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Journal Articles
- 2024
- [j37]Giovanna Di Pasquale, Salvatore Graziani
, Antonino Pollicino
Pullulan-1-Ethyl-3-Methylimidazolium Tetrafluoroborate Composite as a Water-Soluble Active Component of a Vibration Sensor. Sensors 24(4): 1176 (2024) - [j36]Carlo Trigona, Sara Panebianco, Rosaria Galvagno
Bubble Sensors for Temperature Measurements through a Colorimetric Approach. Sensors 24(4): 1278 (2024) - [j35]Slim Naifar
Energy Harvesting Technologies and Applications for the Internet of Things and Wireless Sensor Networks. Sensors 24(14): 4688 (2024) - [j34]Claudia Pirrotta
Vibration Analysis at Castello Ursino Picture Gallery (Sicily, Italy) for the Implementation of Self-Generating AlN-MEMS Sensors. Sensors 24(17): 5617 (2024) - 2023
- [j33]Carlo Trigona:
Living Sensors: The Greenest Paradigm in Instrumentation and Measurements. IEEE Instrum. Meas. Mag. 26(1): 35-41 (2023) - [j32]Carlo Trigona, Olfa Kanoun:
Guest Editorial: Special Issue on "Energy Harvesting in the Instrumentation and Measurement Framework". IEEE Instrum. Meas. Mag. 26(3): 3-4 (2023) - [j31]Carlo Trigona
A "Living Sensor" Based on Sansevieria Plant for Measurement of UV-A Radiation. IEEE Trans. Instrum. Meas. 72: 1-10 (2023) - 2022
- [j30]Rym Chéour
Towards Hybrid Energy-Efficient Power Management in Wireless Sensor Networks. Sensors 22(1): 301 (2022) - [j29]Grzegorz Litak
On Theoretical and Numerical Aspects of Bifurcations and Hysteresis Effects in Kinetic Energy Harvesters. Sensors 22(1): 381 (2022) - [j28]Gabriel Barrientos
Lead-Free LiNbO3 Thick Film MEMS Kinetic Cantilever Beam Sensor/Energy Harvester. Sensors 22(2): 559 (2022) - [j27]Jerzy Margielewicz
Nonlinear Dynamics of a Star-Shaped Structure and Variable Configuration of Elastic Elements for Energy Harvesting Applications. Sensors 22(7): 2518 (2022) - [j26]Carlo Trigona, Eliana Costa, Giuseppe Politi, Anna Maria Gueli
IoT-Based Microclimate and Vibration Monitoring of a Painted Canvas on a Wooden Support in the Monastero of Santa Caterina (Palermo, Italy). Sensors 22(14): 5097 (2022) - 2021
- [j25]Giovanna Di Pasquale, Salvatore Graziani
Investigation on the Role of Ionic Liquids in the Output Signal Produced by Bacterial Cellulose-Based Mechanoelectrical Transducers. Sensors 21(4): 1295 (2021) - [j24]Salvatore Baglio
Conception of a Temperature Sensor Based on 100-μm CoFeSiB Ferromagnetic Wire. IEEE Trans. Instrum. Meas. 70: 1-8 (2021) - [j23]Nunzio Cennamo
Green LSPR Sensors Based on Thin Bacterial Cellulose Waveguides for Disposable Biosensor Implementation. IEEE Trans. Instrum. Meas. 70: 1-8 (2021) - [j22]Ada Fort
An AlN Micromachined Mass Sensor: Modeling and Characterization. IEEE Trans. Instrum. Meas. 70: 1-13 (2021) - 2020
- [j21]Carlo Trigona, Valentina Sinatra, Bruno Andò, Salvatore Baglio
RTD-Fluxgate magnetometers for detecting iron accumulation in the brain. IEEE Instrum. Meas. Mag. 23(1): 7-13 (2020) - [j20]Carlo Trigona, Salvatore Graziani, Salvatore Baglio:
Changes in sensors technologies during the last ten years: Evolution or revolution? IEEE Instrum. Meas. Mag. 23(6): 18-22 (2020) - [j19]Carlo Trigona, Salvatore Graziani, Giovanna Di Pasquale, Antonino Pollicino
Green Energy Harvester from Vibrations Based on Bacterial Cellulose. Sensors 20(1): 136 (2020) - [j18]Marko Gazivoda
Passive Extraction of Signal Feature Using a Rectifier with a Mechanically Switched Inductor for Low Power Acoustic Event Detection. Sensors 20(18): 5445 (2020) - [j17]Carlo Trigona
Characterization of a PiezoMUMPs Microsensor for Contactless Measurements of DC Electrical Current. IEEE Trans. Instrum. Meas. 69(4): 1387-1396 (2020) - [j16]Giovanna Di Pasquale
Performance Characterization of a Biodegradable Deformation Sensor Based on Bacterial Cellulose. IEEE Trans. Instrum. Meas. 69(5): 2561-2569 (2020) - [j15]Ada Fort, Enza Panzardi, Valerio Vignoli, Elia Landi
Performance Analysis of a Humidity Sensor Based on a Microresonator Functionalized With TiO2 Nanoparticles. IEEE Trans. Instrum. Meas. 69(10): 7999-8008 (2020) - 2019
- [j14]Giovanna Di Pasquale, Salvatore Graziani, Antonino Pollicino
The evolution of ionic polymer metal composites towards greener transducers. IEEE Instrum. Meas. Mag. 22(5): 30-35 (2019) - [j13]Carlo Trigona, Ammar Al-Hamry
Analysis of a Hybrid Micro-Electro-Mechanical Sensor Based on Graphene Oxide/Polyvinyl Alcohol for Humidity Measurements. Sensors 19(7): 1720 (2019) - [j12]Roberto La Rosa
Strategies and Techniques for Powering Wireless Sensor Nodes through Energy Harvesting and Wireless Power Transfer. Sensors 19(12): 2660 (2019) - [j11]Nunzio Cennamo
An Eco-Friendly Disposable Plasmonic Sensor Based on Bacterial Cellulose and Gold. Sensors 19(22): 4894 (2019) - 2018
- [j10]Carlo Trigona, Valentina Sinatra, Bruno Andò, Salvatore Baglio
Measurements of Iron Compound Content in the Brain Using a Flexible Core Fluxgate Magnetometer at Room Temperature. IEEE Trans. Instrum. Meas. 67(4): 971-980 (2018) - 2017
- [j9]Carlo Trigona, Valentina Sinatra, Bruno Andò, Salvatore Baglio
Flexible Microwire Residence Times Difference Fluxgate Magnetometer. IEEE Trans. Instrum. Meas. 66(3): 559-568 (2017) - [j8]Carlo Trigona, Bruno Andò, Salvatore Baglio
Sensors for Kinetic Energy Measurement Operating on "Zero-Current Standby". IEEE Trans. Instrum. Meas. 66(4): 812-820 (2017) - [j7]Carlo Trigona
Performance Measurement Methodologies and Metrics for Vibration Energy Scavengers. IEEE Trans. Instrum. Meas. 66(12): 3327-3339 (2017) - 2016
- [j6]Carlo Trigona
Fabrication and Characterization of an MOEMS Gyroscope Based on Photonic Bandgap Materials. IEEE Trans. Instrum. Meas. 65(12): 2840-2852 (2016) - 2014
- [j5]Carlo Trigona, Bruno Andò, Salvatore Baglio
Design, Fabrication, and Characterization of BESOI-Accelerometer Exploiting Photonic Bandgap Materials. IEEE Trans. Instrum. Meas. 63(3): 702-710 (2014) - 2011
- [j4]Salvatore Baglio
Exploiting Nonlinear Dynamics in Novel Measurement Strategies and Devices: From Theory to Experiments and Applications. IEEE Trans. Instrum. Meas. 60(3): 667-695 (2011) - [j3]Bruno Andò, Salvatore Baglio
Cascaded "Triple-Bent-Beam" MEMS Sensor for Contactless Temperature Measurements in Nonaccessible Environments. IEEE Trans. Instrum. Meas. 60(4): 1348-1357 (2011) - [j2]Bruno Andò, Salvatore Baglio
A BE-SOI MEMS for Inertial Measurement in Geophysical Applications. IEEE Trans. Instrum. Meas. 60(5): 1901-1908 (2011) - 2010
- [j1]Bruno Andò, Salvatore Baglio
Autonomous sensors: From standard to advanced solutions [Instrumentation notes]. IEEE Instrum. Meas. Mag. 13(3): 33-37 (2010)
Conference and Workshop Papers
- 2024
- [c86]Santhosh Kurukunda, Salvatore Cerruto, Salvatore Graziani, Carlo Trigona, Giovanna Di Pasquale, Antonino Pollicino, Kaija Põhako-Esko, Alvo Aabloo:
Characterization and Comparison of Bacterial Cellulose/Choline Malonate/EMIM-BF4 Accelerometers. SSD 2024: 1-4 - [c85]Carlo Trigona, Giuliano A. Salerno, Alireza Mehdi, Anna Maria Gueli, Giuseppe Politi:
Artwork Transport Tracking: Empowering Reliability Through Smart Packaging. SSD 2024: 148-152 - [c84]Anna Maria Gueli, Sebastiano Imposa, Barbara Mancuso, Valter Pinto, Claudia Pirrotta
Castello Ursino Museum's Structural Monitoring Enhanced by Self-Energized Solutions. SSD 2024: 292-297 - [c83]Carlo Trigona, Serena Rapisarda, Sebastiano D'Amico, Alfred Micallef, Anna Maria Gueli:
St. Catherine's Church, Valletta, Malta: A Self-Powered Measurement System for Preventive Conservation. SSD 2024: 298-303 - [c82]Carlo Trigona, Sara Panebianco, Rosaria Galvagno, Anna Maria Gueli:
Colorimetric Bubble Sensors Tailored for Temperature Measurements. SSD 2024: 664-668 - [c81]Achraf Derbel, Carlo Trigona, Noura Baccar:
Fuzzy Logic Empowerment for Thermoelectric Transducer Performance Optimization. SSD 2024: 681-687 - [c80]Achraf Derbel, Carlo Trigona, Noura Baccar, Nabil Derbel:
Universal Approximator Approach for Fuzzy Modeling in Thermoelectric Generator. SSD 2024: 688-693 - [c79]Claudia Ferro, Mario Urso, Salvatore Mirabella, Carlo Trigona, Adi R. Bulsara, Salvatore Baglio:
The Residence Times Difference (RTD) Ring Fluxgate Magnetometer. I2MTC 2024: 1-6 - [c78]Alessandro Spalletta, Gianluca Caposciutti, Mirko Marracci, Bernardo Tellini, Carlo Trigona, Salvatore Baglio:
Assessing Mechanical Stress Effects on CoFeSiB Microwires: Modeling and Preliminary Characterization. I2MTC 2024: 1-6 - [c77]Carlo Trigona, Giuliano A. Salerno, Iman Arjmandmanesh, Saad Bin Meraj, Salvatore Baglio, Adi R. Bulsara:
Unveiling Botanical Piezo-Tribo Energy Harvesting for Autonomous Measurement Systems. I2MTC 2024: 1-6 - [c76]Carlo Trigona, Mairaj Wali, Carmelo Finocchiaro, Giovanna Di Pasquale, Salvatore Graziani, Antonino Pollicino:
Dissolvable Piezo-Ionic Pullulan Sensor for Measurements of Applied Deformation. I2MTC 2024: 1-5 - [c75]Carlo Trigona, Suhail Ahmed Almani, Alireza Mehdi, Giuliano A. Salerno, Vincenzina Strano, Ausrine Bartasyte, Samuel Margueron, Salvatore Baglio, Quentin Micard:
Delving into Conversion Effects in 0.5 µm Thin Film Aluminum Nitride MEMS Devices. ROSE 2024: 1-5 - 2023
- [c74]Carlo Trigona, Davide Di Maria, Eusebio Belfiore, Giuseppe Faranda, Anna Maria Gueli, Nunzio Salerno, Salvatore Baglio, Adi R. Bulsara:
Soil-based Sensor for Measurements of Static Magnetic Field. SSD 2023: 218-222 - [c73]Carlo Trigona, Angelo Gresti, Adrian Pirosca Valeriu, Rosaria Galvagno, Sara Panebianco, Emanuele Di Miceli, Salvatore Baglio:
Modeling and Characterization of a Hydroelectric Transducer for Energy Harvesting Applications. SSD 2023: 531-536 - [c72]Carlo Trigona, Barbara Mancuso, Valter Pinto, Muhammad Mujtaba, Serena Rapisarda, Anna Maria Gueli:
Structural Holding Monitoring and Microclimate Measurements in Museum Showcases. SSD 2023: 734-738 - [c71]Gianluca Caposciutti, Alessandro Spalletta, Mirko Marracci, Bernardo Tellini, Carlo Trigona, Salvatore Baglio:
Force sensing utilizing a CoFeSiB microwire: a preliminary experimental study. I2MTC 2023: 1-6 - [c70]Santhosh Kurukunda, Salvatore Graziani, Carlo Trigona, Giovanna Di Pasquale, Antonino Pollicino
A Comparative Investigation of Deformation Transducers Based on Bacterial Cellulose and Different Ionic Liquids. I2MTC 2023: 1-5 - [c69]Claudia Ferro
The "Serpentine" RTD Fluxgate Magnetometer. SAS 2023: 1-4 - 2022
- [c68]Kholoud Hamza, Ghada Bouattour, Carlo Trigona, Roberto La Rosa, Salvatore Baglio, Ahmed Fakhfakh, Olfa Kanoun:
A Combination of Energy Harvesting and Wireless Power Transfer for Applications in Harsh Environments. SSD 2022: 864-869 - [c67]Carlo Trigona, Erika Costa, Nicolò Cascone, Salvatore Baglio:
Energy Harvesting from Rose of Jericho Movements. SSD 2022: 1288-1291 - [c66]Dhouha El Houssaini, Carlo Trigona, Abdallah Adawi
Benchmarking a Sensor-less Kinetic Transducer for Inertial Measurement Unit for Industrial IoT Applications. CIVEMSA 2022: 1-6 - [c65]Carlo Trigona, Caterina Cunsolo, Giuseppe Di Luca Cardillo, Michael Rizza, Salvatore Baglio:
Exploitation of a Spider Silk based Sensing Element. I2MTC 2022: 1-5 - [c64]Carlo Trigona, Tianqi Lu
MEMS based on Chitosan - Tetrasulfonated Copper Phthalocyanine Composite for Detection of Ethanol Vapor in Air. MetroInd4.0& IoT 2022: 240-244 - [c63]Riccardo Caponetto, Andrea Cincotta, Giovanna Di Pasquale, Salvatore Graziani, Antonino Pollicino
Modeling of a Bacterial Cellulose-based Composite in Bending Configuration. SAS 2022: 1-5 - 2021
- [c62]Carlo Trigona, Marco Privitera
A Completely Autonomous TEG-Based Node for Thermal Gradient Measurements. SSD 2021: 206-209 - [c61]Alvo Aabloo, Giovanna Di Pasquale, Salvatore Graziani, Santhosh Kurukunda
A Green Deformation Sensor Based on Bacterial Cellulose and Bio-Derived Ionic Liquids. SSD 2021: 1182-1185 - [c60]Andrea Baglieri, Anna Maria Gueli, Martina Pace, Stefania Pasquale, Ivana Puglisi, Carlo Trigona:
Exploitation of Chemo-Electrical Transduction Properties of Soil as a Function of Energy Radiation Doses and Temperature: Preliminary Results. SSD 2021: 1196-1201 - [c59]Bruno Andò, Salvatore Baglio, Salvatore Castorina
Technologies for the Development of Polymeric Sensors. AISEM 2021: 322-329 - [c58]Riccardo Caponetto, Giovanna Di Pasquale, Salvatore Graziani, Emanuele Murgano, Antonino Pollicino
Investigation of Bacterial Cellulose-based Fractional Order Element behaviour. I2MTC 2021: 1-5 - [c57]Gianluca Caposciutti, Mirko Marracci, Carlo Trigona, Salvatore Baglio, Bernardo Tellini:
Investigation of a 100 µm Magnetic Wire for Temperature Sensing based on a Time Domain Readout. I2MTC 2021: 1-6 - [c56]Giovanna Di Pasquale, Salvatore Graziani, Santhosh Kurukunda
Conditioning of Bacterial Cellulose-based Motion Sensors. I2MTC 2021: 1-5 - [c55]Roberto La Rosa, Mario Costanza, Catherine Dehollain, Patrizia Livreri
A Self-powered Ambient Light Power Measurement Platform with Time-domain Readout. I2MTC 2021: 1-5 - [c54]Carlo Trigona, Giuseppe Napoli, Stefania Pasquale, Ivana Puglisi, Andrea Baglieri, Anna Maria Gueli:
A Plant-Based Sensor for UV-A Radiation Measurements. I2MTC 2021: 1-5 - 2020
- [c53]Carlo Trigona, Salvatore Graziani, Giovanna Di Pasquale, Antonino Pollicino
A Piezoresistive Bacterial Cellulose- based Sensor for Axial Displacement Measurements. SSD 2020: 126-129 - [c52]Santhosh Kurukunda
Laboratory Activity during COVID- 19 as a "Virtual Experience": Restriction or Chance? SSD 2020: 349-353 - [c51]Carlo Trigona:
Feasibility of a Soil-based Sensor for Measurement of Temperature. SSD 2020: 1155-1158 - [c50]Salvatore Baglio, Gianluca Caposciutti, Mirko Marracci, Bernardo Tellini, Carlo Trigona:
Exploitation of Temperature Effect in 100 µm Ferromagnetic Wire. I2MTC 2020: 1-5 - [c49]Riccardo Caponetto, Giovanna Di Pasquale, Salvatore Graziani, Emanuele Murgano, Antonino Pollicino
Green Fractional Order Elements Based on Bacterial Cellulose and Ionic Liquids. I2MTC 2020: 1-6 - [c48]Nunzio Cennamo
An LSPR Sensor based on a thin slab waveguide of bacterial cellulose. I2MTC 2020: 1-5 - [c47]Carlo Trigona, Jaakko Palosaari, Yang Bai
A vibrational energy harvester based on Soft-Nonlinearity for truly random excitation. I2MTC 2020: 1-5 - 2019
- [c46]Carlo Trigona, Slim Naifar
Hybrid Solution for Enhanced Energy Harvester from Torsional Vibration. SSD 2019: 334-338 - [c45]Ammar Al-Hamry
Thermal Analysis of a Microsensor based on GO/Polyvinyl Alcohol for Humidity Measurements. SSD 2019: 626-629 - [c44]Marko Gazivoda
Measurement of Weak Signal Energy at Acoustic Frequencies by using RMSHI as a Passive Conditioning Circuit. I2MTC 2019: 1-5 - [c43]Giovanna Di Pasquale, Salvatore Graziani, Antonino Pollicino
"Paper"Based Sensor for Deformation Measurements. I2MTC 2019: 1-5 - [c42]Carlo Trigona, Valentina Sinatra, Antonio Riccardo Fallico, Salvatore Puglisi, Bruno Andò, Salvatore Baglio:
Dynamic Spatial Measurements based on a Bimorph Artificial Whisker and RTD-Fluxgate Magnetometer. I2MTC 2019: 1-5 - [c41]Marko Gazivoda
Weak Signal Detection Utilizing a Mechanically Switched Inductor. IWASI 2019: 215-220 - [c40]Salvatore Baglio, Alessandro Cammarata, Petramay Cortis, Lucia Lo Bello, Pietro Davide Maddio, Salvatore Nicosia, Gaetano Patti, Stephen Sciberras, Johann Scicluna, Vincenzo Scuderi, Rosario Sinatra, Carlo Trigona:
Virtual biosensors for the estimation of medical precursors. M&N 2019: 1-4 - [c39]Ada Fort, Enza Panzardi
Performance Analysis of an AlN Humidity Sensor based on TiO2 nanoparticles. M&N 2019: 1-5 - [c38]Anna Maria Gueli
Measurements of Wearable Noninvasive Transducers for Sport Performance Improvement. M&N 2019: 1-5 - [c37]Giovanna Di Pasquale, Salvatore Graziani, Antonino Pollicino
A Bacterial Cellulose Based Mass Sensor. M&N 2019: 1-4 - [c36]Valentina Sinatra, Carlo Trigona, Bruno Andò, Salvatore Baglio
Self-generating Microsensor with Meander Architecture for Performance Enhancement in Inertial Systems. M&N 2019: 1-5 - [c35]Carlo Trigona, Bruno Andò, Salvatore Baglio
Smart Nonlinear Energy Harvesting. M&N 2019: 1-4 - [c34]Roberto La Rosa, Carlo Trigona, Bruno Andò, Salvatore Baglio
MEMS based Transducer for Zero-Energy Standby Application. MetroInd4.0&IoT 2019: 12-15 - [c33]Giovanna Di Pasquale, Salvatore Graziani, Antonio Licciulli, Rossella Nisi, Antonino Pollicino
Geometrical Analysis of a Bacterial Cellulose-Based Sensing Element. MetroInd4.0&IoT 2019: 225-228 - [c32]Ada Fort, Enza Panzardi
Conditioning Circuit for Simultaneous Sensing and Actuation in Piezoelectric MEMS Resonators. SAS 2019: 1-6 - [c31]Giovanna Di Pasquale
Green Inertial Sensors based on Bacterial Cellulose. SAS 2019: 1-4 - [c30]Carlo Trigona, Bruno Andò, Salvatore Baglio
Measurements and Investigations of Helicopter-Induced Vibrations for Kinetic Energy Harvesters. SAS 2019: 1-5 - [c29]Carlo Trigona, Bruno Andò, Salvatore Baglio
Piezo Coaxial Cable for Sensing of Mechanical Vibrations. SAS 2019: 1-4 - 2018
- [c28]Olfa Kanoun, Thomas Keutel, Christian Viehweger
Next Generation Wireless Energy Aware Sensors for Internet of Things: A Review. SSD 2018: 1-6 - [c27]Carlo Trigona, Sonia Bradai, Slim Naifar, Roberto La Rosa, Salvatore Baglio
Development of a Smart Acceleration Measurement Unit for Industry 4.0. SSD 2018: 838-841 - [c26]Ghada Bouattour, Carlo Trigona, Houda Ben Jmeaa Derbel, Salvatore Baglio
Non-Destructive Transmissive Inductive Thickness Sensor for IoT Applications. SSD 2018: 1203-1207 - [c25]Carlo Trigona, Bruno Andò, Salvatore Baglio
Measurements and Analysis of Induced Vibrations in Optical Telescopes. SSD 2018: 1476-1480 - [c24]Sonia Bradai, Slim Naifar
Electromagnetic transducer with bistable-RMSHI for energy harvesting from very weak kinetic sources. I2MTC 2018: 1-5 - [c23]Roberto La Rosa, Carlo Trigona, Giulio Zoppi, Calogero Di Carlo, Loreto Di Donato
RF energy scavenger for battery-free Wireless Sensor Nodes. I2MTC 2018: 1-5 - [c22]Carlo Trigona, Bruno Andò, Salvatore Baglio
Measurements and analysis of body induced movements for kinetic energy harvesters. I2MTC 2018: 1-5 - [c21]Carlo Trigona, Valentina Sinatra, Giuseppa Crea, R. Nania, Bruno Andò, Salvatore Baglio
PiezoMUMPs microsensor for contactless measurements of DC-electrical current. I2MTC 2018: 1-5 - [c20]Ghada Bouattour, Carlo Trigona, Rim Barioul
A Smart Sensing Architecture for Misalignment Measurements. IEEE SENSORS 2018: 1-4 - [c19]Slim Naifar
A smart energy harvester for axial-force measurements in vibrating environments. SAS 2018: 1-5 - [c18]Carlo Trigona, Valentina Sinatra, Bruno Andò, Salvatore Baglio
Fluxgate Magnetometer and Performance for Measuring Iron Compounds. Sensors 2018: 509-517 - [c17]Slim Naifar, Carlo Trigona, Sonia Bradai, Salvatore Baglio
Smart Transducers for Energy Scavenging and Sensing in Vibrating Environments. Sensors 2018: 591-598 - [c16]Sonia Bradai, Carlo Trigona, Slim Naifar
RMSHI Solutions for Electromagnetic Transducers from Environmental Vibration. Sensors 2018: 599-607 - 2017
- [c15]Bruno Andò, Salvatore Baglio
A friction less accelerometer exploiting a magnetic levitating mechanism and an inductive readout strategy. I2MTC 2017: 1-5 - [c14]Carlo Trigona, Valentina Sinatra, Bruno Andò, Salvatore Baglio
RTD-fluxgate sensor for measurements of metal compounds in neurodegenerative diseases. I2MTC 2017: 1-5 - [c13]Carlo Trigona, Bruno Andò, Salvatore Baglio
Conformable piezoelectric-foil for energy scavenging applications. M&N 2017: 1-4 - 2016
- [c12]Carlo Trigona, Bruno Andò, Valentina Sinatra, C. Vacirca, E. Rossino, L. Palermo, Santhosh Kurukunda
Implementation and characterization of a smart parking system based on 3-axis magnetic sensors. I2MTC 2016: 1-6 - [c11]Carlo Trigona, Salvatore Giuffrida, Bruno Andò, Salvatore Baglio
Micromachined "Random Mechanical Switching Harvester on Inductor" to recovery energy from very low-amplitude vibrations with zero-voltage threshold. IEEE SENSORS 2016: 1-3 - [c10]Carlo Trigona, Bruno Andò, Salvatore Baglio
Vibration-based transducer for zero-energy standby applications. SAS 2016: 1-4 - 2015
- [c9]Bruno Andò, Salvatore Baglio
"Vibration driven" mechanical switches: A novel transduction methodology with applications to DC-DC "diode-less" voltage multipliers. I2MTC 2015: 1779-1782 - [c8]Carlo Trigona, Alessio Noto, Bruno Andò, Salvatore Baglio
Novel mechanical transducers for switched capacitor circuits. SAS 2015: 1-4 - 2014
- [c7]Carlo Trigona, Felice Maiorca, Fabio Giusa, Alessio Noto, Bruno Andò, Salvatore Baglio
Performance characterization of different nonlinear-transduction mechanisms for piezoelectric energy harvesting. I2MTC 2014: 1148-1151 - [c6]Carlo Trigona, Fabio Giusa, Felice Maiorca, Alessio Noto, Bruno Andò, Salvatore Baglio
Anti-phase coupled bistable transducers: A review of recent progress. SAS 2014: 166-169 - 2013
- [c5]Bruno Andò, Salvatore Baglio
Autonomous bistable microsensors for noninvasive AC electrical current measurements. I2MTC 2013: 93-97 - [c4]Bruno Andò, Salvatore Baglio
Multiple nonlinear oscillators for autonomous Wireless Sensor Nodes. I2MTC 2013: 1311-1314 - 2012
- [c3]Salvatore Baglio
Energy Harvesting from weak random vibrations: Bistable strategies and architectures for MEMS devices. MWSCAS 2012: 154-157 - 2011
- [c2]Bruno Andò, Salvatore Baglio
A smart wireless sensor network for AAL. M&N 2011: 122-125 - 2006
- [c1]Bruno Andò, Alberto Ascia, Salvatore Baglio
RTD Fluxgate performance for application in magnetic label-based bioassay: preliminary results. EMBC 2006: 5060-5063
Coauthor Index
[j28] [j24] [j21] [j20] [j17] [j13] [j10] [j9] [j8] [j7] [j6] [j5] [j4] [j3] [j2] [j1] [c79] [c78] [c77] [c75] [c74] [c73] [c71] [c69] [c68] [c67] [c66] [c65] [c64] [c59] [c57] [c52] [c50] [c45] [c42] [c40] [c36] [c35] [c34] [c30] [c29] [c27] [c26] [c25] [c24] [c22] [c21] [c20] [c19] [c18] [c17] [c16] [c15] [c14] [c13] [c12] [c11] [c10] [c9] [c8] [c7] [c6] [c5] [c4] [c3] [c2] [c1]
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