Abstract: A system may include an adapter, a charger, and a connector. The adapter is configured to receive an alternating current (AC) signal and generate an adapter signal, the adapter signal being generated based on an up-conversion of the AC signal. The charger is configured to generate a direct current (DC) signal from the adapter signal using one or more energy storage elements and supply the DC signal to a load, in which the adapter signal has a voltage greater than that of the DC signal. The connector is configured to couple the adapter and the charger. In some aspects, the adapter signal is adjusted based on one or more measurements of the DC signal at an output of the charger to maintain a target power for charging the load.

Abstract: A method comprises: receiving a signal from a first device that is part of a tag, the tag adapted to be affixed to a person or object, the receiving being performed by a processor within the tag; analyzing the signal within the processor to determine whether the person or object is performing a predetermined type of behavior; adjusting a variable rate of transmitting a monitoring signal from the tag, based on a result of the analyzing, the adjusting being controlled by the processor; and transmitting the monitoring signal from the tag to an external device separate from the tag at the adjusted variable rate.

Abstract: A method comprises: receiving a signal from a first device that is part of a tag, the tag adapted to be affixed to a person or object, the receiving being performed by a processor within the tag; analyzing the signal within the processor to determine whether the person or object is performing a predetermined type of behavior; adjusting a variable rate of transmitting a monitoring signal from the tag, based on a result of the analyzing, the adjusting being controlled by the processor; and transmitting the monitoring signal from the tag to an external device separate from the tag at the adjusted variable rate.

Abstract: A system may include an adapter, a charger, and a connector. The adapter is configured to receive an alternating current (AC) signal and generate an adapter signal, the adapter signal being generated based on an up-conversion of the AC signal. The charger is configured to generate a direct current (DC) signal from the adapter signal using one or more energy storage elements and supply the DC signal to a load, in which the adapter signal has a voltage greater than that of the DC signal. The connector is configured to couple the adapter and the charger. In some aspects, the adapter signal is adjusted based on one or more measurements of the DC signal at an output of the charger to maintain a target power for charging the load.

Abstract: A method comprises: receiving a signal from a first device that is part of a tag, the tag adapted to be affixed to a person or object, the receiving being performed by a processor within the tag; analyzing the signal within the processor to determine whether the person or object is performing a predetermined type of behavior; adjusting a variable rate of transmitting a monitoring signal from the tag, based on a result of the analyzing, the adjusting being controlled by the processor; and transmitting the monitoring signal from the tag to an external device separate from the tag at the adjusted variable rate.

Abstract: A method comprises: receiving a signal from a first device that is part of a tag, the tag adapted to be affixed to a person or object, the receiving being performed by a processor within the tag; analyzing the signal within the processor to determine whether the person or object is performing a predetermined type of behavior; adjusting a variable rate of transmitting a monitoring signal from the tag, based on a result of the analyzing, the adjusting being controlled by the processor; and transmitting the monitoring signal from the tag to an external device separate from the tag at the adjusted variable rate.

Abstract: A method comprises: receiving colliding signals by a receiver from a plurality of signal sources, such that the receiver has a respective non-zero probability of detecting and identifying the colliding signals from each respective one of the signal sources at a given time. The colliding signals are configured with at least one common transmission parameter value so as to interfere with each other, so that the receiver only detects and identifies one of the received colliding signals at any given time. The receiving and identifying are performed during each of a plurality of cycles. A probabilistic model is used to calculate the location of the receiver. The model correlates a respective number of times the receiver detects and identifies one of the colliding signals and the probability of that signal being identified by the receiver, given the location of the receiver.

Abstract: A system comprises a processing server programmed to determine which GPS satellites are currently available for use within a field of view of the processing server. The processing server is programmed to transmit to a terrestrial beacon information about a GPS channel of a GPS satellite which is not currently within the field of view of the processing server. The terrestrial beacon is configured to broadcast a navigation signal useful to determine location using the identified GPS channel. The processing server transmits the ephemeris of the terrestrial beacon to a GPS receiver. The receiver receives the signal from the beacon, and uses the ephemeris received from the processing server for calculating the receiver's location.

Abstract: A coded system for radio-frequency communication (RFC); the system comprising at least one base station (20) and a plurality of mobile devices (10); the base station and mobile devices are individually provided with running time information synchronized inter se; the mobile device is adapted for transmitting an identifying signal to the base station device; the base station is adapted for receiving the signal; wherein the signal further comprises a preamble including a miming-time-dependent code generated according to a predetermined algorithm (220); the base station is adapted for comparing the code with a reference code generated by the base station according to the algorithm (260), authorizing the RFC in response to coincidence of the running-time-dependent codes generated by the base station and the mobile (270).

Abstract: A wireless bidirectional communication system and method for tracking smart tags affixed to assets located within a defined area. Asset tracking is provided by a central processor operated by a user. The central processor combined with communication modules communicates with the system tags for deriving corresponding assets' locations. Communication is synchronized by way of broadcasting a clock generator signal over the communication link. The broadcasted clock signal is further used by the system for generating distinct time slots assigned to a tag by demand. Synchronizing the communication between the tags and the central processor is beneficial for maintaining reliable and short messages across the data link and maintaining low power draw from the tag battery.

Abstract: The present invention discloses a tracking apparatus and system thereof, useful for objects affixed with a smart tags entering and exiting an enclosed area through a gate. A gate consists of two directional antennas directed respectively inward and outward from the gate crossing line and connected to an RF beacon. Each smart tag affixed to an object approaching the gate area, receives a transmission of ID associated with each directional antenna. The smart tag detects crossing of the gate line and direction of crossing by method of processing the ID of the two directional antennas. The detected crossing data is transmitted via a wireless communication link, to a base station located at the enclosed zone. The base station transmits the gate detection data to a service center.

Abstract: A coded system for radio-frequency communication (RFC); the system comprising at least one base station (20) and a plurality of mobile devices (10); the base station and mobile devices are individually provided with running time information synchronized inter se; the mobile device is adapted for transmitting an identifying signal to the base station device; the base station is adapted for receiving the signal; wherein the signal further comprises a preamble including a miming-time-dependent code generated according to a predetermined algorithm (220); the base station is adapted for comparing the code with a reference code generated by the base station according to the algorithm (260), authorizing the RFC in response to coincidence of the running-time-dependent codes generated by the base station and the mobile (270).

Abstract: A method comprises: receiving colliding signals by a receiver from a plurality of signal sources, such that the receiver has a respective non-zero probability of detecting and identifying the colliding signals from each respective one of the signal sources at a given time. The colliding signals are configured with at least one common transmission parameter value so as to interfere with each other, so that the receiver only detects and identifies one of the received colliding signals at any given time. The receiving and identifying are performed during each of a plurality of cycles. A probabilistic model is used to calculate the location of the receiver. The model correlates a respective number of times the receiver detects and identifies one of the colliding signals and the probability of that signal being identified by the receiver, given the location of the receiver.

Abstract: Apparatus for tracking an object (12A, 12B, 12C) including radiator modules (16A, 16B, 16C), disposed in an array of known locations adjoining a region (13) in which the object moves; each module includes at least one emitter (44, 46, 48) which emits a respective color selected from among a first plurality of colors. The apparatus includes a controller (32), which drives the at least one emitter to emit during a respective time slot, selected from among a second plurality of time slots during which the modules may emit. The apparatus also includes a location unit (22), fixed to the object and including at least one camera (72), which captures a sequence of electronic images containing some of the locations of the modules. The apparatus further includes a processing unit (26), which processes the electronic images to determine, responsively to the colors emitted by the modules and the time slots in which the colors are emitted, a location of the object.

Abstract: An assisted global positioning system (AGPS) for tracking a movable object of interest is disclosed. The system comprises a service center for calculating a tag location, a plurality of ground base stations, a plurality of beacons adapted to transmit individual ID data, and at least one GPS-based smart tag releasably affixed to the movable object. The system components are interconnected by means of one or more communication links. The service center is adapted for inquiring the tag and receiving a response from the tag constituting pseudo-ranges according to a predetermined protocol.

Abstract: A method of multiplexing optical signals in a node of an optical network including as inputs a plurality of electrical signals, a plurality of laser transmitters, and as outputs a plurality of optical fibers, (a) generating clock pulses as a first clock frequency; (b) dividing the clock pulses respectively into a number of parallel trigger outputs; (c) sampling the electrical signals respectively by triggering on the parallel trigger outputs; (d) converting the sampled electrical signals to sampled optical signals by modulating respectively the laser transmitters with the sampled electrical signals and outputting respectively the sampled optical signals on the optical fibers; (e) combining the sampled optical signals onto a single optical fiber.

Abstract: A wireless bidirectional communication system and method for tracking smart tags affixed to assets located within a defined area. Asset tracking is provided by a central processor operated by a user. The central processor combined with communication modules communicates with the system tags for deriving corresponding assets' locations. Communication is synchronized by way of broadcasting a clock generator signal over the communication link. The broadcasted clock signal is further used by the system for generating distinct time slots assigned to a tag by demand. Synchronizing the communication between the tags and the central processor is beneficial for maintaining reliable and short messages across the data link and maintaining low power draw from the tag battery.

Abstract: A method for identifying objects including fixing tags to respective objects, each such tag comprising at least one optical emitter. The at least one optical emitter on each of the tags is driven to emit optical radiation of a respective color, selected from among the first plurality of colors emittable by the tags, during a respective time slot, selected from among a second plurality of time slots during which the tags may emit the optical radiation. A camera captures sequence of electronic images of an area containing the objects to which the tags are fixed. The electronic images in the sequence are processed in order to identify, responsively to the colors of the optical radiation emitted by the tags and the time slots in which the optical radiation is emitted, the objects to which the tags are fixed.

Abstract: Apparatus for tracking an object (12A, 12B, 12C) including radiator modules (16A, 16B, 16C), disposed in an array of known locations adjoining a region (13) in which the object moves; each module includes at least one emitter (44, 46, 48) which emits a respective color selected from among a first plurality of colors. The apparatus includes a controller (32), which drives the at least one emitter to emit during a respective time slot, selected from among a second plurality of time slots during which the modules may emit. The apparatus also includes a location unit (22), fixed to the object and including at least one camera (72), which captures a sequence of electronic images containing some of the locations of the modules. The apparatus further includes a processing unit (26), which processes the electronic images to determine, responsively to the colors emitted by the modules and the time slots in which the colors are emitted, a location of the object.

Abstract: A method for identifying objects including fixing tags to respective objects, each such tag comprising at least one optical emitter. The at least one optical emitter on each of the tags is driven to emit optical radiation of a respective color, selected from among the first plurality of colors emittable by the tags, during a respective time slot, selected from among a second plurality of time slots during which the tags may emit the optical radiation. A camera captures sequence of electronic images of an area containing the objects to which the tags are fixed. The electronic images in the sequence are processed in order to identify, responsively to the colors of the optical radiation emitted by the tags and the time slots in which the optical radiation is emitted, the objects to which the tags are fixed.