Global impedance attenuation network for multistage OTAs driving a broad range of load capacitor

Aminzadeh, Hamed; Valinezhad, Mohammad Mahdi; Grasso, Alfio Dario

doi:10.1002/cta.2723

Cited by 7 publications

(11 citation statements)

References 40 publications

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“…Operational transconductance amplifier (OTA) is a fundamental and popular active element, which has been used in various range of applications (Aminzadeh, 2019;Aminzadeh et al, 2020). Figure 3 represents the symbol and CMOS architecture of OTA.…”

Section: Proposed Three Pinch-off Memristor Emulator Employing Otasmentioning

confidence: 99%

Mathematical framework for three cross-over memristor and its realization employing OTAs

Bhardwaj

Srivastava

2021

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Purpose The purpose of the paper is to report an emulation configuration of a three pinch-off memristor (TPM), whose transient characteristics consist three cross-over points on the voltage-current plane, which is dissimilar to a conventional memristor. These characteristics can be very useful in memristor-based multi-bit memory devices and hyperchaotic oscillators. Design/methodology/approach The work describes the Mathematical framework for TPM and a circuit emulator based on the derived conditions. The configuration is based on five operational transconductance amplifier (OTAs) and four grounded passive elements. After which, we have verified its operation using personal simulation program with integrated circuit emphasis simulation environment. Finally, the implementation of OTA-based TPM using commercial integrated circuit (IC) LM13700 has also been presented. Findings It has been shown that a flux-dependent memductance expression of cubic order can show three intersections on the VI contour under certain parameter related constraints. Moreover, the OTA-based emulator reported in the work is very compact in nature because of the no use of external multiplier IC/circuitry, which has been popular in previous emulators. Originality/value For the first time, a multiple cross-over memristor emulator has been reported which can operate under practical operating conditions such as at practical operating frequencies and sinusoidal excitation.

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Section: Proposed Three Pinch-off Memristor Emulator Employing Otasmentioning

confidence: 99%

Mathematical framework for three cross-over memristor and its realization employing OTAs

Bhardwaj

Srivastava

2021

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“…Since the early years of MOS analog integrated circuits, the compensation of two or more stage amplifiers was a key research area [1]- [28]. In this field several novel solutions were continuously proposed, especially for three-and fourstage amplifiers, and, despite several decades have been devoted to this subject, even in the last ten years the interest on this topic appears active [29]- [40]. Indeed, due to the continuous degradation of transistors' intrinsic gain and the low supply voltage of modern scaled technologies, more gain stages are required [35] and in any case the development of novel compensation networks remains an important research area in advanced CMOS technologies.…”

Section: Introductionmentioning

confidence: 99%

“…Despite from one side several multistage amplifier compensation networks were proposed and analyzed [1]- [40], and, hence, we know their voltage transfer functions which are typically reported in the original or successive papers, the continuous research on this domain maintains unchanged the need to evaluate the voltage transfer function especially in a novel more complex topology that could be adopted. Hence, methodologies to calculate the symbolic voltage transfer function simply and efficiently are still important.…”

Section: Introductionmentioning

confidence: 99%

A Methodology to Derive a Symbolic Transfer Function for Multistage Amplifiers

2022

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In this paper, a simple while effective methodology to calculate the symbolic transfer function of a multistage amplifier with frequency compensation is proposed. Three general amplifier models are introduced and analyzed, which represent basic topologies found in the literature. For these amplifier models, the symbolic transfer function is derived and specific strategies for the zero and nondominant pole expressions are presented. The methodology is suited for hand calculations and yields accurate results while offering more intuition into the operation of the widely adopted frequency compensation solutions discussed in the literature. The effectiveness of the proposed approach is validated through various typical cases of study.

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“…The Q-factor cannot be, however, reduced easily since it is related to the stages' transconductances and output impedances that cannot be controlled easily. Local impedance attenuation (LIA) network along with auxiliary feedback loops are used in conjunction with cascode Miller compensation to reduce the high Q-factor using the cascode local impedance attenuation (CLIA) (Tan and Ki, 2015), the cascode global impedance attenuation (CGIA) (Aminzadeh et al, 2020), the cascode Miller compensation with local Q-factor control (CLQC) (Cheng et al, 2019) and the transconductance-enhancement cascode Miller compensation (TECMC) (Dong and Zhu, 2018).…”

Section: Introductionmentioning

confidence: 99%

“…Still, the high Q-factor limits the OTA performance for the small load capacitors. Dual loop cascode Miller compensation with damping factor control unit (DLCDFC) (Aminzadeh and Dashti, 2018) and cascode global impedance attenuation (CGIA) (Aminzadeh et al, 2020) modify the high Q-factor of the HCFC amplifier using a serial RC network at the output of the second stage or both first and second stages, respectively. Significant silicon area is however, occupied by the required resistance and capacitance of hundreds kX and several hundreds fF.…”

Section: Introductionmentioning

confidence: 99%

Hybrid cascode compensation with Q-factor control module for three-stage OTAs driving ultra-large load capacitors

Aminzadeh

Valinezhad

2020

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Purpose The purpose of this study is to discuss the effect of hybrid cascode compensation with quality factor (Q-factor) control module for the three-stage amplifiers driving ultra-large load capacitors. Compared to the present frequency compensation solutions, it extends the amplifier bandwidth by establishing an extra AC feedback pathway besides the primary pathway through the Miller capacitor, increasing the loop gain at the gain–bandwidth product (GBW) frequency by pushing to the higher frequencies the nondominant poles. Design/methodology/approach A Q-factor control block is used to improve the damping factor of the compensation loop with no power or area overhead, thereby reducing the frequency peaking and the undesired oscillation in the time response for small load capacitors. The Q-factor control module is realized by a tiny-size on-chip capacitor, and provides an extra feedback loop to feed the damping current back to the input stage. A left-half-plane (LHP) zero is also introduced to further improve the stability. Findings A prototype of the proposed amplifier is simulated in 180-nm CMOS with a quiescent current of 24-µA from 1.80-V voltage supply. It achieves a 3.98-MHz gain–bandwidth product for 500-pF load capacitor, while the overall compensation capacitor is limited to 0.5-pF and the DC gain is extended beyond 100-dB. Originality/value The proposed amplifier is absolutely stable for the load capacitors ranging between 80-pF and 100-nF.

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Global impedance attenuation network for multistage OTAs driving a broad range of load capacitor

Cited by 7 publications

References 40 publications

Mathematical framework for three cross-over memristor and its realization employing OTAs

Mathematical framework for three cross-over memristor and its realization employing OTAs

A Methodology to Derive a Symbolic Transfer Function for Multistage Amplifiers

Hybrid cascode compensation with Q-factor control module for three-stage OTAs driving ultra-large load capacitors

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