A coin-battery-powered LDO-Free 2.4-GHz Bluetooth Low Energy/ZigBee receiver consuming 2 mA

This paper describes a 1.5-V low dropout regulator (LDO)-free ultra-low-power 2.4-GHz CMOS receiver for direct-powering through a coin battery. By effective merging the quadrature low noise amplifier (LNA), in phase and quadrature (I/Q) mixers, a voltage controlled oscillator (VCO) and a trans-impedance amplifier (TIA) in one cell, while removing the LDO, we fully utilize the available 1.5-V voltage supply for current-reuse between blocks, minimizing the dc current consumption. Specifically, a quadrature LNA operating as both common-source and common-drain provides the I/Q outputs in the signal path. Forward-body-bias applied to the transconductance stage of the I/Q mixers relaxes their voltage headroom consumption. Prototyped in 180-nm CMOS, the receiver exhibits a conversion gain (CG) of 23 dB, a noise figure (NF) of 13.8 dB and an input-referred 3rd-order intercept point (IIP3) of −14 dBm while consuming only 2 mA. The phase noise of the VCO is −118.5 dBc/Hz at 2.5 MHz offset. The low-cost technology and low current consumption renders the receiver suitable for Internet of Things (IoT) devices using the Bluetooth Low Energy (BLE) or ZigBee standards.     

G/sub m/-boosted common-gate LNA and differential colpitts VCO/QVCO in 0.18-/spl mu/m CMOS

The demand for radio frequency (RF) integrated circuits with reduced power consumption is growing owing to the trend toward system-on-a-chip (SoC) implementations in deep-sub-micron CMOS technologies. The concomitant need for high performance imposes additional challenges for circuit designers. In this paper, a g/sub m/-boosted common-gate low-noise amplifier (CGLNA), differential Colpitts voltage-controlled oscillators (VCO), and a quadrature Colpitts voltage-controlled oscillator (QVCO) are presented as alternatives to the conventional common-source LNA and cross-coupled VCO/QVCO topologies. Specifically, a g/sub m/-boosted common-gate LNA loosens the link between noise factor (i.e., noise match) and input matching (i.e., power match ); consequently, both noise factor and bias current are simultaneously reduced. A transformer-coupled CGLNA is described. Suggested by the functional and topological similarities between amplifiers and oscillators, differential Colpitts VCO and QVCO circuits are presented that relax the start-up requirements and improve both close-in and far-out phase noise compared to conventional Colpitts configurations. Experimental results from a 0.18-/spl mu/m CMOS process validate the g/sub m/-boosting design principle.     

基于90nmCMOS工艺的低功耗宽带压控振荡器设计

A low power VCO with a wide tuning range and low phase noise has been designed and realized in a standard 90 nm CMOS technology. A newly proposed current-reuse cross-connected pair is utilized as a negative conductance generator to compensate the energy loss of the resonator. The supply current is reduced by half compared to that of the conventional LC-VCO. An improved inversion-mode MOSFET(IMOS) varactor is introduced to extend the capacitance tuning range from 32.8% to 66%. A detailed analysis of the proposed varactor is provided. The VCO achieves a tuning range of 27–32.5 GHz, exhibiting a frequency tuning range(FTR) of 18.4%and a phase noise of –101.38 d Bc/Hz at 1 MHz offset from a 30 GHz carrier, and shows an excellent FOM of –185d Bc/Hz. With the voltage supply of 1.5 V, the core circuit of VCO draws only 2.1 m A DC current.     

A 5-GHz radio front-end with automatically Q-tuned notch filter and VCO

A low-voltage receiver front-end for 5-GHz radio applications is presented. The receiver consists of a low-noise amplifier (LNA) with notch filter, a voltage-controlled oscillator (VCO), and a mixer. The LNA/notch filter has an automatic Q-tuning circuit integrated with it to provide good image rejection. On-chip transformers are used extensively in the receiver to improve performance and facilitate low-voltage operation. The receiver has a gain of 19.8 dB, noise figure of 4.5 dB, a third-order input intercept point (IIP3) of -11.5 dBm, and an image rejection of 59 dB, and the VCO had a phase noise of -116 dBc/Hz at 1-MHz offset.     

A 77-GHz Phased-Array Transceiver With On-Chip Antennas in Silicon: Receiver and Antennas

In this paper, we present the receiver and the on-chip antenna sections of a fully integrated 77-GHz four-element phased-array transceiver with on-chip antennas in silicon. The receiver section of the chip includes the complete down-conversion path comprising low-noise amplifier (LNA), frequency synthesizer, phase rotators, combining amplifiers, and on-chip dipole antennas. The signal combining is performed using a novel distributed active combining amplifier at an IF of 26 GHz. In the LO path, the output of the 52-GHz VCO is routed to different elements and can be phase shifted locally by the phase rotators. A silicon lens on the backside is used to reduce the loss due to the surface-wave power of the silicon substrate. Our measurements show a single-element LNA gain of 23 dB and a noise figure of 6.0dB. Each of the four receive paths has a gain of 37 dB and a noise figure of 8.0 dB. Each on-chip antenna has a gain of +2 dBi     

A 1.2 V Reactive-Feedback 3.1–10.6 GHz Low-Noise Amplifier in 0.13 μm CMOS

A 15.1 dB gain, 2.1 dB (min.) noise figure low-noise amplifier (LNA) fabricated in 0.13 mum CMOS operates across the entire 3.1-10.6 GHz ultrawideband (UWB). Noise figure variation over the band is limited to 0.43 dB. Reactive (transformer) feedback reduces the noise figure, stabilizes the gain, and sets the terminal impedances over the desired bandwidth. It also provides a means of separating ESD protection circuitry from the RF input path. Bias current-reuse limits power consumption of the 0.87mm² IC to 9 mW from a 1.2 V supply. Comparable measured results are presented from both packaged and wafer probed test samples     

A 1.5-V 2–9.6-GHz Inductorless Low-Noise Amplifier in 0.13-μm CMOS

This paper presents an inductorless low-noise amplifier (LNA) design for an ultra-wideband (UWB) receiver front-end. A current-reuse gain-enhanced noise canceling architecture is proposed, and the properties and limitations of the gain-enhancement stage are discussed. Capacitive peaking is employed to improve the gain flatness and -3-dB bandwidth, at the cost of absolute gain value. The LNA circuit is fabricated in a 0.13-mum triple-well CMOS technology. Measurement result shows that a small-signal gain of 11 dB and a -3-dB bandwidth of 2-9.6 GHz are obtained. Over the -3-dB bandwidth, the input return loss is less than -8.3 dB, and the noise figure is 3.6-4.8 dB. The LNA consumes 19 mW from a low supply voltage of 1.5 V. It is shown that the LNA designed without on-chip inductors achieves comparable performances with inductor-based designs. The silicon area is reduced significantly in the inductorless design, the LNA core occupies only 0.05 mm², which is among the smallest reported designs.     

Design of a capacitor cross-coupled dual-band LNA with switched current-reuse technique

This paper presents the design of a 2.5/3.5-GHz dual-band low-power and low-noise CMOS amplifier (LNA), which uses the capacitor cross-coupling technique and current-reuse method with four switches. The proposed LNA uses a single RF block and a broadband input stage, which is a key aspect for the easy reconfiguration of a dual-band LNA. Switching at the inter-stage and output allows for the selection of a different standard. The dual-band LNA attenuates the undesired interference of a broadband gain response circuit, which allows the linearity of the amplifier to be improved. The capacitor cross-coupled gm-boosting method improves the NF and reduces the current consumption. The proposed LNA employs a current-reused structure to decrease the total power consumption. The inter-stage and output switched resonators switch the LNA between the 2.5-GHz and 3.5-GHz bands. The proposed dual-band LNA optimises power consumption by the securing gain, noise figure and linearity. The simulated performance reveals gains of 16.7 dB and 19.6 dB, and noise figures of 3.04 dB and 2.63 dB at the two frequency bands, respectively. The linearity parameters of IIP3 are ?5.7 dBm at 2.5 GHz and ?9.7 dBm at 3.5 GHz. The proposed dual-band LNA consumes 5.6 mW from a 1.8 V power supply.     

A 0.6-V Low Power UWB CMOS LNA

This paper presents the design of a low-power ultra-wideband low noise amplifier in 0.18-mum CMOS technology. The inductive degeneration is applied to the conventional distributed amplifier design to reduce the broadband noise figure under low power operation condition. A common-source amplifier is cascaded to the distributed amplifier to improve the gain at high frequency and extend the bandwidth. Operated at 0.6V, the integrated UWB CMOS LNA consumes 7mW. The measured gain of the LNA is 10dB with the bandwidth from 2.7 to 9.1GHz. The input and output return loss is more than 10dB. The noise figure of the LNA varies from 3.8 to 6.9dB, with the average noise figure of 4.65dB. The low power consumption of this work leads to the excellent figure of gain-bandwidth product (GBP) per milliwatt     

NBTI Impact on RF Front End in Wireless Sensor Networks

In wireless sensor network （WSN）, the communication node is the heart of the whole system. Negative bias temperature instability （NBTI） is becoming one of the most important factors that decide the life time of node chips, especially with the feature size declining. In this paper, the NBTI impact on the front-end circuits in the WSN nodes is studied, such as voltage-controlled oscillator （VCO）, charge pump （CP）, low noise amplifier （LNA）, and even the whole transceiver system. The circuit level NBTI degeneration models are built for the key modules and the entire transceiver. It is shown that the phase noise of the VCO will be deteriorated, the current mismatch of the CP and the noise figure of the LNA will both be increased, and the sensitivity and the adjacent channel selectivity （ACS） will be depressed by NBTI. The conclusions are proved by simulation results using HJTC 0.18 μm technology.     

A low power current-reuse LC-VCO with an adaptive body-biasing technique

This work presents a low-power low-phase noise current-reuse LC voltage controlled oscillator (VCO) with an adaptive body-biasing technique that enhances the reliability of the proposed circuit under process, voltage, and temperature (PVT) variations. Furthermore, the supply voltage and power consumption of the proposed VCO are reduced by the start-up oscillation condition that is provided by the adaptive body-biased circuit. This property is in fact very interesting from the power management perspective. The proposed VCO works at carrier frequency of 1.8 GHz and draws the power of only 306 µW from a 0.9 V supply. It achieves phase noise of −123.36 dBc/Hz at 1 MHz offset and provides a figure-of-merit (FoM) of −193.61 dBc/Hz. The post-layout simulation results of designed VCO in 0.18 µm standard CMOS technology confirm the effectiveness of the proposed circuit.     

6?10 GHz ultra-wideband CMOS LNA

A two-stage matched ultra-wideband CMOS low noise amplifier (LNA) is presented. The LNA is designed to achieve a low noise figure with high voltage gain. The LNA fabricated in a 0.13 mum CMOS process shows a 3.9 dB average noise figure with a 27 dB voltage gain in the 6-10 GHz frequency band with a power consumption of 14 mW.     

Theoretical analysis of low phase noise design of CMOS VCO

A theoretical analysis on low phase noise of voltage-controlled oscillators (VCOs) based on complementary cross-coupled LC VCO by 0.35-/spl mu/m complementary metal oxide semiconductor technology is demonstrated. From the procedure of optimization steps, the excess noise factor of the amplifier coming from the active device has been determined. The proposed VCO operates at 2 GHz with phase noise of -116 dBc/Hz at offset frequency 600 kHz. The power consumption is 22.62 mW under 3 V bias with 9.1% frequency tuning. The achievement of low phase noise is also matched with prediction by formula in the frequency domain.     

A V-Band Monolithic AlGaN/GaN VCO

A V-band push-push GaN monolithic microwave integrated circuit voltage controlled oscillator (VCO) has been realized based on a 0.2 mum T-gate AlGaN/GaN high electron mobility transistor technology with an fT ~ 65 GHz. The GaN VCO delivered an output power of +11 dBm at 53 GHz with an estimated phase noise of -97 dBc/Hz at 1 MHz offset based on on-wafer measurement. To the best of our knowledge, this is the highest frequency VCO ever reported for GaN technology with a high output power at V-band, without using any buffer amplifier. This work demonstrates the potential of applying GaN technology to millimeter wave band, high power, and low phase noise frequency sources applications.     

GPS射频接收芯片中低功耗压控振荡器的设计

设计了一种应用于GPS射频接收芯片的低功耗环形压控振荡器.环路由5级差分结构的放大器构成.芯片采用TSMC 0.18 μm CMOS工艺,核心电路面积0.25 mm×0.05 mm.测试结果表明,采用1.75 V电源电压供电时,电路的功耗约为9.2 mW,振荡器中心工作频率为62 MHz,相位噪声为-89.39 dBc/Hz @ 1 MHz,该VCO可应用于锁相环和频率合成器中.     

CMOS射频集成电路的研究进展

近年来，射频集成电路(RFIC)的应用和研究得到了飞速的发展，CMOS射频IC的研究更是成为该领域的研究重点和热点。文章对CMOS技术在射频和微波领域的应用进行了详细的探讨，着重介绍了当前射频通讯中常用的收发机结构及其存在的问题和解决方案；分析了射频收发机前端关键电路模块低噪声放大器(LNA)、混频器(Mixer)、压控振荡器(VCO)、功率放大器(PA)和射频关键无源元件的最新研究进展；展望了CMOS技术在射频领域的发展前景。     

一个新结构低功耗2.5 GHz CMOS LC压控振荡器的设计

压控振荡器是锁相环电路的关键的组成部分之一,采用新的电流复用结构,可以明显降低该电路的功耗,而且由于没有尾电流,新结构还能有效改善电路的相位噪声.在TSMC 0.18 CMOS 1P6M工艺下的仿真结果表明:在1.25 V供电电压下振荡器的调节范围是2.26 GHz到2.76 GHz,在频偏1 MHz处的相位噪声为--130 dBc/Hz,平均功耗不超过1.2 mW.     

Power efficient Ka-band low phase noise VCO in 0.13 μm CMOS

A 27 GHz cross-coupled LC voltage controlled oscillator (VCO) using a standard 0.13 mum CMOS technology is presented. The VCO using a high-Q LC resonator with a micro-strip inductor (mu-strip L) provides a phase noise of -113 dBc/Hz at a 1 MHz offset frequency. The figure - of-merit (FoM) is -194.6 dBc/Hz. To obtain high output power, it also uses a common source amplifier as a buffer and it shows the output power of -3.5 dBm at an oscillation frequency of 26.89 GHz. This is believed to be the lowest phase noise and FoM with the highest output power of a millimetre-wave VCO in CMOS technology.     

A 0.18μm CMOS low noise amplifier using a current reuse technique for 3.1-10.6 GHz UWB receivers

A new,low complexity,ultra-wideband 3.1-10.6 GHz low noise amplifier(LNA),designed in a chartered 0.18μm RFCMOS technology,is presented.The ultra-wideband LNA consists of only two simple amplifiers with an inter-stage inductor connected.The first stage utilizing a resistive current reuse and dual inductive degeneration technique is used to attain a wideband input matching and low noise figure.A common source amplifier with an inductive peaking technique as the second stage achieves high flat gain and wide -3 dB bandwidth of the overall amplifier simultaneously.The implemented ultra-wideband LNA presents a maximum power gain of 15.6 dB,and a high reverse isolation of—45 dB,and good input/output return losses are better than -10 dB in the frequency range of 3.1-10.6 GHz.An excellent noise figure(NF) of 2.8-4.7 dB was obtained in the required band with a power dissipation of 14.1 mW under a supply voltage of 1.5 V.An input-referred third-order intercept point(IIP3) is -7.1 dBm at 6 GHz.The chip area,including testing pads,is only 0.8×0.9 mm2.