High efficiency, wide dynamic range variable gain and poweramplifier MMICs for wideband CDMA handsets

A linearized variable gain amplifier (VGA) and a two-stage power amplifier (PA) MMIC were developed for 1.95-GHz wideband CDMA (W-CDMA) handsets application. A complete PA block with power control ability was obtained by cascading the VGA with the PA. The linearized VGA consists of a predistorter (PD) integrated with a conventional VGA, performing dual function for achieving high linearity power control, as well as reducing output distortion level of the following PA. With the use of predistortion, the P_out and power added efficiency (PAE) of the PA block improved from 27.5 dBm and 39.8% to 28.5 dBm and 44.8%, respectively, measured at -35 dBc adjacent channel leakage power ratio (ACPR). Under power control operation, the control range of the PA block increased from 23.6 dB to 31.2 db, and ACPR reduction of over 10 dB was achieved with the use of linearized VGA     

A Low Distortion and Low Dissipation Power Amplifier with Gate Bias Control Circuit for Digital/Analog Dual-Mode Cellular Phones

A power amplifier operating at 3.3 V. has been developed for CDMA/AMPS dual-mode cellular phones. It consists of linear GaAs power MESFET's, a new gate bias control circuit, and an output matching circuit which prevents the drain terminal of the second MESFET from generating the harmonics. The relationship between the intermodulation distortion and the spectral regrowth of the power amplifier has been investigated with gate bias by using the two-tone test method and the adjacent channel leakage power ratio (ACPR) method of CDMA signals. The dissipation power of the power amplifier with a gate bias control circuit is minimized to below 1000 mW in the range of the low power levels while satisfying the ACPR of less than ?26 dBc for CDMA mode. The ACPR of the power amplifier is measured to be ?33 dBc at a high output power of 26 dBm.     

CDMA800多载波线性功率放大器的设计

设计了一款6载波的高线性功率放大器.在功放管绝对稳定基础上,利用Loadpull和Sourcepull技术得到管子的最佳输入输出匹配电路.整个模块采用了4级放大,增益达到了50dB,最大输出功率42 dBm,互调衰减达到了-47dBc,ACPR和PAE效率均达到了电信的系统标准.末级采用了双平衡放大以提高功放的线性度.     

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。     

前馈线性化功率放大器设计

采用自适应结合查表控制的前馈技术,设计了用于CDMA2000的超线性功率放大器.在连续波输出功率达到45dBm时,双音IMD3低于-62dBc,用CDMA2000信号测试,其ACPR分别低于-54dB@750kHz和-71dB@1.98MHz.     

GaAs pHEMT工艺6～18GHz有源倍频器MMIC

基于GaAs pHEMT工艺,设计了一个6～18 GHz宽带有源倍频器MM IC,最终实现了较高的转换增益和谐波抑制特性。芯片内部集成了输入匹配、有源巴伦、对管倍频器和输出功率放大器等电路。外加3.5 V电源电压下的静态电流为80 mA;输入功率为6 dBm时,6～18 GHz输出带宽内的转换增益为6 dB;基波和三次谐波抑制30 dBc。当输出频率为12 GHz时,100 kHz频偏下的单边带相位噪声为-143 dBc/Hz。芯片面积为1 mm×1.5 mm。     

一种电调Doherty功率放大器

提出了一种全新的电调Doherty移动基站功率放大器。该Doherty放大器的载波放大器和峰值放大器的驱动功率分配比及输出合成相位实现了电可调,从而保证了Doherty功率放大器的最佳驱动功率分配比,以及最佳的输出合成相位,同时结合内部线性化技术以实现Doherty功率放大器的最优性能。为保证功率放大器性能的稳定,设计了一种用于Doherty功率放大器的恒静态偏置电路,在-25℃～+50℃的高低温实验中使放大器偏置电流的波动小于5%。功放的工作频率为870～890MHz,增益大于58dB。在CDMA2000信号测试下,输出功率为50.06dBm时,其ACLR(邻道泄漏功率比)小于-47.5dBc,整机效率达42.3%(含驱动级)。     

A 2.7-V SiGe HBT variable gain amplifier for CDMA applications

A monolithic SiGe HBT variable gain amplifier with high dB-linear gain control and high linearity has been developed for CDMA applications. The VGA achieves a 30-dB dynamic gain control with a control range of 0-2.7 Vdc in 824-849 MHz band. The maximum gain and attenuation are 23 dB and 7 dB, respectively. Input/output VSWRs keep low and constant despite change in the gain-control voltage. At a low operation voltage of 2.7 V, the VGA produces a 1-dB compression output power of 13 dBm and /spl plusmn/885-kHz ACPR of -57 dBc at a 5-dBm output power.     

250 W HVHBT Doherty With 57% WCDMA Efficiency Linearized to ${-}$55 dBc for 2c11 6.5 dB PAR

A two-way symmetrical Doherty amplifier exhibiting 250 W saturated power has been developed using high-voltage HBT (HVHBT) GaAs technology biased at 28 V on the collector. Greater than 57% collector efficiency at 50 W (47 dBm) average output power has been demonstrated while achieving -55 dBc linearized ACPR at 5 MHz offset using a two-carrier-side-by-side WCDMA input signal with 6.5 dB PAR measured at 0.01% probability on the CCDF. In addition, a two-stage HVHBT lineup exhibiting 450 W (56.5 dBm) peak power has been demonstrated. The output stage consists of a pair of 250 W two-way symmetrical Doherty amplifiers power combined using a low-loss branchline combiner and driven by a single-ended 100 W class AB high-efficiency amplifier. The lineup demonstrated 44% PAE at 100 W (50 dBm) average output power with 25 dB lineup gain while achieving - 55 dBc linearized ACPR at 5 MHz offset using a two-carrier-side-by-side WCDMA input signal with 6.5 dB PAR measured at 0.01% probability on the CCDF. The lineup exhibits 400 W (56 dBm) PldB at 60% PAE CW, with 45% PAE at 6 dB backoff.     

A 3-V monolithic SiGe HBT power amplifier for dual-mode (CDMA/AMPS)cellular handset applications

A dual-mode (CDMA/AMPS) power amplifier has been successfully implemented by using a monolithic SiGe/Si heterojunction bipolar transistor (HBT) foundry process for cellular handset (824-849 MHz) applications. The designed two-stage power amplifier satisfies both CDMA and AMPS requirements in output power, linearity, and efficiency. At V _cc=3 V,the power amplifier shows an excellent linearity (first ACPR<-44.1 dBc and second ACPR<-57.1 dBc) up to 28 dBm of output power for CDMA applications. Under the same bias condition, the power amplifier also meets AMPS handset requirements in output power (up to 31 dBm) and linearity (with second and third harmonic to fundamental ratios lower than -37 dBc and -55 dBc, respectively). At the maximum output power level, the worst power-added efficiencies (PAEs) are measured to be 36% for CDMA and 49% for AMPS operations. The power amplifier also tolerates severe output mismatch (VSWR>12:1) up to V _cc=4 V, with spurs measured to be <-22 dBc in CDMA outputs at two specific tuning angles, but with no spur in AMPS outputs at any tuning angle     

基于高次谐波体声波谐振器的微波振荡器设计

基于高次谐波体声波谐振器(HBAR)的高品质因数(Q)值和多模谐振特性,设计了Colpitts和Pierce两种形式的微波振荡器。采用HBAR与LC元件组成谐振回路的方法,与放大电路构成反馈环路直接基频输出微波频段信号。Colpitts振荡器输出信号频率为980 MHz,信号输出功率为-4.92dBm,信号相位噪声达-119.64dBc/Hz@10kHz;Pierce振荡电路输出信号频率达到2.962GHz,信号输出功率为-9.77dBm,信号相位噪声达-112.30dBc/Hz@10kHz。     

Joint Polynomial and Look-Up-Table Predistortion Power Amplifier Linearization

Digital predistortion at baseband is an efficient and low-cost method for the linearization of a power amplifier (PA) in a wireless system employing a nonconstant-envelop modulation scheme, so as to reduce the adjacent channel interference. The polynomial and the look-up table (LUT) predistortion schemes are two commonly used approaches. However, in each of the two approaches, to reach a satisfactory adjacent channel power ratio (ACPR) in the PA output signal, people usually end up with a complex system having the involved algorithms converge rather slowly. In this brief, we propose a low-complexity joint-polynomial-and-LUT predistortion PA linearizer, where the two mutually dependent predistortion schemes can skillfully help each other. Simulation results show that the proposed joint linearizer can reduce the algorithm convergence time while achieving an excellent ACPR.     

A Handset Power Amplifier With High Efficiency at a Low Level Using Load-Modulation Technique

A new monolithic-microwave integrated-circuit power amplifier for cellular handsets has been implemented using the load-modulation concept of the Doherty amplifier, which has a high efficiency at a low power level. In order to get a compact module, the$lambda/4$transmission line for the load modulation is replaced by a passive high-pass$pi$-network, and the load-modulation circuit is also modified to function as a power-matching circuit of the main amplifier. The amplifier has two modes of operation, low- and high-power modes, controlled by a control voltage. At the high power mode, both the main and auxiliary amplifiers are operational and, at the low power mode, only the main amplifier generates output power enhancing the efficiency. For the code-division multiple-access environment, the amplifier at the low-power mode provides power-added efficiency (PAE) of 39.8% and an adjacent channel power ratio (ACPR) less than 49.8 dBc at 23.1 dBm, and the high-power mode PAE of 37.9% and ACPR of 46.4 dBc at 28 dBm. The efficiency is improved by approximately 18.8% at$ P_ out=23$dBm by the load-modulation technique. For the advanced mobile phone system-mode operation, the amplifier delivers 26.1 dBm with PAE of 53% and 30.8 dBm with 48.7% at the low and high modes, respectively.     

Analysis and Design of a Dynamic Predistorter for WCDMA Handset Power Amplifiers

This paper presents a dynamic predistorter (PD), which linearizes the dynamic AM-AM and AM-PM of a wideband code division multiple access handset power amplifier (PA). The dynamic PD allows an adjacent channel leakage power ratio (ACPR) improvement of 15.7 dB, which is superior to conventional PDs that linearize static AM-AM and AM-PM. The dynamic PD was designed using an HBT generating nonlinearity, a short circuit at the baseband (les4 MHz), and a load circuit for the HBT at the RF fundamental band (ap1.95 GHz). Volterra-series analysis was performed to understand the mechanism of the dynamic PD. The analysis revealed that the short circuit at the baseband enabled the dynamic PD generating third-order intermodulation distortion (IMD3) with opposite phase to the fundamental tone (i.e., antiphase IMD3). The antiphase IMD3 allows dynamic gain compression, which linearizes the dynamic gain expansion of a PA with low quiescent current. The analysis also revealed that the IMD3 amplitude of the dynamic PD can be adjusted by load impedance at the RF fundamental band, which enables the gradient of dynamic AM-AM and AM-PM to be optimized to linearize the PA. The fabricated two-stage InGaP/GaAs HBT PA module with the dynamic PD exhibited an ACPR of -40 dBc and a power-added efficiency of 50% at an average output power of 26.8 dBm with a quiescent current of 20 mA     

一种温度不敏感的高线性功率放大器

设计了一种温度不灵敏的高线性度的射频功率放大器芯片,采用新颖的带温度反馈环路的有源片上自适应偏置电路,该电路降低了温度引起的放大器集电极直流电流分量的变化量,补偿了由温度变化而引起的性能偏差,进而有效提高了放大器的线性度。基于这个温度不灵敏的偏置结构采用InGaP/GaAs HBT工艺设计了一个工作在2110~2170 MHz频段的功率放大器。测试结果表明,该功放在工作频段内的增益大于等于35.3 dB;在中心频率2140 MHz处,1 dB功率压缩点大于33 dBm,功率附加效率在输出功率24.5 dBm时为18%;使用LTE_FDD调制信号,获得邻信道功率比为-47 dBc。在环境温度为-40℃、+25℃和+80℃条件下,功放的增益平坦度较好,增益变化量小于1.5 dB,输出级集电极电流基本不变,有效降低了功放对温度的敏感性。     

调整峰值功放电流响应提高效率的LTE-A Doherty 功放*

介绍了一种利用宽带输入匹配网络调整峰值功放输出电流,改善Doherty 功放负载调制效果和带内 效率的设计方法。理论分析表明,Doherty功放中峰值功放C 类偏置情况下带来的带内不一致开启特性会影响输出 电流和负载调制效果。通过引入宽带输入匹配网络,能有效改善它的开启不一致性。为验证分析结果设计了具有 宽带(采用简易实频技术)和窄带两种不同输入匹配网络,用于2.15GHz 频段LTE-A 的Doherty功放。仿真和测试 结果表明,功放的输出功率超过49dBm,在7dB 回退功率处,宽带输入匹配Doherty 功放的带内效率达到42% 以上, 效率波动由10%降低到2%。使用100MHz 宽带LTE-A 信号经过线性化改善后,在40dBm 输出时,宽带输入匹配网 络的Doherty功放上下边带ACLR(adjacent channel leakage ratio)指标为-45.1/-44.9dBc,效率为40.5%,均优于窄带输入匹配网络的Doherty功放。     

一种用于短距离无线通信并集成频率合成器的多模式多频带发射机

A reconfigurable multi-mode direct-conversion transmitter(TX) with integrated frequency synthesizer(FS) is presented. The TX as well as the FS is designed with a flexible architecture and frequency plan, which helps to support all the 433/868/915 MHz ISM band signals, with the reconfigurable bandwidth from 250 kHz to 2 MHz. In order to save power and chip area, only one 1.8 GHz VCO is adopted to cover the whole frequency range. All the operation modes can be regulated in real time by configuring the integrated register-bank through an SPI interface. Implemented in 180 nm CMOS, the FS achieves a frequency coverage of 320-460 MHz and 620- 920 MHz. The lowest phase noise can be -107 dBc/Hz at a 100 kHz offset and -126 dBc/Hz at a 1 MHz offset. The transmitter features a C10:2 dBm peak output power with a C9:5 dBm 1-dB-compression point and 250 kHz/500 kHz/1 MHz/2 MHz reconfigurable signal bandwidth.     

A Highly Efficient and Linear Class-AB/F Power Amplifier for Multimode Operation

The class-AB/F power amplifier (PA), a multimode PA, which can operate at both class-AB and class-F modes, is analyzed and compared with the conventional class-F and class-AB PAs. The open-circuited third harmonic control circuit enhances the efficiency of the PA without deteriorating the linearity of class-AB mode of the PA. The voltage and current waveforms are simulated to evaluate the appropriate operation for the modes. To demonstrate the multimode PA, the PA is implemented using an InGaP/GaAs HBT process and it is tested with reverse-link IS-95A code division multiple access (CDMA) and PCS1900 global system for mobile communications signals in the personal communications service band. The class-AB operation for a CDMA signal delivers a power-added efficiency (PAE) of 38.9% and an adjacent channel power ratio of 49.5 and 56.5 dBc at the offset of 1.25 and 2.25 MHz, respectively, at the output power of 28 dBm. The maximum PAE of 64.7% under the class-F operation is measured at 32.5-dBm output power for a GSM signal. The class-AB/F PA is a good candidate for the multimode PA of next-generation wireless communication systems.     

A Parallel Power Amplifier With a Novel Mode Switching Control

Two parallel operating power amplifiers (PAs) are controlled by a novel mode switch for high efficiencies at both the back-off power region and high power region. The mode switch is realized by the base-collector (BC) junction diode which reuses the dc current of the low power mode amplifier. A 836 MHz CDMA PA has been demonstrated using InGaP/GaAs heterojunction bipolar transistor with fully integrated matching component for small package and low cost. It shows a 13 mA idle current, 15.4% power added efficiency (PAE), ACPR1 at 16 dBm of the low power mode operation and a 40.5% PAE, ACPR1 at 28 dBm of the high power mode operation.     

GaN逆F类高效率功率放大器及线性化研究

效率和线性度是功率放大器的重要指标,也是设计的技术难点。该文设计了2.5-2.6 GHz高效率GaN逆F类功率放大器,其输入输出谐波匹配网络由解析的方法设计得到。单音测试结果表明,在2.55 GHz处,功放的漏极效率超过75%。为了建立逆F类功放的行为模型进行数字预失真,对传统的Hammerstein模型进行了改进,提升了模型拟合精度,对20 MHz带宽、峰均功率比为9.6 dB的16-QAM OFDM调制信号,结合峰值因子降低技术和数字预失真技术对逆F类功放进行线性化后,功放的相邻信道功率比(ACPR)优于-48 dBc。