Abstract: Radio-frequency identification-(RFID)-based systems and methods for collecting telecommunications information is disclosed. The methods include storing transceiver information in a transceiver and connector information in an optical fiber connector, and then operably connecting the connector to the transceiver. The connection results in an electrical connection that allows the transceiver information to be communicated to the connector. The connector has a RFID tag that generates a connector RFID-tag signal that includes the connector information and the transceiver information. When electronics equipment are connected to the transceiver, electronics-equipment information is passed through the transceiver to the connector so that the electronics-equipment information can be included in the connector RFID-tag signal.

Abstract: Radio-frequency identification—(RFID)-based systems and methods for collecting telecommunications information is disclosed. The methods include storing transceiver information in a transceiver and connector information in an optical fiber connector, and then operably connecting the connector to the transceiver. The connection results in an electrical connection that allows the transceiver information to be communicated to the connector. The connector has a RFID tag that generates a connector RFID-tag signal that includes the connector information and the transceiver information. When electronics equipment are connected to the transceiver, electronics-equipment information is passed through the transceiver to the connector so that the electronics-equipment information can be included in the connector RFID-tag signal.

Abstract: Radio-frequency identification-(RFID)-based systems and methods for collecting telecommunications information is disclosed. The methods include storing transceiver information in a transceiver and connector information in an optical fiber connector, and then operably connecting the connector to the transceiver. The connection results in an electrical connection that allows the transceiver information to be communicated to the connector. The connector has a RFID tag that generates a connector RFID-tag signal that includes the connector information and the transceiver information. When electronics equipment are connected to the transceiver, electronics-equipment information is passed through the transceiver to the connector so that the electronics-equipment information can be included in the connector RFID-tag signal.

Abstract: There is provided a passive RFID transponder assembly that includes a condition responsive device adapted to read a condition relating to the component that is associated with the RFID transponder assembly. The condition that is read by the condition responsive device relates to physical contact with a field technician or a mating component, relates to electrical connection between an integrated circuit chip and an antenna, relates to one or more environmental conditions, or the like. The components with which the RFID transponder assemblies are associated include components of telecommunications equipment, such as fiber optic connectors, fiber optic adapters, fiber optic patch panels, copper connectors, and copper adapters to list some non-limiting examples.

Abstract: There are provided components, connectors, receptacles, cables, and systems wherein passive RFID functionality is incorporated. Also provided are passive RFID elements in general. The passive RFID elements power visual indicators based on receipt of external RF signals. Passive energy storage devices may be employed to provide electrical energy to the visual indicators. The passive energy storage devices may be charged by the external RF signals. The visual indicators may operate continuously or according to a predetermined flashing pattern.

Abstract: There is provided a system for identifying a connection of two or more components in which one or more RFID transponders are associated with the two or more components. A plug is associated with the first component, such as a fiber optic connector, and a socket is associated with the second component, such as a fiber optic adapter. An RFID transponder is associated with each component and at least one of the RFID transponders is activatable when the plug is received by the socket to enable the activated RFID transponder to communicate with the RFID reader. The antennas and integrated circuit chips that define the RFID transponders are positioned relative to the plug and socket to enable the one or more RFID transponders to activate when the plug is received by the socket. In addition, the RFID transponders may communicate with one another to identify other RFID transponders in order to communicate identities of two or more RFID transponders.

Abstract: There is provided a system for identifying a plurality of components via an RFID reader with an associated database and processing element. The system includes a first component with an associated first RFID transponder and a second component with an associated second RFID transponder. A third RFID transponder may be associated with the first component, wherein either the first or third RFID transponder includes stored information relating to both transponders. The first and second RFID transponders are adapted to communicate with the RFID reader to enable identification of the connection of the first component to the second component. One of the RFID transponders may be adapted to identify the other RFID transponder and store the identification information for subsequent communication to the RFID reader of identification information for both RFID transponders and the associated components. The system is adapted to create a map of the two or more components, such as components of telecommunications equipment.

Abstract: An optical-fiber-network (OFN) radio-frequency identification (RFID) system for deploying and/or maintaining an OFN. The system includes a plurality of OFN components, and at least one RFID tag that includes RFID tag data that has at least one property of the OFN component associated with the RFID tag. The RFID tag data is written to and read from the RFID tags prior, during or after deploying the OFN components. An OFN-component-data database unit is used to store and process the RFID tag data. This allows for different maps of the OFN to be made, such as an inventory map and a maintenance map. The OFN-RFID system allows for automated operations and management of OFN components by service personnel, and provides for faster and more accurate OFN system deployment and maintenance.

Abstract: An optical-fiber-network (OFN) radio-frequency identification (RFID) system for deploying and/or maintaining an OFN. The system includes a plurality of OFN components, and at least one RFID tag that includes RFID tag data that has at least one property of the OFN component associated with the RFID tag. The RFID tag data is written to and read from the RFID tags prior, during or after deploying the OFN components. An OFN-component-data database unit is used to store and process the RFID tag data. This allows for different maps of the OFN to be made, such as an inventory map and a maintenance map. The OFN-RFID system allows for automated operations and management of OFN components by service personnel, and provides for faster and more accurate OFN system deployment and maintenance.

Abstract: Radio-frequency identification—(RFID)-based systems and methods for collecting telecommunications information is disclosed. The methods include storing transceiver information in a transceiver and connector information in an optical fiber connector, and then operably connecting the connector to the transceiver. The connection results in an electrical connection that allows the transceiver information to be communicated to the connector. The connector has a RFID tag that generates a connector RFID-tag signal that includes the connector information and the transceiver information. When electronics equipment are connected to the transceiver, electronics-equipment information is passed through the transceiver to the connector so that the electronics-equipment information can be included in the connector RFID-tag signal.

Abstract: Systems and methods for reading a RFID-tag signal in the presence of noise and other propagation and circuit impairments using a RFID-tag reader are disclosed. The method includes receiving with a RFID-tag reader multiple copies of an original RFID-tag signal from a RFID tag. The original RFID-tag signal comprises an original bit sequence representative of information stored in the RFID tag. At least some of the received RFID-tag signal copies differ from one another due to noise or other signal impairments. The received multiple copies are processed on a sample-by-sample basis in the RFID-tag reader using digital signal processing techniques to obtain an improved received digitized RFID tag signal that substantially removes the noise and other impairments. This improved signal is used to recover the original bit sequence and thus the information stored in the RFID tag.

Abstract: There are provided connectors, cables, cable assemblies, network components, and systems wherein optically addressed RFID functionality is incorporated. Also provided are optically addressed RFID elements in general. The RFID elements utilize an optical tap to direct a portion of the optical signal traveling through an optical fiber to a transducer. The transducer creates an electrical signal which may be used to write information to an integrated circuit of, transmit an RF signal to, and/or provide power to the RFID element.

Abstract: There are provided connectors, cables, cable assemblies, network components, and systems wherein optically addressed RFID functionality is incorporated. Also provided are optically addressed RFID elements in general. The RFID elements utilize an optical tap to direct a portion of the optical signal traveling through an optical fiber to a transducer. The transducer creates an electrical signal which may be used to write information to an integrated circuit of, transmit an RF signal to, and/or provide power to the RFID element.

Abstract: There are provided components, connectors, receptacles, cables, and systems wherein passive RFID functionality is incorporated. Also provided are passive RFID elements in general. The passive RFID elements power visual indicators based on receipt of external RF signals. Passive energy storage devices may be employed to provide electrical energy to the visual indicators. The passive energy storage devices may be charged by the external RF signals. The visual indicators may operate continuously or according to a predetermined flashing pattern.

Abstract: Systems and methods for reading a RFID-tag signal in the presence of noise and other propagation and circuit impairments using a RFID-tag reader are disclosed. The method includes receiving with a RFID-tag reader multiple copies of an original RFID-tag signal from a RFID tag. The original RFID-tag signal comprises an original bit sequence representative of information stored in the RFID tag. At least some of the received RFID-tag signal copies differ from one another due to noise or other signal impairments. The received multiple copies are processed on a sample-by-sample basis in the RFID-tag reader using digital signal processing techniques to obtain an improved received digitized RFID tag signal that substantially removes the noise and other impairments. This improved signal is used to recover the original bit sequence and thus the information stored in the RFID tag.

Abstract: There is provided a system for identifying a connection of two or more components in which one or more RFID transponders are associated with the two or more components. A plug is associated with the first component, such as a fiber optic connector, and a socket is associated with the second component, such as a fiber optic adapter. An RFID transponder is associated with each component and at least one of the RFID transponders is activatable when the plug is received by the socket to enable the activated RFID transponder to communicate with the RFID reader. The antennas and integrated circuit chips that define the RFID transponders are positioned relative to the plug and socket to enable the one or more RFID transponders to activate when the plug is received by the socket. In addition, the RFID transponders may communicate with one another to identify other RFID transponders in order to communicate identities of two or more RFID transponders.

Abstract: There is provided a passive RFID transponder assembly that includes a condition responsive device adapted to read a condition relating to the component that is associated with the RFID transponder assembly. The condition that is read by the condition responsive device relates to physical contact with a field technician or a mating component, relates to electrical connection between an integrated circuit chip and an antenna, relates to one or more environmental conditions, or the like. The components with which the RFID transponder assemblies are associated include components of telecommunications equipment, such as fiber optic connectors, fiber optic adapters, fiber optic patch panels, copper connectors, and copper adapters to list some non-limiting examples.

Abstract: There is provided a system for identifying a plurality of components via an RFID reader with an associated database and processing element. The system includes a first component with an associated first RFID transponder and a second component with an associated second RFID transponder. A third RFID transponder may be associated with the first component, wherein either the first or third RFID transponder includes stored information relating to both transponders. The first and second RFID transponders are adapted to communicate with the RFID reader to enable identification of the connection of the first component to the second component. One of the RFID transponders may be adapted to identify the other RFID transponder and store the identification information for subsequent communication to the RFID reader of identification information for both RFID transponders and the associated components. The system is adapted to create a map of the two or more components, such as components of telecommunications equipment.

Abstract: An optical transmission system is provided. The system includes first and second lines of optical fiber, each line including first, second, and third optical fiber portions, and an optical phase conjugator optically coupling the first and second lines. The first and third optical fiber portions have a local dispersion of like sign to each other, and opposite to the sign of the second optical fiber portion.

Abstract: An optical signal quality monitoring system and method are provided for monitoring signal quality of a plurality of optical signals in a network. The system includes a plurality of input taps for acquiring multiple optical signals from multiple optical fibers of an optical network. The system also includes an optical switch for receiving the tapped optical signals and selecting one of the tapped optical signals at a time as an output, and an optical channel selector for selecting one signal channel at a time of the selected optical signal. The system further includes an optical signal quality measurement device for analyzing the selected optical channel of the selected optical signal and determining a signal quality of the selected optical channel.