Your search keyword '"circuits on paper"' showing total 6 results

1. A 24-GHz Single-Transistor Oscillator on Paper.

Author

Palazzi, Valentina, Alimenti, Federico, Zito, Domenico, Mezzanotte, Paolo, and Roselli, Luca

Abstract

This letter describes a single-transistor oscillator implemented on a paper substrate at the operating frequency of 24 GHz, based on a design procedure that makes it possible to overcome the limitations caused by thin high-loss substrates and package parasitics of commercial components. The commercial transistor adopted in the oscillator is led to instability by exploiting its parasitic gate inductance. The drain network compensates for the parasitic inductance of the transistor package and connects the oscillator circuit to a 50- $\Omega $ load resistance. Finally, an external inductor at the source terminal is used to resonate out the capacitive contribution of the circuit at the oscillation frequency. Overall, the active device appears in a quasi-common-drain stage. Experimental results on prototype show that the oscillator exhibits an output power of +6.2 dBm at 24 GHz, with a dc power consumption of 72.5 mW. [ABSTRACT FROM AUTHOR]

Published

2020

2. Analysis of a multi-node system for crack monitoring based on zero-power wireless harmonic transponders on paper

Author

Luca Roselli, Giulia Orecchini, Paolo Mezzanotte, Valentina Palazzi, and Federico Alimenti

Subjects

structural health monitoring, crack sensor, Computer science, business.industry, Internet of Things, 010401 analytical chemistry, 020206 networking & telecommunications, 02 engineering and technology, 01 natural sciences, Circuits on paper, harmonic radar, 0104 chemical sciences, Power (physics), Harmonic analysis, 0202 electrical engineering, electronic engineering, information engineering, Harmonic, Electronic engineering, Wireless, Node (circuits), Structural health monitoring, business, Focus (optics), Wireless sensor network

Abstract

This effort presents an analysis of a system intended for wireless crack sensing and based on zero-power harmonic transponders. The sensors, which are fabricated by using a paper substrate, are suitable for both structural health and supply-chain monitoring. In the text, different techniques to recover information from the proposed tags are firstly explored, with a particular focus on the potentialities and trade-offs of each approach. Then, the impact of the presence of multiple-nodes on the performance of the system is considered and, finally, some proposals for crack localization in presence of multiple tags are explored and experimentally evaluated.

Published

2018

3. Performance analysis of a ultra-compact low-power rectenna in paper substrate for RF energy harvesting

Author

Christos Kalialakis, Luca Roselli, Paolo Mezzanotte, Apostolos Georgiadis, Ana Collado, Federico Alimenti, and Valentina Palazzi

Subjects

energy harvesting, Engineering, Computer Networks and Communications, circuits on paper, Internet of Things, wireless power transfer, Slot antenna, 02 engineering and technology, rectennas, Rectifier, copper laminate technology, 0202 electrical engineering, electronic engineering, information engineering, Wireless power transfer, Instrumentation, Power density, business.industry, 020208 electrical & electronic engineering, Energy conversion efficiency, Electrical engineering, 020206 networking & telecommunications, Rectenna, green electronics, rectifiers, slot antennas, Radio frequency, business, Energy harvesting, Circuits on paper, Copper laminate technology, Green electronics, Rectennas, Rectifiers, Slot antennas

Abstract

In this paper the experimental results of a compact low-power rectenna in paper substrate, designed to operate in the Wi-Fi band, are presented. The complete prototype, based on an annular slot antenna and a single-diode rectifier, features a weight of 1.5 grams and shows an RF-to-dc conversion efficiency in the design band of about 40 % for a -10 dBm available input power, of about 28 % at -15 dBm, and in the range [10, 22] % at -20 dBm, corresponding to an output DC voltage in the order of 320, 240 and 60 mV respectively. Additionally, the rectenna features an efficiency higher then 7 % in the whole band 1.8-2.7 dBm for a power density estimated around 3 μW/cm2.

Published

2017

4. Design of a ultra-compact low-power rectenna in paper substrate for energy harvesting in the Wi-Fi band

Author

Luca Roselli, Christos Kalialakis, Apostolos Georgiadis, Ana Collado, Valentina Palazzi, Paolo Mezzanotte, and Federico Alimenti

Subjects

energy harvesting, Engineering, Anechoic chamber, Computer Networks and Communications, circuits on paper, Internet of Things, wireless power transfer, Energy Engineering and Power Technology, 02 engineering and technology, rectennas, green electronics, 7. Clean energy, Rectifier, copper laminate technology, rectifiers, slot antennas, Electrical and Electronic Engineering, 0202 electrical engineering, electronic engineering, information engineering, Wireless power transfer, Ground plane, business.industry, 020208 electrical & electronic engineering, Electrical engineering, 020206 networking & telecommunications, Power (physics), Rectenna, Antenna (radio), business, Energy harvesting

Abstract

This paper presents the design of a novel rectenna based on a tapered annular slot and a single-diode rectifier, optimized to operate in the Wi-Fi band and in presence of low input power (Pavs=-15 dBm). In order to obtain a compact layout a double-layer architecture has been considered, according to which the interior metal surface of the annular slot is employed as ground plane for the rectifying circuit placed on the other side of the substrate. As a result, a rectenna with an active area of only 40 × 33 mm2 and an efficiency included between 26.5 and 28% has been obtained. The antenna has been fabricated in paper substrate and tested in the anechoic chamber. Then, the rectifier has been designed and optimized within the Advanced Design System suite. Finally, the rectenna performance has been discussed and compared to the State of the Art (SoA).

Published

2016

5. Demonstration of a high dynamic range chipless RFID sensor in paper substrate based on the harmonic radar concept

Author

Federico Alimenti, Marco Virili, Paolo Mezzanotte, Luca Roselli, Chiara Mariotti, Valentina Palazzi, and Giulia Orecchini

Subjects

RFID, Engineering, Wheatstone bridge, Green Electronics, Dynamic range, business.industry, Frequency multiplier, RFID sensor, Circuits on Paper, Electrical engineering, Substrate (printing), Green Electronics, RFID, loT, Circuits on Paper, Harmonic radar, Frequency doubler, Chipless tag, RFID sensor, Signal, loT, law.invention, Chipless RFID, Frequency doubler, law, Electronic engineering, Harmonic, Chipless tag, Harmonic radar, business, Electrical impedance

Abstract

This paper presents the design and implementation in paper substrate of a harmonic RFID chipless sensing tag. The proposed sensor is based on a Wheatstone bridge, where two of the four impedances change dynamically according to a physical parameter that has to be monitored. The passive tag is interrogated by a signal at f 0 = 1.04 GHz and the signal transmitted back to the reader at 2f 0 = 2.08 GHz is proportional to the magnitude of the parameter variation. A harmonic RFID experiment proves that this kind of architecture is capable of providing a dynamic range of more than 40 dB.

Published

2015

6. Demonstration of a chipless harmonic tag working as crack sensor for electronic sealing applications

Author

Marco Virili, Luca Roselli, Valentina Palazzi, Paolo Mezzanotte, Chiara Mariotti, Giulia Orecchini, and Federico Alimenti

Subjects

RFID, Engineering, Computer Networks and Communications, business.industry, Frequency multiplier, RFID, Circuits on paper, Crack sensor, Harmonic radar, Energy Engineering and Power Technology, Filter (signal processing), Signal, Crack sensor, Harmonic, Electronic engineering, Clutter, Radio-frequency identification, Multiplication, Circuits on paper, Electrical and Electronic Engineering, Harmonic radar, business, Photographic paper

Abstract

This work proposes a chipless radio frequency identification approach based on the working principle of the harmonic radar. A frequency multiplication stage is performed by a non-linearity (i.e. a Shottky diode) on the tag in order for the tag answer to be insulated from the interrogation signal, thus avoiding the need for clutter cancellation techniques. Firstly, the performance of a simple one-bit harmonic tag relying on a low-power frequency doubler is analyzed and then a novel crack sensor, implemented by adding a disposable band-stop filter, is presented. Both solutions demonstrate tag-to-reader operational distances beyond 1 m. The characterizing blocks (namely the frequency doubler and the filter) are fabricated on cellulose substrates (i.e. regular photographic paper), thus being conformal to their implementation for applications in the new paradigm of Internet of Things.

Published

2015