Highly linear wide‐swing continuous tuning of CMOS transconductors

A technique to improve the input and output range of CMOS transconductors with resistive current division for continuous tuning is presented. Using it, a tunable transconductor is proposed which features high linearity over a wide input range and simplicity. Measurement results of the transconductor, fabricated in a 0.5 µm CMOS process, show an IM3 of ?66 dB for a ±1.65 V supply and two input tones centered at 1 MHz of 1 V_pp each, and only 0.7 mW of power consumption. This represents an improvement of 13 dB versus the same transconductor using conventional current division. Copyright © 2013 John Wiley & Sons, Ltd.     

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.     

MEMS-based microheaters integrated gas sensors

Abstract

In the present work efforts have been made to develop microheater integrated gas sensors with low power consumption. The design and simulation of a single-cell microheater is carried out using ANSYS. Low power consumption (<35?mW) platinum micro-heater has been fabricated using bulk micromachining technique on silicon dioxide membrane (1.5?μm thin), which provided improved thermal isolation of the active area of 250?×?250?μm². The micro-heater has achieved a maximum temperature of ～950?°C at an applied dc voltage of 2.5 V. Fabricated mircro-heater has been integrated with SnO₂ based gas sensors for the efficient detection of H₂ and NO₂ gases. The developed sensors were found to yield the maximum sensing response of ～184 and ～2.1 with low power consumption of 29.18 and 34.53?mW towards the detection of 1?ppm of NO₂ gas and 500?ppm of H₂ gas, respectively.     

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.     

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.     

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 performance thin film PZT ultrasonic transducer by CSD for distance measurements in water

Piezoelectric thin film ultrasonic transducers were realised and tested for short range distance measurements. Displacements in air and water as a function of frequency were modelled by Comsol Multiphysics finite element modelling (FEM) and transducer configurations with a two electrode layout were manufactured to enable larger displacements than with the conventional design. The transducer was fabricated on a silicon wafer by chemical solution deposition (CSD) with total PZT (Pb(Zr_0.53Ti_0.47)O₃) thickness of 2 µm. Subsequently, a cavity underneath the PZT was wet etched creating a bending membrane with a total thickness of ??13 µm. The displacements of the transducers as a function of frequency were modelled and measured by fiber-optic laser vibrometer. The effective piezoelectric d₃₃ coefficient of 300 nm/V and 144 nm/V in air and 48 nm/V and 18 nm/V in water was obtained for 260?×?260 µm² and 390?×?390 µm² membranes, respectively. The accuracy of the modelled resonance frequencies both in air and water was relatively good, of ??4-13% and ??5-20%, respectively.     

Rail-to-rail input/output operational transconductance amplifier (OTA) with high CMRR and PSRR

This paper introduces a low-voltage CMOS operational transconductance amplifier (OTA) with rail-to-rail input/output stages. Input stage uses floating gate transistors to realize rail-to-rail scheme. However, this scheme gives rise to reduction in transconductance of the OTA. To increase transconductance (G _m), an effective partial positive feedback is used. Class AB output stage is so designed that improves the gain, slew rate, common mode rejection ratio and maximum swing of the OTA. With ±0.75 v power supply, this OTA consumes the low power of 397.5?μw. G _m variation of input stage is 0.004% for rail-to-rail (±0.75 v) variation in common mode input signals and reaches to 0.036% beyond the rail-to-rail range (±1 v) which is a superior result compared with previously reported works. As is proved by theoretical relations and simulation results, proposed auxiliary circuit for rail-to-rail operation results in both high CMRR due to fixing common source node of input differential pair and high linearity due to attenuation of input signals. Simulation results show that CMRR in DC frequency is 259.5 dB and HD3 is ?46 dB for 2.15 v_P-P differential output voltage signal with applying a 0.48 v_P-P input signal at 1 MHz. Proposed OTA is simulated in TSMC 0.18 μm CMOS technology with Hspice. Monte Carlo simulation results are included to forecast mismatch effects after fabrication process.     

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.     

A high‐performance CMOS CCII

A CMOS second generation Current Conveyor (CCII) is presented which is based on a novel voltage follower with a symmetric two‐gain‐stage topology. Simulations on a 0.8 μm design employing a 3.3 V power supply show a 0.03 per cent low‐frequency voltage gain error, a THD better than ?70 dB for a 1 V_p?p 100 kHz input signal, and reduced offset. Copyright © 2001 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.     

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.     

A low‐power,area‐efficient multichannel receiver for micro MRI

A new integrated, low‐noise, low‐power, and area‐efficient multichannel receiver for magnetic resonance imaging (MRI) is described. The proposed receiver presents an alternative technique to overcome the use of multiple receiver front‐ends in parallel MRI. The receiver consists of three main stages: low‐noise pre‐amplifier, quadrature down‐converter, and a band pass filter (BPF). These components are used to receive the nuclear magnetic resonance signals from a 3 × 3 array of micro coils. These signals are combined using frequency domain multiplexing (FDM) method in the pre‐amplifier and BPF stages, then amplified and filtered to remove any out‐of‐band noise before providing it to an analog‐to‐digital converter at the low intermediate frequency stage. The receiver is designed using a 90 nm CMOS technology to operate at the main B₀ magnetic field of 9.4 T, which corresponds to 400 MHz. The receiver has an input referred noise voltage of 1.1 nV/√Hz, a total voltage gain of 87 dB, a power consumption of 69 mA from a 1 V supply voltage, and an area of 305 µm × 530 µm including the reference current and bias voltage circuits. Copyright © 2013 John Wiley & Sons, Ltd.     

A novel low‐power receiver topology for RF and microwave applications

A novel low‐power receiver topology for radio‐frequency and microwave applications is presented. The proposed solution exploits a simple connection between the low‐noise amplifier and the subsequent mixer, which is realized by means of a high‐value resistor and a current mirror, achieving low noise and high linearity performance with an extremely low power consumption. The criteria for its optimal design are derived in order to accomplish the main trade‐offs among noise figure (NF), linearity, and current consumption performance. As a case of study, the new topology has been designed in the case of I/Q direct conversion receiver for IEEE 802.15.4 standard (ZigBee) applications at 2.45 GHz. The receiver exhibits a NF of 8.7 dB, 50Ω input impedance, a voltage gain of 26 dB, an input‐referred third‐order intercept point of ?13 dBm, and a power consumption of 8.6 mW, which represent one of the best performance trade‐offs obtained in the literature. Copyright © 2008 John Wiley & Sons, Ltd.     

基于FGMOS的电压求和电流传送器及其应用设计

本文提出了一种基于FGMOS晶体管的电压求和电流传送器的设计。通过对FGMOS晶体管的等效电路分析,得到其框图和等效电路,并设计出了其电路结构;为了表明提出的电压求和电流传送器的可用性,将提出的电压求和电流传送器用于实现受控振荡器和电压求和放大器;通过SPICE的仿真结果表明,基于FGMOS的电压求和电流传送器不仅具有高的线性特性,而且其电压传递增益和电流传递增益分别可达0.99和0.98。此外,还有着很好的频率响应性能,?0.5V的低电源电压,79.8?W的低功耗和在14k?~2.1M?的线性电子可调谐电阻值。基于电压求和电流传送器设计的受控振荡器具有稳定的正弦输出,而且振荡频率值可以通过偏置电流来控制,设计的电压求和放大器具有高输入电阻和可控的增益。     

Study of RF Linearity in sub-50 nm MOSFETs Using Simulations

We investigate the linearity performance of dual-gate and fully-depleted silicon-on-insulator MOSFETs through use of 2D computer simulations, which take into account quantum mechanical considerations and non-equilibrium transport effects. We show that DG MOSFET is superior not only in terms of g _m /I _d characteristics, central to analog performance, but also in terms of linearity performance, by up to 5 dBm, in most operating conditions. Linearity figures of devices considered in this work range from ?10 to ?20 dBm, which answer the needs of mobile communication standards currently in use. We also observe that, when properly scaled, bulk MOSFETs display competitive analog performance and have third-order intercept figures very similar to SOI device. We can identify, through simulation experiments, that quantum mechanical effects have positive impact on linearity, while non-equilibrium conditions lower linearity performance. With increasing drain bias, we find that linearity saturates at a moderately low voltage (～1 V) in all devices.     

Multiple output differential OTA with linearizing bulk‐driven active‐error feedback loop for continuous‐time filter applications

A CMOS circuit realization of a highly linear multiple‐output differential operational transconductance amplifier (OTA) has been proposed. The presented approach exploits a differential pair as an input stage with both the gate and the bulk terminals as signal ports. For the proposed OTA, improved linearity is obtained by means of the active‐error feedback loop operating at the bulk terminals of the input stage. SPICE simulations of the OTA show that, for 0.35 µm AMS process, total harmonic distortion at 1.36Vpp is less than 1% with dynamic range equal to 60.1 dB at power consumption of 276 μW from 3.3 V supply. As an example, both single output and dual differential OTAs are used to design third‐order elliptic low‐pass filters. The cut‐off frequency of the filters is 1 MHz. The power consumption of the OTA‐C filter utilizing the dual output differential OTA is reduced to 1.24 mW in comparison to 2.2 mW consumed by the single output differential OTA‐C filter counterpart. Copyright © 2014 John Wiley & Sons, Ltd.     

67 GHz three‐spiral transformer CMOS oscillator

This paper presents a 67GHz LC oscillator exploiting a three‐spiral transformer and implemented in 65nm bulk complementary metal–oxide–semiconductor technology by STMicroelectronics. The three‐spiral transformer allows operating with a lower voltage supply, still obtaining good phase noise performance, and achieving a compact design. Measured performances when supplied with 1.2 V are: oscillation frequency of 67 GHz, phase noise (PN) equal to ?96 dBc/Hz at 1 MHz frequency offset from the carrier, power consumption (P_C) equal to 19.2 mW and figure of merit (FOM) equal to ?179.7 dB/Hz. Measured performances when supplied with 0.6 V are: oscillation frequency of 67 GHz; PN equal to ?88.7 dBc/Hz at a 1 MHz frequency offset from the carrier; P_C equal to 3.6 mW and FOM equal to ?179.7 dB/Hz. Copyright © 2016 John Wiley & Sons, Ltd.     

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.     

A proposal for high‐performance CCII‐based analogue CMOS design

A novel fully differential CMOS second‐generation current conveyor (CCII) topology is presented. It can be considered as a universal fully differential programmable active element. The circuit operates in moderate inversion region, and features high linearity over a wide input range. Current gain between terminals X and Z can be continuously tuned in a wide range. These features are essential to extend the utilization of CCII‐based circuits to high‐performance VLSI applications. Analogue design based on this new cell is illustrated by various examples. The proposed CCII has been fabricated in a 0.5‐µm CMOS technology and its main performance characteristics have been measured. They are in good agreement with theory and demonstrate that operation in moderate inversion can lead to distortion levels much lower than those achieved in strong inversion. Experimental results for a Tow–Thomas biquadratic filter fabricated on the same chip are also presented, showing continuous frequency tuning in more than a decade. Copyright © 2005 John Wiley & Sons, Ltd.