Abstract: A wireless sensor network includes a network sink node and a plurality of cluster nodes. The cluster nodes are configured to pass communications upstream and downstream. Each cluster node has a communication range, or coverage area. A cluster node is configured to communicate with sensor nodes within the coverage area of cluster node. The sensor nodes are configured to register with at least one cluster node. The cluster nodes are configured to register with the network sink. Identifiers for the sensor nodes may be dynamically generated. Identifiers for the cluster nodes may be dynamically generated.

Abstract: An apparatus for use in an RFID data collection system includes an antenna portion for wirelessly exchanging signals and a memory portion for storing RFID data. A signal processing portion is coupled among the antenna portion and the memory portion. The signal processing portion is configured to receive RFID data and to at least encode or decode the received RFID data via space-time block codes (STBC). For example, an RFID tag employs two spatially separated antennas and circuitry for transmitting to an RFID reader data stored in tag memory as STBC encoded data. Other configurations are also disclosed.

Abstract: An apparatus for use in an RFID data collection system includes an antenna portion for wirelessly exchanging signals and a memory portion for storing RFID data. A signal processing portion is coupled among the antenna portion and the memory portion. The signal processing portion is configured to receive RFID data and to at least encode or decode the received RFID data via at least two orthogonal modulation signals. Other configurations are also disclosed.

Abstract: An apparatus for use in an RFID data collection system includes an antenna portion for wirelessly exchanging signals and a memory portion for storing RFID data. A signal processing portion is coupled among the antenna portion and the memory portion. The signal processing portion is configured to receive RFID data and to at least encode or decode the received RFID data via at least one spreading code, such as a mutually orthogonal code. Other configurations are also disclosed.

Abstract: A system and method of autofocusing an optical system uses transforms of images or portions of images formed by the optical system. A detector is used to capture images at different positions relative to the optical system. Transforms and blur spread parameters are calculated for the images for use in determining a position to which the detector should be moved to autofocus the system.

Abstract: A system and method is described for determining a distance to a desired target via correlating a pulse modulated signal with its corresponding reflected signal, while compensating for noise error in the reflected signal to allow for a more precise distance determination. Further details and features are described herein.

Abstract: A data request from a requesting device is received at a network of wireless sensor nodes. The data request is then forwarded through the network of wireless sensor nodes to a source wireless sensor node, where data responsive to the data request is generated. A reply including the responsive data is then forwarded along at least two communication paths through the network of wireless sensor nodes back to the requesting device.

Abstract: A wireless sensor network includes a network sink node and a plurality of cluster nodes. The cluster nodes are configured to pass communications upstream and downstream. Each cluster node has a communication range, or coverage area. A cluster node is configured to communicate with sensor nodes within the coverage area of cluster node. The sensor nodes are configured to register with at least one cluster node. The cluster nodes are configured to register with the network sink. Identifiers for the sensor nodes may be dynamically generated. Identifiers for the cluster nodes may be dynamically generated.

Abstract: A carrier structure has a plurality of cells. A corresponding plurality of objects having data carriers, such as radio frequency identification (RFID) tags, is placed in each cell. Each cell has an indicator associated therewith and is defined by walls that substantially prevent waves (such as RF waves) from propagating between cells. A control module is coupled to the carrier structure and is operative to selectively activate individual ones of the indicators. An automatic data collection device (such as an RFID reader) interrogates the data carriers of the objects placed in the cells, and the data carriers can provide response signals to the data collection device. The control module also monitors the response signals using an antenna present in each cell. If the data collection device selects a particular one of the responsive data carriers, the data collection device provides a notification signal to the control module to notify the control module of the selection.

Abstract: Data carriers (such as RFID tags) are formed into clusters of data carriers. Each cluster has at least one bridge data carrier that can communicate with a bridge data carrier of another cluster, thereby allowing data carriers in each cluster to communicate directly or indirectly with each other using a stochastic communication protocol method. Direct tag-to-tag communication capability is provided between data carriers in each cluster and/or between clusters. The data carriers can backscatter and modulate a carrier wave from a source, thereby using the backscattered and modulated carrier wave to convey data to each other.

Abstract: A lab-on-chip system comprises an antenna and a communications subsystem to wirelessly transmit information from the lab-on-chip system. The communications subsystem may also receive information, data or instructions from an off-chip system or device. The lab-on-chip system may comprise a passive power subsystem coupled to an antenna to wirelessly receive power in the form of an electromagnetic field, which provides electrical power derived therefrom to at least one other subsystem of the lab-on-chip system.

Abstract: A microchip system comprises a self check subsystem operable to perform a self test of at least one subsystem of the microchip system, and/or on the interoperability of subsystems. An antenna and a communications subsystem wirelessly transmit self check information from the microchip system. The communications subsystem may also receive information, data or instructions from an off-chip system or device. Self check tests may occur during manufacture of the microchip system and/or during operation. The microchip system may comprise a passive power subsystem coupled to an antenna to receive power in the form of an electromagnetic field, and which provides electrical power derived therefrom to at least one other subsystem of the microchip system.

Abstract: A monolithic micro scanning device comprising multiple substrates; source of light for generating a light beam disposed on one of said substrates; and micro mirror disposed on one of said substrates for repetitively and cyclically moving light beam to scan insignia impregnated on a surface of different articles is described. More particularly, the scanning device comprises a combination of stacked dies in suitable form factor to optimize a system configuration and packaging.

Abstract: A lab-on-chip system comprises an antenna and a communications subsystem to wirelessly transmit information from the lab-on-chip system. The communications subsystem may also receive information, data or instructions from an off-chip system or device. The lab-on-chip system may comprise a passive power subsystem coupled to an antenna to wirelessly receive power in the form of an electromagnetic field, which provides electrical power derived therefrom to at least one other subsystem of the lab-on-chip system.

Abstract: A microchip system comprises a self check subsystem operable to perform a self test of at least one subsystem of the microchip system, and/or on the interoperability of subsystems. An antenna and a communications subsystem wirelessly transmit self check information from the microchip system. The communications subsystem may also receive information, data or instructions from an off-chip system or device. Self check tests may occur during manufacture of the microchip system and/or during operation. The microchip system may comprise a passive power subsystem coupled to an antenna to receive power in the form of an electromagnetic field, and which provides electrical power derived therefrom to at least one other subsystem of the microchip system.

Abstract: A monolithic micro scanning device comprising multiple substrates; source of light for generating a light beam disposed on one of said substrates; and micro mirror disposed on one of said substrates for repetitively and cyclically moving light beam to scan insignia impregnated on a surface of different articles is described. More particularly, the scanning device comprises a combination of stacked dies in suitable form factor to optimize a system configuration and packaging.

Abstract: A method for tracking tax payment information includes fixing a unique machine readable identifier to each of a number of taxable items, storing each of the unique machine readable identifiers in a computer readable memory, and storing tax payment information in the computer readable memory for each of the items. The unique machine readable identifier may take the form of a machine readable symbol such as a barcode symbol or as a wireless memory device such as a radio frequency identification (“RFID”) tag. The tax information may include data such as the tax payment status, tax payment authority, a tax payment sum, a tax payment date, identify of a manufacturer, identify of a product or product type, and the identify of a product origin. Tax payment information may include tax payment information from multiple taxing authorities.

Abstract: A method for tracking tax payment information includes fixing a unique machine readable identifier to each of a number of taxable items, storing each of the unique machine readable identifiers in a computer readable memory, and storing tax payment information in the computer readable memory for each of the items. The unique machine readable identifier may take the form of a machine readable symbol such as a barcode symbol or as a wireless memory device such as a radio frequency identification (“RFID”) tag. The tax information may include data such as the tax payment status, tax payment authority, a tax payment sum, a tax payment date, identify of a manufacturer, identify of a product or product type, and the identify of a product origin. Tax payment information may include tax payment information from multiple taxing authorities.

Abstract: An RFID tag is provided with a timing module to measure elapsed time and an environment module to detect certain environmental conditions. The RFID tag includes a transmitter/receiver, memory module, antenna module, converter, and the timing and environment modules. In an embodiment of the invention, the timing module enables the user, upon interrogating the RFID tag, to determine the precise length of time from the previous charge of the RFID tag. The environment module enables the user to determine how long the RFID tag has been exposed to certain environmental conditions that have been pre-defined by the user.