（英）D波段InP基高增益、低噪声放大芯片的设计与实现

利用90-nm InAlAs/InGaAs/InP HEMT工艺设计实现了两款D波段（110~170 GHz）单片微波集成电路放大器。两款放大器均采用共源结构,布线选取微带线。基于器件A设计的三级放大器A在片测试结果表明：最大小信号增益为11.2 dB@140 GHz,3 dB带宽为16 GHz,芯片面积2.6×1.2 mm2。基于器件B设计的两级放大器B在片测试结果表明：最大小信号增益为15.8 dB@139 GHz,3dB带宽12 GHz,在130~150 GHz频带范围内增益大于10 dB,芯片面积1.7×0.8 mm2,带内最小噪声为4.4 dB、相关增益15 dB@141 GHz,平均噪声系数约为5.2 dB。放大器B具有高的单级增益、相对高的增益面积比以及较好的噪声系数。该放大器芯片的设计实现对于构建D波段接收前端具有借鉴意义。     

220GHz低噪声放大器研究

基于IHP锗硅BiCMOS工艺,研究和实现了两种220 GHz低噪声放大器电路,并将其应用于220 GHz太赫兹无线高速通信收发机电路。一种是220 GHz四级单端共基极低噪声放大电路,每级电路采用了共基极（Common Base, CB）电路结构,利用传输线和金属-绝缘体-金属(Metal-Insulator-Metal, MIM)电容等无源电路元器件构成输入、输出和级间匹配网络。该低噪放电源的电压为1.8 V,功耗为25 mW,在220 GHz频点处实现了16 dB的增益,3 dB带宽达到了27 GHz。另一种是220 GHz四级共射共基差分低噪声放大电路,每级都采用共射共基的电路结构,放大器利用微带传输线和MIM电容构成每级的负载、Marchand-Balun、输入、输出和级间匹配网络等。该低噪放电源的电压为3 V,功耗为234 mW,在224 GHz频点实现了22 dB的增益,3 dB带宽超过6 GHz。这两个低噪声放大器可应用于220 GHz太赫兹无线高速通信收发机电路。     

S/N performance of aperiodic monopoles

A short monopole connected to a high-impedance amplifier provides an output to field strength transfer function nearly independent of frequency over a wide band. Such antennas are advantageous for receiving at low frequencies where external noise greatly exceeds amplifier noise. An examination is made ofS/Nperformance of these antennas for the HF band. TheS/Ndegradation compared to an external noise limited system is 1 to 3 dB for a 2.5-dB noise figure amplifier and 2 to 5 dB for a 5-dB noise figure amplifier, over 3 to 30 mHz.     

An analysis of low-frequency second-order distortion in bipolar transistors applied to an amplifier

A distortion theory for bipolar transistors is applied to reduce low-frequency second-order distortion M/SUB 2/ in an amplifier. An equation for M/SUB 2/ is developed in terms of the physical parameters of the transistor. It is found that M/SUB 2/ depends critically on generator resistance that can be optimized for the transistor studied. The theory and this finding are then applied to the distortion producing Darlington pair in an amplifier, and an optimal value of base resistance for the second transistor is predicted and verified to improve M/SUB 2/ by 30 dB at 5 MHz for the pair. The corresponding improvement in the amplifier is 17 dB (from -50 to -70 dB) at 5 MHz and is accompanied by a small, acceptable degradation in M/SUB 3/ of 3 dB at high frequencies.     

Gigahertz-band high-gain low-noise AGC amplifiers in fine-line NMOS

The design and test results of a single-chip NMOS automatic gain control (AGC) amplifier are described. The amplifier has a maximum flat gain of 50 dB, dynamic range of 70 dB, and a noise figure of 11 dB. The flat response from near DC to a 3-dB bandwidth of 1 GHz does not require tuning of any peaking circuits. The chip is also capable of operating at 3 GHz with unity gain delivering -8 dBm into a 50-/spl Omega/ load. The global feedback scheme designed for this chip stabilizes it against large shifts in threshold voltage and ambient temperature variation of 170/spl deg/C. This feedback scheme can provide stable DC feedback for a forward amplifier gain of at least 60 dB. Application of this application in the design of low-noise high-speed fibre-optic systems is envisaged.     

GaAs Monolithic Low-Power Amplifiers with RC Parallel Feedback (Short Paper)

GaAs monolithic broad-band low-power-dissipated amplifiers with inductive/resistive load and RC parallel feedback circuits have been developed. An inductive load amplifier provides a gain of 8 dB, a 3-dB bandwidth of 2.5 GHz, and a noise figure of 2.7 dB at 1 GHz with less than + 1-V supply voltage and very low-power dissipation of 20 mW. A resistive load two-stage amplifier provides a gain of 15 dB and a 3-dB bandwidth of 2 GHz. Input and output reflection coefficients at 1 GHz are -13 dB and -21 dB, respectively.     

2.0～3.5 GHz单路宽带低噪声放大器

使用微波仿真软件ADS设计了一款用于2.0³.5 GHz无线通信的宽带低噪声放大器。匹配网络采用微带线,减小了分立元件的寄生效应。详细阐述了提高放大器稳定性的方法,实现了PHEMT放大器在全频段的稳定性,并分析了源极反馈电感对放大器性能的影响。在2.03.5 GHz无线通信的宽带低噪声放大器。匹配网络采用微带线,减小了分立元件的寄生效应。详细阐述了提高放大器稳定性的方法,实现了PHEMT放大器在全频段的稳定性,并分析了源极反馈电感对放大器性能的影响。在2.0³.5 GHz频段内,放大器增益为12 dB左右,增益平坦度为0.23 dB,最大噪声系数为2.8 dB,输入输出驻波比小于2,三阶输出截点值OIP3大于35.5 dBm。设计的放大器可以用于无线通信的前段中。     

60 GHz amplifier employing slow-wave transmission lines in 65-nm CMOS

A three-stage V-band amplifier implemented in 65-nm baseline CMOS technology is presented in this paper. Slow-wave coplanar waveguides are used for matching and interconnects to study the benefits of using this line type in amplifier design. Measured power gain, noise figure and 1 dB output compression point at 60 GHz are 13 dB, 6.3 dB and +4 dBm, respectively. The amplifier has 19.6 GHz of 3 dB bandwidth, thus covering entirely the unlicensed band around 60 GHz. The performance is achieved with a 1.2 V supply and 45 mA DC current consumption.     

宽带CMOS可变增益放大器的设计

采用TSMC 0.18μm RF CMOS工艺设计实现了一种对数增益线性控制型的宽带可变增益放大器.电路采用两级结构,前级采用电压并联负反馈的Cascode结构以实现良好的输入匹配和噪声性能;后级采用信号相加式电路实现增益连续可调.同时本文设计了一种新型指数控制电压转换电路,解决了射频CMOS电路中,由于漏源电流与栅源电压通常不为指数关系而造成放大器对数增益与控制电压不成线性关系的难题,实现了可变增益放大器的对数增益随控制电压呈线性变化.芯片测试结果表明,电路在1.8V电源电压下,电流为9mA,3dB带宽为430～2330MHz.增益调节范围为-3.3～9.5dB,最大增益下噪声系数为6.2dB,最小增益下输入1dB压缩点为-9dBm.     

Bipolar monolithic amplifiers for a gigabit optical repeater

Main amplifier, AGC amplifier, and preamplifier ICs have been designed and fabricated using an advanced silicon bipolar process to provide the required characteristics of repeater circuits for a gigabit optical fiber transmission system. The bipolar technology used involved a separation width of 0.3 /spl mu/m between the emitter and the base electrode. New circuit techniques were also used. The differential type main amplifier has a peaking function which can be varied widely by means of DC voltage supplied at the outside IC terminal. A bandwidth which can be varied to about three times the value for a nonpeaking amplifier is easily obtained. The gain and maximum 3-dB down bandwidth were 4 dB and 4 GHz, respectively. The main feature of the AGC amplifier is that the diodes are connected to the emitters of the differential transistor pair to improve the linearity. The maximum gain and 3-dB down bandwidth were 15 dB and 1.4 GHz, respectively, and a dynamic range of 25 dB was obtained. The preamplifier has a shunt-series feedback configuration. Furthermore, a gain and 3-dB down bandwidth of 22 dB and 2 GHz, respectively, were achieved with an optimum circuit design. The noise figure obtained was 3.5 dB.     

基于WCDMA接收机系统的低噪声放大器设计

介绍了低噪声放大器的基本工作原理,并对噪声源进行了分析。提出了采用先进的TSMC90 nm工艺,设计了一种基于WCDMA接收机系统的全差分拓扑共源共栅型低噪声放大器。该放大器片内集成了电感、电容,片外配置匹配网络。芯片测试结果表明:电路在2 GHz工作频率下,电压增益达到20 dB、噪声系数NF为1.4 dB、IIP3为-3.43 dBm。综合各项数据表明,该低噪声放大器具备良好的性能,可广泛适用于通讯系统之中。     

Noise characteristics of Pr/sup 3+/-doped fluoride fibre amplifier

The noise characteristics of a Pr/sup 3+/-doped fluoride fibre amplifier (PDFFA) are reported for the first time. Using an amplifier with a 20 dB gain, a noise figure of 3.2 dB is obtained at a wavelength of 1.31 mu m at an amplified output signal power between -18 and -2 dBm. However, it is observed that the noise figure increases when the signal wavelength is above 1.32 mu m.<>     

Integrated Amplifier Circuits for 60 GHz Broadband Telecommunication

Wide frequency bandwidth has been internationally allocated for unlicensed operation around the oxygen absorption frequency at 60 GHz. A power amplifier and a low noise amplifier are presented as building blocks for a T/R-unit at this frequency. The fabrication technology was a commercially available 0.15 m gallium arsenide (GaAs) process featuring pseudomorphic high electron mobility transistors (PHEMT). Using on-wafer tests, we measured a gain of 13.4 dB and a +17 dBm output compression point for the power amplifier at 60 GHz centre frequency when the MMIC was biased to 3 volts V_dd. At the same frequency, the low noise amplifier exhibited 24 dB of gain with a 3.5 dB noise figure. The AM/AM and AM/PM characteristics of the power amplifier chip were obtained from the large-signal S-parameter measurement data. Furthermore, the power amplifier was assembled in a split block package, which had a WR-15 waveguide interface in input and output. The measured results show a 12.5 dB small-signal gain and better than 8 dB return losses in input and output for the packaged power amplifier.     

A 3-GHz 32-dB CMOS limiting amplifier for SONET OC-48 receivers

A CMOS limiting amplifier with a bandwidth of 3 GHz, a gain of 32 dB, and a noise figure of 16 dB is described. The amplifier is fabricated in a standard 2.5-V 0.25-μm CMOS technology and consumes 53 mW. Inversely scaled amplifier stages and active inductors with a low voltage drop are used to achieve this performance. The amplifier is targeted for use in 2.5-Gb/s (OC-48) SONET systems     

Gain saturation properties of a polarization insensitivesemiconductor amplifier implemented with tensile and compressive strainquantum wells

The gain saturation properties of a 1.3 μm polarization insensitive semiconductor amplifier implemented with tensile and compressive strain quantum well active region are experimentally investigated in order to determine how well the amplifier maintains its polarization insensitivity in the saturation regime. The amplifier has unsaturated gain of 12 dB and in the saturation regime the maximum observed gain imbalance between TE and TM gains is 0.9 dB. The measured 3 dB saturation output power is 5 mW     

Design and performance of wideband GaAs MMIC's for high-speedoptical communication systems

Advanced design techniques for GaAs wideband direct-coupled amplifiers are described. The amplifier achieved a 20 dB gain with a 3 dB bandwidth of 13 GHz and a 5-7 dB noise figure. An equalizing amplifier module consisting of amplifier and variable attenuator monolithic microwave integrated circuits (MMICs) exhibited a high gain of 43 dB over a 10 GHz band with a controllable gain of 20-43 dB     

微型化2GHz低噪声高选择性放大模组的研制

本文介绍一种将微波低频段分布参数电路与超微细薄膜工艺结合的微型化、低噪声、高选择性的放大模组。对低噪声放大电路、椭圆函数带通滤波电路及后级平衡放大电路的设计完成后,将其制作在76×20×0.5mm^3氧化铝陶瓷基片上。本模组在1.8-2.2GHz范围内,增益Gp≥50dB,噪声系数Nf≤0.9dB,其1dB压缩点输出功率Po≈30dBm,带外抑制≥80dB。     

80-GHz Tuned Amplifier in Bulk CMOS

An 80-GHz six-stage common source tuned amplifier has been demonstrated using low leakage (higher V_T) NMOS transistors of a 65-nm digital CMOS process with six metal levels. It achieves power gain of 12 dB at 80 GHz with a 3-dB bandwidth of 6 GHz, noise figures (NF's) lower than 10.5 dB at frequencies between 75 and 81 GHz with the lowest NF of 9 dB. IP_{1 dB} is -21 dBm and IIP3 is -11.5 dBm. The amplifier consumes 27 mA from a 1.2 V supply. At V_DD = 1.5 V and 33 mA bias current, NF is less than 9.5 dB within the 3-dB bandwidth and reaches a minimum of 8 dB at 80 GHz.     

A highly linear and efficient differential CMOS power amplifier with harmonic control

A 2.45 GHz fully differential CMOS power amplifier (PA) with high efficiency and linearity is presented. For this work, a 0.18-/spl mu/m standard CMOS process with Cu-metal is employed and all components of the two-stage circuit except an output transformer and a few bond wires are integrated into one chip. To improve the linearity, an optimum gate bias is applied for the cancellation of the nonlinear harmonic generated by g/sub m3/ and a new harmonic termination technique at the common source node is adopted along with normal harmonic termination at the drain. The harmonic termination at the source effectively suppresses the second harmonic generated from the input and output. The amplifier delivers a 20.5dBm of P/sub 1dB/ with 17.5 dB of power gain and 37% of power-added efficiency (PAE). Linearity measurements from a two-tone test show that the power amplifier with the second harmonic termination improves the IMD3 and IMD5 over the amplifier without the harmonic termination by maximally 6 dB and 7 dB, respectively. Furthermore, the linearity improvements appear over a wide range of the power levels and the linearity is maintained under -45 dBc of IMD3 and -57dBc of IMD5 when the output power is backed off by more than 5dB from P/sub 1dB/. From the OFDM signal test, the second harmonic termination improves the error vector magnitude (EVM) by over 40% for an output power level satisfying the 4.6% EVM specification.     

Optical time-division multiplexed transmission at 8 Gbit/s using single laser and semiconductor optical power amplifier

The authors report transmission over 57 km of single-mode fibre in a two-channel, 8 Gbit/s optical time-division multiplexed system experiment using a transmitter with a single laser and a semiconductor optical power amplifier at the transmitter output. The amplifier operates with a net gain of 11.5 dB, which corresponds to 0.8 dB gain compression, and a fibre coupled output power of +6 dBm. The amplifier facet output power for which the gain is compressed by 3 dB is +13 dBm. The experimental system uses neither an isolator nor an optical filter.<>