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2020 – today
- 2023
[j10]Tomasz Kulej
, Montree Kumngern, Fabian Khateb, Daniel Arbet:
0.5 V Versatile Voltage- and Transconductance-Mode Analog Filter Using Differential Difference Transconductance Amplifier. Sensors 23(2): 688 (2023)- [c39]Martin Kovác, Miroslav Potocný, Daniel Arbet, Róbert Ondica, Richard Ravasz, Viera Stopjaková:
Low-Power CMOS Frequency Comparator. MIPRO 2023: 196-201 - [c38]Richard Ravasz, David Maljar, Daniel Arbet, Viera Stopjaková, Peter Kubinec:
Design of the Slope Detection Circuit for On-Chip Current Sensing. MIXDES 2023: 111-115 - 2022
- [j9]Tomasz Kulej, Fabian Khateb, Daniel Arbet, Viera Stopjaková:
A 0.3-V High Linear Rail-to-Rail Bulk-Driven OTA in 0.13 μm CMOS. IEEE Trans. Circuits Syst. II Express Briefs 69(4): 2046-2050 (2022) - [c37]David Maljar, Daniel Arbet, Martin Kovác, Róbert Ondica, Viera Stopjaková:
Autocalibration Approach for Improving Robustness of Analog ICs. DDECS 2022: 54-59 - [c36]Richard Ravasz, Adam Hudec, Daniel Arbet, Viera Stopjaková:
On-Chip Current Sensing Approaches for DC-DC Converters. DDECS 2022: 64-67 - [c35]Daniel Arbet, Martin Kovác, David Maljas, Lukás Nagy, Viera Stopjaková:
High Power Supply Rejection LDO Regulator for Switching Applications. MIPRO 2022: 162-167 - [c34]Lukás Nagy, Daniel Arbet, Martin Kovác, Miroslav Potocný, Michal Sovcik, Viera Stopjaková:
Low-Power Rail-to-Rail Comparator in 130 nm CMOS Technology. RADIOELEKTRONIKA 2022: 1-4 - 2021
- [j8]Miroslav Potocný, Martin Kovác, Daniel Arbet, Michal Sovcik, Lukás Nagy, Viera Stopjaková, Richard Ravasz:
Low-Voltage DC-DC Converter for IoT and On-Chip Energy Harvester Applications. Sensors 21(17): 5721 (2021) - [c33]Lukás Nagy, Daniel Arbet, Martin Kovác, Miroslav Potocný, Róbert Ondica, Viera Stopjaková:
EKV Model for Bulk-Driven Circuit Design Using gmb/ID Method. AFRICON 2021: 1-4 - [c32]Lukás Nagy, Daniel Arbet, Martin Kovác, Miroslav Potocný, Michal Sovcik, Viera Stopjaková:
EKV MOS Transistor Model For Ultra Low-Voltage Bulk-Driven IC Design. DDECS 2021: 6-10 - [c31]David Maljar, Michal Sovcík, Daniel Arbet, Viera Stopjaková:
Enhanced Reliability of Fully Differential Difference Amplifier Through On-chip Digital Calibration. DDECS 2021: 119-122 - [c30]Daniel Arbet, Miroslav Potocný, Martin Kovác, Lukás Nagy, Viera Stopjaková:
Fully On-Chip Low-Drop Regulator for Low-Power Applications. MIPRO 2021: 101-106 - [c29]Róbert Ondica, Daniel Arbet, Martin Kovác, Viera Stopjaková:
Investigation of Inductor-based Fully On-chip Boost Converter. MIXDES 2021: 115-119 - 2020
- [c28]Lukás Nagy, Daniel Arbet, Martin Kovác, Miroslav Potocný, Michal Sovcik, Viera Stopjaková:
Dynamic Properties Of Ultra Low-Voltage Rail-to-Rail Comparator Designed In 130 nm CMOS Technology. DDECS 2020: 1-4 - [c27]Martin Kovác, Daniel Arbet, Lukás Nagy, Michal Sovcik, Viera Stopjaková:
Multi-Topology DC-DC Converter for Low-Voltage Energy Harvesting Systems. MIPRO 2020: 77-82 - [c26]Michal Sovcík, Viera Stopjaková, Daniel Arbet, Miroslav Potocný:
Autonomous On-Chip Digital Calibration for Analog ICs in Nanotechnologies. RADIOELEKTRONIKA 2020: 1-5
2010 – 2019
- 2019
- [c25]Lukás Nagy, Daniel Arbet, Martin Kovác, Miroslav Potocný, Michal Sovcik, Viera Stopjaková:
Performance Analysis Of Ultra Low-Voltage Rail-to-Rail Comparator In 130 nm CMOS Technology. AFRICON 2019: 1-5 - [c24]Martin Kovác, Daniel Arbet, Viera Stopjaková, Michal Sovcik, Lukás Nagy:
Investigation of Low-Voltage, Sub-threshold Charge Pump with Parasitics Aware Design Methodology. DDECS 2019: 1-4 - [c23]Lukás Nagy, Daniel Arbet, Martin Kovác, Miroslav Potocný, Viera Stopjaková:
Ultra Low-Voltage Rail-to-Rail Comparator Design in 130 nm CMOS Technology. DDECS 2019: 1-6 - [c22]Daniel Arbet, Martin Kovác, Viera Stopjaková, Miroslav Potocný:
Voltage-to-Frequency Converter for Ultra-Low-Voltage Applications. MIPRO 2019: 53-58 - [c21]Viera Stopjaková, Martin Kovác, Daniel Arbet, Lukás Nagy:
Towards Energy-autonomous Integrated Systems Through Ultra-low Voltage Analog IC Design. MIXDES 2019: 38-45 - 2018
- [j7]Michal Sovcik, Martin Kovác, Daniel Arbet, Viera Stopjaková, Miroslav Potocný:
Ultra-low-voltage boosted driver for self-powered systems. Microelectron. Reliab. 80: 155-163 (2018) - [c20]Daniel Arbet, Martin Kovác, Lukás Nagy, Viera Stopjaková, Michal Sovcik:
Two-Stage Bulk-Driven Variable Gain Amplifier for Low-Voltage Applications. DDECS 2018: 45-50 - [c19]Lukás Nagy, Daniel Arbet, Martin Kovác, Miroslav Potocný, Viera Stopjaková:
Design and Performance Analysis of Ultra-Low Voltage Rail-to-Rail Comparator in 130 nm CMOS Technology. DDECS 2018: 51-54 - [c18]Daniel Arbet, Martin Kovác, Viera Stopjaková, Miroslav Potocný:
Bulk-driven fully differential difference amplifier for ultra-low voltage applications. MIPRO 2018: 93-98 - 2017
- [j6]Daniel Arbet, Viera Stopjaková, Martin Kovác, Lukás Nagy, Matej Rakus, Michal Sovcik:
130 nm CMOS Bulk-Driven Variable Gain Amplifier for Low-Voltage Applications. J. Circuits Syst. Comput. 26(8): 1740003:1-1740003:19 (2017) - [j5]Juraj Brenkus, Viera Stopjaková, Viera Cernanová, Daniel Arbet, Lukás Nagy, Vladimír Sedlák:
A Novel Method Towards Time-Efficient Fault Analysis of Analog and Mixed-Signal Circuits. J. Circuits Syst. Comput. 26(8): 1740005:1-1740005:20 (2017) - [c17]Lukás Nagy, Daniel Arbet, Martin Kovác, Viera Stopjaková:
Low-power bulk-driven rail-to-rail comparator in 130 nm CMOS technology. AFRICON 2017: 649-652 - [c16]Michal Sovcik, Martin Kovác, Daniel Arbet, Viera Stopjaková:
Ultra-low-voltage driver for large load capacitance in 130nm CMOS technology. DDECS 2017: 127-132 - 2016
- [j4]Daniel Arbet, Gabriel Nagy, Martin Kovác, Viera Stopjaková:
Fully Differential Difference Amplifier for Low-Noise and Low-Distortion Applications. J. Circuits Syst. Comput. 25(3): 1640019:1-1640019:18 (2016) - [c15]Matej Rakus, Viera Stopjaková, Daniel Arbet:
Comparison of gate-driven and bulk-driven current mirror topologies. DDECS 2016: 27-30 - [c14]Daniel Arbet, Martin Kovác, Lukás Nagy, Viera Stopjaková, Juraj Brenkus:
Low-voltage bulk-driven variable gain amplifier in 130 nm CMOS technology. DDECS 2016: 40-45 - [c13]Juraj Brenkus, Viera Stopjaková, Lukás Nagy, Daniel Arbet:
Impedance calculation based method for AC fault analysis of mixed-signal circuits. DDECS 2016: 74-79 - [c12]Michal Sovcik, Michal Matuska, Daniel Arbet, Viera Stopjaková:
CMOS variable-gain amplifier for low-frequency applications. DDECS 2016: 243-246 - [c11]Daniel Arbet, Martin Kovác, Lukás Nagy, Viera Stopjaková, Michal Sovcik:
Variable-gain amplifier for ultra-low voltage applications in 130nm CMOS technology. MIPRO 2016: 51-56 - 2015
- [j3]Daniel Arbet, Viera Stopjaková, Martin Kovác:
Investigation of the optimum oscillation frequency value towards increasing the efficiency of OBIST approach. Microelectron. Reliab. 55(7): 1120-1125 (2015) - [c10]Daniel Arbet, Gabriel Nagy, Martin Kovác, Viera Stopjaková:
Fully Differential Difference Amplifier for Low-Noise Applications. DDECS 2015: 57-62 - [c9]Daniel Arbet, Gabriel Nagy, Martin Kovác, Viera Stopjaková, Lukás Nagy:
Readout interface for capacitive MEMS microphone in CMOS technology. MIXDES 2015: 370-374 - 2014
- [j2]Gábor Gyepes, Viera Stopjaková, Daniel Arbet, Libor Majer, Juraj Brenkus:
A new IDDT test approach and its efficiency in covering resistive opens in SRAM arrays. Microprocess. Microsystems 38(5): 359-367 (2014) - [j1]Daniel Arbet, Viera Stopjaková, Juraj Brenkus, Gábor Gyepes, Martin Kovác, Libor Majer:
BIST architecture for oscillation test of analog ICs and investigation of test hardware influence. Microelectron. Reliab. 54(5): 985-992 (2014) - [c8]Juraj Brenkus, Viera Stopjaková, Daniel Arbet, Gábor Gyepes, Libor Majer:
A novel impedance calculation method and its time efficiency evaluation. DDECS 2014: 99-103 - [c7]Martin Kovác, Daniel Arbet, Gabriel Nagy, Viera Stopjaková:
An approach towards selection of the oscillation frequency for oscillation test of analog ICs. DDECS 2014: 266-267 - 2013
- [c6]Gabriel Nagy, Daniel Arbet, Viera Stopjaková:
Digital methods of offset compensation in 90nm CMOS operational amplifiers. DDECS 2013: 124-127 - [c5]Daniel Arbet, Gabriel Nagy, Viera Stopjaková, Gábor Gyepes:
Efficiency of oscillation-based BIST in 90nm CMOS active analog filters. DDECS 2013: 263-266 - 2012
- [c4]Gábor Gyepes, Daniel Arbet, Juraj Brenkus, Viera Stopjaková:
Application of IDDT test towards increasing SRAM reliability in nanometer technologies. DDECS 2012: 167-170 - [c3]Daniel Arbet, Gábor Gyepes, Juraj Brenkus, Viera Stopjaková:
OBIST strategy versus parametric test - Efficiency in covering catastrophic faults in active analog filters. DDECS 2012: 193-194 - 2011
- [c2]Daniel Arbet, Juraj Brenkus, Gábor Gyepes, Viera Stopjaková:
Increasing the efficiency of analog OBIST using on-chip compensation of technology variations. DDECS 2011: 71-74 - [c1]Gábor Gyepes, Juraj Brenkus, Daniel Arbet, Viera Stopjaková:
Comparison of iddt test efficiency in covering opens in SRAMs realised in two different technologies. DDECS 2011: 395-396
Coauthor Index
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