2022
DOI: 10.3390/jlpea12010012
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A Tree-Based Architecture for High-Performance Ultra-Low-Voltage Amplifiers

Abstract: In this paper, we introduce a novel tree-based architecture which allows the implementation of Ultra-Low-Voltage (ULV) amplifiers. The architecture exploits a body-driven input stage to guarantee a rail-to-rail input common mode range and body-diode loading to avoid Miller compensation, thanks to the absence of high-impedance internal nodes. The tree-based structure improves the CMRR of the proposed amplifier with respect to the conventional OTA architectures and allows achievement of a reasonable CMRR even at… Show more

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Cited by 20 publications
(22 citation statements)
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References 50 publications
(59 reference statements)
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“…The transconductance-to-current ratios, in terms of inversion level, are given by using expressions (10)- (12) in which I D,sat stands for the approximation of the drain current in the saturation region, where i r << i f [13].…”
Section: Small-signal Transconductancesmentioning
confidence: 99%
See 1 more Smart Citation
“…The transconductance-to-current ratios, in terms of inversion level, are given by using expressions (10)- (12) in which I D,sat stands for the approximation of the drain current in the saturation region, where i r << i f [13].…”
Section: Small-signal Transconductancesmentioning
confidence: 99%
“…In the fast expanding ultra-low-voltage domain [6], some short-channel effects, such as velocity saturation, are not relevant; thus, a simplified MOSFET model can be satisfactory for circuit design. Targeting the increasing number of ultra-low-voltage designs [7][8][9][10][11][12], this work proposes a four-parameter model (4PM) based on the all-region advanced compact MOSFET model (ACM) [13].…”
Section: Introductionmentioning
confidence: 99%
“…Each of these stages performs differential to single-ended conversion exploiting a current mirror connection (M n 1 -M n 2 and M p 1 -M p 2 , respectively): The use of regular current mirrors, as opposed to body-driven current mirrors, allows minimizing the current gain error, improving the common-mode rejection ratio (CMRR). 45 As discussed before, each stage provides current gain through ratioed current mirrors (M n 1 -M n 2 and M p 5 -M p 6 for the up section, M p 1 -M p 2 and M n 5 -M n 6 for the down one), and the currents are recombined in two push-pull output stages that drive the second stage.…”
Section: Description Of the Proposed Topologymentioning
confidence: 99%
“…As an alternative approach, body-driven and gate-biased OTAs are much more suitable for such scanty supply voltages, and as a consequence, this has raised an ever-increasing interest in body-driven architectures. [31][32][33][34][35][36][37][38][39][40][41][42][43][44][45][46] Indeed, gate-bias configurations allow controlling the operating point over the whole dynamic range and are thus more robust when supply voltage or temperature variations are considered. However, body-driven techniques present some drawbacks with respect to gate-driven architectures, such as higher noise, lower bandwidth, and worse slew-rate behavior.…”
Section: Introductionmentioning
confidence: 99%
“…Most ULV OTAs in the literature exploit body driving (the input signal is applied to the body terminal) [9], [13]- [21], complementary n-type and p-type pseudodifferential transconductors [22] or floating-gate and quasifloating-gate solutions [23]. CMRR is improved by the use of common mode feedback (CMFB) loops, common mode feedforward (CMFF) [9], [24], by optimizing the topology of differential-to-single-ended converter (D2S) stages [21] or by optimizing the OTA architecture [20]; gain can be improved by exploiting positive feedback [15], [18] or by using additional gain stages [14], [16], [17], [19].…”
Section: Introductionmentioning
confidence: 99%