Abstract: This invention provides an RFID-equipped retainer for hearing aids. In one embodiment, the retainer consists of a hollow string or tube. Located at one end of the retainer is a clasp that can attach to a hearing aid, and at the other end is a clip or similar fastener for optionally attaching the retainer to the clothing of the wearer. Also provided are the designs for passive and battery-assisted-passive, ultra high frequency, far-field RFID tags that can be embedded within this retainer. The tags consist of an RFID microchip with an impedance matching circuit mounted on a substrate and an antenna connected to the microchip. In another embodiment, the retainer consists of an RFID tag enclosed in a package or case that sits behind the wearer's ear and is physically connected to the hearing aid in the ear. The RFID microchip can be optionally programmed with an identification number that can be associated with information about the hearing aid to which it is attached.

Abstract: Provided is a portable transport apparatus having an enclosure for containing an item to be transported, a RFID reader connected to a near field antenna disposed within the enclosure for a first RFID reading of an area inside the enclosure and to a far field antenna disposed on the enclosure for a second RFID reading of an area outside the enclosure, and a wireless communication module, and a method of use of the portable transport apparatus.

Abstract: This invention provides an RFID-equipped retainer for hearing aids. In one embodiment, the retainer consists of a hollow string or tube. Located at one end of the retainer is a clasp that can attach to a hearing aid, and at the other end is a clip or similar fastener for optionally attaching the retainer to the clothing of the wearer. Also provided are the designs for passive and battery-assisted-passive, ultra high frequency, far-field RFID tags that can be embedded within this retainer. The tags consist of an RFID microchip with an impedance matching circuit mounted on a substrate and an antenna connected to the microchip. In another embodiment, the retainer consists of an RFID tag enclosed in a package or case that sits behind the wearer's ear and is physically connected to the hearing aid in the ear. The RFID microchip can be optionally programmed with an identification number that can be associated with information about the hearing aid to which it is attached.

Abstract: A radio frequency identification (RFID) system for detecting and identifying lost dentures in a facility, includes readers deployed in fixed locations in the facility. Each of the readers is configured to transmit a first signal and to detect from a distance a second signal, which is generated at an RFID transponder embedded in a denture in response to receiving the first signal by backscattering a part of the first signal. The second signal contains information related to the denture, including an identification of the denture owner. The RFID system also includes a first server located within the facility. The first server is configured to communicate with the readers over a network in the facility and to control operations of the readers. Each of the readers sends the information related to the denture to the first server when it detects the second signal from the RFID transponder.

Abstract: A radio frequency identification (RFID) system for detecting and identifying lost dentures in a facility, includes readers deployed in fixed locations in the facility. Each of the readers is configured to transmit a first signal and to detect from a distance a second signal, which is generated at an RFID transponder embedded in a denture in response to receiving the first signal by backscattering a part of the first signal. The second signal contains information related to the denture, including an identification of the denture owner. The RFID system also includes a first server located within the facility. The first server is configured to communicate with the readers over a network in the facility and to control operations of the readers. Each of the readers sends the information related to the denture to the first server when it detects the second signal from the RFID transponder.

Abstract: A radio frequency identification (RFID) transponder for use in dentures is provided. The RFID transponder includes a passive RFID microchip configured for storing information related to a denture and a loop dipole antenna configured for sending the information in response to receiving a signal from an RFID reader. The loop dipole antenna in turn includes a wire forming a loop structure and a set of dipole arms going out from the loop structure. Each end of the set of dipole arms is folded at least once to form at least one meander and the dipole arms follow a shape of the denture. The RFID transponder also includes at least one tuning patch configured for tuning input impedance of the loop dipole antenna. The RFID transponder is embedded in the denture and the passive RFID microchip is electrically coupled to the loop structure.

Abstract: We describe RFID systems for localization and proximity detection and with improved read rates. The systems include three components, (a) RFID readers, (b) passive and/or semipassive tags, (c) sensor-tags (STs), (d) STs integrated with sensors, and (e) and processing elements. The key new elements are the STs, which are like regular tags that communicate with RFID readers on the principle of backscattering. However, they have an additional functionality of reading the communication of standard tags in their physical proximity and reporting it, if queried, to an RFID reader or a processing element. They can also use other types of communication with the RFID readers and processing elements. These functionalities allow for a variety of new solutions to many RFID problems some of which are described in this document.

Abstract: A radio frequency identification (RFID) transponder for use in dentures is provided. The RFID transponder includes a passive RFID microchip configured for storing information related to a denture and a loop dipole antenna configured for sending the information in response to receiving a signal from an RFID reader. The loop dipole antenna in turn includes a wire forming a loop structure and a set of dipole arms going out from the loop structure. Each end of the set of dipole arms is folded at least once to form at least one meander and the dipole arms follow a shape of the denture. The RFID transponder also includes at least one tuning patch configured for tuning input impedance of the loop dipole antenna. The RFID transponder is embedded in the denture and the passive RFID microchip is electrically coupled to the loop structure.