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.     

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.     

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.     

A 10 b 25 MS/s 4.8 mW 0.13 µm CMOS ADC with switched‐bias power‐reduction techniques

This paper proposes a 10 b 25 MS/s 4.8 mW 0.13 µm CMOS analog‐to‐digital converter (ADC) for high‐performance portable wireless communication systems, such as digital video broadcasting, digital audio broadcasting, and digital multimedia broadcasting (DMB) systems, simultaneously requiring a low‐voltage, low‐power, and small chip area. A two‐stage pipeline architecture optimizes the overall chip area and power dissipation of the proposed ADC at the target resolution and sampling rate, while switched‐bias power‐reduction techniques reduce the power consumption of the power‐hungry analog amplifiers. Low‐noise reference currents and voltages are implemented on chip with optional off‐chip voltage references for low‐power system‐on‐a‐chip applications. An optional down‐sampling clock signal selects a sampling rate of 25 or 10 MS/s depending on applications in order to further reduce the power dissipation. The prototype ADC fabricated in a 0.13 µm 1P8M CMOS technology demonstrates a measured peak differential non‐linearity and integral non‐linearity within 0.42 LSB and 0.91 LSB and shows a maximum signal‐to‐noise‐and‐distortion ratio and spurious‐free dynamic range of 56 and 65 dB at all sampling frequencies up to 25 MHz, respectively. The ADC with an active die area of 0.8 mm² consumes 4.8 and 2.4 mW at 25 and 10 MS/s, respectively, with a 1.2 V supply. Copyright © 2008 John Wiley & Sons, Ltd.     

A simultaneously bidirectional inductively coupled link in a 0.13‐µm CMOS technology

A simultaneously bidirectional inductively coupled link has been developed to provide higher signaling bandwidth for a given inductively coupled channel. Two types of echo signals, that is, the resistive and inductive echo signals, are canceled without an inductive replica load to save silicon area. The resistive echo signal is canceled with a replica driver driving a resistive replica load, while the inductive echo signal is canceled by deliberately controlling the timing of a receiver comparator. The prototype implemented in a 0.13‐µm complementary metal–oxide–semiconductor (CMOS) technology occupies 0.019 mm² including an on‐chip channel inductor and shows 9.1‐pJ/b energy efficiency at 3.0‐Gbps signaling bandwidth, that is, 1.5 Gbps in each signaling direction. Copyright © 2016 John Wiley & Sons, Ltd.     

Low‐noise,low‐sensitivity,active‐RC allpole filters using impedance tapering

In this paper it is shown that active‐RC filters whose sensitivity to component tolerances can be minimized by impedance tapering, will also have low output thermal noise. It is shown that impedance tapering will also reduce output thermal noise in OTA‐C filters. Copyright © 2010 John Wiley & Sons, Ltd.     

A 14b 150 MS/s 140 mW 2.0 mm2 0.13µm CMOS A/D converter for software‐defined radio systems

This work proposes a 14 b 150 MS/s CMOS A/D converters (ADC) for software‐defined radio systems requiring simultaneously high‐resolution, low‐power, and small chip area at high speed. The proposed calibration‐free ADC employs a wide‐band low‐noise input sample‐and‐hold amplifier (SHA) along with a four‐stage pipelined architecture optimizing scaling‐down factors for the sampling capacitance and the input trans‐conductance of amplifiers in each stage to minimize thermal noise effect and power consumption. A signal‐insensitive 3‐D fully symmetric layout achieves a 14 b level resolution by reducing a capacitor mismatch of three MDACs. The prototype ADC in a 0.13µm 1P8M CMOS technology demonstrates a measured differential nonlinearity (DNL) and integral nonlinearity within 0.81LSB and 2.83LSB at 14 b, respectively. The ADC shows a maximum signal‐to‐noise‐and‐distortion ratio of 64 and 61 dB and a maximum spurious‐free dynamic range of 71 and 70 dB at 120 and 150 MS/s, respectively. The ADC with an active die area of 2.0mm² consumes 140 mW at 150 MS/s and 1.2 V. Copyright © 2010 John Wiley & Sons, Ltd.     

A 0.7 V, 2.7 μW, 12.9 ppm/° C over 180° C CMOS subthreshold voltage reference

An all‐CMOS, low‐power, wide‐temperature‐range, curvature‐compensated voltage reference is presented. The proposed topology achieves a measured temperature coefficient of 12.9 ppm/°C for a wide temperature range of 180°C ( − 60 to 120°C) at a bias voltage of 0.7 V while consuming a mere 2.7 μW. The high‐order curvature compensation, which leads to a low‐temperature sensitivity of the reference voltage, is performed using a new, simple, but efficient methodology. The non‐linearities of an N‐type metal‐oxide‐semiconductor (NMOS) device operated in subthreshold are combined with the non‐linearities of two different kinds of polysilicon resistors, leading to the improved performance. The extended temperature range of this voltage reference gives it an important competitive advantage, especially at lower temperatures, where prior art designs' performance deteriorate abruptly. In addition, it utilizes an innovative trimming methodology whereby two trimmable resistors enable the tuning of both the overall slope and non‐linearities of the temperature sensitivity. The design was fabricated using TowerJazz Semiconductor's CMOS 0.18 μm technology, without using diodes or any external components such as compensating capacitors. It has an area of 0.023 mm² and is suitable for high‐performance power‐aware applications as well as applications operating in extreme temperatures. Copyright © 2016 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.     

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.     

Low‐power,low‐noise,active‐RC band‐pass filters using a ‘lossy’ LP–BP transformation

A new and straightforward design procedure for simple canonical topologies of allpole, active‐RC, low‐selectivity band‐pass (BP) filters, with low sensitivity to component tolerances is presented. The procedure is primarily intended for discrete‐component, low‐power filter applications using just one amplifier for relatively high‐order filters. The design procedure starts out with an ‘optimized’ low‐pass (LP) prototype filter, yielding an ‘optimized’ BP filter, whereby the wealth of ‘optimized’ single‐amplifier LP filter designs can be exploited. Using a so‐called ‘lossy’ LP–BP transformation, closed‐form design equations for the design of second‐ to eighth‐order, single‐amplifier BP filters are presented. The low sensitivity, low power consumption, and low noise features of the resulting circuits, as well as the influence of the finite gain‐bandwidth product and component spread, are demonstrated for the case of a fourth‐order filter example. The optimized single‐opamp fourth‐order filter is compared with other designs, such as the cascade of optimized Biquads. Using PSpice with a TL081 opamp model, the filter performance is simulated and the results compared and verified with measurements of a discrete‐component breadboard filter using 1% resistors, 1% capacitors, and a TL081 opamp. Copyright © 2011 John Wiley & Sons, Ltd.     

Design and implementation of sub 0.5‐V OTAs in 0.18‐μm CMOS

A family of bulk‐driven CMOS operational transconductance amplifiers (OTAs) has been designed for extremely low supply voltages (0.3‐0.5 V). Three OTA design schemes with different gain boosting techniques and class AB input/output stages are discussed. A detailed comparison among these schemes has been presented in terms of performance characteristics such as voltage gain, gain‐bandwidth product, slew rate, circuit sensitivity to process/mismatch variations, and silicon area. The design procedures for all the compared structures have been developed. The OTAs have been fabricated in a standard 0.18‐μm n‐well CMOS process from TSMC. Chip test results are in good agreement with theoretical predictions and simulations.     

A 40 M–1000 MHz 77.2‐dB spurious free dynamic range CMOS RF variable gain amplifier for digital TV tuner ICs

In this paper, a 40 M–1000 MHz 77.2‐dB spurious free dynamic range (SFDR) CMOS RF variable gain amplifier (VGA) has been presented for digital TV tuner applications. The proposed RFVGA adopts a wideband operational‐amplifier‐based VGA and a wideband buffer with differential multiple gated transistor linearization method for wideband operation and high linearity. The SFDR of the proposed RFVGA is also analyzed in detail. Fabricated in a 0.13‐µm CMOS process, the RFVGA provides 31‐dB gain range with 1‐dB gain step, a minimum noise figure of 7.5 dB at a maximum gain of 27 dB, and maximum in‐band output‐referred third‐order intercept point of 27.7 dBm, while drawing an average current of 27.8 mA with a supply voltage of 3.3 V. The chip core area is 0.54 mm × 0.4 mm. 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.     

Modified telescopic amplifier with improved DC gain in 0.18 µm CMOS process

A new operational amplifier is presented based on the conventional telescopic amplifier structure. A novel method is used to increase the DC gain of the telescopic amplifier. This method does not degrade the output swing, bandwidth, settling time and the phase margin of the telescopic amplifier. Proposed structure has been simulated by HSPICE software using level 49 parameters (BSIM3v3) in a typical 0.18 µm Complementary metal‐oxide‐semiconductor (CMOS) technology. HSPICE simulation confirms the theoretical estimated improvements. Copyright © 2011 John Wiley & Sons, Ltd.     

An 11‐μ W, 9‐bit fully differential,cyclic/algorithmic ADC in 0.13 μm CMOS

This paper describes a fully differential, cyclic, analogue‐to‐digital converter (ADC). It utilizes a 4‐bit binary weighted capacitor array to obtain 9‐bit resolution. The ADC uses an operational amplifier to suppress supply voltage variations. The operational amplifier with the slew‐rate detection is used to increase the speed of the ADC. The ADC is fabricated in IBM 0.13 μm CMOS process and occupies 650 × 850μm² active area. At 10 kS/s sampling rate, the ADC consumes 11 μW. In order to test immunity of the ADC on the supply voltage variations, static and dynamic performance of the ADC is measured with triangular supply voltage (V _{D C}  = 1.5 V, V _{A C}  = 200mV _pp, f  = 1 kHz). The measured peak of differential nonlinearity and integral nonlinearity is  + 0.26/ − 0.67 and  + 0.65/ − 0.59, respectively. At 250 Hz, effective number of bit is 8.4 bits, S F D R  = 66.7 dB and S N D R  = 52.6 dB. Copyright © 2016 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.     

A 63‐dB gain OTA operating in subthreshold with 20‐nW power consumption

This paper presents a two‐stage bulk‐driven operational transconductance amplifier operating in weak‐inversion region. The proposed amplifier is upgraded using recycling structure, current shunt technique, positive feedback source degeneration and indirect frequency compensation feedback to enhance transconductance under a reasonable stability. Combining these approaches leads to an ultra‐low‐power high performance amplifier without increasing power dissipation compared to the conventional one. Simulation results in 0.13‐µm complementary metal–oxide–semiconductor technology show the proposed structure achieves a 63‐dB DC gain at 0.25‐V supply voltage with just 20‐nW power dissipation. Copyright © 2016 John Wiley & Sons, Ltd.     

Circuit and system design for an 860–960 MHz RFID reader front‐ends with Tx leakage suppression in 0.18 − µm CMOS technology

This paper presents an RF Front‐END for an 860–960thinspaceMHz passive RFID Reader. The direct conversion receiver architecture with the feedback structure in the RF front‐end circuit is used to give good immunity against the large transmitter leakage and to suppress leakage. The system design considerations for receiver on NF and IIP3 have been discussed in detail. The RF Front‐END contains a power amplifier (PA) in transmit chain and receive front‐end with low‐noise amplifier, up/down mixer, LP filter and variable‐gain amplifier. In the transmitter, a differential PA with a new power combiner is designed and fabricated in a 0.18‐µm technology. The chip area is 2.65 mm × 1.35 mm including the bonding pads. The PA delivers an output power of 29 dBm and a power‐added efficiency of 24% with a power gain of 20 dB, including the losses of the bond‐wires. Copyright © 2011 John Wiley & Sons, Ltd.