采用内嵌了离散时间滤波器的射频直接采样混频器的CMOS宽带前端芯片

本文展示了一种新型的CMOS宽带射频前端芯片。它由低噪声跨到放大器（LNTA）和内嵌了可编程的离散时间滤波器的射频直接采样混频器（DSM）组成。第一级的LNTA具有0.5到6GHz的带宽,宽带输入匹配以及低噪声的特性。DSM之后的内嵌滤波器工作在离散时间电荷域,可以根据始终频率控制中频带宽,同时滤除混叠和干扰信号。测试结果显示,在0.5到6GHz的带宽内,噪声系数均低于7dB。在2.4GHz处,转换增益为12.6dB,IP1dB为-7.5dBm。该芯片所占面积为0.23mm2,消耗14mA直流电流。     

一种高性能宽带直接变频射频前端设计

提出一种宽带(250 MHz~4.7 GHz)无电感BiCMOS射频前端结构,包含低噪声跨导放大器(LNTA)、带电阻无源混频器和跨阻级。低噪声跨导放大器使用了噪声和线性度消除技术,例如输入交叉耦合结构、互补输入和电流复用技术。带电阻无源混频器采用退化电阻来提高线性度。仿真结果表明, 当电源电压为3.3 V时,总电流为9.38 mA, 噪声系数为9.8 dB(SSB),电压转换增益为20 dB,输入3阶交调为+11.8 dBm。     

An 800-MHz–6-GHz Software-Defined Wireless Receiver in 90-nm CMOS

A software-defined radio receiver is designed from a low-power ADC perspective, exploiting programmability of windowed integration sampler and clock-programmable discrete-time analog filters. To cover the major frequency bands in use today, a wideband RF front-end, including the low-noise amplifier (LNA) and a wide tuning-range synthesizer, spanning over 800 MHz to 6 GHz is designed. The wideband LNA provides 18-20 dB of maximum gain and 3-3.5 dB of noise figure over 800 MHz to 6 GHz. A low 1/f noise and high-linearity mixer is designed which utilizes the passive mixer core properties and provides around +70 dBm IIP2 over the bandwidth of operation. The entire receiver circuits are implemented in 90-nm CMOS technology. Programmability of the receiver is tested for GSM and 802.11g standards     

0.5 V ultra-low power wideband LNA with forward body bias technique

An ultra-low power wideband CMOS low noise amplifier (LNA) fabricated in TSMC 0.18 μm RF CMOS process for sub 1 GHz applications is presented. The capacitive cross-coupled LNA with forwardbody- bias (FBB) technique is adopted to achieve wideband input impedance matching and low power, low noise factor. The LNA is tested in the frequency range of 400?900 MHz, and exhibits a voltage gain of 18.5?20.7 dB, and a noise figure of 2.95 dB, drawing only 0.385 mW from 0.5 V power supply.     

Theoretical Analysis of a Low Dispersion SiGe LNA for Ultra-Wideband Applications

We demonstrate a low dc power consumption SiGe heterojunction bipolar transistor (HBT) low noise amplifier (LNA) for ultra-wideband (UWB) applications covering the 0.5GHz to 10GHz band. Using theoretical analysis, the dominant design factor for low group delay variation is identified and applied to UWB LNA design. The implemented SiGe LNA achieves a gain of 13dB, a minimum noise figure of 3.3dB, and an IIP3 of$-$7.5dBm between 0.5GHz and 10GHz, while consuming a dc power of only 9.6mW. This SiGe UWB LNA exhibits less than 22ps of uniform group delay variation over the entire band. To the best of the authors' knowledge, this is the first attempt to analyze the effects of group delay variation on the operation of wideband LNAs.     

Noise current feedforward for noise cancellation in the wideband transformer shunt feedback low noise amplifier

A noise current feedforward (NCF) technique for noise cancellation in the wideband transformer shunt feedback (TSF) low noise amplifier (LNA) is proposed. The NCF can detect and cancel the thermal noise of the TSF network. It is also suitable to cancel those noise contributed by the passive unilateral shunt feedback networks in common current mode LNAs. Implemented in SMIC 0.18 μm CMOS process and operated in the typical radio astronomy frequency range from 0.6 GHz to 1.6 GHz, the TSF LNA that employs the NCF shows approximately 0.2–0.5 dB lower noise figure than the overwhelming resistive shunt feedback LNA that exploits a conventional noise voltage feedforward technique when consuming the same power.     

毫米波大动态宽带单片低噪声放大器

利用0.25μmGaAsPHEMT低噪声工艺,设计并制造了2种毫米波大动态宽带单片低噪声放大器。第1种为低增益大动态低噪声放大器,单电源+5V工作,测得在26～40GHz范围内,增益G=10±0.5dB,噪声系数NF≤2.2dB,1分贝压缩点输出功率P1dB≥15dBm;第2种为低压大动态低噪声放大器,工作电压为3.6V,静态电流0.6A(输出功率饱和时,动态直流电流约为0.9A),在28～35GHz范围内,测得增益G=14～17dB,噪声系数约4.0dB,1分贝压缩点输出功率P1dB≥24.5dBm,最大饱和输出功率≥26.8dBm,附加效率约10%～13.6%。结果中还给出了2种放大器直接级联的情况。     

3.1～5.2GHz超宽带可变增益低噪声放大器设计

低噪声放大器是超宽带接收机系统中最重要的模块之一,设计了一种可应用于3.1～5.2GHz频段超宽带可变增益低噪声放大器。电路输入级采用共栅结构实现超宽带输入匹配,并引入电流舵结构实现了放大器的可变增益。仿真基于TSMC 0.18μm RF CMOS工艺。结果表明,在全频段电路的最大功率增益为10.5dB,增益平坦度小于0.5dB,噪声系数小于5dB,输入反射系数低于-15dB,在1.8V电源电压下,功耗为9mW。因此,该电路能够在低功耗超宽带射频接收机系统中应用。     

一个6GHz宽带低相位噪声CMOS LC VCO

用SMIC 0.13 μm CMOS工艺实现了一个低相位噪声的6 GHz压控振荡器(VCO).在对其相位噪声分析的基础上,通过改进和优化传统的调谐单元和噪声滤波电路以及加入源极负反馈电阻实现了一个宽带、低增益、低相位噪声VCO.测试结果显示,在中心频率频偏1 MHz处的相位噪声为-119 dBc/Hz,频率调谐范围为6...     

A 75 GHz to 115 GHz quasi-optical amplifier

A wideband quasi-optical amplifier employing two pyramidal back-to-back horns has been developed. Using a four-stage W-band low noise amplifier (LNA) designed and fabricated by Martin Marietta Laboratories, the quasi-optical amplifier gives a system gain greater than 11 dB from 86 GHz to 113 GHz without any low frequency oscillations. A peak system gain of 15.5 dB is measured at 102 GHz, and the measured noise figure of the system is 7.4 dB at 94 GHz. The quasi-optical amplifier design maintains the same polarization of the received and transmitted signal, provides better than -40 dB isolation, and can be fabricated monolithically at millimeter-wave frequencies     

3.6~4.7GHz低噪声放大器

以一种经典的窄带低噪声放大器结构为基础,分析级联放大器的S参数,通过优化元件参数,获得了一种在3.6~4.7 GH z范围内具有低输入回波损耗、低噪声系数的放大器。采用标准的0.18μm RF CM O S工艺进行了设计和实现。芯片面积为0.6 mm×1.5 mm。测试结果表明:在3.6~4.7 GH z的范围内,该宽带低噪声放大器输入回波损耗小于-14 dB;噪声系数小于2.8 dB,增益大于10 dB。在1.8 V电源下功耗约为45 mW。     

2～12 GHz CMOS超宽带低噪声放大器设计

提出了一种基于双反馈电流复用结构的新型CMOS超宽带(UWB)低噪声放大器(LNA),放大器工作在2～12 GHz的超宽带频段,详细分析了输入输出匹配、增益和噪声系数的性能。设计采用TSMC 0.18μm RF CMOS工艺,在1.4 V工作电压下,放大器的直流功耗约为13mW(包括缓冲级)。仿真结果表明,在2～12 GHz频带范围内,功率增益为15.6±1.4 dB,输入、输出回波损耗分别低于-10.4和-11.5 dB,噪声系数(NF)低于3 dB(最小值为1.96 dB),三阶交调点IIP3为-12 dBm,芯片版图面积约为712μm×614μm。     

Wideband HEMT balanced amplifier

The high electron mobility transistor (HEMT) has demonstrated great potential for high-gain and low-noise applications, achieving a noise figure and current gain cutoff frequency fT superior to that of the GaAs MESFET. The letter presents the practical use of an HEMT in a hybrid wideband balanced amplifier covering 8.5 to 16 GHz producing 9.7 ± 0.5 dB gain and 2.6 dB midband noise figure. The performance is also compared to a GaAs MESFET stage.     

A Packaged and ESD-Protected Inductorless 0.1–8 GHz Wideband CMOS LNA

In this letter, an inductorless 0.1-8 GHz wideband CMOS differential low noise amplifier (LNA) based on a modified resistive feedback topology is proposed. Without using any passive inductors, the modified resistive feedback technique implemented with a parallel R-C feedback, an active inductor load, and neutralization capacitors achieves high gain, low noise, and good return loss over a wide bandwidth. To ensure the robustness in the system integration, electro-static discharge diodes are added to the radio frequency pads. The LNA was fabricated using a digital 90 nm CMOS technology. It achieves a 3 dB bandwidth of 8 GHz with a 16 dB voltage gain, noise figures from 3.4 dB to 5.8 dB across the whole band, and an input third-order intermodulation product (IIP3) of -9 dBm. The active area of the chip is 0.034 mm². The chip was packaged and tested on an FR4 PCB using the chip-on-board approach.     

A wideband LNA employing gate-inductive-peaking and noise-canceling techniques in 0.18μm CMOS

正This paper presents a wideband low noise amplifier(LNA) for multi-standard radio applications.The low noise characteristic is achieved by the noise-canceling technique while the bandwidth is enhanced by gateinductive -peaking technique.High-frequency noise performance is consequently improved by the flattened gain over the entire operating frequency band.Fabricated in 0.18μm CMOS process,the LNA achieves 2.5 GHz of -3 dB bandwidth and 16 dB of gain.The gain variation is within±0.8 dB from 300 MHz to 2.2 GHz.The measured noise figure(NF) and average HP3 are 3.4 dB and -2 dBm,respectively.The proposed LNA occupies 0.39 mm2 core chip area.Operating at 1.8 V,the LNA drains a current of 11.7 mA.     

High‐Gain Wideband CMOS Low Noise Amplifier with Two‐Stage Cascode and Simplified Chebyshev Filter

An ultra‐wideband low‐noise amplifier is proposed with operation up to 8.2 GHz. The amplifier is fabricated with a 0.18‐μm CMOS process and adopts a two‐stage cascode architecture and a simplified Chebyshev filter for high gain, wide band, input‐impedance matching, and low noise. The gain of 19.2 dB and minimum noise figure of 3.3 dB are measured over 3.4 to 8.2 GHz while consuming 17.3 mW of power. The Proposed UWB LNA achieves a measured power‐gain bandwidth product of 399.4 GHz.     

微波毫米波宽带单片低噪声放大器

推导了反馈电路理论,利用0.25μmGaAs PHEMT工艺,研制了两种并联反馈单片低噪声放大器。第一种放大器的工作频带为6～18GHz,测得增益G≥21dB,带内增益波动ΔG≤±1.0dB,噪声系数NF典型值为2.0dB,输入驻波VSWRin≤1.5,输出驻波VSWRout≤2.0,1分贝压缩点输出功率P1dB≥11dBm。第二种放大器的工作频带为26～40GHz,测得增益G≥17dB,噪声系数NF约为2.0dB,输入、输出驻波VSWR≤2.5,1分贝压缩点输出功率P1dB≥10dBm。两种电路的测试结果验证了设计的正确性。     

一种用于卫星导航接收机的低噪声放大器设计

设计了一种可用于多模式卫星导航接收机的射频前端低噪声放大器,设计电路可在1.13～1.95 GHz工作,兼容了GPS,北斗及GLONOSS导航系统的工作频段。电路采用0.18 μm CMOS工艺实现。仿真结果表明,频带内S11和S22均在-10 dB以下,功率增益＞10 dB,带内最小噪声系数可达到2.2 dB,输出1 dB压缩点为-5.585 dBm,在1.8 V电源电压下,主体电路消耗12 mA电流。因此,该低频噪声放大器模块可满足当前各种导航系统的工作要求。     

一种采用噪声抵消及多重功耗优化技术的UWB-LNA

采用噪声抵消及多重功耗优化技术,提出了一种超宽带低噪声低功耗放大器。它主要包括采用RL网络的共栅输入级、电流复用型噪声抵消级、放大输出级以及偏置电路四个部分。验证结果表明,该放大器,在2-6GHz频带内,增益(S21)可以在14dB以上;输入回波损耗(S11)小于-10dB;输出回波损耗(S22)小于-25dB;噪声系数(NF)小于3.2dB;在3.8V的工作电压下,功耗仅为14mW。     

A low power high gain UWB LNA in 0.18-μm CMOS

A low power high gain differential UWB low noise amplifier (LNA) operating at 3-5 GHz is presented.A common gate input stage is used for wideband input matching; capacitor cross coupling (CCC) and current reuse techniques are combined to achieve high gain under low power consumption. The prototypes fabricated in 0.18-μm CMOS achieve a peak power gain of 17.5 dB with a -3 dB bandwidth of 2.8-5 GHz, a measured minimum noise figure (NF) of 3.35 dB and -12.6 dBm input-referred compression point at 5 GHz, while drawing 4.4 mA from a 1.8 V supply. The peak power gain is 14 dB under a 4.5 mW power consumption (3 mA from a 1.5 V supply). The proposed differential LNA occupies an area of 1.01 mm~2 including test pads.