Radio Frequency IDentification (RFI

Radio Frequency IDentification (RFID) systems are largely used in practical applications such as anticounterfeiting,
logistics, warehouse management, to efficiently identify, track and manage items. On the basis of the
operating frequency band, it is possible to distinguish two main RFID classes: HF RFID system (13.56 MHz) and UHF
RFID system (865-928 MHz). HF RFID systems are short-range communication systems which can find application in
Item Level Tagging (ILT), in pharmaceutical and retailing industry. Since the tag is powered up through the magnetic
field (inductive coupling), these systems are not susceptible to the presence of liquids or other dielectric and conductive
materials in the tag proximity (loop antennas are typically employed). On the other hand, UHF RFID systems are able
to detect tags at longer distances (up to meters) since reader antenna and tag communicate through electromagnetic
waves. Besides, they are able to transmit a larger amount of data in a shorter time, and small and low-cost tags can be
used, even if they are more susceptible to the presence of surrounding materials. More recently, Near-Field (NF) UHF
RFID systems have been developed for those applications where reader antenna and tags are in the near-field region of
each other [1]-[4]; they keep the typical advantages of UHF RFID systems, with an improved robustness with respect to
the effects of metals and liquids nearby the tag, as in the HF RFID systems. While a large number of antenna solutions
have been proposed in the open literature for UHF RFID systems oriented to far-field applications (e.g. patch antennas
[5], slot antennas [6] and inverted-F meandered dipoles [7]), the near-field antenna design appears more challenging.
Indeed, differently from conventional far-field antennas, near-field antennas have to be able to confine the
electromagnetic field in proximity of the antenna, by generating a strong and uniform electromagnetic field in the whole
interrogation area just above the antenna surface. Different antenna technologies can be adopted, depending on the
specific application. As for example, in RFID portals a near-field focused array [8]-[11] can be adopted to get a few
meters read range, while in RFID desktop readers, a segmented loop antenna [12]-[13] or a travelling wave antenna
[14]-[18] can be designed to have a read range less than a few tens of cm. In the framework of UHF RFID desktop
reader applications, it is worth noting that, the item material the tag is attached to and the mutual coupling among tags
in a stacked configuration can compromise the tags readability and reduce the read range. For this reason, it could beuseful to design desktop reader antennas that in unloaded condition exhibit a read range larger than that required in real
operational conditions. Also, reconfigurable antennas can be considered, which allow for a shaping of the interrogation
field in the antenna near-field region, when a simple control of the reader output power is not enough to guarantee high
reading percentages on the whole antenna surface and for any tagged item and tag topology/orientation.