A large dynamic‐range,high dB‐linearity VGA using switch arrays and second‐order mismatch‐shaping DEM technique

A new large dynamic‐range variable gain amplifier (VGA) with improved dB linearity is presented. The traditional cascade VGA has the disadvantages of gain mismatch between sub‐stages and difficulty of employing mismatch cancelation or suppression algorithms. In this paper, switch arrays were used to make the sub‐stages or called gain cells in the coarse‐tuning stage (CTS) work independently and therefore prevent the integral operation of the gain errors. Then, a second‐order mismatch‐shaping DEM was applied conveniently to the CTS and shown to be a useful design technique in improving the dB‐linearity performance. The cascade VGA and its second‐order mismatch‐shaping DEM had been integrated in a 2.4‐GHz receiver chip which was fabricated in a 0.18‐µm CMOS technology with a supply voltage of 1.8 V. Measurement results showed that the gain errors were significantly reduced with second‐order mismatch‐shaping DEM with respect to the traditionally thermometric decoding over a temperature range of [?40, 80] °C. Copyright © 2015 John Wiley & Sons, Ltd.     

Design of 3.1 to 10.6 GHz ultra‐wideband flat gain LNA

In this paper, a new ultra‐wideband low‐noise amplifier (LNA) is proposed. The proposed LNA has flat gain and low noise figure (NF) in the frequency range of 3.1 to 10.6 GHz. To obtain higher gain, cascode architecture is used. In this design, to have a lower NF, the noise cancellation technique applies to the cascode architecture. In addition, to have better matching at the input and output, active feedback and matching transistors are used, which also leads to better NF. To have flat gain, RLC load is used. In the proposed LNA, only one inductor is used, which leads to the smaller chip area. The proposed circuit is designed in 90 nm CMOS technology. The simulation shows NF of between 1.62 and 2.1 dB, flat gain between 11.9 and 12 dB and power consumption of 11.72 mW in the frequency range of 3.1 to 10.6 GHz. The simulation results support the theoretical predictions. Copyright © 2017 John Wiley & Sons, Ltd.     

Low‐power and low‐noise complementary metal oxide semiconductor distributed amplifier using the gain‐peaking technique

This paper presents an improved topology for ultra‐low‐power complementary metal oxide semiconductor (CMOS) distributed amplifier (DA) based on modified folded cascode gain cells. The proposed CMOS‐DA can be applicable in low‐supply‐voltage applications, because of the use of folded gain cell's structure. The proposed DA decreases power consumption by employing the forward body biasing network, while maintains high gain. By using a gain‐peaking inductor at the gate of the transistor, the proposed DA structure achieved to the gain flatness in high frequencies while the bandwidth is improved as well. In addition, employing RC network at the body terminal improves the noise performance of the proposed DA. The DA architecture consists of three amplification stages. Detailed analysis is provided for the proposed folded cascode DA. According to the post‐layout simulation results of the proposed amplifier using a 0.13‐µm CMOS process, DA achieves power gain of 17.3 ± 0.8 dB in bandwidth of 14.5 GHz, a good input third‐order intercept point (IIP3) of +5.5 dBm. The minimum noise figure is 1.8–5 dB, and input and output return losses are less than −11.5 dB and −10 dB, respectively, and the proposed structure consumes 12 mW from a 0.5 V voltage supply. Copyright © 2016 John Wiley & Sons, Ltd.     

Low‐noise low‐power front‐end logarithmic amplifier for neural recording system

In this work, a low‐power, low‐noise logarithmic preamplifier for biopotential and neural recording application is presented. The amplifier is based on a linear limit logarithmic amplifier technique, and an active filter as a DC cancellation filter has been included to its input in order to eliminate DC offsets, which are produced at the electrode–tissue interface. This system has been simulated in a UMC standard 90‐nm 1P9M CMOS process. Five dual gain stages are used to produce the required linear limit logarithmic amplifier. The dynamic range of the amplifier is measured to be 48 dB which covers the signals with amplitude from 20 μV to 5 mV. The amplifier consumes 23.5 μW from a 1.2‐V power supply and has a maximum gain of 69.8 dB. The simulated input referred noise is 5.3 μV over 0.1 Hz to 20 kHz. Copyright © 2012 John Wiley & Sons, Ltd.     

A low-power 75 dB digitally programmable variable-gain amplifier in 0.18μm CMOS

Variable-gain amplifiers (VGAs) are essential building blocks of many communication systems. In this paper, a monolithic low-power digitally programmable VGA with 75 dB of gain range is presented. The core of the design is based on a low-distortion source-degenerated differential amplifier structure. The gain is varied by changing the source-degeneration resistor and tuning the resistors in the common-mode feedback circuitry. The complete VGA consists of three gain stages. As a proof of concept, a 24 dB single-gain stage with 2 dB gain steps is fabricated in a 0.18 ?m CMOS technology. The prototype chip is tested, and measurement results are obtained. Based on these results, the gain stage is redesigned to optimize its performance, and a three-stage 75 dB VGA is designed and simulated. Each stage has a digitally tunable gain range of 25 dB. The overall gain can be varied from ?15 dB to 60 dB in 2.5 dB gain steps. The bandwidth of the multi-stage VGA is higher than 140 MHz, and the gain error is less than 0.3 dB. The overall VGA draws 6.5mA from a 1.8V power supply. The noise figure of the system at maximum gain is 12.5 dB, and the third-order intermodulation intercept point (IIP3) at minimum gain is 14.4 dBm.     

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.     

High‐efficiency CMOS push‐pull power amplifier with multilayer center‐tapped transformer

This paper describes the design of a push‐pull power amplifier (PA) with a center‐tapped transformer for transmitter applications on the 5.2‐GHz band using 0.18μm CMOS technology. The type of the proposed PA is based on a double‐ended push–pull (DEPP) configuration. DEPP has a simple construction with only transistors and transformers. The PA has reverse‐phased cascode‐connected transistors. The proposed transformer has a multilayer structure and was designed using electromagnetic field simulation. To achieve high power added efficiency (PAE), we assumed the optimized output impedance technique with a tunable impedance antenna. The PA has 13.2 dB linearity gain, 14.9 dBm 1‐dB compression point (P1dB), and 27.4% maximum PAE. © 2016 Institute of Electrical Engineers of Japan. Published by John Wiley & Sons, Inc.     

A 0.7‐dB NF, +8.2‐dBm IIP3 CMOS low noise amplifier using frequency selective feedback

A CMOS amplifier employing the frequency selective feedback technique using a shunt feedback capacitor is designed and measured. The proposed amplifier can achieve a high IIP3 (input referred third‐order intercept point) by reducing the third‐ and second‐order nonlinearity contributions to the IMD3 (third‐order intermodulation distortion), which is accomplished using a capacitor as the frequency selective element. Also, the shunt feedback capacitor improves the noise performance of the amplifier. By applying the technique to a cascode LNA using 0.18‐µm CMOS technology, we obtain the NF of 0.7 dB, an IIP3 of +8.2 dBm, and a gain of 15.1 dB at 14.4 mW of power consumption at 900 MHz. Copyright © 2015 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.     

A 60‐GHz power amplifier design with on‐chip tunable load‐matching network and power detect in 90‐nm CMOS

This paper presents a 60‐GHz power amplifier with on‐chip varactor‐based tunable load‐matching networks and an embedded DC temperature‐sensor‐based power detector. The output power can be monitored by the DC temperature sensor, and load‐matching network can be tuned by regulating the control voltage of the varactors, which can be used for correcting unpredictable process, supply voltage, and temperature (PVT) variations and load mismatch. Measured results show that the small‐signal gain of the CMOS power amplifier is up to 6.5 dB at 52 GHz. The power amplifier achieves 5 dBm output P1dB and 7 dBm saturated output power with 4.5% maximun power added efficiency (PAE) at 1 V control voltage. By sweeping the control voltage of the varactors, the power amplifier can obtain the maximun power gain, which can be used to solve the load mismatch. © 2016 Institute of Electrical Engineers of Japan. Published by John Wiley & Sons, Inc.     

A 1–6 GHz analog radio frequency power driver in 90 nm complementary metal‐oxide semiconductor technology for wireless applications

One of the most challenging subsystems for integrated radio frequency (RF) complementary metal‐oxide semiconductor (CMOS) solutions is the power amplifier. A 1–6 GHz RF power driver (RFPD) in 90 nm CMOS technology is presented, which receives signals from on‐chip RF signal chain components at ?12 dBm power levels and produces a 0 dBm signal to on‐chip or off‐chip 50 Ω loads. A unique unit cell design is developed for the RFPD to offset issues associated with very wide multi‐fingered transistors. The RF driver was fabricated as a stand‐alone sub‐circuit on a 90 nm CMOS die with other sub‐circuits. Experimental tests confirmed that the on‐chip RFPD operates up to 6 GHz and is able to drive 50 Ω loads to the desired 0 dBm power level. Spur free dynamic range exceeded 70 dB. The measured power gain was 11.6 dB at 3 GHz. The measured 1 dB compression point and input third‐order intercept point (IIP3) were ?4.7 dBm and ?0.5 dBm, respectively. Also, included are modeling, simulation, and measured results addressing issues associated with interfacing the die to a package with pinouts and the package to a printed circuit test fixture. The simulations were made through direct current (DC), alternating current (AC), and transient analysis with Cadence Analog Design Environment. The stability was also verified on the basis of phase margin simulations from extracted circuit net‐lists. Copyright © 2013 John Wiley & Sons, Ltd.     

A 0.6 V, 2.11 MHz, 62 dB SFDR active‐RC filter in 0.13µm CMOS process

Active‐RC biquad is proposed, which allows the DC level of the input of operational amplifier (op‐amp) to be different from that of the op‐amp output, enabling the low‐voltage operation. The proposed biquad realizes a second‐order transfer function with only one op‐amp, rendering even lower power consumption. By cascading two biquads, a 0.6 V fourth‐order filter is realized in a 0.13µm CMOS technology. While dissipating only 0.42 mW, the filter shows 2.11 MHz cut‐off frequency and 62 dB spurious‐free dynamic range. Copyright © 2008 John Wiley & Sons, Ltd.     

A 1.9‐GHz silicon‐on‐insulator CMOS stacked‐FET power amplifier with uniformly distributed voltage stresses

A 1.9‐GHz single‐stage differential stacked‐FET power amplifier with uniformly distributed voltage stresses was implemented using 0.32‐μm 2.8‐V thick‐oxide MOSFETs in a 0.18‐μm silicon‐on‐insulator CMOS process. The input cross‐coupled stacked‐FET topology was proposed to evenly distribute the voltage stresses among the stacked transistors, alleviating the breakdown and reliability issues of the stacked‐FET power amplifier in sub‐micrometer CMOS technology. With a 4‐V supply voltage, the proposed power amplifier with an integrated output coupled‐resonator balun showed a small‐signal gain of 17 dB, a saturated output power of 26.1 dBm, and a maximum power‐added efficiency of 41.5% at the operating frequency. Copyright © 2017 John Wiley & Sons, Ltd.     

DC–3 GHz low‐noise,flat‐gain‐response,and high‐linearity amplifier

This paper describes the design, fabrication, and testing of a DC–3 GHz ultra‐wideband low‐noise amplifier (LNA) using Avago ATF‐54143 enhanced‐mode pseudomorphic high‐electron mobility transistor. Negative feedback network is introduced to ensure unconditional stability of the LNA over the full waveband. Simulation results show that the LNA provides a gain varying between 14.872 and 14.052 dB, a noise figure (NF) of less than 2.2 dB, and voltage standing wave ratios (VSWRs) approaching 2. A high simulated output third‐order intercept point (OIP₃) of >30.2 dBm is achieved. In contrast, in 1‐dB bandwidth of DC–3 GHz, the measured gain is nominal at 13.10 dB. The obtained NF changes in a small range of 2–2.178 dB, and the measured VSWRs are no more than 1.64, which are better than obtained from simulation results. At the same time, OIP₃ at 1, 2, and 3 GHz is 30.3, 29.13, and 29.34 dBm, respectively, while the output at the 1‐dB compression point (P _1dB ) is 15.43, 14.83, and 14.33 dBm, respectively. © 2016 Institute of Electrical Engineers of Japan. Published by John Wiley & Sons, Inc.     

A duplex current‐reused CMOS LNA with complementary derivative superposition technique

A duplex current‐reused complementary metal–oxide–semiconductor low‐noise amplifier (LNA) is proposed for 2.5‐GHz application. The duplex current‐reused topology with equivalent three common‐source gain stages cascaded is utilized to fulfil the low‐power consumption and high gain simultaneously. The complementary derivative superposition linearization technique with bulk‐bias control is employed to improve the linearity performance with large‐signal swing and to extend the auxiliary transistors bias‐control range. The proposed LNA is fabricated in a 0.18‐um 1P5M complementary metal–oxide–semiconductor process and consumes a 3.13‐mA quiescent current from a 1.5 V voltage supply. The measurement results show that the proposed LNA achieves power gain of 28.1 dB, noise figure of 1.64 dB, input P1dB and IIP3 of −19.6 dBm and 3.2 dBm, respectively, while the input and output return loss is 19.2 dB and 18.4 dB. Copyright © 2016 John Wiley & Sons, Ltd.     

Low‐Noise Fully Differential Amplifiers Using JFET‐CMOS Integration Technology for Smart Sensors

In this paper, CMOS‐based low‐noise amplifiers with JFET‐CMOS technology for high‐resolution sensor interface circuits are presented. A differential difference amplifier (DDA) configuration is employed to realize differential signal amplification with very high input impedance, which is required for the front‐end circuit in many sensor applications. Low‐noise JFET devices are used as input pair of the input differential stages or source‐grounded output load devices, which are dominant in the total noise floor of DDA circuits. A fully differential amplifier circuit with pure CMOS DDA and three types of JFET‐CMOS DDAs were fabricated and their noise performances were compared. The results show that the total noise floor of the JFET‐CMOS amplifier was much lower compared to that of the pure CMOS configuration. The noise‐reduction effect of JFET replacement depends on the circuit configuration. The noise reduction effect by JFET device was maximum of about − 18 dB at 2.5 Hz. JFET‐CMOS technology is very effective in improving the signal‐to‐noise ratio (SNR) of a sensor interface circuit with CMOS‐based sensing systems. © 2008 Institute of Electrical Engineers of Japan. Published by John Wiley & Sons, Inc.     

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 linearized and low noise CMOS mixer with B‐type amplifier‐based sub‐harmonic balun

A low noise and high linearity down‐conversion CMOS mixer for 2.4‐GHz wireless receiver is presented in this paper. Using a sub‐harmonic balun with a simple but effective B‐type amplifier, the local oscillator frequency required for this mixer has been reduced by half, and the input local oscillator signal could be single‐ended rather than differential, which simultaneously simplifies the design of local oscillator. A distortion and noise cancelation transconductor in association with current bleeding technique is employed to improve the noise and linearity of the entire mixer under a reduced bias current without compromising the voltage gain. Fabricated in a 0.18‐µm RF CMOS technology of Global Foundries, the mixer demonstrates a voltage gain of 15.8 dB and input‐referred third‐order intercept point of 6.6 dBm with a noise figure of 2.6 dB. It consumes 7.65 mA from a 1.0‐V supply and occupies a compact area of 0.75 × 0.71 mm² including all test pads. Copyright © 2016 John Wiley & Sons, Ltd.     

Optimal sizing and design of CMOS analogue amplifier circuits using craziness‐based particle swarm optimization

This paper presents the optimal designs of two analogue complementary metal–oxide–semiconductor (CMOS) amplifier circuits, namely differential amplifier with current mirror load and two‐stage operational amplifier. A modified Particle Swarm Optimization (PSO), called Craziness‐based Particle Swarm Optimization (CRPSO) technique is applied to minimize the total MOS area of the designed circuits. CRPSO is a highly modified version of conventional PSO, which adopts a number of random variables and has a better and faster exploration and exploitation capability in the multidimensional search space. Integration of craziness factor in the fundamental velocity term of PSO not only brings diversity in particles but also pledges convergence close to global best solution. The proposed CRPSO‐based circuit optimization technique is reassured to be free from the intrinsic disadvantages of premature convergence and stagnation, unlike Differential Evolution (DE), Harmony Search (HS), Artificial Bee Colony (ABC) and Particle Swarm Optimization (PSO). The simulation results achieved for the two analogue CMOS amplifier circuits establish the efficacy of the proposed CRPSO‐based approach over those of DE, HS, ABC and PSO in terms of convergence haste, design conditions and design goals. The optimally designed analogue CMOS amplifier circuits occupy the least MOS area and show the best performance parameters like gain and power dissipation, in compared with the other reported literature. Copyright © 2016 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.