Abstract: In a wireless network that includes a plurality of nodes, a method of communicating a message from an originating node, intended for receipt by a destination node, via one or more intermediate nodes, includes the steps of: (a) communicating with just a single node within the communications range of the originating node—including sending the message and the known network pathway—if a network pathway to the destination node is known by the originating node, the single node being the first intermediate node identified in the known network pathway; and (b) communicating with one or more first intermediate nodes within the communications range of the originating node—including sending the message—if a network pathway to the destination node is unknown by the originating node.

Abstract: A tactical GPS denial/denial detection system includes a plurality of GPS detection/denial devices, a gateway, and a computer management system. Each GPS detection/denial includes a GPS receiver for determining positional parameters based on the GPS satellite signals, a GPS denier, which may be selectively activated, for disrupting reliable operation of GPS receivers, and a remote sensor interface adapted to extract the GPS parameters from the GPS receiver and to effectuate the activation of the GPS denier. The remote sensor interfaces and the gateway are communication nodes in an ad hoc wireless network. The gateway receives the GPS parameters from the remote sensor interfaces and communicates instructions to the remote sensor interfaces to selectively activate the GPS deniers. The computer management system receives the extracted GPS parameters from the gateway and analyzes the GPS parameters to detect whether an active GPS denial device is present in the vicinity of the system.

Abstract: An all weather housing assembly for protection of electrical components includes a first housing having an open end and defining a first compartment for receipt therein of electronic components; a cover attached to the first housing for enclosing the first compartment, the cover further including a mounting structure for receiving and retaining a power source which structure is mounted on a side of the cover that is exterior to the enclosed first compartment; and a second housing having an open end and defining a second compartment that is dimensioned to cover and protect a power source when received and retained by the mounting structure of the cover, the second housing being connected to the first housing independent of the attachment of the cover to the first housing.

Abstract: Systems and methods utilized a wireless transceiver (5008) having a low power radio frequency (LPRF) component (5010) that powers down to conserve energy and powers up in response to a signal; and a second receiver (5014) that provides the signal via line (5018) in response to receipt of a radio frequency broadcast. The broadcast is targeted to activate particular transceivers by including in the broadcast identifications such as class designations, in which case the transceivers power up and form networks. A transceiver may include one or more identifications and may include a unique identification of the transceiver itself. The LPRF component may be a Bluetooth radio, but in such case the overall transceiver itself only draws about 10 to 15 ?A while actively awaiting and screening for a targeted broadcast.

Abstract: A system for detecting a GPS denial device includes a plurality of GPS receivers, a plurality of remote sensor interfaces, a gateway, and a computer management system. Each of the plurality of GPS receivers determines positional parameters based on the signals received from the GPS satellites. Each remote sensor interface is associated with a respective GPS receiver such that each remote sensor interface extracts the GPS parameters from a respective GPS receiver. The plurality of remote sensor interfaces and the gateway are communication nodes in an ad hoc wireless network. The gateway receives the extracted GPS parameters from the remote sensor interfaces. The computer management system receives the extracted GPS parameters from the gateway and compares the determined GPS parameters with historical GPS parameters for the plurality of GPS receivers to detect whether an active GPS denial device is present in the vicinity of the system.

Abstract: A device for receiving and transmitting wireless signals includes a transceiver capable of receiving a wireless signal; and a standards-based radio capable of activation thereof in response to a reception of a wireless signal by the transceiver. The transceiver includes a receiver capable of receiving a wireless signal transmitted to prompt activation of said standards-based radio; and a transmitter configured, in response to a reception by said receiver of a wireless signal transmitted to prompt activation of said standards-based radio, to selectively transmit a wireless signal for another transceiver to prompt activation of another standards-based radio.

Abstract: A method for determining a terrestrial location of an apparatus that is deployed in a generally known geographical region includes capturing, by the apparatus, an earthbound image of the sky from a terrestrial location at an identified time; communicating, by the apparatus, data representative of the captured earthbound image of the sky; and determining the terrestrial location of the apparatus based on the data communicated by the apparatus by comparing the captured earthbound image of the sky to a master mapping of the sky relative to the surface of the Earth.

Abstract: Multiple standards based radio (“SBR”) devices, each having a high-gain directional antenna, are utilized in a remote sensor interface (“RSI”) unit to optimize detection and reception by the RSI of radio signals from gateway controllers, hopping radios, and other wireless devices.

Abstract: A first apparatus includes an imaging component configured to capture an earthbound image of the sky from a terrestrial location, a chronometric component, a communication component configured to transmit data representative of a captured earthbound image of the sky, and a controller. The controller is configured to cause an earthbound image of the sky to be captured using the imaging component at a time identified by the chronometric component and data representative of the captured earthbound image to be transmitted. A second apparatus includes a computer and a computer readable medium accessible by the computer and including data representative of a master mapping of the sky relative to the Earth and computer-executable instructions for determining a terrestrial location based on data representative of a captured earthbound image of the sky and an identified time at which the earthbound image was captured. A system includes the first and second apparatus.

Abstract: A transceiver includes a two-way communication component capable of powering down to conserve energy and capable of powering up in response to an electronic signal, the two-way communication component including a transmitter and a first receiver; and a second receiver that is configured to screen a radio frequency broadcast and provide the electronic signal to the two-way communication component in order to power up the two-way wireless communication component. The second receiver is configured to screen the radio frequency broadcast for first criteria, and screen the radio frequency broadcast for second criteria. The electric current may be an order of magnitude larger when screening for the first criteria than the second criteria. Screening also may be performed for third criteria, namely, specific data. The second receiver is adapted to draw substantially less current while awaiting receipt of and listening for a radio frequency broadcast than the two-way wireless communication component.

Abstract: A method is disclosed for manufacturing a wireless transceiver (5008) having a low power radio frequency (LPRF) component (5010) that powers down to conserve energy and powers up in response to a signal; and a second receiver (5014) that provides the signal via line (5018) in response to receipt of a radio frequency broadcast. The broadcast is targeted to activate particular transceivers by including in the broadcast identifications such as class designations, in which case the transceivers power up and form networks. A transceiver may include one or more identifications and may include a unique identification of the transceiver itself. The LPRF component is a Bluetooth radio, but the overall transceiver itself only draws about 10 to 15 ?A while actively awaiting and screening for a targeted broadcast.