Your search keyword '"Palazzi, Valentina"' showing total 22 results

1. On UAV Terrestrial Connectivity Enhancement through Smart Selective Antennas.

Author

Pagliari, Emanuele, Davoli, Luca, Cicioni, Giordano, Palazzi, Valentina, and Ferrari, Gianluigi

Published

2024

2. Biomaterial Inks from Peptide-Functionalized Silk Fibers for 3D Printing of Futuristic Wound-Healing and Sensing Materials.

Author

Ceccarini, Maria Rachele, Palazzi, Valentina, Salvati, Raffaele, Chiesa, Irene, De Maria, Carmelo, Bonafoni, Stefania, Mezzanotte, Paolo, Codini, Michela, Pacini, Lorenzo, Errante, Fosca, Rovero, Paolo, Morabito, Antonino, Beccari, Tommaso, Roselli, Luca, and Valentini, Luca

Subjects

*SILK fibroin, *PEPTIDES, *SCHOTTKY barrier diodes, *SILK, *THREE-dimensional printing, *CELL adhesion, *PLATELET-rich plasma, *FIBERS

Abstract

This study illustrates the sensing and wound healing properties of silk fibroin in combination with peptide patterns, with an emphasis on the printability of multilayered grids, and envisions possible applications of these next-generation silk-based materials. Functionalized silk fibers covalently linked to an arginine–glycine–aspartic acid (RGD) peptide create a platform for preparing a biomaterial ink for 3D printing of grid-like piezoresistors with wound-healing and sensing properties. The culture medium obtained from 3D-printed silk fibroin enriched with RGD peptide improves cell adhesion, accelerating skin repair. Specifically, RGD peptide-modified silk fibroin demonstrated biocompatibility, enhanced cell adhesion, and higher wound closure rates at lower concentration than the neat peptide. It was also shown that the printing of peptide-modified silk fibroin produces a piezoresistive transducer that is the active component of a sensor based on a Schottky diode harmonic transponder encoding information about pressure. We discovered that such biomaterial ink printed in a multilayered grid can be used as a humidity sensor. Furthermore, humidity activates a transition between low and high conductivity states in this medium that is retained unless a negative voltage is applied, paving the way for utilization in non-volatile organic memory devices. Globally, these results pave the way for promising applications, such as monitoring parameters such as human wound care and being integrated in bio-implantable processors. [ABSTRACT FROM AUTHOR]

Published

2023

3. The MTT-S Technical Coordinating and Future Directions Committee: Promoting Our Technical Communities-2022.

Author

Palazzi, Valentina, Schreurs, Dominique, and Caverly, Robert

Abstract

Reports on news of interest to MMTS society members. [ABSTRACT FROM AUTHOR]

Published

2022

4. MTT-S Technical Committee 26 Report [MTT-S Society News].

Author

Tedjini, Smail, Palazzi, Valentina, and Zannas, Konstantinos

Published

2022

5. Compact 3-D-Printed 4 × 4 Butler Matrix Based on Low-Cost and Curing-Free Additive Manufacturing.

Author

Palazzi, Valentina, Cicioni, Arianna, Alimenti, Federico, Mezzanotte, Paolo, Tentzeris, Manos M., and Roselli, Luca

Abstract

This letter presents a $4 \times 4$ Butler matrix realized using stereolithography 3-D printing technology and liquid metal filling. The matrix is in coaxial technology and relies on circular branch lines and curved $50~\Omega $ lines. Input and output ports are aligned and placed on the same plane, while branch lines are organized using all three dimensions to minimize the length of the connecting lines. A prototype, designed at an operating frequency of 12 GHz, is manufactured and tested, showing a footprint of only $1.7\times 1.3\,\,\lambda _{0}^{2}$. A good agreement between simulated and measured transmission coefficients is observed regardless of the selected input port. These encouraging results open the door to the realization of compact low-cost and high-performing RF beam-steering networks in coaxial technology, based on curing-free additive manufacturing processes. [ABSTRACT FROM AUTHOR]

Published

2021

6. Self‐adhesive plasticized regenerated silk on poly(3‐hydroxybutyrate‐co‐3‐hydroxyvalerate) for bio‐piezoelectric force sensor and microwave circuit design.

Author

Bittolo Bon, Silvia, Valentini, Luca, Degli Esposti, Micaela, Morselli, Davide, Fabbri, Paola, Palazzi, Valentina, Mezzanotte, Paolo, and Roselli, Luca

Subjects

MICROWAVE circuits, DETECTOR circuits, BIODEGRADABLE materials, PIEZOELECTRIC detectors, BIOMEDICAL materials

Abstract

This study shows that regenerated silk (RS), a natural biodegradable and biocompatible polymer, can behave as a self‐adhesive thermoplastic material with multifunctional properties. In particular, Ca ions‐plasticized RS hybrids with gold nanorods have been produced. It has been found that at mild conditions of temperature and pressure, RS hybrids undergo to the loss of the β‐sheet content and forms a tough self‐adhesive material on poly(3‐hydroxybutyrate‐co‐3‐hydroxyvalerate) (PHBV) substrate. The structure‐dependent piezoelectricity of such RS adhesives on PHBV films was investigated and it was demonstrated that this forms a RS/PHBV piezoelectric sensor that can be used for the monitoring of force. The constitutive parameters (i.e., permittivity and loss tangent) of both PHBV and RS/PHBV were measured in view of their use as dielectric substrates in microwave circuit design. Being fully made of biodegradable and biocompatible materials, this self‐adhesive material can be used in tissue engineering for different applications. [ABSTRACT FROM AUTHOR]

Published

2021

7. Novel Magnitude and Phase Reconfigurable 1 × 4 RF Power Distribution Network.

Author

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

Subjects

*POWER distribution networks, *POWER dividers, *PHASE shifters, *TRANSMISSION line matrix methods, *INSERTION loss (Telecommunication), *RADIO frequency, *RADIO frequency allocation

Abstract

This article presents a new circuit topology for a highly reconfigurable $1\times 4$ radio frequency network that, for a given input, is able to modify magnitude and phase relations among its output signals with great flexibility while preserving matching at all ports. The circuit, based on a four-way power divider, four hybrid couplers, and eight variable phase shifters, is first theoretically analyzed. It is shown that magnitude and phase relations among signals at the output ports can be modified just by changing the state of the variable phase shifters, while the sum of the squared magnitude of the transmission coefficients of the network is always equal to one. For the specific purpose of the experimental validation of the developed theory, a particular version of the network, working at 3.6 GHz, is then designed and tested. All configurations are affected by the same insertion loss, depending on the adopted phase-shifting technology. The obtained results show the potential of the conceived circuit and testify its unprecedented degree of reconfigurability. [ABSTRACT FROM AUTHOR]

Published

2021

8. 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

9. Noncontact Measurement of River Surface Velocity and Discharge Estimation With a Low-Cost Doppler Radar Sensor.

Author

Alimenti, Federico, Bonafoni, Stefania, Gallo, Elisa, Palazzi, Valentina, Vincenti Gatti, Roberto, Mezzanotte, Paolo, Roselli, Luca, Zito, Domenico, Barbetta, Silvia, Corradini, Cristiano, Termini, Donatella, and Moramarco, Tommaso

Subjects

DOPPLER radar, WATER depth, COMPUTING platforms, VELOCITY, RIVERS

Abstract

River discharge is an important variable to measure in order to predict droughts and flood occurrences. Once the cross-sectional geometry of the river is known, discharge can be inferred from water level and surface flow velocity measurements. Since river discharges are of particular interest during extreme weather events, when river sites cannot be safely accessed, noncontact sensing technologies are particularly appealing. To this purpose, this work proposes a prototype of a low-cost continuous wave (CW) Doppler radar sensor, which is able to monitor the surface flow velocity of rivers. The prototype is tested at two gauged sites in central Italy, along the Tiber River. The surface flow velocity distribution across the river is monitored by means of the analysis of received Doppler signal. The surface velocity statistics are then extracted using a novel algorithm that is optimized to run on a microprocessor platform with minimal computing power (ArduinoUNO). In particular, the radar measurements are used to initialize a 2-D entropy-based velocity model (EVM) that is able to estimate river discharges in any flow condition. Finally, the results concerning the observed discharge provided by the EVM prove to be comparable with those obtained with more expensive commercial solutions. The results are important since the described methodology can be extended to small-size Doppler radar sensors onboard unmanned aerial vehicles (UAVs), the latter providing a method for mapping surface velocity of rivers. [ABSTRACT FROM AUTHOR]

Published

2020

10. Feeding the World With Microwaves: How Remote and Wireless Sensing Can Help Precision Agriculture.

Author

Palazzi, Valentina, Bonafoni, Stefania, Alimenti, Federico, Mezzanotte, Paolo, and Roselli, Luca

Abstract

Precision agriculture is an increasingly hot topic. The world population is in constant growth [1], which means that global food production needs to rise to keep pace with the projected demand. Although food production has increased by 100% in the last 30 years, it must rise by another 60% by 2050 to reduce the risk of malnutrition. This can be achieved only by improving productivity because, globally, the cultivated area is slowly contracting [2], thus drastically reducing the amount of arable land per person. [ABSTRACT FROM AUTHOR]

Published

2019

11. 3-D-Printing-Based Selective-Ink-Deposition Technique Enabling Complex Antenna and RF Structures for 5G Applications up to 6 GHz.

Author

Palazzi, Valentina, Su, Wenjing, Bahr, Ryan, Bittolo-Bon, Silvia, Alimenti, Federico, Mezzanotte, Paolo, Valentini, Luca, Tentzeris, Manos M., and Roselli, Luca

Subjects

*SLOT antennas, *ANTENNAS (Electronics), *THREE-dimensional printing, *REFLECTANCE, *BROADBAND antennas, *CAD/CAM systems

Abstract

This paper introduces a novel additive-manufacturing technique to obtain high-resolution selective-ink-deposition on complex 3-D objects, packages, and modules for 5G applications. The technique consists of embossing the desired pattern directly on the 3-D printed dielectric surface and then applying ink with a suitable tool. This approach is tested in combination with stereolithography 3-D printing technology to obtain selectively metallized 3-D circuits. In particular, the “clear” resin from FormLab is utilized for the 3-D printed dielectric, while the metallization is performed with silver nanoparticle ink from Suntronic. As a preliminary study, test samples containing lines with different widths are manufactured, demonstrating a pitch down to $135~\mu \text {m}$ and satisfactory sheet resistance of $0.011~\Omega /\text {sq.}$ (the electromagnetic characterization of the dielectric resin is reported in the Appendix). Then, two broadband multiport RF structures are developed to show the versatility of the proposed technology. First, an ultrawideband 3-D crossover, operating in the range 100 MHz–5 GHz, is conceived to test the suitability of the proposed technology to perform selective metallization on curved semienclosed areas. Then, the technology is applied to a multiple-input–multiple-output (MIMO) antenna system, based on four proximity-fed annular slot antennas, arranged on the lateral sides of a cube and decoupled by introducing a cross-shaped structure in the interior of the cube. This circuit offers a broad range of metallization challenges, as it features embossed and engraved parts, high-resolution patterns (line widths down to 0.7 mm) and sharp edges. Each slot radiates unidirectionally with the same polarization and uses the cube and its internal cross-shaped structure as a resonant cavity. The antenna system is designed to operate in the band 3.4–3.8 GHz, which is one of the sub-6-GHz 5G bands in Europe, and it is thought for hotspot and access-point applications. The final antenna topology is composed of only two blocks, weighs 21.29 g, and occupies a volume of $44.4\times 45.8\times 45.8\,\,\text {mm}^{3}$ , featuring an envelope correlation coefficient (ECC) lower than 0.005 and a total active reflection coefficient (TARC) lower than −6 dB in all the bands of interests. [ABSTRACT FROM AUTHOR]

Published

2019

12. Smart Hardware for Smart Objects: Microwave Electronic Circuits to Make Objects Smart.

Author

Alimenti, Federico, Palazzi, Valentina, Mariotti, Chiara, Mezzanotte, Paolo, Correia, Ricardo, Borges Carvalho, Nuno, and Roselli, Luca

Abstract

Let?s conform electronics to objects! Up to now, the most common approach has been exactly the opposite: the size, weight, and shape of the electronic devices around us have been conformed to the electronics. However, the Internet of Things (IoT) vision will necessarily lead to a paradigm shift, where the electronics need to conform to the objects. [ABSTRACT FROM AUTHOR]

Published

2018

13. A Novel Ultra-Lightweight Multiband Rectenna on Paper for RF Energy Harvesting in the Next Generation LTE Bands.

Author

Palazzi, Valentina, Hester, Jimmy, Bito, Jo, Alimenti, Federico, Kalialakis, Christos, Collado, Ana, Mezzanotte, Paolo, Georgiadis, Apostolos, Roselli, Luca, and Tentzeris, Manos M.

Subjects

*BROADBAND antennas, *RECTENNAS, *LONG-Term Evolution (Telecommunications), *RADIO frequency power transmission, *ENERGY harvesting, *SLOT antennas, *EQUIPMENT & supplies

Abstract

This paper introduces a novel compact ultralightweight multiband RF energy harvester fabricated on a paper substrate. The proposed rectenna is designed to operate in all recently released LTE bands (range 0.79–0.96 GHz; 1.71–2.17 GHz; and 2.5–2.69 GHz). High compactness and ease of integration between antenna and rectifier are achieved by using a topology of nested annular slots. The proposed rectifier features an RF-to-dc conversion efficiency in the range of 5%–16% for an available input power of −20 dBm in all bands of interest, which increases up to 11%–30% at −15 dBm. The rectenna has been finally tested both in laboratory and in realistic scenarios featuring a superior performance to other state-of-the-art RF harvesters on flexible substrates. [ABSTRACT FROM PUBLISHER]

Published

2018

14. A 24-GHz Front-End Integrated on a Multilayer Cellulose-Based Substrate for Doppler Radar Sensors.

Author

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

Abstract

This paper presents a miniaturized Doppler radar that can be used as a motion sensor for low-cost Internet of things (IoT) applications. For the first time, a radar front-end and its antenna are integrated on a multilayer cellulose-based substrate, built-up by alternating paper, glue and metal layers. The circuit exploits a distributed microstrip structure that is realized using a copper adhesive laminate, so as to obtain a low-loss conductor. The radar operates at 24 GHz and transmits 5 mW of power. The antenna has a gain of 7.4 dBi and features a half power beam-width of 48 degrees. The sensor, that is just the size of a stamp, is able to detect the movement of a walking person up to 10 m in distance, while a minimum speed of 50 mm/s up to 3 m is clearly measured. Beyond this specific result, the present paper demonstrates that the attractive features of cellulose, including ultra-low cost and eco-friendliness (i.e., recyclability and biodegradability), can even be exploited for the realization of future high-frequency hardware. This opens opens the door to the implementation on cellulose of devices and systems which make up the “sensing layer” at the base of the IoT ecosystem. [ABSTRACT FROM AUTHOR]

Published

2017

15. Scavenging for Energy: A Rectenna Design for Wireless Energy Harvesting in UHF Mobile Telephony Bands.

Author

Palazzi, Valentina, Del Prete, Massimo, and Fantuzzi, Marco

Abstract

The development of distributed and ubiquitous electronic devices is an achievement of modern technology that has the potential to revolutionize many aspects of human life. Such electronic devices are being employed not only in consumer areas like home automation, intelligent transportation systems, and personal entertainment but also for health-care applications, such as noninvasive biomedical parameter monitoring, as well as industrial and military applications. [ABSTRACT FROM PUBLISHER]

Published

2017

16. Design of planar resonators on flexible substrate for chipless tags intended for crack sensing.

Author

Rodrigues, Raquel Aline A., Gurjao, Edmar Candeia, de Assis, Francisco M., Palazzi, Valentina, Alimenti, Federico, Roselli, Luca, Mezzanotte, Paolo, and Tedjini, Smail

Published

2015

17. 24-GHz CW radar front-ends on cellulose-based substrates: A new technology for low-cost applications.

Author

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

Published

2015

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

Author

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

Published

2015

19. Communication and Sensing Circuits on Cellulose.

Author

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

Subjects

DETECTOR circuits, GREEN electronics, INTERNET of things

Abstract

This paper proposes a review of several circuits for communication and wireless sensing applications implemented on cellulose-based materials. These circuits have been developed during the last years exploiting the adhesive copper laminate method. Such a technique relies on a copper adhesive tape that is shaped by a photo-lithographic process and then transferred to the hosting substrate (i.e., paper) by means of a sacrificial layer. The presented circuits span from UHF oscillators to a mixer working at 24 GHz and constitute an almost complete set of building blocks that can be applied to a huge variety communication apparatuses. Each circuit is validated experimentally showing performance comparable with the state-of-the-art. This paper demonstrates that circuits on cellulose are capable of operating at record frequencies and that ultra- low cost, green i.e., recyclable and biodegradable) materials can be a viable solution to realize high frequency hardware for the upcoming Internet of Things (IoT) era. [ABSTRACT FROM AUTHOR]

Published

2015

20. Energy-Efficient Harmonic Transponder Based on On-Off Keying Modulation for Both Identification and Sensing.

Author

Palazzi, Valentina, Roselli, Luca, Tentzeris, Manos M., Mezzanotte, Paolo, and Alimenti, Federico

Subjects

*TRANSPONDERS, *AMPLITUDE modulation, *SQUARE waves, *TEST systems, *METAL oxide semiconductor field-effect transistors, *ANTENNAS (Electronics)

Abstract

This paper presents a novel passive Schottky-diode frequency doubler equipped with an on-off keying (OOK) modulation port to be used in harmonic transponders for both identification and sensing applications. The amplitude modulation of the second-harmonic output signal is achieved by driving a low-frequency MOSFET, which modifies the dc impedance termination of the doubler. Since the modulation signal is applied to the gate port of the transistor, no static current is drained. A proof-of-concept prototype was manufactured and tested, operating at 1.04 GHz. An on/off ratio of 23 dB was observed in the conversion loss of the doubler for an available input power of −10 dBm. The modulation port of the circuit was excited with a square wave ( f m up to 15 MHz), and the measured sidebands in the spectrum featured a good agreement with the theory. Then, the doubler was connected to a harmonic antenna system and tested in a wireless experiment for f m up to 1 MHz, showing an excellent performance. Finally, an experiment was conducted where the output signal of the doubler was modulated by a reed switch used to measure the rotational speed of an electrical motor. This work opens the door to a new class of frequency doublers, suitable for ultra low-power harmonic transponders for identification and sensing applications. [ABSTRACT FROM AUTHOR]

Published

2022

21. Low-Power Frequency Doubler in Cellulose-Based Materials for Harmonic RFID Applications.

Author

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

Abstract

This letter presents the design of a Schottky diode frequency doubler suitable for harmonic RFID tags. A microwave frequency doubler is implemented in a cellulose-based (paper) substrate, i.e., an ultra-low cost, recyclable and biodegradable material. The circuit exploits a distributed microstrip structure that is fabricated using a copper adhesive laminate to have low conductor losses. The measurements show a conversion loss of 13.4 dB at the output frequency of 2.08 GHz. This is achieved with an available input power of -10 dBm only. Finally a harmonic RFID experiment proves a reading range of 50 cm, obtained by transmitting 0 dBm and receiving a second harmonic of -60 dBm, i.e., well above the sensitivity of a typical microwave receiver. [ABSTRACT FROM PUBLISHER]

Published

2014

22. K/Ka-Band Very High Data-Rate Receivers: A Viable Solution for Future Moon Exploration Missions.

Author

Alimenti, Federico, Mezzanotte, Paolo, Roselli, Luca, Palazzi, Valentina, Bonafoni, Stefania, Vincenti Gatti, Roberto, Rugini, Luca, Baruffa, Giuseppe, Frescura, Fabrizio, Banelli, Paolo, Bernardi, Federico, Gemma, Fabrizio, Nannetti, Gianni, Gervasoni, Paolo, Glionna, Paolo, Pagana, Enrico, Gotti, Giambattista, Petrini, Paolo, Coromina, Francesc, and Pergolesi, Federico

Subjects

LUNAR exploration, QUADRATURE phase shift keying, FIELD programmable gate arrays, MICROWAVE circuits, SYSTEM analysis, MILANKOVITCH cycles

Abstract

This paper presents a feasibility study for a very high data rate receiver operating in the K/Ka-band suitable to future Moon exploration missions. The receiver specifications are outlined starting from the mission scenario and from a careful system analysis. The designed architecture uses a low noise front-end to down-convert the incoming K/Ka-band signal into a 3.7 GHz intermediate frequency (IF). For maximum flexibility, a software defined radio (SDR) is adopted for the I/Q demodulation and for the analog to digital conversion (ADC). The decoding operations and the data interface are carried out by a processor based on field programmable gate array (FPGA) circuits. To experimentally verify the above concepts, a preliminary front-end breadboard is implemented, operating between 27.5 and 30 GHz. The breadboard, which uses components off the shelf (COTS) and evaluation boards (EVBs), is characterized by a 46 dB gain, a 3.4 dB noise figure and a − 37 dBm input-referred 1 dB compression point. Finally, a 40 Msym / s quadrature phase shift keying (QPSK) signal is demodulated by means of a commercially available SDR, demonstrating the above concept. The importance of these results is that they have been obtained exploiting a class of miniaturized and low cost microwave integrated circuits currently available on the market, opening the way to a dense communication infrastructure on cislunar space. [ABSTRACT FROM AUTHOR]

Published

2019