483 research outputs found
A Novel differential to single-ended converter for ultra-low-voltage inverter-based OTAs
For the design of inverter-based OTAs with differential input and single-ended output, the
differential to single-ended (D2S) converter is a key building block. In fact, the performance of the D2S strongly affects the overall common-mode rejection ratio (CMRR) and input common-mode range (ICMR) of the whole OTA. In recent literature, inverter-based OTAs rely on a D2S topology based on an inverter driving another inverter with the input and output tight together which behaves as a “diode" connected device to implement a voltage gain approximately equal to -1. However, since this approach is based on the matching of the inverters, the performance of this D2S results sensitive to PVT variations if the bias point of the inverters is not properly stabilized. In this paper we present a novel topology of inverterbased D2S converter, exploiting an auxiliary, standard-cell-based, error amplifier and a local feedback loop. The proposed D2S, compared to the conventional one, exhibits higher CMRR, improved ICMR and better robustness with respect to PVT variations.We present also an ULV, standard-cell-based OTA, which exploits the proposed D2S converter and shows excellent performance figures of merit with low area footprint
A novel clock gating approach for the design of low-power linear feedback shift register
This paper presents an efficient solution to reduce the power consumption of the popular
linear feedback shift register by exploiting the gated clock approach. The power reduction with respect to
other gated clock schemes is obtained by an efficient implementation of the logic gates and properly
reducing the number of XOR gates in the feedback network. Transistor level simulations are performed by
using standard cells in a 28-nm FD-SOI CMOS technology and a 300-MHz clock. Simulation results show
a power reduction with respect to traditional implementations, which reaches values higher than 30%
A 0.3 V, rail-to-rail, ultralow-power, non-tailed, body-driven, sub-threshold amplifier
A novel, inverter-based, fully differential, body-driven, rail-to-rail, input stage topology is
proposed in this paper. The input stage exploits a replica bias control loop to set the common mode
current and a common mode feed-forward strategy to set its output common mode voltage. This
novel cell is used to build an ultralow voltage (ULV), ultralow-power (ULP), two-stage, unbuffered
operational amplifier. A dual path compensation strategy is exploited to improve the frequency
response of the circuit. The amplifier has been designed in a commercial 130 nm CMOS technology
from STMicroelectronics and is able to operate with a nominal supply voltage of 0.3 V and a power
consumption as low as 11.4 nW, while showing about 65 dB gain, a gain bandwidth product around
3.6 kHz with a 50 pF load capacitance and a common mode rejection ratio (CMRR) in excess of
60 dB. Transistor-level simulations show that the proposed circuit outperforms most of the state
of the art amplifiers in terms of the main figures of merit. The results of extensive parametric and
Monte Carlo simulations have demonstrated the robustness of the proposed circuit to PVT and
mismatch variations
the euso balloon instrument
EUSO-Balloon is a pathfinder mission for JEM-EUSO (Extreme Universe Space Observatory on-board the Japanese Experiment Module), the near-UV telescope proposed to be installed on board the International Space Station (ISS) before the end of this decade. The main objective of this pathfinder mission is to perform a full scale end-to-end test of all the key technologies and instrumentation of JEM-EUSO detectors and to prove the entire detection chain. The JEM-EUSO instrument consists of an UV telescope designed to focus the signal of the UV tracks generated by Extreme Energy Cosmic Rays propagating in Earth's atmosphere, onto a finely pixelized UV camera. The EUSO-Balloon instrument, smaller than the one designed for the ISS, is currently developed as a payload of a stratospheric balloon operated by the French Centre National d'Etudes Spatiales (CNES) and will be launched during the CNES flight campaign in August 2014. This telescope will point towards the nadir from a float altitude of about 40 km. With its Fresnel Optics and Photo-Detector Module, EUSO-Balloon will monitor a 12◦×12◦ wide field of view in a wavelength range between 290 and 430 nm, at a rate of 400'000 frames/sec. In this paper, we will review the main stages of the signal processing of the EUSO-Balloon instrument: the photodetection, the analog electronics, the trigger stages, which select events while rejecting random background, the electronic acquisition system which performs the data management and the monitoring, allowing the instrument control during operation
Response of human engineered cartilage based on articular or nasal chondrocytes to interleukin-1? and low oxygen
Previous studies showed that human nasal chondrocytes (HNC) exhibit higher proliferation and chondrogenic capacity as compared to human articular chondrocytes (HAC). To consider HNC as a relevant alternative cell source for the repair of articular cartilage defects it is necessary to test how these cells react when exposed to environmental factors typical of an injured joint. We thus aimed this study at investigating the responses of HNC and HAC to exposure to interleukin (IL)-1? and low oxygen. For this purpose HAC and HNC harvested from the same donors (N=5) were expanded in vitro and then cultured in pellets or collagen-based scaffolds at standard (19%) or low oxygen (5%) conditions. Resulting tissues were analyzed after a short (3 days) exposure to IL-1?, mimicking the initially inflammatory implantation site, or following a recovery time (1 or 2 weeks for pellets and scaffolds, respectively). After IL-1? treatment, constructs generated by both HAC and HNC displayed a transient loss of GAG (up to 21.8% and 36.8%, respectively) and, consistently, an increased production of metalloproteases (MMP)-1 and -13. Collagen type II and the cryptic fragment of aggrecan (DIPEN), both evaluated immunohistochemically, displayed a trend consistent with GAG and MMPs production. HNC-based constructs exhibited a more efficient recovery upon IL-1? withdrawal, resulting in a higher accumulation of GAG (up to 2.6-fold) compared to the corresponding HAC-based tissues. On the other hand, HAC displayed a positive response to low oxygen culture, while HNC were only slightly affected by oxygen percentage. Collectively, under the conditions tested mimicking the postsurgery articular environment, HNC retained a tissue-forming capacity, similar or even better than HAC. These results represent a step forward in validating HNC as a cell source for cartilage tissue engineering strategies
Analysis and modelling of broad-band ferrite-based coaxial transmission-line transformers
The work presented in the paper focuses on accuracy of models for broad-band ferrite based coaxial transmission-line transformers. Soft-ferrites are largely used in VHF/UHF components allowing band enlargement on the low-edge side. Degradation of frequency performance on the high-edge side are produced both by ferrite losses, and by parasitic capacitance due to connection to the thermal and electrical ground in high power applications. Both a circuital model for low-power applications and a scalable e.m. model for high-power applications are presented and discussed. © 2010 EuMA
A power efficient frequency divider with 55 GHz self-oscillating frequency in SiGe BiCMOS
A power efficient static frequency divider in commercial 55 nm SiGe BiCMOS technology isreported. A standard Current Mode Logic (CML)-based architecture is adopted, and optimizationof layout, biasing and transistor sizes allows achieving a maximum input frequency of 63 GHz anda self-oscillating frequency of 55 GHz, while consuming 23.7 mW from a 3 V supply. This resultsin high efficiency with respect to other static frequency dividers in BiCMOS technology presentedin the literature. The divider topology does not use inductors, thus optimizing the area footprint:the divider core occupies 60×65μm2on silicon
Methods for Model Complexity Reduction for the Nonlinear Calibration of Amplifiers Using Volterra Kernels
Volterra models allow modeling nonlinear dynamical systems, even though they require the estimation of a large number of parameters and have, consequently, potentially large computational costs. The pruning of Volterra models is thus of fundamental importance to reduce the computational costs of nonlinear calibration, and improve stability and speed, while preserving accuracy. Several techniques (LASSO, DOMP and OBS) and their variants (WLASSO and OBD) are compared in this paper for the experimental calibration of an IF amplifier. The results show that Volterra models can be simplified, yielding models that are 4–5 times sparser, with a limited impact on accuracy. About 6 dB of improved Error Vector Magnitude (EVM) is obtained, improving the dynamic range of the amplifiers. The Symbol Error Rate (SER) is greatly reduced by calibration at a large input power, and pruning reduces the model complexity without hindering SER. Hence, pruning allows improving the dynamic range of the amplifier, with almost an order of magnitude reduction in model complexity. We propose the OBS technique, used in the neural network field, in conjunction with the better known DOMP technique, to prune the model with the best accuracy. The simulations show, in fact, that the OBS and DOMP techniques outperform the others, and OBD, LASSO and WLASSO are, in turn, less efficient. A methodology for pruning in the complex domain is described, based on the Frisch–Waugh–Lovell (FWL) theorem, to separate the linear and nonlinear sections of the model. This is essential because linear models are used for equalization and cannot be pruned to preserve model generality vis-a-vis channel variations, whereas nonlinear models must be pruned as much as possible to minimize the computational overhead. This methodology can be extended to models other than the Volterra one, as the only conditions we impose on the nonlinear model are that it is feedforward and linear in the parameters
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