0.13-µm CMOS tunable transconductor based on the body-driven gain boosting technique with application in Gm-C filters

We present a low-voltage low-power CMOS tunable transconductor exploiting body gain boosting to increase the small-signal output resistance. As a distinctive feature, the proposed scheme allows the OTA transconductance to be tuned via the current biasing the gain-boosting circuit. The proposed transconductor has been designed in a 0.13-µm CMOS technology and powered from a 1.2-V supply. To show a possible application, a 0.5-MHz tunable third order Chebyshev low pass filter suitable for the Ultra Low Power Bluetooth Standard has been designed. The filter simulations show that all the requirements of the chosen standard are met, with good performance in terms of linearity, noise and power consumption

Achieving rail-to-rail input operation using level-shift multiplexing technique for all CMOS op-amps

This paper presents a new design approach which can convert any CMOS operational amplifiers to have rail-to-rail common-mode input capability by utilizing few additional hardware elements. The proposed circuit can operate over a wide range of supply voltages from 1-volt to the maximum allowed for the CMOS process, without degrading the ac and dc performances of the amplifier in question over the rail-to-rail operation

Low-voltage Low-power Bulk-driven CMOS Op-Amp Using Negative Miller Compensation for ECG

Two bulk-driven CMOS (Complementary Metal Oxide Semiconductor) operational amplifier (op-amp) designs for electrocardiogram (ECG) application are presented and compared in this paper. Both op-amps are based on two-stage amplification, where bulk-driven differential input is the first stage, while additional DC gain is the second stage. Different compensation techniques were integrated in each op-amp design. Standard Miller compensation was used for the first op-amp parallel with the second stage. The novelty of the second op-amp is that it utilizes negative Miller compensation between the bulk-driven input node and the output node of the first stag, while standard Miller compensation was used in the second stage. The purpose of this work was to compare DC gain, phase margin (PM) and unit gain frequency (UGF) obtained through different simulated compensation strategies and test results. The op-amps were simulated using 0.25 μm CMOS technology. The simulation results are presented using the standard model libraries from Tanner EDA tools, operating on a single rail +0.8V power supply

Low-voltage Low-power Bulk-driven CMOS Op-Amp Using Negative Miller Compensation for ECG

Two bulk-driven CMOS (Complementary Metal Oxide Semiconductor) operational amplifier (op-amp) designs for electrocardiogram (ECG) application are presented and compared in this paper. Both op-amps are based on two-stage amplification, where bulk-driven differential input is the first stage, while additional DC gain is the second stage. Different compensation techniques were integrated in each op-amp design. Standard Miller compensation was used for the first op-amp parallel with the second stage. The novelty of the second op-amp is that it utilizes negative Miller compensation between the bulk-driven input node and the output node of the first stag, while standard Miller compensation was used in the second stage. The purpose of this work was to compare DC gain, phase margin (PM) and unit gain frequency (UGF) obtained through different simulated compensation strategies and test results. The op-amps were simulated using 0.25 μm CMOS technology. The simulation results are presented using the standard model libraries from Tanner EDA tools, operating on a single rail +0.8V power supply

Design of ultra-low-voltage and ultra-low-power analog integrated circuits

埼玉工業大学201

1-V rail-to-rail CMOS opamp with improved bulk-driven input stage

This paper introduces a CMOS operational amplifier with rail-to-rail input and output voltage ranges, suitable for operation in extremely low-voltage environments. The approach is based on a bulk-driven input stage with extended input common-mode voltage range, in which the effective input transconductance is enhanced by means of a partial positive feedback loop. As a result, a gain and gain-bandwidth product performance similar to that of an amplifier using a gate-driven approach is obtained. Output rail-to-rail operation is achieved by means of a push-pull stage, which is biased in class-AB by using a static feedback loop, thus avoiding frequency limitations inherent in dynamic-feedback tuning schemes. The proposed two-stage operational amplifier was designed to operate with a 1-V supply, and a test chip prototype was fabricated in 0.35-µm standard CMOS technology. The experimental performance features an open-loop DC gain higher than 76 dB and a closed-loop unity-gain bandwidth above 8 MHz when a 1-MOhm//17-pF load is connected to the amplifier output

Low-Voltage Bulk-Driven Amplifier Design and Its Application in Implantable Biomedical Sensors

The powering unit usually represents a significant component of the implantable biomedical sensor system since the integrated circuits (ICs) inside for monitoring different physiological functions consume a great amount of power. One method to reduce the volume of the powering unit is to minimize the power supply voltage of the entire system. On the other hand, with the development of the deep sub-micron CMOS technologies, the minimum channel length for a single transistor has been scaled down aggressively which facilitates the reduction of the chip area as well. Unfortunately, as an inevitable part of analytic systems, analog circuits such as the potentiostat are not amenable to either low-voltage operations or short channel transistor scheme. To date, several proposed low-voltage design techniques have not been adopted by mainstream analog circuits for reasons such as insufficient transconductance, limited dynamic range, etc. Operational amplifiers (OpAmps) are the most fundamental circuit blocks among all analog circuits. They are also employed extensively inside the implantable biosensor systems. This work first aims to develop a general purpose high performance low-voltage low-power OpAmp. The proposed OpAmp adopts the bulk-driven low-voltage design technique. An innovative low-voltage bulk-driven amplifier with enhanced effective transconductance is developed in an n-well digital CMOS process operating under 1-V power supply. The proposed circuit employs auxiliary bulk-driven input differential pairs to achieve the input transconductance comparable with the traditional gate-driven amplifiers, without consuming a large amount of current. The prototype measurement results show significant improvements in the open loop gain (AO) and the unity-gain bandwidth (UGBW) compared to other works. A 1-V potentiostat circuit for an implantable electrochemical sensor is then proposed by employing this bulk-driven amplifier. To the best of the author’s knowledge, this circuit represents the first reported low-voltage potentiostat system. This 1-V potentiostat possesses high linearity which is comparable or even better than the conventional potentiostat designs thanks to this transconductance enhanced bulk-driven amplifier. The current consumption of the overall potentiostat is maintained around 22 microampere. The area for the core layout of the integrated circuit chip is 0.13 mm2 for a 0.35 micrometer process

Low Voltage Low Power Analogue Circuits Design

Disertační práce je zaměřena na výzkum nejběžnějších metod, které se využívají při návrhu analogových obvodů s využití nízkonapěťových (LV) a nízkopříkonových (LP) struktur. Tyto LV LP obvody mohou být vytvořeny díky vyspělým technologiím nebo také využitím pokročilých technik návrhu. Disertační práce se zabývá právě pokročilými technikami návrhu, především pak nekonvenčními. Mezi tyto techniky patří využití prvků s řízeným substrátem (bulk-driven - BD), s plovoucím hradlem (floating-gate - FG), s kvazi plovoucím hradlem (quasi-floating-gate - QFG), s řízeným substrátem s plovoucím hradlem (bulk-driven floating-gate - BD-FG) a s řízeným substrátem s kvazi plovoucím hradlem (quasi-floating-gate - BD-QFG). Práce je také orientována na možné způsoby implementace známých a moderních aktivních prvků pracujících v napěťovém, proudovém nebo mix-módu. Mezi tyto prvky lze začlenit zesilovače typu OTA (operational transconductance amplifier), CCII (second generation current conveyor), FB-CCII (fully-differential second generation current conveyor), FB-DDA (fully-balanced differential difference amplifier), VDTA (voltage differencing transconductance amplifier), CC-CDBA (current-controlled current differencing buffered amplifier) a CFOA (current feedback operational amplifier). Za účelem potvrzení funkčnosti a chování výše zmíněných struktur a prvků byly vytvořeny příklady aplikací, které simulují usměrňovací a induktanční vlastnosti diody, dále pak filtry dolní propusti, pásmové propusti a také univerzální filtry. Všechny aktivní prvky a příklady aplikací byly ověřeny pomocí PSpice simulací s využitím parametrů technologie 0,18 m TSMC CMOS. Pro ilustraci přesného a účinného chování struktur je v disertační práci zahrnuto velké množství simulačních výsledků.The dissertation thesis is aiming at examining the most common methods adopted by analog circuits' designers in order to achieve low voltage (LV) low power (LP) configurations. The capability of LV LP operation could be achieved either by developed technologies or by design techniques. The thesis is concentrating upon design techniques, especially the non–conventional ones which are bulk–driven (BD), floating–gate (FG), quasi–floating–gate (QFG), bulk–driven floating–gate (BD–FG) and bulk–driven quasi–floating–gate (BD–QFG) techniques. The thesis also looks at ways of implementing structures of well–known and modern active elements operating in voltage–, current–, and mixed–mode such as operational transconductance amplifier (OTA), second generation current conveyor (CCII), fully–differential second generation current conveyor (FB–CCII), fully–balanced differential difference amplifier (FB–DDA), voltage differencing transconductance amplifier (VDTA), current–controlled current differencing buffered amplifier (CC–CDBA) and current feedback operational amplifier (CFOA). In order to confirm the functionality and behavior of these configurations and elements, they have been utilized in application examples such as diode–less rectifier and inductance simulations, as well as low–pass, band–pass and universal filters. All active elements and application examples have been verified by PSpice simulator using the 0.18 m TSMC CMOS parameters. Sufficient numbers of simulated plots are included in this thesis to illustrate the precise and strong behavior of structures.

Scaling the bulk-driven MOSFET into deca-nanometer bulk CMOS technologies

The International Technology Roadmap for Semiconductors predicts that the nominal power supply voltage, VDD, will fall to 0.7 V by the end of the bulk CMOS era. At that time, it is expected that the long-channel threshold voltage of a MOSFET, VT0, will rise to 35.5% of VDD in order to maintain acceptable off-state leakage characteristics in digital systems. Given the recent push for system-on-a-chip integration, this increasing trend in VT0/VDD poses a serious threat to the future of analog design because it causes traditional analog circuit topologies to experience progressively problematic signal swing limitations in each new process generation. To combat the process-scaling-induced signal swing limitations of analog circuitry, researchers have proposed the use of bulk-driven MOSFETs. By using the bulk terminal as an input rather than the gate, the bulk-driven MOSFET makes it possible to extend the applicability of any analog cell to extremely low power supply voltages because VT0 does not appear in the device\u27s input signal path. Since the viability of the bulk-driven technique was first investigated in a 2 um p-well process, there have been numerous reports of low-voltage analog designs incorporating bulk-driven MOSFETs in the literature - most of which appear in technologies with feature sizes larger than 0.18 um. However, as of yet, no effort has been undertaken to understand how sub-micron process scaling trends have influenced the performance of a bulk-driven MOSFET, let alone make the device more adaptable to the deca-nanometer technologies widely used in the analog realm today. Thus, to further the field\u27s understanding of the bulk-driven MOSFET, this dissertation aims to examine the implications of scaling the device into a standard 90 nm bulk CMOS process. This dissertation also describes how the major disadvantages of a bulk-driven MOSFET - i.e., its reduced intrinsic gain, its limited frequency response and its large layout area requirement - can be mitigated through modifications to the device\u27s vertical doping profile and well structure. To gauge the potency of the proposed process changes, an optimized n-type bulk-driven MOSFET has been designed in a standard 90 nm bulk CMOS process via the 2-D device simulator, ATLAS

Blocker Tolerant Radio Architectures

Future radio platforms have to be inexpensive and deal with a variety of co- existence issues. The technology trend during the last few years is towards system- on-chip (SoC) that is able to process multiple standards re-using most of the digital resources. A major bottle-neck to this approach is the co-existence of these standards operating at different frequency bands that are hitting the receiver front-end. So the current research is focused on the power, area and performance optimization of various circuit building blocks of a radio for current and incoming standards. Firstly, a linearization technique for low noise amplifiers (LNAs) called, Robust Derivative Superposition (RDS) method is proposed. RDS technique is insensitive to Process Voltage and Temperature (P.V.T.) variations and is validated with two low noise transconductance amplifier (LNTA) designs in 0.18µm CMOS technology. Measurement results from 5 dies of a resistive terminated LNTA shows that the pro- posed method improves IM3 over 20dB for input power up to -18dBm, and improves IIP_(3) by 10dB. A 2V inductor-less broadband 0.3 to 2.8GHz balun-LNTA employing the proposed RDS linearization technique was designed and measured. It achieves noise figure of 6.5dB, IIP3 of 16.8dBm, and P1dB of 0.5dBm having a power consumption of 14.2mW. The balun LNTA occupies an active area of 0.06mm2. Secondly, the design of two high linearity, inductor-less, broadband LNTAs employing noise and distortion cancellation techniques is presented. Main design issues and the performance trade-offs of the circuits are discussed. In the fully differential architecture, the first LNTA covers 0.1-2GHz bandwidth and achieves a minimum noise figure (NFmin) of 3dB, IIP_(3) of 10dBm and a P_(1dB) of 0dBm while dissipating 30.2mW. The 2^(nd) low power bulk driven LNTA with 16mW power consumption achieves NFmin of 3.4dB, IIP3 of 11dBm and 0.1-3GHz bandwidth. Each LNTA occupy an active area of 0.06mm2 in 45nm CMOS. Thirdly, a continuous-time low-pass ∆ΣADC equipped with design techniques to provide robustness against loop saturation due to blockers is presented. Loop over- load detection and correction is employed to improve the ADC’s tolerance to blockers; a fast overload detector activates the input attenuator, maintaining the ADC in linear operation. To further improve ADC’s blocker tolerance, a minimally-invasive integrated low-pass filter that reduces the most critical adjacent/alternate channel blockers is implemented. An ADC prototype is implemented in a 90nm CMOS technology and experimentally it achieves 69dB dynamic range over a 20MHz bandwidth with a sampling frequency of 500MHz and 17.1mW of power consumption. The alternate channel blocker tolerance at the most critical frequency is as high as -5.5dBFS while the conventional feed-forward modulator becomes unstable at -23.5dBFS of blocker power. The proposed blocker rejection techniques are minimally-invasive and take less than 0.3µsec to settle after a strong agile blocker appears. Finally, a new radio partitioning methodology that gives robust analog and mixed signal radio development in scaled technology for SoC integration, and the co-design of RF FEM-antenna system is presented. Based on the proposed methodology, a CMOS RF front-end module (FEM) with power amplifier (PA), LNA and transmit/receive switch, co-designed with antenna is implemented. The RF FEM circuit is implemented in a 32nm CMOS technology. Post extracted simulations show a noise figure < 2.5dB, S_(21) of 14dB, IIP3 of 7dBm and P1dB of -8dBm for the receiver. Total power consumption of the receiver is 11.8mW from a 1V supply. On the trans- mitter side, PA achieves peak RF output power of 22.34dBm with peak power added efficiency (PAE) of 65% and PAE of 33% with linearization at -6dB power back off. Simulations show an efficiency of 80% for the miniaturized dipole antenna