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2020 – today
- 2024
[j59]Montree Kumngern
, Fabian Khateb, Tomasz Kulej:
Low-Voltage Mixed-Mode Analog Filter Using Multiple-Input Multiple-Output Operational Transconductance Amplifiers. IEEE Access 12: 51073-51085 (2024)- [j58]Fabian Khateb, Tomasz Kulej, Montree Kumngern, Pipat Prommee:
0.5-V High Linear Fully Differential Multiple-Input Bulk-Driven OTA With Effective Self-Embedded CMFB. IEEE Access 12: 58338-58348 (2024) - [j57]Montree Kumngern, Fabian Khateb, Tomasz Kulej:
Low-Voltage Low-Power Differential Difference Current Conveyor Transconductance Amplifier and Its Application to a Versatile Analog Filter. IEEE Access 12: 92523-92535 (2024) - [j56]Montree Kumngern, Fabian Khateb, Tomasz Kulej:
A Novel Multiple-Input Single-Output Current-Mode Shadow Filter and Shadow Oscillator Using Current-Controlled Current Conveyors. Circuits Syst. Signal Process. 43(9): 5438-5462 (2024) - [j55]Fabian Khateb, Montree Kumngern, Tomasz Kulej:
0.5-V 281-nW Versatile Mixed-Mode Filter Using Multiple-Input/Output Differential Difference Transconductance Amplifiers. Sensors 24(1): 32 (2024) - [j54]Montree Kumngern, Fabian Khateb, Tomasz Kulej, Martin Kyselak, Somkiat Lerkvaranyu, Boonying Knobnob:
Current-Mode Shadow Filter with Single-Input Multiple-Output Using Current-Controlled Current Conveyors with Controlled Current Gain. Sensors 24(2): 460 (2024) - [j53]Montree Kumngern, Fabian Khateb, Tomasz Kulej, Lukas Langhammer:
1 V Electronically Tunable Differential Difference Current Conveyors Using Multiple-Input Operational Transconductance Amplifiers. Sensors 24(5): 1558 (2024) - [j52]Tomasz Kulej, Fabian Khateb, Montree Kumngern:
0.5 V Multiple-Input Fully Differential Operational Transconductance Amplifier and Its Application to a Fifth-Order Chebyshev Low-Pass Filter for Bio-Signal Processing. Sensors 24(7): 2150 (2024) - [j51]Montree Kumngern, Fabian Khateb, Tomasz Kulej, Boonying Knobnob:
1 V Tunable High-Quality Universal Filter Using Multiple-Input Operational Transconductance Amplifiers. Sensors 24(10): 3013 (2024) - 2023
- [j50]Prashant Kumar, Pushkar Srivastava, Rajeev Kumar Ranjan, Montree Kumngern:
New Zero Power Memristor Emulator Model and Its Application in Memristive Neural Computation. IEEE Access 11: 5609-5616 (2023) - [j49]Montree Kumngern, Fabian Khateb, Tomasz Kulej:
0.5 V Universal Filter and Quadrature Oscillator Based on Multiple-Input DDTA. IEEE Access 11: 9957-9966 (2023) - [j48]Fabian Khateb, Montree Kumngern, Tomasz Kulej, Rajeev Kumar Ranjan:
0.5 V Multiple-Input Multiple-Output Differential Difference Transconductance Amplifier and Its Applications to Shadow Filter and Oscillator. IEEE Access 11: 31212-31227 (2023) - [j47]Fabian Khateb, Montree Kumngern, Tomasz Kulej:
0.5-V Nano-Power Voltage-Mode First-Order Universal Filter Based on Multiple-Input OTA. IEEE Access 11: 49806-49818 (2023) - [j46]Montree Kumngern, Tomasz Kulej, Fabian Khateb:
31.3 nW, 0.5 V Bulk-Driven OTA for Biosignal Processing. IEEE Access 11: 56516-56525 (2023) - [j45]Fabian Khateb, Montree Kumngern, Tomasz Kulej, Viera Stopjaková, Costas Psychalinos:
0.3-V, 357.4-nW Voltage-Mode First-Order Analog Filter Using a Multiple-Input VDDDA. IEEE Access 11: 96636-96647 (2023) - [j44]Fabian Khateb, Montree Kumngern, Tomasz Kulej:
58-nW 0.5-V Mixed-Mode Universal Filter Using Multiple-Input Multiple-Output OTAs. IEEE Access 11: 130345-130357 (2023) - [j43]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) - [j42]Montree Kumngern, Fabian Khateb, Tomasz Kulej:
Shadow Filters Using Multiple-Input Differential Difference Transconductance Amplifiers. Sensors 23(3): 1526 (2023) - [j41]Fabian Khateb, Montree Kumngern, Tomasz Kulej, Mohammad Yavari:
0.5-V Nano-Power Shadow Sinusoidal Oscillator Using Bulk-Driven Multiple-Input Operational Transconductance Amplifier. Sensors 23(4): 2146 (2023) - [j40]Montree Kumngern, Fabian Khateb, Tomasz Kulej, Pavel Steffan:
0.3-V Voltage-Mode Versatile First-Order Analog Filter Using Multiple-Input DDTAs. Sensors 23(13): 5945 (2023) - 2022
- [j39]Montree Kumngern, Fabian Khateb, Tomasz Kulej:
0.5 V Current-Mode Low-Pass Filter Based on Voltage Second Generation Current Conveyor for Bio-Sensor Applications. IEEE Access 10: 12201-12207 (2022) - [j38]Fabian Khateb, Montree Kumngern, Tomasz Kulej, Dalibor Biolek:
0.5 V Differential Difference Transconductance Amplifier and Its Application in Voltage-Mode Universal Filter. IEEE Access 10: 43209-43220 (2022) - [j37]Montree Kumngern, Pichai Suksaibul, Fabian Khateb, Tomasz Kulej:
Electronically Tunable Universal Filter and Quadrature Oscillator Using Low-Voltage Differential Difference Transconductance Amplifiers. IEEE Access 10: 68965-68980 (2022) - [j36]Fabian Khateb, Montree Kumngern, Tomasz Kulej, Dalibor Biolek:
0.3-Volt Rail-to-Rail DDTA and Its Application in a Universal Filter and Quadrature Oscillator. Sensors 22(7): 2655 (2022) - [j35]Montree Kumngern, Pichai Suksaibul, Fabian Khateb, Tomasz Kulej:
1.2 V Differential Difference Transconductance Amplifier and Its Application in Mixed-Mode Universal Filter. Sensors 22(9): 3535 (2022) - [j34]Fabian Khateb, Montree Kumngern, Tomasz Kulej, Meysam Akbari, Viera Stopjaková:
0.5 V, nW-Range Universal Filter Based on Multiple-Input Transconductor for Biosignals Processing. Sensors 22(22): 8619 (2022) - [c38]Montree Kumngern, Usa Torteanchai, Natapong Wongprommoon, Wirote Jongchanachavawat, Siraphop Tooprakai, Somkiat Lerkvaranyu:
0.3 V Fully Differential Current Conveyor Using MIBD-DT MOST technique. ISPACS 2022: 1-4 - 2021
- [j33]Montree Kumngern, Fabian Khateb, Tomasz Kulej, Costas Psychalinos:
Multiple-Input Universal Filter and Quadrature Oscillator Using Multiple-Input Operational Transconductance Amplifiers. IEEE Access 9: 56253-56263 (2021) - [j32]Niranjan Raj, Rajeev Kumar Ranjan, Fabian Khateb, Montree Kumngern:
Mem-Elements Emulator Design With Experimental Validation and Its Application. IEEE Access 9: 69860-69875 (2021) - [j31]Fabian Khateb, Tomasz Kulej, Meysam Akbari, Montree Kumngern:
0.5-V High Linear and Wide Tunable OTA for Biomedical Applications. IEEE Access 9: 103784-103794 (2021) - 2020
- [j30]Tomasz Kulej, Fabian Khateb, Montree Kumngern:
0.3-V Nanopower Biopotential Low-Pass Filter. IEEE Access 8: 119586-119593 (2020) - [j29]Pankaj Kumar Sharma, Rajeev Kumar Ranjan, Fabian Khateb, Montree Kumngern:
Charged Controlled Mem-Element Emulator and Its Application in a Chaotic System. IEEE Access 8: 171397-171407 (2020) - [j28]Winai Jaikla, Fabian Khateb, Montree Kumngern, Tomasz Kulej, Rajeev Kumar Ranjan, Peerawut Suwanjan:
0.5 V Fully Differential Universal Filter Based on Multiple Input OTAs. IEEE Access 8: 187832-187839 (2020) - [j27]Montree Kumngern, Fabian Khateb, Tomasz Kulej:
0.3 V Differential Difference Current Conveyor Using Multiple-Input Bulk-Driven Technique. Circuits Syst. Signal Process. 39(6): 3189-3205 (2020) - [j26]Winai Jaikla, Suchin Adhan, Peerawut Suwanjan, Montree Kumngern:
Current/Voltage Controlled Quadrature Sinusoidal Oscillators for Phase Sensitive Detection Using Commercially Available IC. Sensors 20(5): 1319 (2020) - [j25]Montree Kumngern, Nattharinee Aupithak, Fabian Khateb, Tomasz Kulej:
0.5 V Fifth-Order Butterworth Low-Pass Filter Using Multiple-Input OTA for ECG Applications. Sensors 20(24): 7343 (2020)
2010 – 2019
- 2019
- [j24]Fabian Khateb, Tomasz Kulej, Montree Kumngern:
0.3V Bulk-Driven Current Conveyor. IEEE Access 7: 65122-65128 (2019) - [j23]Fabian Khateb, Tomasz Kulej, Montree Kumngern, Costas Psychalinos:
Multiple-Input Bulk-Driven MOS Transistor for Low-Voltage Low-Frequency Applications. Circuits Syst. Signal Process. 38(6): 2829-2845 (2019) - [j22]Fabian Khateb, Montree Kumngern, Tomasz Kulej, Costas Psychalinos:
0.5 V Universal Filter Based on Multiple-Input FDDAs. Circuits Syst. Signal Process. 38(12): 5896-5907 (2019) - [j21]Montree Kumngern, Fabian Khateb, Tomasz Kulej:
0.5 V bulk-driven CMOS fully differential current feedback operational amplifier. IET Circuits Devices Syst. 13(3): 314-320 (2019) - [j20]Montree Kumngern, Pichai Suksaibul, Fabian Khateb:
Four-Input One-Output Voltage-Mode Universal Filter Using Simple OTAs. J. Circuits Syst. Comput. 28(5): 1950078:1-1950078:20 (2019) - [j19]Montree Kumngern, Thanat Nonthaputha, Fabian Khateb:
Arbitrary Waveform Generators Using Current-Controlled Current Conveyor Transconductance Amplifier and Current Conveyor Analog Switches. J. Circuits Syst. Comput. 28(11): 1950179:1-1950179:20 (2019) - [j18]Montree Kumngern:
0.4 V fully differential current conveyor using multiple-input bulk-driven MOST technique. Microelectron. J. 90: 96-104 (2019) - [j17]Pipat Prommee, Natapong Wongprommoon, Montree Kumngern, Winai Jaikla:
Low-Voltage Low-Pass and Band-Pass Elliptic Filters Based on Log-Domain Approach Suitable for Biosensors. Sensors 19(24): 5581 (2019) - 2018
- [j16]Fabian Khateb, Montree Kumngern, Tomasz Kulej, Vilem Kledrowetz:
Low-voltage fully differential difference transconductance amplifier. IET Circuits Devices Syst. 12(1): 73-81 (2018) - [j15]Montree Kumngern, Thanat Nonthaputha, Fabian Khateb:
Low-power sample and hold circuits using current conveyor analogue switches. IET Circuits Devices Syst. 12(4): 397-402 (2018) - [c37]Montree Kumngern, Usa Torteanchai, Sathian Yutthanaboon, Fabian Khateb:
Sub-Volt Bulk-Driven Transconductance Amplifier and Filter Application. APCCAS 2018: 1-4 - [c36]Eakluck Wareechol, Boonying Knobnob, Montree Kumngern:
FDCCII -Based Third-Order Quadrature Sinusoidal Oscillator. TSP 2018: 1-4 - 2017
- [j14]Montree Kumngern, Fabian Khateb, Tomasz Kulej:
Fully-balanced four-terminal floating nullor for ultra-low voltage analogue filter design. IET Circuits Devices Syst. 11(2): 173-182 (2017) - [j13]Fabian Khateb, Winai Jaikla, Tomasz Kulej, Montree Kumngern, David Kubánek:
Shadow filters based on DDCC. IET Circuits Devices Syst. 11(6): 631-637 (2017) - [j12]Thanat Nonthaputha, Montree Kumngern:
Programmable Universal Filters Using Current Conveyor Transconductance Amplifiers. J. Circuits Syst. Comput. 26(7): 1750121:1-1750121:23 (2017) - [j11]Fabian Khateb, Tomasz Kulej, Montree Kumngern, Vilem Kledrowetz:
Low-Voltage Diode-Less Rectifier Based on Fully Differential Difference Transconductance Amplifier. J. Circuits Syst. Comput. 26(11): 1750172:1-1750172:8 (2017) - [c35]Montree Kumngern, Usa Torteanchai, Fabian Khateb:
0.5-V bulk-driven quasi-floating gate transconductance amplifier. ICECS 2017: 152-155 - 2016
- [j10]Fabian Khateb, Montree Kumngern, Tomasz Kulej:
1-V Inverting and Non-inverting Loser-Take-All Circuit and Its Applications. Circuits Syst. Signal Process. 35(5): 1507-1529 (2016) - [j9]Montree Kumngern, Fabian Khateb:
0.5 V fully differential current conveyor using bulk-driven quasi-floating-gate technique. IET Circuits Devices Syst. 10(1): 78-86 (2016) - [j8]Punnavich Phatsornsiri, Montree Kumngern, Panit Lamun:
A Voltage-Mode Universal Biquadratic Filter Using DDCCTA. J. Circuits Syst. Comput. 25(5): 1650034:1-1650034:24 (2016) - [c34]Thanat Nonthaputha, Montree Kumngern, Somkiat Lerkvaranyu:
CMOS sample-and-hold circuit using current conveyor analogue switch. ISPACS 2016: 1-4 - [c33]Thanat Nonthaputha, Montree Kumngern, Phichet Moungnoul:
CMOS D/A converter using current conveyor analogue switches. ISPACS 2016: 1-4 - [c32]Punnavich Phatsornsiri, Montree Kumngern, Fabian Khateb:
0.5-V fully differential allpass section. ISPACS 2016: 1-4 - [c31]Pichai Suksaibul, Somkiat Lerkvaranyu, Montree Kumngern:
A Wien-type oscillator using ECCII. ISPACS 2016: 1-4 - 2015
- [j7]Fabian Khateb, Spyridon Vlassis, Montree Kumngern, Costas Psychalinos, Tomasz Kulej, Radimír Vrba, Lukas Fujcik:
1 V Rectifier Based on Bulk-Driven Quasi-Floating-Gate Differential Difference Amplifiers. Circuits Syst. Signal Process. 34(7): 2077-2089 (2015) - [j6]Fabian Khateb, Montree Kumngern, Spyridon Vlassis, Costas Psychalinos, Tomasz Kulej:
Sub-Volt Fully Balanced Differential Difference Amplifier. J. Circuits Syst. Comput. 24(1): 1550005:1-1550005:18 (2015) - [c30]Montree Kumngern, Fabian Khateb:
Fully differential difference transconductance amplifier using FG-MOS transistors. ISPACS 2015: 337-341 - [c29]Amornchai Chaichana, Montree Kumngern, Montree Siripruchyanun, Winai Jaikla:
Amplitude controllable current-mode first order allpass filter including minimum component count circuits. TSP 2015: 1-4 - [c28]Fabian Khateb, Salma Bay Abo Dabbous, Montree Kumngern, Tomasz Kulej:
Novel current controlled differential-input buffered output active element and its application in all-pass filter. TSP 2015: 335-338 - 2014
- [j5]Fabian Khateb, Montree Kumngern, Spyridon Vlassis, Costas Psychalinos:
Differential Difference Current Conveyor Using Bulk-Driven Technique for Ultra-Low-Voltage Applications. Circuits Syst. Signal Process. 33(1): 159-176 (2014) - [j4]Montree Kumngern:
New versatile precision rectifier Montree Kumngern. IET Circuits Devices Syst. 8(2): 141-151 (2014) - [c27]Montree Kumngern, Usa Torteanchai:
FDCCII-based P, PI, PD and PID controllers. DICTAP 2014: 415-418 - [c26]Usa Torteanchai, Montree Kumngern:
Three-input single-output current-mode universal filter using a single FDCCII and grounded passive components. ISPACS 2014: 275-278 - [c25]Montree Kumngern:
Three-input single-output voltage-mode universal filter using single FDCCII. ISPACS 2014: 283-286 - 2013
- [j3]Fabian Khateb, Winai Jaikla, Montree Kumngern, Pipat Prommee:
Comparative study of sub-volt differential difference current conveyors. Microelectron. J. 44(12): 1278-1284 (2013) - [c24]Montree Kumngern, Amornchai Chaichana:
MIMO-type current-mode multifunction biquadratic filter using a MCDTA. APCC 2013: 54-57 - [c23]Montree Kumngern, Panit Lamun:
Allpass section-based mixed-mode quadrature sinusoidal oscillator. ICCSCE 2013: 226-229 - [c22]Montree Kumngern, Somyot Junnapiya, Jirasak Chanwutitum:
Voltage-mode lowpass, highpass, bandpass biquadratic filter using OTRAs. ICCSCE 2013: 230-233 - 2012
- [c21]Montree Kumngern, Panit Lamun:
Electronically Tunable Voltage-Mode Universal Filter with One Input and Four Outputs Using Seven OTAs and Two Grounded Capacitors. CICSyN 2012: 70-73 - [c20]Montree Kumngern, Somyot Junnapiya:
Tunable Quadrature Sinusoidal Oscillator Using Single-Ended OTAs. CICSyN 2012: 74-77 - [c19]Montree Kumngern, Pattarapong Phasukkit:
Versatile Voltage-Mode Multifunction Biquadratic Filter Employing Only Eight Single-Ended OTAs and Two Grounded Capacitors. CICSyN 2012: 441-444 - [c18]Montree Kumngern:
CMOS Tunable Positive/Negative Floating Resistor Using OTAs. CICSyN 2012: 445-448 - [c17]Montree Kumngern, Usa Torteanchai:
Current-controlled quadrature oscillator using a new single ZC-CG-CCCCTA. DICTAP 2012: 267-270 - [c16]Montree Kumngern:
CMOS current-mode precision full-wave rectifier with improved bandwidth. DICTAP 2012: 283-286 - [c15]Montree Kumngern:
Electronically tunable versatile voltage-mode biquadratic filter with three-input six-output using OTAs and grounded capacitors. DICTAP 2012: 300-304 - [c14]Montree Kumngern, Jirasak Chanwutitum:
Voltage-mode first-order allpass filter using single-ended OTAs and grounded capacitor. DICTAP 2012: 305-308 - [c13]Montree Kumngern, Kobchai Dejhan:
Current-mode multifunction biquad filter with three inputs five outputs using ZC-CDTAs. DICTAP 2012: 309-313 - [c12]Montree Kumngern:
Electronically tunable current-mode universal biquadratic filter using a single CCCFTA. ISCAS 2012: 1175-1178 - 2011
- [j2]Montree Kumngern:
Precision Full-Wave Rectifier Using Two DDCCs. Circuits Syst. 2(3): 127-132 (2011) - [c11]Montree Kumngern, Peerawut Suwanjan, Kobchai Dejhan:
Electronically tunable versatile voltage-mode MIMO OTA-C universal filter. APCC 2011: 752-755 - [c10]Montree Kumngern, Peerawut Suwanjan, Kobchai Dejhan:
Electronically tunable voltage-mode SIMO OTA-C universal biquad filter. APCC 2011: 774-777 - [c9]Montree Kumngern, Kobchai Dejhan:
Electronically tunable voltage-mode MIMO universal filter using single-ended OTAs. ICCSCE 2011: 54-57 - [c8]Montree Kumngern:
High input impedance voltage-mode universal filter using OTAs and grounded capacitors. ICCSCE 2011: 58-61 - [c7]Montree Kumngern:
Voltage-controlled floating resistor using differential difference amplifier. ICEEI 2011: 1-4 - [c6]Montree Kumngern, Jirasak Chanwutitum, Kobchai Dejhan:
Fully integrated current-mode quadrature sinusoidal oscillator circuit. ICEEI 2011: 1-4 - [c5]Montree Kumngern, Somyot Junnapiya:
Current-mode third-order quadrature oscillator using minimum elements. ICEEI 2011: 1-4 - 2010
- [j1]Montree Kumngern, Boonying Knobnob, Kobchai Dejhan:
High Frequency and High Precision CMOS Half-Wave Rectifier. Circuits Syst. Signal Process. 29(5): 815-836 (2010) - [c4]Montree Kumngern:
Current-mode multiphase sinusoidal oscillator using current-controlled current differencing transconductance amplifiers. APCCAS 2010: 728-731 - [c3]Montree Kumngern, Somyot Junnapiya:
A sinusoidal oscillator using translinear current conveyors. APCCAS 2010: 740-743 - [c2]Montree Kumngern, Usa Torteanchai, Kobchai Dejhan:
Electronically tunable multiple-input single-output voltage-mode multifunction filter employing simple CMOS OTAs. APCCAS 2010: 1099-1102
2000 – 2009
- 2006
- [c1]Pipat Prommee, Montree Kumngern, Kobchai Dejhan:
Current-mode Active-only Universal Filter. APCCAS 2006: 896-899
Coauthor Index
[j59] [j58] [j57] [j56] [j55] [j54] [j53] [j52] [j51] [j49] [j48] [j47] [j46] [j45] [j44] [j43] [j42] [j41] [j40] [j39] [j38] [j37] [j36] [j35] [j34] [j33] [j32] [j31] [j30] [j29] [j28] [j27] [j25] [j24] [j23] [j22] [j21] [j20] [j19] [j16] [j15] [c37] [j14] [j13] [j11] [c35] [j10] [j9] [c32] [j7] [j6] [c30] [c28] [j5] [j3]
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