Abstract
In this work, two fully-textile wearable devices, to be used as chipless identification tags in identification and tracking applications are presented. For the fabrication of the fully-textile tags, a layer of fleece was used as a substrate, while an adhesive non-woven conductive fabric was employed for the conductive parts. To allow radio-frequency identification of these chipless tags, two alternative techniques were used. One relies on associating a binary code with the resonance frequency of resonant devices: the presence/absence of the resonance peaks in the transmission scattering parameter, , of a set of resonators is used to encode a string of bits. The second technique for accomplishing radio-frequency identification of the chipless tags resorts to a frequency-shift coding technique, which is implemented by modifying the configuration of a hairpin resonator. The obtained numerical and experimental results confirm the suitability of the proposed strategies for obtaining entirely-textile, wearable chipless tags for identification and tracking purposes, which can be particularly useful, especially in the industrial sector. In this field, in fact, the proposed solutions would guarantee a seamless integration with clothes and would facilitate the user’s interaction with the IoT infrastructure. In this regard, one of the envisaged application scenarios related to the tracking of hides in the leather industry is also presented.
Highlights
The Internet of Things (IoT) relies on smart environments, equipped with wireless sensor networks [1] and synergistic personal area networks [2,3], in which the user must be uniquely identified, while he/she interacts with the IoT infrastructure
A 0.11 m-thick non-woven conductive fabric (NWCF) was used. This NWCF, which is made of nickel and copper, is manufactured by Saint Gobain company [27]
To analyze possible radiating effects caused by the slots in the ground plane, the far-field and the near-field behaviour of the proposed devices were analyzed through full-wave simulations
Summary
The Internet of Things (IoT) relies on smart environments, equipped with wireless sensor networks [1] and synergistic personal area networks [2,3], in which the user must be uniquely identified, while he/she interacts with the IoT infrastructure. In an industrial IoT sensory environment, the proposed strategies could be implemented to work, for example, as chipless identification tags or, in general, as wearable sensors [17,18,19,20,21,22,23]. Starting from these considerations, in this work, the design, fabrication and characterization of fully-textile, chipless tags for wearable applications are presented. This objective is accomplished by implementing two strategies.
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