A 60 GHz SiGe-HBT Power Amplifier With 20% PAE at 15 dBm Output Power

A monolithic power amplifier (PA) operating in the 60 GHz band is presented. The circuit has been designed utilizing an advanced 0.25 SiGe-heterojunction bipolar transistor (HBT) technology, featuring npn transistors with and . A two-stage cascode architecture has been chosen for the implementation. Design techniques and optimization procedure are explained in detail. Measurements show a small signal gain of 18.8 dB and an output power of 14.5 dBm under 1 dB gain compression at 61 GHz. At this frequency, the saturated output power is 15.5 dBm and the peak power added efficiency (PAE) is 19.7%. To our knowledge, this is the highest PAE reported so far for a monolithic 61 GHz PA in SiGe-HBT technology.     

A 50 to 70 GHz Power Amplifier Using 90 nm CMOS Technology

A 50 to 70 GHz wideband power amplifier (PA) is developed in MS/RF 90 nm 1P9M CMOS process. This PA achieves a measured P_sat of 13.8 dBm, P_{1 dB} of 10.3 dBm, power added efficiency (PAE) of 12.6%, and linear power gain of 30 dB at 60 GHz under V_DD biased at 1.8 V. When V_DD is biased at 3 V, it exhibits P_sat of 18 dBm, P_{1 dB} of 12 dBm, PAE of 15%, and linear gain of 32.4 dB at 60 GHz. The MMIC PA also has a wide 3 dB bandwidth from 50 to 70 GHz, with a chip size of 0.66 times 0.5 mm². To the author's knowledge, this PA demonstrates the highest output power, with the highest gain among the reported CMOS PAs in V-band.     

基于40 nm CMOS工艺的高效率功率放大器设计

针对硅基毫米波功率放大器存在的饱和输出功率较低、增益不足和效率不高的问题,基于TSMC 40nm CMOS工艺,设计了一款工作在28GHz的高效率和高增益连续F类功率放大器。提出的功率放大器由驱动级和功率级组成。针对功率级设计了一款基于变压器的谐波控制网络来实现功率合成和谐波控制,有效地提高了功率放大器的饱和输出功率和功率附加效率。采用PMOS管电容抵消功率级的栅源电容,进一步提高线性度和增益。电路后仿真结果表明,设计的功率放大器在饱和输出功率为20.5dBm处的峰值功率附加效率54%,1dB压缩点为19dBm,功率增益为27dB,在24GHz~32GHz频率处的功率附加效率大于40%。     

应用于无线传感器网络的功率放大器的设计

给出一种基于TSMC 0.18 μm RF CMOS工艺,应用于无线传感器网络的2.4 GHz 功率放大器的设计.该功率放大 器工作频率范围为2.4 GHz～2.4835 GHz,采用全差分AB类共源共栅电路结构,使用功率控制技术以节省功耗,当输入信号 功率-12.5 dBm时,输出功率在-10.4 dBm至5.69 ...     

一种输出匹配可调的、高线性度宽带功率放大器

采用自适应偏置技术和有源电感实现了一款输出匹配可调的、高线性度宽带功率放大器(PA)。自适应偏置技术抑制了功放管直流工作点的漂移,提高了PA的线性度。有源电感参与输出匹配,实现了输出匹配可调谐,该策略可调整因工艺偏差、封装寄生造成的输出匹配退化。利用软件ADS对电路进行验证,结果表明,在4 GHz频率下,输入1dB压缩点(Pin 1dB)为-7dBm,输出1dB压缩点(Pout 1dB)为11dBm,功率附加效率(PAE)为8.7%。在3.1GHz~4.8 GHz频段内,增益为(20.3±1.1)d B,输入、输出的回波损耗均小于-10dB。     

A 5.8 GHz 1 V Linear Power Amplifier Using a Novel On-Chip Transformer Power Combiner in Standard 90 nm CMOS

A fully integrated 5.8 GHz Class AB linear power amplifier (PA) in a standard 90 nm CMOS process using thin oxide transistors utilizes a novel on-chip transformer power combining network. The transformer combines the power of four push-pull stages with low insertion loss over the bandwidth of interest and is compatible with standard CMOS process without any additional analog or RF enhancements. With a 1 V power supply, the PA achieves 24.3 dBm maximum output power at a peak drain efficiency of 27% and 20.5 dBm output power at the 1 dB compression point.     

改进负载调制的GaN Doherty功率放大器及其线性化

在分析传统Doherty负载调制的基础上,通过选取合适的峰值放大器负载阻抗和采用较高的偏置电压,增强了Doherty功率放大器的负载调制,使其适用于大范围（9dB）回退情况下的应用。为了验证分析的有效性,设计和实现了一个具有100MHz瞬时带宽的2.55GHz GaN Doherty功率放大器。测试结果表明：在工作带宽内饱和功率约为49.4dBm,平均峰值效率为64%,9dB回退时的平均效率约为40%。当使用5载波100MHz带宽LTE-advanced信号激励时,在平均输出功率为40.2dBm时效率可达40.3%,经过数字预失真校正过的邻道泄漏比（ACLR）低于-48dBc,达到较好的线性度。     

A modified class-F power amplifier with miniaturized harmonic control circuit

In this paper, a modified class-F power-amplifier (PA) for GSM applications is designed, simulated and tested. In this design, novel symmetrical meandered lines compact microstrip resonant cell (SMLCMRC), is proposed as a new harmonics control circuit (HCC), which resulted in size compression, power added efficiency (PAE) enhancement, power gain improvement, and better linearization in the PA. In this work both of the conventional class-F amplifier and proposed amplifier with SMLCMRC is designed at 1.8 GHz. The measurements show that the proposed PA with SMLCMRC has 72.54% maximum PAE, 17.13 dB gain and the 1 dB compression point (P1dB) is about 35.1 dBm. These results show, 16.5% improvement in PAE, 1.33 dB increment in gain and 1.1 dB improvement in linearity operating range of proposed amplifier compared to the conventional PA.     

A Wideband 77-GHz, 17.5-dBm Fully Integrated Power Amplifier in Silicon

A 77-GHz,$+$17.5 dBm power amplifier (PA) with fully integrated 50-$Omega$input and output matching and fabricated in a 0.12-$muhbox m$SiGe BiCMOS process is presented. The PA achieves a peak power gain of 17 dB and a maximum single-ended output power of 17.5dBm with 12.8% of power-added efficiency (PAE). It has a 3-dB bandwidth of 15 GHz and draws 165 mA from a 1.8-V supply. Conductor-backed coplanar waveguide (CBCPW) is used as the transmission line structure resulting in large isolation between adjacent lines, enabling integration of the PA in an area of 0.6$hbox mm^2$. By using a separate image-rejection filter incorporated before the PA, the rejection at IF frequency of 25 GHz is improved by 35 dB, helping to keep the PA design wideband.     

Area-Efficient 60 GHz +18.9 dBm Power Amplifier with On-Chip Four-Way Parallel Power Combiner in 65-nm CMOS

This paper presents a compact 60-GHz power amplifier utilizing a four-way on-chip parallel power combiner and splitter. The proposed topology provides the capability of combining the output power of four individual power amplifier cores in a compact die area. Each power amplifier core consists of a three-stage common-source amplifier with transformer-coupled impedance matching networks. Fabricated in 65-nm CMOS process, the measured gain of the 0.19-mm² power amplifier at 60 GHz is 18.8 and 15 dB utilizing 1.4 and 1.0 V supply. Three-decibel band width of 4 GHz and P_1dB of 16.9 dBm is measured while consuming 424 mW from a 1.4-V supply. A maximum saturated output power of 18.3 dBm is measured with the 15.9% peak power added efficiency at 60 GHz. The measured insertion loss is 1.9 dB at 60 GHz. The proposed power amplifier achieves the highest power density (power/area) compared to the reported 60-GHz CMOS power amplifiers in 65 nm or older CMOS technologies.     

基于GaAs PHEMT工艺的60~90GHz功率放大器MMIC

研制了一款60~90 GHz功率放大器单片微波集成电路(MMIC),该MMIC采用平衡式放大结构,在较宽的频带内获得了平坦的增益、较高的输出功率及良好的输入输出驻波比(VSWR)。采用GaAs赝配高电子迁移率晶体管(PHEMT)标准工艺进行了流片,在片测试结果表明,在栅极电压为-0.3 V、漏极电压为+3 V、频率为60~90 GHz时,功率放大器MMIC的小信号增益大于13 dB,在71~76 GHz和81~86 GHz典型应用频段,功率放大器的小信号增益均大于15 dB。载体测试结果表明,栅极电压为-0.3 V、漏极电压为+3 V、频率为60~90 GHz时,该功率放大器MMIC饱和输出功率大于17.5 dBm,在71~76 GHz和81~86 GHz典型应用频段,其饱和输出功率可达到20 dBm。该功率放大器MMIC尺寸为5.25 mm×2.10 mm。     

Cross Cancellation TechniqueEmploying an Error Amplifier

In this letter, we propose a new distortion cancellation mechanism for a balanced power amplifier (PA) structure using the cross cancellation technique employing an error amplifier. The proposed cross cancellation balanced linear PA is implemented in the IMT-2000 ( 2.14GHz) band. With commercial PAs with a peak power of 240 W for base-station application, the proposed system shows 18.6 dB improvement at an average output power of 40 dBm for adjacent channel leakage ratio measurement with wideband code division multiple access 4FA signal. The efficiency of the proposed structure is about 2% higher than the conventional feedforward amplifier for modulated carrier.     

High Efficiency RF Power Amplifier Designed With Harmonic Real-Time Active Load-Pull

In this work, a high efficiency p-HEMT radio frequency power amplifier (PA) is designed using a new multiharmonic real-time active load-pull using the large signal network analyzer. This technique synthesizes a large set of instantaneous load mismatches to quickly find the optimal harmonic impedances, so as to achieve high PA efficiency in a shortened design cycle. At 2 GHz a demo power amplifier implemented with a p-HEMT demonstrated a power added efficiency (PAE) of 68.5% for 18.0 dBm output power, while achieving a maximum PAE of 75% below the 1 dB compression point for 18.6 dBm output power.     

2.4GHz 0.35-μm CMOS全集成线性功率放大器设计

片上系统射频功率放大器是射频前端的重要单元.通过分析和对比各类功率放大器的特点,电路采用SMIC0.35-μm CMOS工艺设计2.4 GHz WLAN全集成线性功率放大器.论文中设计的功率放大器采用不同结构的两级放大,驱动级采用共源共栅A类结构组成,输出级采用共源级大MOSFET管组成.电路采用SMIC 0.35-μ...     

2.4GHz CMOS高线性功率放大器

采用A类与B类并联的结构,设计了一种2.4GHz高线性功率放大器.输入信号较小时,A类放大器起主要作用;随着输入信号的增大,B类放大器起的作用越来越明显,来补偿A类的压缩,由此显著提高了放大器的线性度.电路主体为共栅管采用自偏置方法的共源共栅结构,提升了功放大信号工作时的可靠性.电路采用中芯国际0.13 μmCMOS工...     

基于SiGe工艺的高增益射频功率放大器

基于0.13μm SiGe HBT工艺,设计应用于无线局域网(WLAN)802.11b/g频段范围内的高增益射频功率放大器.该功放工作在AB类,由三级放大电路级联构成,并带有温度补偿和线性化的偏置电路.仿真结果显示:功率增益高达30dB,1dB压缩点输出功率为24dBm,电路的S参数S11在1.5～4GHz大的频率范围内均小于-17dB,S21大于30dB,输出匹配S22小于-10dB,S12小于-90dB.最高效率可达42.7%,1dB压缩点效率为37%.     

5.2 GHz variable-gain amplifier and power amplifier driver for WLAN IEEE 802.11a transmitter front-end

A 5.2 GHz variable-gain amplifier (VGA) and a power amplifier (PA) driver are designed for WLAN IEEE 802.11a monolithic RFIC. The VGA and the PA driver are implemented in a 50 GHz 0.35 μm SiGe BiCMOS technology and occupy 1.12×1.25 mm2 die area. The VGA with effective temperature compensation is controlled by 5 bits and has a gain range of 34 dB. The PA driver with tuned loads utilizes a differential input, single-ended output topology, and the tuned loads resonate at 5.2 GHz. The maximum overall gain of the VGA and the PA driver is 29 dB with the output third-order intercept point (OIP3) of 11 dBm. The gain drift over the temperature varying from -30 to 85℃ converges within±3 dB. The total current consumption is 45 mA under a 2.85 V power supply.     

A High Gain 77 GHz Power Amplifier Operating at 0.7 V Based on 90 nm CMOS Technology

A 77 GHz 90 nm CMOS power amplifier (PA) demonstrates a gain of 17.4 dB and a saturated output power of 5.8 dBm at a low supply voltage of 0.7 V. To take care of hot-carrier injection degradation, the supply voltage is reduced from a standard voltage of 1.0 V. The saturated output power is increased to 9.4 dBm with a linear gain of 20.6 dB at 1.0 V operation. The amplifier consists of three-stage common-source nMOSFETs with gate widths of 40, 80, and 160 $mu{rm m}$. To our best knowledge, the developed PA shows the highest gain ever achieved for W-band CMOS amplifier. The measured temperature characteristics suggest that a simple compensation technique is possible by gate bias control.      

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 77 GHz mHEMT MMIC Chip Set for Automotive Radar Systems

A monolithic microwave integrated circuit (MMIC) chip set consisting of a power amplifier, a driver amplifier, and a frequency doubler has been developed for automotive radar systems at 77 GHz. The chip set was fabricated using a 0.15 µm gate‐length InGaAs/InAlAs/GaAs metamorphic high electron mobility transistor (mHEMT) process based on a 4‐inch substrate. The power amplifier demonstrated a measured small signal gain of over 20 dB from 76 to 77 GHz with 15.5 dBm output power. The chip size is 2 mm × 2 mm. The driver amplifier exhibited a gain of 23 dB over a 76 to 77 GHz band with an output power of 13 dBm. The chip size is 2.1 mm × 2 mm. The frequency doubler achieved an output power of –6 dBm at 76.5 GHz with a conversion gain of ?16 dB for an input power of 10 dBm and a 38.25 GHz input frequency. The chip size is 1.2 mm × 1.2 mm. This MMIC chip set is suitable for the 77 GHz automotive radar systems and related applications in a W‐band.