A multiband sensing system includes an active multiband sensing unit configured to transmit a radio frequency (RF) signal in multiple bands and communicate with a network. The active multiband sensing unit includes at least one transmitting antenna configured to transmit the RF signal. The multiband sensing system includes a passive multiband sensing unit including at least one receiving antenna configured to receive the RF signal, an acoustic actuator powered by the received RF signal including an actuating sensor element configured to actuate in response to receiving extracted modulated information of the RF signal, and an acoustic detector. The acoustic detector includes a detector transmitting antenna configured to backscatter a new frequency band signal to the active multiband sensing unit and a detector sensor element configured to sense data. The sensed data is modulated over the received RF signal to produce the new frequency band signal.

According to one example aspect of the present invention, provided is a radio wave communication device having a dipole type transmission antenna used for performing over-the-horizon communication using tropospheric scattering or diffraction; and a signal processing unit that performs digital signal processing on a signal and outputs the signal to the transmission antenna.

A communication system and method is described, comprising of two or more locations in which an artificially modulated ionized region is created at one or more locations and either passively or actively remotely sensed from another distant location, to create a communication exchange between locations which may lie over-the-horizon from one another. The height of the artificially modulated ionized region may be adjusted in altitude, to optimize the communications link for either maximum distance, or low latency. The system and method may use radio frequencies ranging from 400-2400 MHz, at power levels ranging from 1-10 MW to remain above a threshold where the negative effects of atmospheric ducting may occur, but also low enough to avoid the negative effects of rain fading at higher frequencies. This frequency range may be optimal for reliable use in adverse weather conditions and able to produce data rates that are commercially viable.

A communication system and method is described, comprising of two or more locations in which an artificially modulated ionized region is created at one or more locations and either passively or actively remotely sensed from another distant location, to create a communication exchange between locations which may lie over-the-horizon from one another. The height of the artificially modulated ionized region may be adjusted in altitude, to optimize the communications link for either maximum distance, or low latency. The system and method may use radio frequencies ranging from 400-2400 MHz, at power levels ranging from 1-10 MW to remain above a threshold where the negative effects of atmospheric ducting may occur, but also low enough to avoid the negative effects of rain fading at higher frequencies. This frequency range may be optimal for reliable use in adverse weather conditions and able to produce data rates that are commercially viable.

Disclosed is a first portable electronic device for facilitating a proximity based interaction with a second portable electronic device based on a plurality of gestures. The first portable electronic device includes at least one first sensor device configured to generate at least one of a first sensor data, a second sensor data, and a third sensor data, a first transceiver configured for communicating with a second transceiver associated with the second portable electronic device, and a first processor configured for detecting a pre-tap gesture based on the first sensor data, entering the first portable electronic device in an interaction mode based on the detecting of the pre-tap gesture, detecting a proximity based event based on the second sensor data, performing a predetermined action, detecting a post-tap gesture, determining if the post-tap gesture is detected within a predetermined time period, and performing one of an acceptance and a rejection of the predetermined action based on the determining

Disclosed herein is a portable electronic device for facilitating a proximity based interaction with a short range communication enabled object. Further, the portable electronic device may include a transceiver configured for transmitting a transmitted short range communication signal and receiving a received short range communication signal. Further, the portable electronic device may include a processor communicatively coupled to the transceiver, configured for detecting a proximity based event based on receiving the received short range communication signal from the short range communication enabled object, analyzing the received short range communication signal based on the detecting of the proximity based event, determining a second object identifier associated with the short range communication enabled object based on the analyzing, and performing a predetermined action based on the second object identifier. Further, the portable electronic device may include a memory device configured for storing a first digital asset and a first object identifier associated with the first digital asset.

Disclosed herein is a short range communication enabled object for facilitating proximity based interaction with at least one electronic device. Further, the short range communication enabled object may include a memory device configured for storing a designated number associated with a predetermined action. Further, the short range communication enabled object may include a processing device communicatively coupled to the memory device. Further, the processing device may be configured for manipulating the designated number. Further, the short range communication enabled object may include at least one sensor communicatively coupled to the processing device. Further, the at least one sensor may be configured for generating at least one sensor data. Further, the manipulating of the designated number may be based on the at least one sensor data. Further, the short range communication enabled object may include a transmitter device configured for transmitting the designated number over a short range communication channel to the at least one electronic device.

Disclosed herein is a first portable electronic device for facilitating a proximity based interaction with at least one second portable electronic device. The first portable electronic device may include at least one first sensor device configured to generate at least one first sensor data, a first transceiver configured for communicating with at least one second transceiver associated with the at least one second portable electronic device, a first processor configured for detecting at least one proximity based event based on the at least one first sensor data from the at least one first sensor device, and generating a combined digital asset using a first digital asset and at least one second digital asset based on the detecting, and a memory device configured for storing the combined digital asset and the first digital asset.

The present invention relates to a fall detection method and system. The fall detection method comprises: receiving, by a first receiving antenna, a first WiFi signal stream propagating through an environment; receiving, by a second receiving antenna, a second WiFi signal stream propagating through the environment; determining a physical layer Channel State Information (CSI) stream, namely, a first CSI stream, of the first WiFi signal stream; determining a physical layer CSI stream, namely, a second CSI stream, of the second WiFi signal; determining a phase difference, namely, a CSI phase difference, between respective phase of the physical layer CSI stream of the first WiFi signal stream and the physical layer CSI stream of the second WiFi signal stream at the same time point, to form a CSI phase difference stream; and determining, according to the CSI streams and the CSI phase difference stream, a fall event.

The present invention relates to a fall detection method and system. The fall detection method comprises: receiving, by a first receiving antenna, a first WiFi signal stream propagating through an environment; receiving, by a second receiving antenna, a second WiFi signal stream propagating through the environment; determining a physical layer Channel State Information (CSI) stream, namely, a first CSI stream, of the first WiFi signal stream; determining a physical layer CSI stream, namely, a second CSI stream, of the second WiFi signal; determining a phase difference, namely, a CSI phase difference, between respective phase of the physical layer CSI stream of the first WiFi signal stream and the physical layer CSI stream of the second WiFi signal stream at the same time point, to form a CSI phase difference stream; and determining, according to the CSI streams and the CSI phase difference stream, a fall event.