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ORCIDAndrea Ballo
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2020 – today
- 2024
[j22]Andrea Ballo
, Alfio Dario Grasso, Marco Privitera:
A High Efficiency and High Power Density Active AC/DC Converter for Battery-Less US-Powered IMDs in a 28-nm CMOS Technology. IEEE Access 12: 7063-7070 (2024)- [c13]Marco Privitera, Andrea Ballo, Alfio Dario Grasso, Massimo Alioto:
A 15-nA quiescent current capacitor-less LDO for sub-1V μW-powered fully-harvested systems. ISCAS 2024: 1-5 - 2023
- [j21]Abdol Rasool Ghasemi, Hamed Aminzadeh, Andrea Ballo:
Ladder-Type Gm-C Filters With Improved Linearity. IEEE Access 11: 41503-41513 (2023) - [j20]Andrea Ballo, Alfio Dario Grasso, Marco Privitera:
Demystifying Regulating Active Rectifiers for Energy Harvesting Systems: A Tutorial Assisted by Verilog-A Models. IEEE Access 11: 43891-43908 (2023) - [j19]Andrea Ballo, Alfio Dario Grasso, Gaetano Palumbo:
Very-Low-Voltage Charge Pump Topologies for IoT Applications. IEEE Trans. Circuits Syst. I Regul. Pap. 70(6): 2283-2292 (2023) - [j18]Andrea Ballo, Alfio Dario Grasso, Salvatore Pennisi, Giovanni Susinni:
A 0.3-V 8.5-μ a Bulk-Driven OTA. IEEE Trans. Very Large Scale Integr. Syst. 31(9): 1444-1448 (2023) - [j17]Hamed Aminzadeh, Andrea Ballo, Alfio Dario Grasso, Mohammad Mahdi Valinezhad, Mohammad Jamali:
Hybrid Cascode Frequency Compensation for Four-Stage OTAs Driving a Wide Range of CL. IEEE Trans. Very Large Scale Integr. Syst. 31(11): 1665-1674 (2023) - [c12]Andrea Ballo, Alfio Dario Grasso, Gaetano Palumbo:
Fully On-Chip Charge Pump-based Boost Converter in 65-nm CMOS for Single Solar Cell Powered IC. ISCAS 2023: 1-5 - [c11]Andrea Ballo, Alfio Dario Grasso, Marco Privitera:
A 28-nm, 0.5-V, 78.5-nA Switched Capacitor Current Reference with Active Trimming for sub-1V Implantable Medical Devices. ISCAS 2023: 1-5 - [c10]Andrea Ballo, Alfio Dario Grasso, Gaetano Palumbo:
Triple Clock Boosted Voltage Multiplier: A Design Strategy to Heavily Reduce Rise Time. NEWCAS 2023: 1-5 - [c9]Andrea Ballo, Alfio Dario Grasso, Gaetano Palumbo:
An Energy-Efficient Design Strategy for Dickson Charge Pumps with Linear Distributed Capacitance. NEWCAS 2023: 1-5 - 2022
- [j16]Hamed Aminzadeh, Andrea Ballo, Alfio Dario Grasso:
Frequency Compensation of Three-Stage OTAs to Achieve Very Wide Capacitive Load Range. IEEE Access 10: 70675-70687 (2022) - [j15]Andrea Ballo, Alfio Dario Grasso, Marco Privitera:
A 6.3-ppm/°C, 100-nA Current Reference With Active Trimming in 28-nm Bulk CMOS Technology. IEEE Access 10: 108342-108353 (2022) - [j14]Andrea Ballo, Alfio Dario Grasso, Gaetano Palumbo, Toru Tanzawa:
A Charge Loss Aware Advanced Model of Dickson Voltage Multipliers. IEEE Access 10: 118082-118092 (2022) - [j13]Andrea Ballo, Alfio Dario Grasso, Gaetano Palumbo:
The Dickson Charge Pump as a Signal Amplifier. IEEE Trans. Circuits Syst. I Regul. Pap. 69(9): 3476-3489 (2022) - [j12]Andrea Ballo, Alfio Dario Grasso, Gaetano Palumbo:
A Bulk Current Regulation Technique for Dual-Branch Cross-Coupled Charge Pumps. IEEE Trans. Circuits Syst. II Express Briefs 69(10): 4128-4132 (2022) - [c8]Chiara Venezia, Andrea Ballo, Salvatore Pennisi:
A 0.5-V 28-nm CMOS Inverter-Based Comparator with Threshold Voltage Control. PRIME 2022: 77-80 - [c7]Marco Privitera, Andrea Ballo, Alfio Dario Grasso:
A 0.63 pJ/bit Fully-Digital BPSK Demodulator for US-powered IMDs downlink in a 28-nm bulk CMOS technology. PRIME 2022: 125-128 - [c6]Andrea Ballo, Alfio Dario Grasso, Marco Privitera:
A Design Procedure for Sizing Comparators in Active Rectifiers using $g_{m}/I_{D}$ Technique. SBCCI 2022: 1-6 - 2021
- [j11]Andrea Ballo, Alfio Dario Grasso, Gaetano Palumbo:
A Memory-Targeted Dynamic Reconfigurable Charge Pump to Achieve a Power Consumption Reduction in IoT Nodes. IEEE Access 9: 41958-41964 (2021) - [j10]Andrea Ballo, Alfio Dario Grasso, Gaetano Palumbo, Toru Tanzawa:
Charge Pumps for Ultra-Low-Power Applications: Analysis, Design, and New Solutions. IEEE Trans. Circuits Syst. II Express Briefs 68(8): 2895-2901 (2021) - [c5]Andrea Ballo, Alfio Dario Grasso, Marco Privitera:
An Efficient AC-DC Converter in 28nm Si-Bulk CMOS Technology for Piezo-Powered Medical Implanted Devices. MWSCAS 2021: 344-347 - [c4]Andrea Ballo, Alfio Dario Grasso, Gaetano Palumbo:
Comparison of the Wide-Frequency Range Dynamic Behavior of the Dickson and Cockcroft-Walton Voltage Multipliers. MWSCAS 2021: 348-351 - [c3]Andrea Ballo, Alfio Dario Grasso, Gaetano Palumbo:
Dickson Charge Pump: Design Strategy for Optimum Efficiency. NEWCAS 2021: 1-4 - 2020
- [j9]Andrea Ballo, Alfio Dario Grasso, Gaetano Palumbo:
A Subthreshold Cross-Coupled Hybrid Charge Pump for 50-mV Cold-Start. IEEE Access 8: 188959-188969 (2020) - [j8]Andrea Ballo, Alfio Dario Grasso, Gaetano Palumbo:
A simple and effective design strategy to increase power conversion efficiency of linear charge pumps. Int. J. Circuit Theory Appl. 48(2): 157-161 (2020) - [j7]Andrea Ballo, Alfio Dario Grasso, Gaetano Palumbo, Toru Tanzawa:
Linear distribution of capacitance in Dickson charge pumps to reduce rise time. Int. J. Circuit Theory Appl. 48(4): 555-566 (2020) - [j6]Andrea Ballo, Alfio Dario Grasso, Gaetano Palumbo:
Current-mode body-biased switch to increase performance of linear charge pumps. Int. J. Circuit Theory Appl. 48(11): 1864-1872 (2020) - [j5]Andrea Ballo, Alfio Dario Grasso, Gaetano Palumbo:
A High-Performance Charge Pump Topology for Very-Low-Voltage Applications. IEEE Trans. Circuits Syst. II Express Briefs 67-II(7): 1304-1308 (2020) - [j4]Andrea Ballo, Alfio Dario Grasso, Gaetano Palumbo:
Charge Pump Improvement for Energy Harvesting Applications by Node Pre-Charging. IEEE Trans. Circuits Syst. 67-II(12): 3312-3316 (2020) - [j3]Andrea Ballo, Giuseppe Bruno, Alfio Dario Grasso, Michele G. G. Vaiana:
A Compact Temperature Sensor With a Resolution FoM of 1.82 pJ·K2. IEEE Trans. Instrum. Meas. 69(10): 8571-8579 (2020)
2010 – 2019
- 2019
- [j2]Andrea Ballo, Alfio Dario Grasso, Salvatore Pennisi:
Active load with cross-coupled bulk for high-gain high-CMRR nanometer CMOS differential stages. Int. J. Circuit Theory Appl. 47(10): 1700-1704 (2019) - [j1]Andrea Ballo, Alfio Dario Grasso, Gianluca Giustolisi, Gaetano Palumbo:
Optimized Charge Pump With Clock Booster for Reduced Rise Time or Silicon Area. IEEE Trans. Circuits Syst. II Express Briefs 66-II(12): 1977-1981 (2019) - [c2]Andrea Ballo, Alfio Dario Grasso, Salvatore Pennisi:
CMOS Differential Stage with Improved DC Gain, CMRR and PSRR Performance. ICECS 2019: 154-157 - 2018
- [c1]Andrea Ballo, Gianluca Giustolisi, Alfio Dario Grasso, Gaetano Palumbo:
A Clock Boosted Charge Pump with Reduced Rise Time. ICECS 2018: 605-608
Coauthor Index
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last updated on 2024-07-17 21:24 CEST by the dblp team
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