A 2.7-V 900-MHz CMOS LNA and mixer

A CMOS low-noise amplifier (LNA) and a mixer for RF front-end applications are described. A current reuse technique is described that increases amplifier transconductance for the LNA and mixer without increasing power dissipation, compared to standard topologies. At 900 MHz, the LNA minimum noise figure (NF) is 1.9 dB, input third-order intercept point (IIP3) is -3.2 dBm and forward gain is 15.6 dB. With a 1-GHz local oscillator (LO) and a 900-MHz RF input, the mixer minimum double sideband noise figure (DSB NF) is 5.8 dB, IIP3 is -4.1 dBm, and power conversion gain is 8.8 dB. The LNA and mixer, respectively, consume 20 mW and 7 mW from a 2.7 V power supply. The active areas of the LNA and mixer are 0.7 mm×0.4 mm and 0.7 mm×0.2 mm, respectively. The prototypes were fabricated in a 0.5-μm CMOS process     

Design and optimization of a 2.4 GHz RF front-end with an on-chip balun

A 2.4 GHz low-power,low-noise and highly linear receiver front-end with a low noise amplifier(LNA) and balun optimization is presented.Direct conversion architecture is employed for this front-end.The on-chip balun is designed for single-to-differential conversion between the LNA and the down-conversion mixer,and is optimized for the best noise performance of the front-end.The circuit is implemented with 0.35μm SiGe BiCMOS technology.The front-end has three gain steps for maximization of the input dynamic range.The overall maximum gain is about 36 dB.The double-sideband noise figure is 3.8 dB in high gain mode and the input referred third-order intercept point is 12.5 dBm in low gain mode.The down-conversion mixer has a tunable parallel R-C load at the output and an emitter follower is used as the output stage for testing purposes.The total front-end dissipation is 33 mW under a 2.85 V supply and occupies a 0.66 mm~2 die size.     

A 1-GHz BiCMOS RF front-end IC

An RF front-end IC containing a low-noise amplifier and mixer is described. On-chip temperature and supply-voltage compensation is used to stabilize circuit performance. Realized in a BiCMOS process, the circuit consumes 13.0-mA total current from a 5-V supply. The amplifier gain at 900 MHz is 16 dB, the noise figure is 2.2 dB, and the input third-order intermodulation intercept is -10 dBm. The mixer input third-order intermodulation intercept is +6 dBm with 15.8 dB noise figure     

A 12-mW wide dynamic range CMOS front-end for a portable GPSreceiver

This paper describes a CMOS low-noise amplifier (LNA) and mixer intended for use in the front-end of a global positioning system (GPS) receiver. The circuits were implemented in a standard 0.35-μm (drawn) CMOS process, with one poly and two metal layers. The LNA has a forward gain (S21) of 17 dB and a noise figure of 3.8 dB. The mixer has a voltage conversion gain of -3.6 dB and a third-order intermodulation intercept point (IP3) of 10 dBm, input referred. The combination draws 12 mW from a 1.5-V supply     

A high-IP3 RF receiver chip set for mobile radio base stations upto 2 GHz

We present a monolithically integrated high third-order intercept point (IP3) radio frequency (RF) receiver chip set for mobile radio base stations up to 2 GHz, in a 25-GHz f_T Si bipolar production technology. The chip set consists of a RF preamplifier, active mixer circuits, and an intermediate frequency (IF) limiter. The preamplifier gain is 12 dB, the noise figure is 5.5 dB at 900 MHz, and the output (OIP3) is up to +24 dBm depending on supply voltage. The two different mixers provide a conversion gain of 1.5 dB up to 3 dB, an OIP3 in the range of +21 dBm up to +29 dBm, and a minimal single sideband (SSB) noise figure of 13 dB. The IF limiter shows an excellent limiting characteristic at 10 dBm output power and has a high bandwidth of more than 1 GHz     

Doubly balanced dual-gate CMOS mixer

The operation, biasing, and measured results of a CMOS doubly balanced dual-gate downconversion mixer are presented. Measurements show, with a radio-frequency input of 1.9 GHz and an intermediate-frequency output of 250 MHz, that the mixer has a conversion gain of 0 dB, an input-referred third-order intercept point of +2 dBm, and a single-sideband noise figure of 13.6 dB while requiring +5 dBm of local-oscillator power and consuming 10.2 mA from a 3 V power supply     

2.4GHz带片上非平衡变压器射频前端的设计与优化

本文介绍了一种工作在2.4GHz频段的低功耗、低噪声、高线性射频接收机前端电路,该接收前端电路使用新型的带三种增益模式的LNA,并提出一种新的片上非平衡变压器优化技术。前端电路采用了直接变频结构,使用片上非平衡变压器实现低噪声放大器与下变频混频器之间的单端-差分转换,优化设计以提高前端电路的噪声性能。本文使用锗硅0.35um BiCMOS工艺,所采用的技术同样适用于CMOS工艺。前端电路总的最大转换增益为36dB;在高增益模式下的双边带噪声系数为3.8dB;低增益模式下,输入三阶交调点位12.5dBm。为了获得最大的输入动态范围,低噪声放大器采用三种可调增益模式,低增益模式使用by-pass结构,大大提高了大信号输入下接收前端的线性度。下变频混频器在输出端使用可调R-C tank,滤除带外高频杂波。混频器输出使用射极跟随器作为输出极驱动片外50ohm负载。该接收前端在2.85-V电源供电下,功耗为33mW,芯片面积为0.66mm2。     

Design techniques for mitigation of intermodulation distortion components in CMOS RF receiver front-end circuits with subthreshold operation

This paper provides an overview of target applications and design aspects for emerging radio frequency front-end circuits with subthreshold biasing to reduce power consumption. Design methods are described to linearize a subthreshold pseudo-differential common-source cascode low-noise amplifier (LNA) and a subthreshold active mixer. The linearization techniques can improve the third-order intermodulation intercept point (IIP3) through the use of passive components, which implies that they do not require auxiliary amplifiers to suppress third-order distortion components, and therefore do not incur any extra power consumption. A 1.95 GHz receiver front-end chip with a narrowband LNA and down-conversion mixer was designed and fabricated in 110 nm CMOS technology. Measurement results show that the linearized low-power front-end has a 20.6 dB voltage gain, a 9.5 dB double sideband noise figure, and a ? 10.8 dBm IIP3 with a power consumption of 0.9 mW.     

基于802.11a协议的无线局域网低噪声放大器和改进的有源双平衡混频器

提出了采用0.18μm CMOS工艺,应用于802.11a协议的无线局域网接受机的低噪声放大器和改进的有源双平衡混频器的一些简单设计概念。通过在5.8 GHz上采用1.8 V供电所得到的仿真结果,低噪声放大器转换电压增益,输入反射系数,输出反射系数以及噪声系数分别为14.8 dB,-20.8 dB,-23.1 dB和1.38 dB。其功率损耗为26.3 mW。设计版图面积为0.9 mm×0.67 mm。混频器的射频频率,本振频率和中频频率分别为5.8 GHz,4.6 GHz和1.2 GHz。在5.8 GHz上,混频器的传输增益,单边带噪声系数（SSB NF）,1 dB压缩点,输入3阶截点（IIP3）以及功率损耗分别为-2.4 dB,12.1 dB,3.68 dBm,12.78 dBm和22.3 mW。设计版图面积为1.4 mm×1.1 mm。     

Design of a High Performance 2-GHz Direct-Conversion Front-End With a Single-Ended RF Input in 0.13 $mu$m CMOS

A 2.1 GHz CMOS front-end with a single-ended low-noise amplifier (LNA) and a double balanced, current-driven passive mixer is presented. The LNA drives an on-chip transformer load that performs single-ended to differential conversion. A detailed comparison in gain, noise, and second and third order linearity performance is presented to motivate the choice of a current-driven passive mixer over an active mixer. The front-end prototype was implemented on a 0.13 $mu$m CMOS process and occupies an active chip area of 1.1 mm $^{2}$. It achieves 30 dB conversion gain, a low noise figure of 3.1 dB (integrated from 40 KHz to 1.92 MHz), an in-band IIP3 of ${-}$12 dBm, and IIP2 better than 39 dBm, while consuming only 12 mW from a 1.5 V power supply.      

A 2.1-6 GHz SiGe BiCMOS low-noise amplifier design for a multi-mode wideband receiver

A wideband low-noise amplifier (LNA) with ESD protection for a multi-mode receiver is presented.The LNA is fabricated in a 0.18-μm SiGe BiCMOS process,covering the 2.1 to 6 GHz frequency band.After optimized noise modeling and circuit design,the measured results show that the LNA has a 12 dB gain over the entire bandwidth,the input third intercept point (IIP3) is -8 dBm at 6 GHz,and the noise figure is from 2.3 to 3.8 dB in the operating band.The overall power consumption is 8 mW at 2.5 V voltage supply.     

A C-band high-dynamic range GaN HEMT low-noise amplifier

A C-band low-noise amplifier (LNA) is designed and fabricated using GAN HEMT power devices. The one-stage amplifier has a measured noise figure of 1.6 dB at 6 GHz, with an associated gain of 10.9 dB and IIP3 of 13 dBm. it also exhibits broadband operation from 4-8 GHz with noise figure less than 1.9 dB. The circuit can endure up to 31 dBm power from the input port. Compared to circuits based on other material and technology, the circuit shows comparable noise figure with improved dynamic range and survivability.     

A 60-GHz Phased Array Receiver Front-End in 0.13-$mu {hbox{m}}$ CMOS Technology

This paper presents a fully integrated dual-antenna phased-array RF front-end receiver architecture for 60-GHz broadband wireless applications. It contains two differential receiver chains, each receiver path consists of an on-chip balun, ag_m-boosted current-reuse low-noise amplifier (LNA), a sub-harmonic dual-gate down-conversion mixer, an IF mixer, and a baseband gain stage. An active all-pass filter is employed to adjust the phase shift of each LO signal. Associated with the proposed dual conversion topology, the phase shift of the LO signal can be scaled to one-third. Differential circuitry is adopted to achieve good common-mode rejection. The g_m-boosted current-reuse differential LNA mitigates the noise, gain, robustness, stability, and integration challenges. The sub-harmonic dual-gate down-conversion mixer prevents the third harmonic issue in LO as well. Realized in a 0.13-mum 1P8M RF CMOS technology, the chip occupies an active area of 1.1 times 1.2 mm². The measured conversion gain and input P1 dB of the single receiver path are 30 dB and -27 dBm , respectively. The measured noise figure at 100 MHz baseband output is around 10 dB. The measured phased array in the receiver achieves a total gain of 34.5 dB and theoretically improves the receiver SNR by 4.5 dB. The proposed 60 GHz receiver dissipates 44 mW from a 1.2 V supply voltage. The whole two-channel receiver, including the vector modulator circuits for built-in testing, consumes 93 mW from a 1.2 V supply voltage.     

Low-power single-to-differential LNA at S-band based on optimised transformer topology and integrated ESD

A single-ended to differential low-power low-noise amplifier (LNA) designed and implemented in 0.18 mum CMOS technology is presented. The device takes advantage of a current reuse strategy by stacking two common-source differential transistor pair stages for minimum current dissipation, together with the design of optimised high Q differential transformers and inductors in order to minimise the impact of parasitics. The fully integrated, including ESD protection diodes, 2.1 GHz LNA consumes 1.1 mW at 1.2 V supply voltage and presents 29.8 dB gain, 4.5 dB noise figure, -21.1 dBm 1 dB compression point, -11.6 dBm input third-order intercept point and -12.3 dB input return loss performance.     

A highly linear receiver front-end employing modified derivative superposition method with tuned inductors for 5.25 GHz

We design a highly linear CMOS RF receiver front-end operating in the 5 GHz band using the modified derivative superposition (DS) method with one- or two-tuned inductors in the low noise amplifier (LNA) and mixer. This method can be used to adjust the magnitude and phase of the third-order currents at output, and thus ensure that they cancel each other out. We characterize the two front-ends by the third-order input intercept point (IIP3), voltage conversion gain, and a noise figure based on the TSMC 0.18 μm RF CMOS process. Our simulation results suggest that the front-end with one-tuned inductor in the mixer supports linearization with the DS method, which only sacrifices 1.9 dB of IIP3 while the other performance parameters are improved. Furthermore, the front-end with two-tuned inductors requires a precise optimum design point, because it has to adjust two inductances simultaneously for optimization. If the inductances have deviated from the optimum design point, the front-end with two-tuned inductors has worse IIP3 characteristic than the front-end with one-tuned inductor. With two-tuned inductors, the front-end has an IIP3 of 5.3 dBm with a noise figure (NF) of 4.7 dB and a voltage conversion gain of 23.1 dB. The front-end with one-tuned inductor has an IIP3 of 3.4 dBm with an NF of 4.4 dB and a voltage conversion gain of 24.5 dB. There is a power consumption of 9.2 mA from a 1.5 V supply.     

3 V, 28 mW Si-bipolar front-end IC for 900 MHz homodyne wirelessreceivers

A 900 MHz homodyne receiver front-end bipolar chip is presented. The circuit consists of a low-noise amplifier and two double-balanced mixers for in-phase and quadrature channels. The power supply voltage is 3 V and power dissipation is 28 mW. The measured performance includes 33.5 dB voltage gain, a 3.1 dB noise figure, -13 dBm input referred IP3, -95 dB LO leakage into the RF port on wafer probing, and less than 0.1 dB I/Q magnitude imbalance     

用于IEEE802．11b／g WLAN直接下变频接收机的射频前端设计

介绍了一种应用于IEEE802．11b／g无线局域网接收机射频前端的设计。基于直接下变频的系统架构。接收机集成了低噪声放大器、I／Q下变频器、去直流偏移滤波器、基带放大器和信道选择滤波器。电路采用TSMC0．18μm CMOS工艺设计,工作在2．4GHz ISM（工业、科学和医疗）频段,实现的低噪声放大器噪声系数为0．84dB,增益为16dB,S11低于-15dB,功耗为13mW;I／Q下变频器电压增益为2dB,输入1dB压缩点为-1 dBm,噪声系数为13dB,功耗低于10mw。整个接收机射频前端仿真得到的噪声系数为3．5dB,IIP3为-8dBm,IP2大于30dBm,电压增益为31dB,功耗为32mW。     

宽带低噪声混频器的设计

文章利用安捷伦公司的ADS仿真软件,设计了一款应用于GNSS接收机射频前端的Gilbert混频器芯片,它的工作电压都为3.3V,中频输出口外接负载为800Ω,具有面积小、噪声系数低的特点。通过优化设计,在频率从1~1.6GHz的范围内,获得了超过15dB的转换增益,以及4dB的噪声系数,输入1dB增益压缩点(P-1dB)为-17dBm,功耗为29mW。     

应用于IEEE 802.11b无线局域网系统的2.4GHzCMOS单片收发机射频前端

实现了一个应用于IEEE 802.11b无线局域网系统的2.4GHz CMOS单片收发机射频前端,它的接收机和发射机都采用了性能优良的超外差结构.该射频前端由五个模块组成:低噪声放大器、下变频器、上变频器、末前级和LO缓冲器.除了下变频器的输出采用了开漏级输出外,各模块的输入、输出端都在片匹配到50Ω.该射频前端已经采用0.18μm CMOS工艺实现.当低噪声放大器和下变频器直接级联时,测量到的噪声系数约为5.2dB,功率增益为12.5dB,输入1dB压缩点约为-18dBm,输入三阶交调点约为-7dBm.当上变频器和末前级直接级联时,测量到的噪声系数约为12.4dB,功率增益约为23.8dB,输出1dB压缩点约为1.5dBm,输出三阶交调点约为16dBm.接收机射频前端和发射机射频前端都采用1.8V电源,消耗的电流分别为13.6和27.6mA.     

A Low-Power Wideband CMOS LNA for WiMAX

In this brief, the design of a low-power inductorless wideband low-noise amplifier (LNA) for worldwide interoperability for microwave access covering the frequency range from 0.1 to 3.8 GHz using 0.13-mum CMOS is described. The core consumes 1.9 mW from a 1.2-V supply. The chip performance achieves S₁₁ below -10 dB across the entire band and a minimum noise figure of 2.55 dB. The simulated third-order input intercept point is -2.7 dBm. The voltage gain reaches a peak of 11.2 dB in-band with an upper 3-dB frequency of 3.8 GHz, which can be extended to reach 6.2 GHz using shunt inductive peaking. A figure of merit is devised to compare the proposed designs to recently published wideband CMOS LNAs