Linearised InGaP/GaAs HBT MMIC power amplifier with active biascircuit for W-CDMA application

A high linearity InGaP/GaAs heterojunction bipolar transistor (HBT) monolithic microwave integrated circuit (MMIC) power amplifier is demonstrated using a new structure for a bias circuit for wideband-code division multiple access (W-CDMA) application. A one shunt capacitor is added to a novel active bias circuit and acts as a lineariser improving input P_{1 dB} of 16 dB and phase distortion of 5.1° for the hybrid phase shift keying (HPSK) modulated signal at the 28 dBm output power; the lineariser showing no significant increase of signal loss and chip area. The two-stage HBT MMIC amplifier exhibits a power-added efficiency (PAE) of 37%, a linear power gain of 24.5 dB, and an output power of 28 dBm with an adjacent channel power ratio (ACPR) of -45 dBc, under a 3 V operation voltage     

SiGe MMIC power amplifier with on-chip lineariser for X-band applications

An X-band linear power amplifier with an on-chip lineariser is developed using a 0.25 mum SiGe HBT BiCMOS process. The proposed on-chip lineariser improves the 1 dB compression to as much as 3.4 dB with no additional DC power consumption. Under a 3.3 V DC power supply, the single-stage cascode amplifier shows a measured small-signal gain of 12.2 dB and output PI dB of 20.8 dBm, with power added efficiency of 27.4% at the operating frequency range 8.5-10.5 GHz.     

An InGaP-GaAs HBT MMIC smart power amplifier for W-CDMA mobile handsets

We demonstrate a new linearized monolithic microwave integrated circuit smart power amplifier of extraordinary high power-added efficiency (PAE), especially at the most probable transmission power of wide-band code-division multiple-access handsets. A PAE of 21% at 16 dBm of output power, which is the maximum bound of the most probable transmission power in IS-95 systems, was obtained, as well as 40% at 28 dBm, the required maximum output power, with a single-chip MMIC power amplifier. The power amplifier has been devised with two InGaP-GaAs heterojunction bipolar transistor amplifying chains parallel connected, each chain being optimized for a different P/sub 1dB/ (1-dB compression point) value: one for 16 dBm for the low-power mode, targeting the most probable transmission power, and the other for 28 dBm for the high-power mode. The high-power mode operation shows 40% of PAE and -30 dBc of adjacent channel leakage power ratio (ACLR) at the maximum output power of 28 dBm. The low-power mode operation exhibits -34 dBc of ACLR at 16 dBm with 14 mA of a quiescent current. This amplifier improves power usage efficiency and, consequently, the battery lifetime of the handset by a factor of three.     

High Power SiGe X-Band (8～10GHz) Heterojunction Bipolar Transistors and Amplifiers

Limited by increased parasitics and thermal effects as device size increases, current commercial SiGe power HBTs are difficult to operate at X-band (8～ 12GHz) frequencies with adequate power added efficiencies at high power levels. We find that, by changing the heterostructure and doping profile of SiGe HBTs, their power gain can be significantly improved without resorting to substantial lateral scaling. Furthermore, employing a common-base configuration with a proper doping profile instead of a common-emitter configuration improves the power gain characteristics of SiGe HBTs, thus permitting these devices to be efficiently operated at X-band frequencies. In this paper,we report the results of SiGe power HBTs and MMIC power amplifiers operating at 8～10GHz. At 10GHz,a 22.5dBm (178mW) RF output power with a concurrent gain of 7.32dB is measured at the peak power-added efficiency of 20.0%, and a maximum RF output power of 24.0dBm (250mW) is achieved from a 20 emitter finger SiGe power HBT. The demonstration of a single-stage X-band medium-power linear MMIC power amplifier is also realized at 8GHz. Employing a 10-emitter finger SiGe HBT and on-chip input and output matching passive components, a linear gain of 9.7dB,a maximum output power of 23.4dBm,and peak power added efficiency of 16% are achieved from the power amplifier. The MMIC exhibits very low distortion with 3rd order intermodulation (IM) suppression C/I of -13dBc at an output power of 21.2dBm and over 20dBm 3rd order output intercept point (OIP3).     

High Power SiGe X-Band (8～10GHz) Heterojunction Bipolar Transistors and Amplifiers

Limited by increased parasitics and thermal effects as device size increases, current commercial SiGe power HBTs are difficult to operate at X-band (8～ 12GHz) frequencies with adequate power added efficiencies at high power levels. We find that, by changing the heterostructure and doping profile of SiGe HBTs, their power gain can be significantly improved without resorting to substantial lateral scaling. Furthermore, employing a common-base configuration with a proper doping profile instead of a common-emitter configuration improves the power gain characteristics of SiGe HBTs, thus permitting these devices to be efficiently operated at X-band frequencies. In this paper,we report the results of SiGe power HBTs and MMIC power amplifiers operating at 8～10GHz. At 10GHz,a 22.5dBm (178mW) RF output power with a concurrent gain of 7.32dB is measured at the peak power-added efficiency of 20.0%, and a maximum RF output power of 24.0dBm (250mW) is achieved from a 20 emitter finger SiGe power HBT. The demonstration of a single-stage X-band medium-power linear MMIC power amplifier is also realized at 8GHz. Employing a 10-emitter finger SiGe HBT and on-chip input and output matching passive components, a linear gain of 9.7dB,a maximum output power of 23.4dBm,and peak power added efficiency of 16% are achieved from the power amplifier. The MMIC exhibits very low distortion with 3rd order intermodulation (IM) suppression C/I of -13dBc at an output power of 21.2dBm and over 20dBm 3rd order output intercept point (OIP3).     

High Power SiGe X-Band (8～10GHz) Heterojunction Bipolar Transistors and Amplifiers

Limited by increased parasitics and thermal effects as device size increases,current commercial SiGe power HBTs are difficult to operate at X-band (8～12GHz) frequencies with adequate power added efficiencies at high power levels.We find that,by changing the heterostructure and doping profile of SiGe HBTs,their power gain can be significantly improved without resorting to substantial lateral scaling.Furthermore,employing a common-base configuration with a proper doping profile instead of a common-emitter configuration improves the power gain characteristics of SiGe HBTs,thus permitting these devices to be efficiently operated at X-band frequencies.In this paper,we report the results of SiGe power HBTs and MMIC power amplifiers operating at 8～10GHz.At 10GHz,a 22.5dBm (178mW) RF output power with a concurrent gain of 7.32dB is measured at the peak power-added efficiency of 20.0%,and a maximum RF output power of 24.0dBm (250mW) is achieved from a 20 emitter finger SiGe power HBT.The demonstration of a single-stage X-band medium-power linear MMIC power amplifier is also realized at 8GHz.Employing a 10-emitter finger SiGe HBT and on-chip input and output matching passive components,a linear gain of 9.7dB,a maximum output power of 23.4dBm,and peak power added efficiency of 16% are achieved from the power amplifier.The MMIC exhibits very low distortion with 3rd order intermodulation (IM) suppression C/I of -13dBc at an output power of 21.2dBm and over 20dBm 3rd order output intercept point (OIP3).     

An X-band high-power amplifier using SiGe/Si HBT and lumped passivecomponents

We report the design and fabrication of a compact microwave monolithic integrated circuit (MMIC) amplifier, which demonstrates high output power at X-Band. A single-stage power amplifier is demonstrated, with a double-mesa type SiGe/Si HBT as the active device and spiral inductors and MIM capacitors as lumped passive components. At 8.4 GHz, a linear gain of 8.7 dB, an output power at peak efficiency of 23 dBm, and a saturated output power P_sat of 25 dBm, are measured. To our knowledge, this is the first MMIC X-Band power amplifier using SiGe/Si HBTs     

A monolithically integrated HEMT-HBT low noise high linearityvariable gain amplifier

We report on a 1-6 GHz HEMT-HBT three-stage variable gain amplifier (VGA), which is realized using selective molecular beam epitaxy (MBE). The VGA integrates an HEMT low noise amplifier with an HBT analog current-steer variable gain cell and output driver stage to achieve a combination of low noise figure, wide gain control, and high linearity. The HEMT-HBT VGA MMIC obtains a maximum gain of 21 dB with a gain control range >30 dB, a minimum noise figure of 4.3 dB, and an input IP3 (IIP3) greater than -4 dBm over 25 dB of gain central range. By integrating an HEMT instead of on HBT preamplifier stage, the VGA noise figure is improved by as much as 2 dB compared to an all-HBT single-technology design. The HEMT-HBT MMIC demonstrates the functional utility and RF performance advantage of monolithically integrating both HEMT and HBT devices on a single substrate     

5W ISM波段InGaP/GaAs HBT功率放大器MMIC

通过分析InGaP/GsAsHBT器件的热学和电学特点,结合HBT大功率放大器芯片在技术性能、稳定性、可靠性及尺寸等方面的要求,通过优化设计HBT功率器件单元和匹配电路,开发了一个大功率、高效率、小尺寸的ISM波段功率放大器单片集成电路。该三级放大器的各级器件单元的发射极面积分别为320μm2,1280μm2,5760μm2,芯片内部包括了输入、输出50Ω匹配电路,面积仅为1.9mm×2.1mm。放大器采用5V单电源供电,在2.4～2.5GHz频率范围内线性增益为27dB,2dB增益压缩点输出饱和功率达到37dBm,功率附加效率为46%。     

0.1-42 GHz InP DHBT distributed amplifiers with 35 dB gain and 15 dBm output

An InP double hetero-junction bipolar transistor (DHBT) distributed power amplifier MMIC with 35 dB gain, 42 GHz bandwidth and 15 dBm output power is reported. This represents the highest power and largest gain reported over this bandwidth from a single chip HBT amplifier. A lumped preamplifier with a novel distributed output is used to obtain high gain and wide bandwidth at these power levels.     

基于InGaP/GaAs HBT的X波段MMIC功率放大器研制

研制了X波段的InGaP/GaAs HBT单级MMIC功率放大器,该电路采用自行开发的GaAs HBT自对准工艺技术制作.电路偏置于AB类,小信号S参数测试在8～8.5GHz范围内,线性增益为8～9dB,输入驻波比小于2,输出驻波比小于3,优化集电极偏置后,线性增益为9～10dB.在8.5GHz进行连续波功率测试,在优化的负载阻抗条件下,P1dB输出功率为29.4dBm,相应增益7.2dB,相应PAE〉40%,电路的饱和输出功率Psat为30dBm.     

用于W-LAN的5.8GHz InGaP/GaAs HBT MMIC线性功率放大器

介绍了一种应用于W-LAN系统的5.8 GHz InGaP/GaAs HBT MMIC功率放大器。该功率放大器采用了自适应线性化偏置电路来改善线性度和效率,同时偏置电路中的温度补偿电路可以抑制直流工作点随温度的变化,采用RC稳定网络使放大器在较宽频带内具有绝对稳定性。在单独供电3.6 V电压情况下,功率放大器的增益为26 dB,1 dB压缩点处输出功率为26.4 dBm,功率附加效率(PAE)为25%。三阶交调系数(IMD3)在输出功率为26.4 dBm时为-19 dBc,输出功率为20 dBm时低于-38 dBc,在1 dB压缩点处偏移频率为20 MHz时邻道功率比(ACPR)值为-31 dBc。     

移动通信用GaAs HBT功率放大器

介绍了移动通信用 Ga As HBT功率放大器的设计、制作 ,给出了电路拓扑。该两级放大电路在 180 0 MHz、3.6 V偏压下 ,相关增益 >30 d B,1分贝压缩点输出功率达到 2 8.8d Bm,饱和输出功率 >30 d Bm,最大效率 >37%。采用 Φ 76 mm工艺制作 ,工艺成品率高     

Ka频段PHEMT 1W功率单片放大器

设计制作了Ka频段高输出功率的单片功率放大器.基于河北半导体研究所的0.25μm栅长的75mm GaAsPHEMT工艺制作的三级功率放大器,芯片尺寸为19.25mm2(3.5mm×5.5mm).在32.5～35.5GHz的频率范围内,小信号线性增益大于16dB,带内平均1dB增益压缩点输出功率为29.8dBm,最大饱和输出功率为31dBm.     

9.5-14.5 GHz GaAs HBT 1W MMIC with 55% peak power added efficiency

A fully matched, broadband, high efficiency MMIC power amplifier using AlGaAs/GaAs HBTs has been designed and tested. At 7 V collector bias, this HBT amplifier produced 31 dBm CW peak output power with 9 dB gain and 55% peak power-added efficiency in the 9.5-14.5 GHz band. To the authors' knowledge, this is the highest efficiency ever achieved from a broadband MMIC power amplifier     

A new diode-based curve-fitting predistortion lineariser for GaN power amplifier

In this article, a new strategy is presented for selecting the breakpoints on a typical characteristic of a lineariser for a saturating nonlinear amplifier. As a proof of concept, using this strategy, a new Schottky-diode based curve-fitting predistortion lineariser for a 1.65?GHz centre frequency, 50?MHz bandwidth, 30?W GaN power amplifier is developed. The proposed lineariser is tested using the two-tone test and the Quadrature Phase-Shift Keying (QPSK) modulated signal. The results show that a 3?dB improvement in the overall gain of the linearised amplifier is achieved. Moreover, for output power levels up to 36?dBm, the linearised power amplifier provides better rejection of the third-order intermodulation. Because of the hard nonlinearity of the GaN power amplifier at the high end, this improvement in intermodulation rejection vanishes for output power levels around 41?dBm.     

5~6GHz自适应线性化偏置的InGaP/GaAs HBT功率放大器

针对高质量无线局域网的传输需求,设计了一款工作在5~6 GHz的宽带磷化镓铟/砷化镓异质结双极型晶体管(InGaP/GaAs HBT)功率放大器芯片。针对HBT晶体管自热效应产生的非线性和电流不稳定现象,采用自适应线性化偏置技术,有效地解决了上述问题。针对射频系统的功耗问题,设计了改进的射频功率检测电路,以实现射频系统的自动增益控制,降低功耗。通过InGaP/GaAs HBT单片微波集成电路(MMIC)技术实现该功率放大器芯片。仿真结果表明,功放芯片的小信号增益达到32 dB;1 dB压缩点功率为28.5 dBm@5.5 GHz,功率附加效率PAE超过32%@5.5 GHz;输出功率为20 dBm时,IMD3低于-32 dBc。     

应用于C-X-Ku波段的宽带功率放大器

采用0.25μm AlGaAs/InGaAs/GaAs PHEMT工艺技术,研制出了6～18GHz三级MMIC全匹配宽带功率放大器单片.在6～18GHz的工作频率下,放大器的平均功率增益为19dB,输出功率大于33.3dBm,在10GHz处有最大输出功率34.7dBm,输入回波损耗S11低于-10dB,输出回波损耗S22低于-6dB.与报道的C-X-Ku频段宽带功率放大器相比,有较好的功率平坦度.     

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%.     

A monolithic double-balanced direct conversion mixer with an integrated wideband passive balun

This paper presents the design and performance characteristics of a 20-40 GHz monolithic double-balanced direct conversion mixer implemented using InGaP/GaAs HBT process. The compact MMIC mixer makes use of a Gilbert-cell multiplier and utilizes a broadband monolithic passive balun that has been developed for MMIC applications. The new balun makes use of multidielectric layer structure to achieve a broadband performance in a simple coplanar configuration. A measured return loss better than 15 dB, with a maximum insertion loss of 4.5 dB including the 3-dB power splitting loss has been achieved over the band from 15 to 45 GHz. Operated as a downconverter mixer, the newly developed direct conversion mixer achieves a measured conversion gain of 16 dB given an RF signal at 30 GHz, LO drive of 5 dBm and a downconverted baseband signal at 10 MHz. The mixer IP3 occurs at an output power of 4 dBm while the IP2 occurs at an output power of 11 dBm.