A code reading method and a radar system using a short-range millimeter wave (mmWave) radar are provided. The method includes transmitting a mmWave radar signal to a target object from a radar system and receiving a reflection wave signal reflected on the target object, extracting reflection signal strengths for a plurality of line codes constituting the target object from the reflection wave signal, compensating for the reflection signal strengths considering a difference in antenna gain between the plurality of line codes as per an antenna radiation pattern of the radar system, forming a radar image using the compensated reflection signal strengths, and reading a binary code from the radar image.

A method for coding and identification of biological samples for in vitro fertilization comprises the steps of applying to receptacles intended for unfertilized eggs and sperm, respectively, an identification code characteristic of the patient; placing unfertilized eggs and sperm, respectively, in the receptacles; storing, transporting and admixing the respective samples in receptacles which each carry the same code; and implanting the resulting embryo in the patient. The identification code may based on RFID technology, in which sample vessels (12) are codified by the application of an RFID tag (13).

A portable item reporting device is configured to be attached to and in substantial collocation with a portable item, or to be integrated into a portable item. The device includes an environmental sensor to monitor two or more real-time environmental factors, such as item location, item movement, ambient light, ambient sounds, ambient temperature, etc. The device is configured to store usage expectation data indicative of historical and/or expected item usage and environments when the item is in normal use/storage associated with an authorized user. The device monitors current environmental conditions surrounding and pertaining to the item. The device compares the expected environment with the current environment, and/or with the recent historical environment. If the current/recent historical environment is inconsistent with expected conditions for the two or more environmental factors, the device assesses that the item is displaced, meaning either that the item is in abnormal use or abnormal storage, or is under the control of an unauthorized user who is other than the authorized user. Based on the assessment of displacement, the device initiates a signal or message to an authorized user of the item or to a recipient designated by the authorized user, indicating that the item usage/storage is displaced or otherwise anomalous.

The present disclosure provides a system and method for managing patient data during ophthalmic surgery. The systems and methods include an ophthalmic surgical device operable to receive data from a RFID chip. Data from the RFID chip is transmitted to a RFID read-write module operably coupled to the ophthalmic surgical system. A processor identifies the RFID chip based on the received data and determines whether the data stored to the RFID chip varies from data received from a surgical microscope by more than a predetermined percentage. The processor can generate a warning when the data stored to the RFID chip varies from data received from a surgical microscope by more than a predetermined percentage.

A data reader can read data regardless of the position of a radio IC tag. The data reader reads data at a separate position from a radio IC tag provided with a storage unit storing data and a communicating antenna for transmitting the data stored in the storage unit, and includes a reader/writer for generating a modulated signal by modulating a carrier wave and a plurality of antenna units for transmitting radio waves for a read for communicating data with a storage medium by radiating the modulated signal into the air. The reader/writer includes a phase adjustment circuit for changing the phase of a carrier wave.

A radio frequency identifier (RFID) tag can comprise an RFID chip, an antenna provided by a patch cell stack; and a feed line electrically coupling the RFID chip to the antenna. An equivalent circuit for the patch cell stack can comprise at least one inductance group comprising at least two series inductances, and at least one shunt capacitance. The antenna can have a composite right- and left-handed (CRLH) structure.

A tag board includes an insulation substrate with a lower surface bonded to the outside and an upper surface including a recess, an upper surface conductor on the upper surface of the insulation substrate, a ground conductor on the lower surface of the insulation substrate, and a short-circuit-portion through conductor that penetrates the insulation substrate in the thickness direction and electrically connects the upper surface conductor and the ground conductor to each other. The short-circuit-portion through conductor is connected to the upper surface conductor only at a part of the periphery of the upper surface conductor.

The present invention relates to the identification of RFID devices that are arranged closely together and placed on shelving for logistical and storage purposes. Furthermore, the aspects of the present invention relate to an arrangement and/or layout of antenna coils for example in an interrogator. There is disclosed a RFID interrogator and/or method of interrogating comprising, in one form, an RFID docking station consisting of a stationary RFID interrogator with RFID shelving antennas and mobile cabinets with shelves where the docking station antennas and the cabinet shelves interpenetrate when the mobile cabinet is offered up to the docking station such that the antennas are able to identify tagged items on the cabinet shelves. In another form, an RFID docking station consisting of a mobile RFID interrogator with RFID shelving antennas and stationary cabinets with shelves where the docking station antennas and the cabinet shelves interpenetrate when the docking station is offered up to the shelving such that the antennas are able to identify tagged items on the cabinet shelves.

A radio frequency identification (RFID) tag and reader system including an array of circular resonators with interdigitated capacitor fingers wherein the fingers of each pair are radially aligned and bars disposed between the resonators to reduce coupling between adjacent resonators, wherein subsets of the resonators resonate at respective different resonant frequencies, and the resonators of each of the subsets have the same resonant frequency; and the radio frequency response produced by the tag at a resonant frequency varies depending on the activation of resonators of the subset corresponding to the resonant frequency.

A method begins by a first radio frequency identification (RFID) sensor, that is associated with a first object element, receiving a first data request signal from an RFID reader and sending a first radio frequency (RF) signal that includes first data to the RFID reader in response to the first data request signal. The method continues with a second RFID sensor receiving a second data request signal from, and sending second data to, the RFID reader. The method continues with the RFID reader sending a representation of the first and second data to a data processing unit, which processes the representation of the first and second data to determine a first and second data point regarding first and second object elements. The method continues by the data processing unit processing the first and second data points to determine an environmental relationship between the first and second object elements.