple RF field anomaly detection nodes may be spaced through the monitored area and connected, such as in a mesh network. The RF field anomaly detection nodes may include radio transceivers that communicate with one another and which monitor a signal strength of received signals. The nodes may compare the signal strengths to expected strength values. As a target enters a portion of the monitored area, the dielectric properties of the target cause at least one signal strength of at least one received signal to change. The RF field anomaly detection nodes may detect this change and trigger a further action or human readable alert corresponding to the presence of the target.

Methods, apparatus and systems for power supply design of a wireless monitoring system or device are described. In one example, an accessory of a wireless monitoring system is described. The accessory comprises at least one physical attachment feature attaching the accessory to at least one of: a first wireless device in the wireless monitoring system or a second wireless device in the wireless monitoring system. The first wireless device is configured for transmitting a first wireless signal through a wireless multipath channel of a venue. The second wireless device is configured for receiving a second wireless signal through the wireless multipath channel. The second wireless signal differs from the first wireless signal due to the wireless multipath channel that is impacted by a motion of an object in the venue. The wireless monitoring system comprises a processor configured for: obtaining a time series of channel information (TSCI) of the wireless multipath channel based on the second wireless signal, and monitoring the motion of the object in the venue based on the TSCI.

In a detecting device, infrared light is emitted by a first source in a detection target space; second light of a wavelength different from the infrared light is emitted by a second source in a direction different from a direction of the infrared light being emitted by the first source. A reflecting section provided in the direction of the second light being emitted reflects the second light. A light receiver receives infrared light emitted by the first source and reflected by the object, and receives infrared light radiating from the object as a result of the object being irradiated with the infrared light emitted by the first source and being irradiated with the second light emitted by the second source and reflected by the reflecting section. A detector detects the object based on the infrared light received by the light receiver.