A racing tracking system and process includes one or more RFID-based tower units connected to a computer. Pairs of tower units may be positioned to provide redundancy of detection so that the front of a participant and the rear of a participant (where bibs may be worn) are detected. The redundancy of RFID-based tower unit detection of front and rear worn bibs assures that all bibs will be read, and improves on the accuracy of a participant's position being confirmed.

An incontinence detection system includes an incontinence detection pad for placement beneath a person to be monitored. The incontinence detection pad has a passive radio frequency identification (RFID) tag. A reader is provided and a plurality of antennae is coupled to the reader. The reader includes a bistatic radio frequency (RF) switch matrix which is operable to establish a first antenna of the plurality of antennae as a transmit antenna that is used to wirelessly energize the passive RFID tag and to establish a second antennae of the plurality of antennae as a receive antenna that is used to read backscattered data that may be emitted from the passive RFID tag. The first and second antennae are situated in respective housings that are spaced apart from each other. An arrangement of first and second electrodes on an electrical sheet of an incontinence pad is also provided.

Techniques for radio-frequency identification systems include sensor systems having a sensor unit and one or more sensors and a server. The sensor system includes one or more antennas at a location configured to receive signals from a tag proximate to an antenna and a processor configured to process tag detection signals based on the received signals. The processing may include selectively storing tag detection signals received from one or more antennas and identify an event related to the presence of a tag proximate to an antenna at the location. Sensor system may include a transmitter configured to transmit a message indicating the event over a network to a server. The server may be configured to process the message by analyzing a feature of the signals related to the event. The analysis may evaluate an adjustment of a configuration parameter used to operate an antenna. The configuration parameter may be updated by the server, and the server may transmit a message indicating the configuration parameter to the sensor system.

Synthesized-beam RFID readers may be used to locate RFID tags. In one embodiment, a tag's response rates on different beams can be used, along with the target locations of those beams, to estimate the tag's location. The estimated tag location is within a region where beams with nonzero tag response rates overlap, and the distances of the estimated tag location from any two different beam target locations may correspond to a ratio of tag response rates on the two different beams. In another embodiment, a tag's response rates on different beam pairs configured to cooperatively power RFID tags can be used, along with the target locations of those beam pairs, to estimate the tag's location.

To promote ease of use, as well as a reduction in bit error rates during extended data exchange between a coupled NFC tag/reader pair, signal strength is measured from a plurality of NFC tag antennas each positioned differently with respect to a common reader field, and differences in signal strength are used to determine an optimum positioning of the tag, or tag emulator, with respect to the reader. Alternative embodiments may include signal time of flight for determining orientation of the NFC antennas within the reader field. Information is generated by the tag, or tag emulator, and output by the tag, or tag emulator, such that a user may direct the positioning of the tag, or tag emulator, for improved communication with the reader.

A RFID system, according to one embodiment, includes: a plurality of radiating elements, a transmission line, and power dividers coupling the plurality of radiating elements to the transmission line. The power dividers are coupled along the transmission line, and are configured such that they provide an equal distribution of power between each of the plurality of radiating elements. Moreover, an input impedance of each of the power dividers is about equal to an impedance of the transmission line.

Systems and methods for determining a time of a passing at a reference line of an RFID tag traveling along a route and a time of lapsing of the tracked RFID tag on the route, the system have a plurality of spaced apart tag reader systems for wirelessly obtaining tag reads, wherein at least one of the tag reader systems is space apart from the reference line. The timing system receives a plurality of tag reads and determines the time of passing of the RFID at the reference line responsive to the plurality of received tag read messages received from the plurality of tag reader systems.

Techniques for determining an item location based on multiple RFID parameters from multiple read events are described. In an example, a computer system may access a first read event. A first RFID reader located within a first zone may have generated the first read event at a first time. The first read event may identify an RFID tag and may include first RFID parameters. The computer system may access a second read event. A second RFID reader located within a second zone may have generated the second read event at a second time within a predefined amount of time from the first time. The second read event may identify the RFID tag and include second RFID parameters. The computer system may determine whether the item location falls within the first zone or the second zone based on two or more first RFID parameters and two or more second RFID parameters.

Technologies for monitoring discharged bales or bale position on a baler can be improved by applying processes for identifying radio-frequency identification (RFID) tag location. A bale can include an RFID tag and a baler can include an RFID reader. The RFID reader can interrogate the RFID tag and a computing device of or connected to the RFID reader can identify the location of the RFID tag based on the interrogation. The computing device can determine a position of the bale on the baler based on the identified location of the RFID tag since spatial information of the bale and the baler is known. Also, the computing device can estimate a geographic location of the bale, after it has been discharged from the baler, based on an identified location of the RFID tag and an identified geographic location of the baler during the discharge of the bale.

Surgical instrument RFID tag reading apparatus (10) comprises an interrogation zone (12) for receiving a surgical instrument set (14) comprising: a plurality of surgical instruments, each having a respective RFID tag containing identification information; an RFID tag reader (16); RF antenna (18) arranged to transmit an RF signal (20) and arranged to receive RF return signals from at least some of the RFID tags; guidance apparatus (22) arranged to cause predetermined relative movement between the RFID tags on the surgical instruments and the RF signal; and a controller (24) arranged to: receive the surgical instrument identification information from the RFID tag reader for each RFID tag from which an RF return signal is received; compare the received surgical instrument identification information with a surgical instrument list of the set; and; determine whether surgical instrument identification information has been received for each of the surgical instruments on the surgical instrument list, and if not, generate an incomplete list alert.