An automatic data collection system tracks medical articles by providing a robust electromagnetic (EM) field within an enclosure in which the articles are stored. Respective data carriers, such as RFID tags, attached to each medical article respond to the EM field by transmitting unique data identified with each medical article. The use of probes for injecting the EM field into the enclosure results in a greater likelihood of activation of the tags and greater accuracy in detecting and tracking medical articles.

A system and method for monitoring the inventory of a medical storage container such as a tray that has a required inventory of medical articles. An enclosure is used to isolate, scan, and take an inventory of the tray or other container of medical articles. The tray and each of the medical articles in the tray have RFID tags. The enclosure having a size differing from the size needed for a resonant frequency at the RFID frequency of operation of the tags. A probe is used to create a robust electromagnetic field standing wave of constructive interference in the enclosure and a program compares the scanned present inventory of the tray to the required inventory database and indicates any differences. Expired and recalled articles and substitutes for recalled articles are identified.

An inventory management system for wirelessly taking inventories of medical trays comprises an easily assemblable and disassemblable enclosure comprising interconnected electrically conductive walls to form a Faraday cage. The interior space defined by the walls is large enough to accept the trays. RFID readers are placed within the enclosure directed at the tray to excite and read the RFID tags disposed on the medical articles within the tray. The walls of the enclosure are flexible and one of the walls is rolled up and down to act as an opening to the interior space. A host computer stores the inventory of the tray and compares it against a previous inventory existence for resupply purposes. The host computer also detects expired and recalled medical articles in the tray. If a recalled article is detected, the host computer determines if a substitute article exists.

A wireless data transmitting device comprising a first antenna unit for receiving energy from an alternating electromagnetic field and for converting the energy into an alternating current energy signal and a rectifying unit for converting the alternating current energy signal into a direct current signal. The wireless data transmitting device further comprises a data transmitting unit configured to receive the direct current signal and to generate an aircraft related wireless data signal and a second antenna unit configured to output the aircraft related wireless data signal. Further, a system for wireless data transmission, an aircraft, and a method for wireless data transmission are presented.

A retrofit self-contained RFID-enabling module for automatically identifying and tracking medical articles having RF tags located in a container having electrically-conductive walls includes a base having a probe mounted to the base for injecting activating rf energy into the container in which the module has been mounted. The base also includes a reader board that controls the probe between an injection mode, in which it injects RFID tag activation energy into the container to activate the tags on the medical articles, and a non-injecting mode during which the identification signals of the activated RFID tags on the medical articles can be read. The module is self-contained in that only power is needed to operate. The size of the module, including its components, is selected in relation to the size of the container so that the module may be dropped into the container.

An inventory management system for wirelessly taking inventories of medical trays comprises an easily assemblable and disassemblable enclosure comprising interconnected electrically conductive walls to form a Faraday cage. The interior space defined by the walls is large enough to accept the trays. RFID readers are placed within the enclosure directed at the tray to excite and read the RFID tags disposed on the medical articles within the tray. The walls of the enclosure are flexible and one of the walls is rolled up and down to act as an opening to the interior space. A host computer stores the inventory of the tray and compares it against a previous inventory existence for resupply purposes. The host computer also detects expired and recalled medical articles in the tray. If a recalled article is detected, the host computer determines if a substitute article exists.

A system and method for managing the contents of a medical storage container such as a tray that has a required inventory of medical articles. A Faraday cage enclosure is used to isolate, scan, and inventory the container. The container and each of the medical articles in the container have a respective RFID tag. A processor is programmed to retrieve the inventory list for the container based on its tag and compare the actual contents of the container according to their tags to the inventory list. Missing items and extra items are noted.

An information acquisition system includes an inner wall, an outer wall, and an antenna. The inner wall includes a reflective layer which reflects a radio wave. A reading space is located on an inner side of the reflective layer. Reading of tag information from an RF tag attached to an item is performed in the reading space. The outer wall is disposed on an opposite side of the inner wall from the reading space. The antenna is configured to output the radio wave toward the reading space in order to communicate with the RF tag. Between the inner wall and the outer wall, a peripheral space is provided. The reflective layer of the inner wall has a hole. The hole penetrates through the reflective layer in a thickness direction of the reflective layer.

An RF module and method include a base with a probe, a reader unit, a communications unit, and a control unit that establish tracking activation EM field into a container having electrically-conductive walls. RFID tags attached to medical articles located within the container are activated and produce identification signals. The probe and base receive the identification signals and provide identification data related to medical articles located within the container. The RF module is self-contained excepting power and a data connection with which to operate. Where an Ethernet is used, power is obtained by PoE. The RF module is used to retrofit existing medication containers and may be used during the construction of a new medication container.

Embodiments of the invention pertain to Radio Frequency Identification (RFID) method and system using an antenna array, an array controller, and control algorithms. Embodiments of the invention can induce strong radio-frequency (RF) excitation, for a given level of radiated RF power, at any point within an arbitrary inhomogeneous medium. For RFID applications, one typical inhomogeneous medium is an ensemble of cases on a pallet. Another typical medium is a warehouse environment having stored goods together with shelving and other material present. An embodiment of the invention is applicable to the process of reading battery-less, or passive RFID tags, which rely on incident RF electromagnetic fields established by RFID readers to power the electronic circuitry within the tags.