0.3‐V bulk‐driven programmable gain amplifier in 0.18‐µm CMOS

A new solution for an ultra low voltage bulk‐driven programmable gain amplifier (PGA) is described in the paper. While implemented in a standard n‐well 0.18‐µm complementary metal–oxide–semiconductor (CMOS) process, the circuit operates from 0.3 V supply, and its voltage gain can be regulated from 0 to 18 dB with 6‐dB steps. At minimum gain, the PGA offers nearly rail‐to‐rail input/output swing and the input referred thermal noise of 2.37 μV/Hz^1/2, which results in a 63‐dB dynamic range (DR). Besides, the total power consumption is 96 nW, the signal bandwidth is 2.95 kHz at 5‐pF load capacitance and the third‐order input intercept point (IIP₃) is 1.62 V. The circuit performance was simulated with LTspice. Copyright © 2016 John Wiley & Sons, Ltd.     

Design and simulation of novel amplifier‐based mixer for ISM band wireless applications

This letter describes a low‐voltage low‐power (LV‐LP) 2.4‐GHz mixer for Industrial, Scientific and Medical (ISM) band wireless applications. The approach is based on a two‐stage amplifier, and the Gilbert switch stage is inserted between the two amplifier stages. The proposed amplifier‐based mixer delivers a remarkable conversion gain of 13 dB with a local oscillator (LO) power of 7 dBm, while consuming only 1.05‐mW DC power from a 0.8‐V supply voltage. The input‐referred third‐order intercept point (IIP3) of the mixer is 3.82 dBm, and the chip area is only 0.429 mm². The results indicate that this mixer is suitable for the low‐voltage low‐power applications. Copyright © 2014 John Wiley & Sons, Ltd.     

A pseudo‐differential current‐reuse structure for opamp‐sharing pipelined analog‐to‐digital converters

In this paper, a power efficient pseudo‐differential (PD) current‐reuse structure is presented to alleviate the memory effects of opamp‐sharing in pipelined analog‐to‐digital converters. To implement the PD current‐reuse structure, a switched‐capacitor circuit is introduced for multiplying digital‐to‐analog converter, which has a slight modification compared with the conventional switching scheme with no power penalty. In the proposed multiplying digital‐to‐analog converter circuit, the common‐mode offset amplification of the PD structures is eliminated. Moreover, a PD current‐reuse amplifier is developed from the telescopic structure with an inverter‐based gain‐boosting circuit. The effectiveness of the proposed structure is evaluated in comparison with existing current‐reuse techniques. Copyright © 2014 John Wiley & Sons, Ltd.     

A high‐order curvature‐corrected CMOS bandgap voltage reference with constant current technique

A high‐order curvature‐corrected complementary metal–oxide–semiconductor (CMOS) bandgap voltage reference (BGR), utilizing the temperature‐dependent resistor and constant current technique, is presented. Considering the process variation, a resistor trimming network is introduced in this work. The circuit is implemented in a standard 0.35‐µm CMOS process. The measurement results have confirmed that the proposed BGR operates with a supply voltage of 1.8 V, consuming 45 μW at room temperature (25 °C), and the temperature coefficient of the output voltage reference is about 5.5 ppm/°C from −40 °C to 125 °C. The measured power supply rejection ratio is −38.8 dB at 1 kHz. The BGR is compatible with low‐voltage and low‐power circuit design when the structure of operational amplifiers and all the devices in the proposed bandgap reference are properly designed. Copyright © 2012 John Wiley & Sons, Ltd.     

A sub‐1 V nanopower temperature‐compensated sub‐threshold CMOS voltage reference with 0.065%/V line sensitivity

We present the design of a nanopower sub‐threshold CMOS voltage reference and the measurements performed over a set of more than 70 samples fabricated in 0.18 µm CMOS technology. The circuit provides a temperature‐compensated reference voltage of 259 mV with an extremely low line sensitivity of only 0.065% at the price of a less effective temperature compensation. The voltage reference properly works with a supply voltage down to 0.6 V and with a power dissipation of only 22.3 nW. Very similar performance has been obtained with and without the inclusion of the start‐up circuit. Copyright © 2013 John Wiley & Sons, Ltd.     

A common‐mode replica compensated inductor–capacitor voltage‐controlled oscillator for mixed‐signal system‐on‐chip applications

A novel 1.57 GHz complementary metal–oxide semiconductor inductor–capacitor voltage‐controlled oscillator with the common‐mode replica compensation is introduced for mixed‐signal system‐on‐chip applications. In order to alleviate power line disturbances, the center tap node of differential symmetric inductor and the replica biasing circuit are adopted in the differential voltage regulating unit to reduce power supply sensitivity. In addition, this proposed design also leads to low tuning gain and low power dissipation. The post‐layout simulation results under the Taiwan Semiconductor Manufacturing Company's mixed‐signal 0.18 µm 1P6M process show that the proposed design achieves power supply rejection of ?68.6 dB at low frequencies and 1.2 MHz/V pushing sensitivity. It exhibits phase noise of ?130.6 dBc/Hz at a 1 MHz offset from a 1.57 GHz carrier yet dissipates only 5.58 mW under a 1.8 V power supply. Copyright © 2011 John Wiley & Sons, Ltd.     

A sub‐1V supply CMOS voltage reference generator

An integrated sub‐1V voltage reference generator, designed in standard 90‐nm CMOS technology, is presented in this paper. The proposed voltage reference circuit consists of a conventional bandgap core based on the use of p‐n‐p substrate vertical bipolar devices and a voltage‐to‐current converter. The former produces a current with a positive temperature coefficient (TC), whereas the latter translates the emitter‐base voltage of the core p‐n‐p bipolar device to a current with a negative TC. The circuit includes two operational amplifiers with a rail‐to‐rail output stage for enabling stable and robust operation overall process and supply voltage variations while it employs a total resistance of less than 600 K Ω. Detailed analysis is presented to demonstrate that the proposed circuit technique enables die area reduction. The presented voltage reference generator exhibits a PSRR of 52.78 dB and a TC of 23.66ppm/^°C in the range of ? 40 and 125^°C at the typical corner case at 1 V. The output reference voltage of 510 mV achieves a total absolute variation of ± 3.3% overall process and supply voltage variations and a total standard deviation, σ, of 4.5 mV, respectively, in the temperature range of ? 36 and 125^°C. Copyright © 2011 John Wiley & Sons, Ltd.     

A low‐voltage band‐gap reference circuit with second‐order analyses

A new band‐gap reference (BGR) circuit employing sub‐threshold current is proposed for low‐voltage operations. By employing the fraction of V_BE and the sub‐threshold current source, the proposed BGR circuit with chip area of 0.029mm² was fabricated in the standard 0.18µm CMOS triple‐well technology. It generates reference voltage of 170 mV with power consumption of 2.4µW at supply voltage of 1 V. The agreement between simulation and measurement shows that the variations of reference voltage are 1.3 mV for temperatures from ?20 to 100^°C, and 1.1 mV per volt for supply voltage from 0.95 to 2.5 V, respectively. Copyright © 2010 John Wiley & Sons, Ltd.     

Study of a DC voltage equalizing circuit and a zero‐sequence voltage control method for a diode‐clamped linear amplifier

2,3 This paper proposes a DC voltage equalizing circuit for a diode‐clamped linear amplifier (DCLA). The DCLA consists of series‐connected complementary MOSFETs and diode clamping circuits, with an experimental efficiency as high as 90% without switching operation. The DCLA requires a DC voltage equalizing circuit to divide the DC voltage into several levels. The proposed DC voltage equalizing circuit allows the use of a diode rectifier with a smoothing capacitor as a power supply for the DCLA. Zero‐sequence voltage control is proposed to improve the efficiency of the DCLA. As a result, a prototype 12‐series DCLA demonstrates an experimental efficiency as high as 94.7%. © 2012 Wiley Periodicals, Inc. Electr Eng Jpn, 179(2): 55–63, 2012; Published online in Wiley Online Library ( wileyonlinelibrary.com ). DOI 10.1002/eej.21131     

A portable class of 3‐transistor current references with low‐power sub‐0.5 V operation

This work proposes a new class of current references based on only 3 transistors that allows sub‐0.5 V operation. The circuit consists of a 2‐transistor block that generates a proportional‐to‐absolute‐temperature or a complementary‐to‐absolute‐temperature voltage and a load transistor. The idea of a 3T current reference is validated by circuit simulations for different complementary metal‐oxide‐semiconductor technologies and by experimental measurements on a large set of test chips fabricated with a commercial 0.18 μm complementary metal‐oxide‐semiconductor process. As compared to the state‐of‐art competitors, the 3T current reference exhibits competitive performance in terms of temperature coefficient (578 ppm/°C), line sensitivity (3.9%/V), and power consumption (213 nW) and presents a reduction by a factor of 2 to 3 in terms of minimum operating voltage (0.45 V) and an improvement of 1 to 2 orders of magnitude in terms of area occupation (750 μm²). In spite of the extremely reduced silicon area, the fabricated chips exhibit low‐process sensitivity (2.7%). A digital trimming solution to significantly reduce the process sensitivity is also presented and validated by simulations.     

A 0.8‐V supply bulk‐driven operational transconductance amplifier and Gm‐C filter in 0.18 µm CMOS process

A low voltage bulk‐driven operational transconductance amplifier (OTA) and its application to implement a tunable Gm‐C filter are presented. The linearity of the proposed OTA is achieved by nonlinear terms cancelation technique, using two paralleled differential topologies with opposite signs in the third‐order harmonic distortion term of the differential output current. The proposed OTA uses 0.8 V supply voltage and consumes 31.2 μW. The proposed OTA shows a total harmonic distortion of better than ?40 dB over the tuning range of the transconductance, by applying 800 mV_ppd sine wave input signal with 1 MHz frequency. The OTA has been used to implement a third‐order low‐pass Gm‐C filter, which can be used for wireless sensor network applications. The filter can operate as the channel select filter and variable gain amplifier, simultaneously. The gain of the filter can be tuned from ?1 to 23 dB, which results in power consumptions of 187.2 to 450.6 μW, respectively. The proposed OTA and filter have been simulated in a 0.18 µm CMOS technology. Simulations of process corners and temperature variations are also included in the paper. Copyright © 2014 John Wiley & Sons, Ltd.     

A common‐gate common‐source low noise amplifier based RF front end with selective input impedance matching for blocker‐resilient receivers

This paper presents an integrated wideband radio frequency front end with improved blocker resilience achieved through selective voltage attenuation at both input and output nodes of the low noise amplifier (LNA). The architecture differs from traditional LNA architectures where blockers are only attenuated at LNA output node. The proposed dual attenuation is attained by designing a low intrinsic input impedance common‐gate common‐source LNA with capacitive feedback, together with an N‐path filtering load. The capacitive feedback across the LNA ensures that the selective N‐path filtering profile at the LNA output is transferred to the LNA input nodes creating a selective input impedance. Consequently, the achieved front‐end input impedance is low at blocker frequencies and matched to the source impedance at the desired frequencies, creating the desired voltage attenuation for blockers. Further, a detailed theoretical analysis of proposed architecture is presented, which leads to clear design guidelines. Evaluated in a 28‐nm fully depleted silicon‐on‐insulator complementary metal oxide semiconductor (CMOS) process, front end is designed for wideband operation from 0.7 to 2.7 GHz. It consumes 11‐mA current from a 1‐V supply (excluding local oscillator (LO) buffering) and possesses a maximum noise figure of 5.1 dB. The front end demonstrates an out‐of‐band blocker compression point of ?1.5 dBm and out‐of‐band IIP3 of +14 dBm at a 100‐MHz offset from LO frequency. In comparison with a traditional common‐gate common‐source LNA‐based front end with wideband input impedance matching, the proposed front end achieves 3.5‐dB improvement in the blocker compression point at a 100‐MHz offset from LO.     

Design of a 75‐nW, 0.5‐V subthreshold complementary metal–oxide–semiconductor operational amplifier

This work focuses on the subthreshold design of ultra low‐voltage low‐power operational amplifiers. A well‐defined procedure for the systematic design of subthreshold operational amplifiers (op‐amps) is introduced. The design of a 0.5‐V two‐stage Miller‐compensated amplifier fabricated with a 0.18‐µm complementary metal–oxide–semiconductor process is presented. The op‐amp operates with all transistors in subthreshold region and achieves a DC gain of 70 dB and a gain–bandwidth product of 18 kHz, dissipating just 75 nW. The active area of the chip is ≈0.057 mm². Experimental results demonstrate that well‐designed subthreshold op‐amps are a very attractive solution to implement sub‐1‐V energy‐efficient applications for modern portable electronic systems. A comparative analysis with low‐voltage, low‐power op‐amp designs available in the literature highlights that subthreshold op‐amps designed according to the proposed design procedure achieve a better trade‐off among speed, power, and load capacitance. Copyright © 2013 John Wiley & Sons, Ltd.     

A subthreshold current‐sensing ΣΔ modulator for low‐voltage and low‐power sensor interfaces

A continuous‐time (CT) ΣΔ modulator for sensing and direct analog‐to‐digital conversion of nA‐range (subthreshold) currents is presented in this work. The presented modulator uses a subthreshold technique based on subthreshold source‐coupled logic cells to efficiently convert subthreshold current to digital code without performing current‐to‐voltage conversion. As a benefit of this technique, the current‐sensing CT ΣΔ modulator operates at low voltage and consumes very low power, which makes it convenient for low‐power and low‐voltage current‐mode sensor interfaces. The prototype design is implemented in a 0.18 µm standard complementary metal‐oxide semiconductor technology. The modulator operates with a supply voltage of 0.8 V and consumes 5.43 μW of power at the maximum bandwidth of 20 kHz. The obtainable current‐sensing resolution ranges from effective number of bits (ENOB) = 7.1 bits at a 5 kHz bandwidth to ENOB = 6.5 bits at a 20 kHz bandwidth (ENOB). The obtained power efficiency (peak FoM = 1.5 pJ/conv) outperforms existing current‐mode analog‐to‐digital converter designs and is comparable with the voltage‐mode CT ΣΔ modulators. The modulator generates very low levels of switching noise thanks to CT operation and subthreshold current‐mode circuits that draw a constant subthreshold current from the voltage supply. The presented modulator is used as a readout interface for sensors with current‐mode output in ultra low‐power conditions and is also suitable to perform on‐chip current measurements in power management circuits. Copyright © 2014 John Wiley & Sons, Ltd.     

A 0.75‐V, 4‐μW, 15‐ppm/°C, 190 °C temperature range,voltage reference

A low‐voltage, low‐power, low‐area, wide‐temperature‐range CMOS voltage reference is presented. The proposed reference circuit achieves a measured temperature drift of 15 ppm/°C for an extremely wide temperature range of 190 °C (?60 to 130 °C) while consuming only 4 μW at 0.75 V. It performs a high‐order curvature correction of the reference voltage while consisting of only CMOS transistors operating in subthreshold and polysilicon resistors, without utilizing any diodes or external components such as compensating capacitors. A trade‐off of this circuit topology, in its current form, is the high line sensitivity. The design was fabricated using TowerJazz semiconductor's 0.18‐µm standard CMOS technology and occupies an area of 0.039 mm². The proposed reference circuit is suitable for high‐precision, low‐energy‐budget applications, such as mobile systems, wearable electronics, and energy harvesting systems. Copyright © 2015 John Wiley & Sons, Ltd.     

A 0.6‐V sub‐mW X‐band RFSOI CMOS LNA with novel complementary current‐reused technique

A fully integrated 0.6 V low‐noise amplifier (LNA) for X‐band receiver application based on 0.18 μm RFSOI CMOS technology is presented in this paper. To achieve low noise and high gain with the constraint of low voltage and low power consumption, a novel modified complementary current‐reused LNA using forward body bias technique is proposed. A diode connected MOSFET forward bias technique is employed to minimize the body leakage and improve the noise performance. A notch filter isolator is constructed to improve the linearity of low voltage. The measured results show that the proposed LNA achieves a power gain of 11.2 dB and a noise figure of 3.8 dB, while consuming a DC current of only 1.6 mA at supply voltage of 0.6 V. Copyright © 2017 John Wiley & Sons, Ltd.     

0.5‐V bulk‐driven OTA and its applications

A new 0.5‐V bulk‐driven operational transconductance amplifier (OTA), designed in 50 nm CMOS technology, is presented in the paper. The circuit is characterized by improved linearity and dynamic range obtained for MOS devices operating in moderate inversion region. Some basic applications of the OTA such as a voltage integrator and a second‐order low‐pass filter have also been described. The filter is compared to other low‐voltage filters presented in the literature. Copyright © 2013 John Wiley & Sons, Ltd.     

0.5‐V bulk‐driven differential amplifier

A new 0.5‐V fully differential amplifier is proposed in this article. The structure incorporates a differential bulk‐driven voltage follower with conventional gate‐driven amplification stages. The bulk‐driven voltage follower presents differential gain equal to unity while suppressing the input common‐mode voltage. The amplifier operates at a supply voltage of less than 0.5 V, performing input transconductance almost equal to a gate transconductance and relatively high voltage gain without the need for gain boosting. The circuit was designed and simulated using a standard 0.18‐µm CMOS n‐well process. The low‐frequency gain of the amplifier was 56 dB, the unity gain bandwidth was approximately 3.2 MHz, the spot noise was 100 nV/√Hz at 100 kHz and the current consumption was 90 μΑ. Copyright © 2012 John Wiley & Sons, Ltd.     

A 4.8–6.8 GHz low phase noise LC VCO in 0.13‐µm CMOS technology

This letter presents a novel LC voltage controlled oscillator (VCO) supporting the high‐speed serial transmission standard of RapidIO in 0.13‐µm complementary metal‐oxide semiconductor technology. The low phase noise is achieved through several techniques including current source switching, parallel coupled negative transconductance cell, and varactor bias combination scheme. Measured results of proposed circuit show a low phase noise of ?120 dBc/Hz at 1 MHz offset from 6.25 GHz carrier and tuning range of 4.8 ~ 6.8 GHz (34.48%) while consuming 7.4 mW under the supply voltage of 1.2 V. Copyright © 2015 John Wiley & Sons, Ltd.     

Noise‐immune dual‐rail dynamic circuit for wide fan‐in gates in asynchronous designs

Dual‐rail dynamic logic circuits can provide inverting and noninverting outputs, especially for asynchronous designs, to implement complicated gates at the cost of approximately doubling the area and power consumption. In this paper, a new dual‐rail dynamic circuit is proposed which has lower die area consumption and higher noise immunity without dramatic speed degradation for even wide fan‐in gates for asynchronous circuits. The main idea in the proposed circuit is that voltage due to the current of the pulldown network (PDN) is compared with the reference voltage to provide two complementary outputs. The reference voltage almost corresponds to the leakage current of the PDN with all transistors being off. The proposed circuit is compared with conventional dual‐rail circuits such as differential domino logic and differential cross‐coupled domino logic. Simulation results for 32‐bit‐wide OR gates designed using high‐performance 16‐nm predictive technology model demonstrate significant performance advantages such as 66% power reduction and at least 2.86× noise‐immunity improvement at the same delay compared to the differential domino circuits. © 2012 Institute of Electrical Engineers of Japan. Published by John Wiley & Sons, Inc.