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.     

5-GHz CMOS radio transceiver front-end chipset

Incorporating the direct-conversion architecture, a 5-GHz band radio transceiver front end chipset for wireless LAN applications is implemented in a 0.25-μm CMOS technology. The 4-mm² 5.25-GHz receiver IC contains a low noise amplifier with 2.5-dB noise figure (NF) and 16-dB power gain, a receive mixer with 12.0 dB single sideband NF, 13.7-dB voltage gain, and -5 dBm input 1-dB compression point. The 2.7-mm² transmitter IC achieves an output 1-dB compression of -2.5 dBm at 5.7 GHz with 33.4-dB (image) sideband rejection by using an integrated quadrature voltage-controlled oscillator. Operating from a 3-V supply, the power consumptions for the receiver and transmitter are 114 and 120 mW, respectively     

A 1.9 GHz low-voltage silicon bipolar receiver front-end forwireless personal communications systems

A 1.9 GHz wireless receiver front-end (low-noise preamplifier and mixer) is described that incorporates monolithic microstrip transformers for significant improvements in performance compared to silicon broadband designs. Reactive feedback and coupling elements are used in place of resistors to lower the front-end noise figure through the reduction of resistor thermal noise, and this also allows both circuits to operate at supply voltages below 2 V. These circuits have been fabricated in a production 0.8 μm BiCMOS process that has a peak npn transistor transit frequency (f_T) of 11 GHz. At a supply voltage of 1.9 V, the measured mixer input third-order intercept point is +2.3 dBm with a 10.9 dB single-sideband noise figure. Power dissipated by the mixer is less than 5 mW. The low-noise amplifier input intercept is -3 dBm with a 2.8 dB noise figure and 9.5 dB gain. Power dissipation of the preamplifier is less than 4 mW, again from a 1.9 V supply     

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。     

Low-voltage 1.9-GHz front-end receiver in 0.5-μm CMOS technology

This paper describes the design of a 1.9-GHz front-end receiver. The target application of the receiver is the personal communications standard PCS1900. Powered by a 1-V supply, the receiver consists of a low noise amplifier (LNA) and a downconversion mixer. The receiver was fabricated within a 0.5-μm CMOS technology. The LNA features 15 dB of gain and a 1.8-dB noise figure. The mixer exhibits 1.5-dB conversion loss, 12-dB noise figure, and 0 dBm 1 dB-compression point     

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.     

An interference-robust receiver for ultra-wideband radio in SiGe BiCMOS technology

A 3.1-4.8 GHz ultra-wideband (UWB) receiver front-end for high data rate, short-range communication is presented. The receiver, based on the Multi Band OFDM Alliance (MBOA) standard proposal, consists of a zero-IF receive chain and an ultra-fast frequency-hopping synthesizer. The combination of high-linearity RF circuits, aggressive baseband filtering and low local oscillator spurs from the synthesizer results in an interference-robust receiver, having the ability to co-exist with systems operating in the 2.4-GHz and 5-GHz ISM bands. The packaged device shows an overall noise figure of 4.5 dB and has a measured input IP3 of -6 dBm and input IP2 of +25 dBm. Spurious tones generated by the synthesizer are below -45 dBc and -50 dBc in the 2.4-GHz and 5-GHz ISM bands, respectively. The hopping speed is well below the required 9.5 ns. The complete receive chain has been realized in a 0.25 /spl mu/m BiCMOS technology and draws 78mA from a 2.5-V 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。     

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     

A 5.2-GHz CMOS receiver with 62-dB image rejection

A 5.2-GHz CMOS receiver employs a double downconversion heterodyne architecture with a local oscillator frequency of 2.6 GHz and applies offset cancellation to the baseband amplifiers. Placing the image around the zero frequency, the receiver achieves an image rejection of 62 dB with no external components while minimizing the flicker noise upconversion in the first mixing operation. Realized in a 0.25-μm digital CMOS technology, the circuit exhibits a noise figure of 6.4 dB, an IP₃ of -15 dBm, and a voltage conversion gain of 43 dB, while draining 29 mW from a 2.5-V supply     

A 2.4-GHz low-IF receiver for wideband WLAN in 6-μmCMOS-architecture and front-end

This paper presents the 2.4-GHz front-end and the first downconversion section of a fully integrated low-IF receiver. The dual-conversion receiver rejects the image repeatably by 60 dB using integrated polyphase filters without calibration or tuning. The gain of the RF mixer and IF amplifier is switchable to slide the available dynamic range of the following stages based on the conditions of the input signal. The front-end and downconversion sections drain 35 mA on average from a 3.3-V supply. Minimum cascade noise figure is 7.2 dB, and maximum cascade IIP3 is -3.4 dBm     

一种接收前端三级低噪声放大器的设计

针对单片雷达接收机中对低噪声放大器（LNA）的要求,采用CMOS0．18,um工艺设计了一个三级级联的镜像抑制低噪声放大器。通过在低噪声放大器中接入限波滤波器,实现对镜像信号的衰减,从而减小了后端混频器电路的设计难度。在ADS中对设计的放大器仿真,其结果为：最大供电电压为5V情况下,信号频段为3．0～3．2GHz,中频输出为225MHz,功率增益≥31dB,噪声系数（FN）≤O．5dB,1dB点的输入／输出功率分别为-19．5dBm和11．5dBm,对镜像信号的抑制度达22dB。     

Highly integrated 60 GHz transmitter and receiver MMICs in a GaAs pHEMT technology

Highly integrated transmitter and receiver MMICs have been designed in a commercial 0.15 /spl mu/m, 88 GHz f/sub T//183 GHz f/sub MAX/ GaAs pHEMT MMIC process and characterized on both chip and system level. These chips show the highest level of integration yet presented in the 60 GHz band and are true multipurpose front-end designs. The system operates with an LO signal in the range 7-8 GHz. This LO signal is multiplied in an integrated multiply-by-eight (X8) LO chain, resulting in an IF center frequency of 2.5 GHz. Although the chips are inherently multipurpose designs, they are especially suitable for high-speed wireless data transmission due to their very broadband IF characteristics. The single-chip transmitter MMIC consists of a balanced resistive mixer with an integrated ultra-wideband IF balun, a three-stage power amplifier, and the X8 LO chain. The X8 is a multifunction design by itself consisting of a quadrupler, a feedback amplifier, a doubler, and a buffer amplifier. The transmitter chip delivers 3.7/spl plusmn/1.5 dBm over the RF frequency range of 54-61 GHz with a peak output power of 5.2 dBm at 57 GHz. The single-chip receiver MMIC contains a three-stage low-noise amplifier, an image reject mixer with an integrated ultra-wideband IF hybrid and the same X8 as used in the transmitter chip. The receiver chip has 7.1/spl plusmn/1.5 dB gain between 55 and 63 GHz, more than 20 dB of image rejection ratio between 59.5 and 64.5 GHz, 10.5 dB of noise figure, and -11 dBm of input-referred third-order intercept point (IIP3).     

A 5-GHz highly integrated receiver front-end

In this paper a radio front-end for a IEEE 802.11a and HIPERLAN2 sliding-IF receiver is presented. The circuit, implemented in a low-cost 46-GHz-f _T silicon bipolar process, includes a variable-gain low noise amplifier and a double-balanced mixer. Thanks to monolithic LC filters and on-chip single-ended-to-differential conversion of the RF signal, the proposed solution does not require the expensive image rejection filter and an external input balun. The receiver front-end exhibits a 4.3-dB noise figure and a power gain of 21 dB, providing an image rejection ratio higher than 50 dB. By using a 1-bit gain control, it achieves an input 1-dB compression point of −11 dBm, while drawing only 22 mA from a 3-V supply voltage.     

A 17.1-17.3-GHz image-reject downconverter with phase-tunable LO using 3/spl times/ subharmonic injection locking

A 17-GHz RF receiver, consisting of a low-noise amplifier (LNA) and doubly balanced mixers coupled by a monolithic 3.7:1 step-down transformer, realizes over 75 dB of image rejection in a production 100-GHz f/sub T/ SiGe BiCMOS technology. A new coupling transformer winding improves the magnetic coupling coefficient by more than 20% compared to conventional designs, which reduces parasitic effects and increases the overall efficiency of the LNA/mixer combination. Quadrature LO signals with electronically tunable phase are generated by a subharmonically injection-locked oscillator. The measured receiver IIP3 is -5.1 dBm with 17.3-dB conversion gain and 6.5-dB noise figure (SSB 50 /spl Omega/) at 17.2 GHz. The 1.9/spl times/1.0 mm/sup 2/ IC consumes 62.5 mW from a 2.2-V supply.     

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。     

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.     

A low-voltage 5.1-5.8-GHz image-reject receiver with wide dynamicrange

A monolithic 5-6-GHz band receiver, consisting of a differential preamplifier, dual doubly balanced mixers, cascaded injection-locked frequency doublers, and a quadrature local oscillator generator and prescaler, realizes over 45 dB of image-rejection in a mature 25-GHz silicon bipolar technology. The measured single sideband (50 Ω) noise figure is 5.1 dB with an IIP3 of -4.5 dBm and 17-dB conversion gain at 5.3 GHz. The 1.9×1.2 mm² IC is packaged in a standard 32-pin ceramic quad flatpack and consumes less than 50 mW from a 2.2-V supply     

A 5.25-GHz image rejection RF front-End Receiver With Polyphase filters

A 5.25-GHz image rejection (IR) radio frequency (RF) front-end receiver is proposed, which is implemented in 0.18-/spl mu/m CMOS technology. The proposed receiver adopts both a high-intermediate frequency (IF) and the double quadrature architecture to achieve high IR at 5-GHz frequency. The measured results show a power gain of 14 dB, a minimum noise figure of 7.9dB, and IIP3 of -8dBm. The measured maximum image rejection ratio is 45dBc. The receiver consumes a total of 32mA from a 1.8-V supply.     

A 2.4-GHz sub-mW CMOS receiver front-end for wireless sensors network

A 2.4-GHz fully integrated CMOS receiver front-end using current-reused folded-cascode circuit scheme is presented. A configuration utilizing vertically stacked low-noise amplifier (LNA) and a folded-cascode mixer is proposed to improve both conversion gain and noise figure suitable for sub-mW receiver circuits. The proposed front-end achieves a conversion gain of 31.5dB and a noise figure of 11.8dB at 10MHz with 500-/spl mu/A bias current from a 1.0-V power supply. The conversion gain and noise figure improvements of the proposed front-end over a conventional merged LNA and single-balanced mixer are 11dB and 7.2dB at 10MHz, respectively, with the same power consumption of 500/spl mu/W.