An image-reject down-converter for 802.11a and HIPERLAN2 wireless LANs

An image-reject down-converter for IEEE 802.11a and ETSI HIPERLAN2 wireless local area networks was implemented in a low-cost 46-GHz-f _T silicon bipolar process. The circuit integrates a variable-gain low noise amplifier and a double-balanced mixer along with passive image rejection filters. It exhibits a 4-dB noise figure and a power gain of 23 dB. By reducing the low noise amplifier gain by 9 dB (thanks to a 1-bit gain control), the down-converter achieves an input 1-dB compression point of –14 dBm, while drawing only 23 mA from a 3-V supply voltage. The adopted filtering approach provides an image rejection ratio higher than 60 dB.     

Micro-power low-offset instrumentation amplifier IC design for biomedical system applications

This work presents a micro-power low-offset CMOS instrumentation amplifier integrated circuit with a large operating range for biomedical system applications. The equivalent input offset voltage is improved using a new circuit technique of offset cancellation that involves a two-phase clocking scheme with a frequency of 20 kHz. Channel charge injection is cancelled by the symmetrical circuit topology. With the wide-swing cascode bias circuit design, this amplifier realizes a very high power-supply rejection ratio (PSRR), and can be operated at single supply voltage in the range between 2.5-7.5 V. It was fabricated using 0.5-/spl mu/m double-poly double-metal n-well CMOS technology, and occupies a die area of 0.2 mm/sup 2/. This amplifier achieves a 160-/spl mu/V typical input offset voltage, 0.05% gain linearity, greater than 102-dB PSRR, an input-referred rms noise voltage of 45 /spl mu/V, and a current consumption of 61 /spl mu/A at a low supply voltage of 2.5 V. Experimental results indicate that the proposed amplifier can process the input electrocardiogram signal of a patient monitoring system and other portable biomedical devices.     

A fully integrated, untrimmed CMOS instrumentation amplifier withsubmicrovolt offset

A low-noise CMOS instrumentation amplifier intended for low-frequency thermoelectric microsensor applications is presented that achieves submicrovolt offset and noise. Key to its performance is the chopper modulation technique combined with a bandpass filter and a matching on-chip oscillator. No external components or trimming are required. The achievable offset performance depends on the bandpass filter Q and the oscillator-to-bandpass filter matching accuracy. Constraints are derived for an optimum Q and a given matching accuracy. The improvement of common-mode rejection ratio (CMRR) in chopper amplifiers is discussed. The amplifier features a total gain of 77±0.3 dB and a bandwidth of approximately 600 Hz. The measured low-frequency input noise is 8.5 nV/√Hz and the input offset is 600 nV. The measured low-frequency CMRR is better than 150 dB. The circuit has been implemented in a standard 1-μm single-poly CMOS process     

A low-noise CMOS instrumentation amplifier for thermoelectricinfrared detectors

A low-noise CMOS instrumentation amplifier for low-frequency thermoelectric infrared sensor applications is described which uses a chopper technique to reduce low-frequency noise and offset. The offset reduction efficiency of the band-pass filter, implemented to reduce residual offset due to clock feedthrough, has been analyzed and experimentally verified. The circuit has been integrated in a transistor-only 1-μm single-poly n-well CMOS process. It features a gain of 52 dB with a 500 Hz bandwidth and a common-mode rejection ratio (CMRR) of more than 70 dB. The equivalent input low frequency noise is 15 nV/√Hz. The typical residual input offset is 1.5 μV. The amplifier power consumption is 1.3 mW     

A 0.18μm CMOS low noise amplifier using a current reuse technique for 3.1-10.6 GHz UWB receivers

A new,low complexity,ultra-wideband 3.1-10.6 GHz low noise amplifier(LNA),designed in a chartered 0.18μm RFCMOS technology,is presented.The ultra-wideband LNA consists of only two simple amplifiers with an inter-stage inductor connected.The first stage utilizing a resistive current reuse and dual inductive degeneration technique is used to attain a wideband input matching and low noise figure.A common source amplifier with an inductive peaking technique as the second stage achieves high flat gain and wide -3 dB bandwidth of the overall amplifier simultaneously.The implemented ultra-wideband LNA presents a maximum power gain of 15.6 dB,and a high reverse isolation of—45 dB,and good input/output return losses are better than -10 dB in the frequency range of 3.1-10.6 GHz.An excellent noise figure(NF) of 2.8-4.7 dB was obtained in the required band with a power dissipation of 14.1 mW under a supply voltage of 1.5 V.An input-referred third-order intercept point(IIP3) is -7.1 dBm at 6 GHz.The chip area,including testing pads,is only 0.8×0.9 mm2.     

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。     

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。     

A switch‐controlled multimode narrowband receiver RF front‐end

This work illustrates a flexible and convenient method to build a multimode narrowband receiver RF front‐end by means of controlled switches, switched capacitors, and switched inductors. The front‐end comprises a dual‐gain‐mode narrowband low‐noise amplifier (LNA) and a dual‐linearity‐mode mixer. A four‐mode receiver RF front‐end constructed with the dual‐gain‐mode LNA and the dual‐linearity‐mode mixer operating in frequency band range from 1800 to 2050 MHz was demonstrated with an IBM 90‐nm CMOS process. The front‐end achieves a 1/1.6 dB noise figure, 30/20 dB power gain, and 16/?10 dBm third‐order input intercept point while draws a 5.9/3.6 mA current from a 1.8‐V supply voltage at the low noise mode and high linearity mode, respectively. The proposed technique can be employed to build an intelligent mobile system.     

一种基于BiFET工艺的高输入阻抗运算放大器

针对CMOS运算放大器存在的输入失调电压高、噪声性能差等问题,提出了一种基于双极结型场效应晶体管(BiFET)工艺的高输入阻抗运算放大器。采用P沟道JFET差分对作为输入级,实现了pA量级的极低输入偏置电流/失调电流和nV/Hz量级的极低输入噪声电压谱密度。采用双极晶体管构成的共集-共射增益级和互补推挽输出级,实现了100 dB的开环增益、10 V/μs的输出电压转换速率和10 MHz的带宽。该运算放大器适用于对微弱模拟信号的采集和放大。     

A novel fully differential biopotential amplifier with dc suppression

Fully differential amplifiers yield large differential gains and also high common mode rejection ratio (CMRR), provided they do not include any unmatched grounded component. In biopotential measurements, however, the admissible gain of amplification stages located before dc suppression is usually limited by electrode offset voltage, which can saturate amplifier outputs. The standard solution is to first convert the differential input voltage to a single-ended voltage and then implement any other required functions, such as dc suppression and dc level restoring. This approach, however, yields a limited CMRR and may result in a relatively large equivalent input noise. This paper describes a novel fully differential biopotential amplifier based on a fully differential dc-suppression circuit that does not rely on any matched passive components, yet provides large CMRR and fast recovery from dc level transients. The proposed solution is particularly convenient for low supply voltage systems. An example implementation, based on standard low-power op amps and a single 5-V power supply, accepts input offset voltages up to +/-500 mV, yields a CMRR of 102 dB at 50 Hz, and provides, in accordance with the AAMI EC38 standard, a reset behavior for recovering from overloads or artifacts.     

A Precision High-Voltage Current Sensing Circuit

This paper presents a precision current sensor featuring a high voltage, high gain (~ 140 dB), and low input offset ( < 1 mV) current sense amplifier. This amplifier does not require offset trimming even for low offset applications. It is a single stage amplifier that has a common gate pMOS differential input pair, which makes it inherently stable. This amplifier topology allows for a wide input common-mode range, thus increasing the versatility of current sensing circuit.     

High-temperature characterisation and analysis of leakage-current-compensated,low-power bandgap temperature sensors

This paper presents a low-power, high-performance current-feedback instrumentation amplifier (CFIA) for portable bio-potential sensing applications. Noise analysis is performed to assign an optimized current for the input stage of the amplifier. Analysis on selecting nested chopping frequencies is performed, further reducing 1/f noise and the residual offset. Enhanced power efficiency is achieved by sharing cascode branches and using a Class-AB output stage. Through these methods, a good balance between noise performance and other parameters such as output ripples and power consumption of the ripple reduction feedback loop (RRFL) is achieved. The amplifier is developed using a 1-poly 6-metal 0.18 μm CMOS process. Three gain stages with a gain-boosting input stage provide a low-frequency, open-loop gain >250 dB. When configured to a closed-loop gain of 60 dB, the amplifier achieves a noise voltage density of 18 \({\text{nV}}/\sqrt {{\text{H}}z}\) and a 1/f noise corner of 3 Hz. With a current of 75 μA and a supply voltage of 3.3 V, a CMRR of 110 dB and a PSRR of 120 dB are achieved, with an average input offset of about 6.5 μV. The amplifier achieves a state-of-art noise efficiency factor of 4.2. Practical application of the CFIA is demonstrated with an in vivo electrocardiogram detection.     

A Low-Power Low-Noise Amplifier for K-Band Applications

This study presents a high performance K-band low noise amplifier. By utilizing transformer feedback at the input stage, an excellent noise figure (NF) of 4.3 dB is obtained at 22 GHz. With the current-reused technique between the two stages, the amplifier achieves a maximum power gain of 10.1 dB under a supply voltage of 1.8 V and a power consumption of only 7.2 mW. The proposed LNA has comparable NF and gain, while it can operate under the lowest power among the published works in 0.18 $mu{rm m}$ CMOS technology for K-band applications.      

AC-coupled front-end for biopotential measurements

AC coupling is essential in biopotential measurements. Electrode offset potentials can be several orders of magnitude larger than the amplitudes of the biological signals of interest, thus limiting the admissible gain of a dc-coupled front end to prevent amplifier saturation. A high-gain input stage needs ac input coupling. This can be achieved by series capacitors, but in order to provide a bias path, grounded resistors are usually included, which degrade the common mode rejection ratio (CMRR). This paper proposes a novel balanced input ac-coupling network that provides a bias path without any connection to ground, thus resulting in a high CMRR. The circuit being passive, it does not limit the differential dc input voltage. Furthermore, differential signals are ac coupled, whereas common-mode voltages are dc coupled, thus allowing the closed-loop control of the dc common mode voltage by means of a driven-right-leg circuit. This makes the circuit compatible with common-mode dc shifting strategies intended for single-supply biopotential amplifiers. The proposed circuit allows the implementation of high-gain biopotential amplifiers with a reduced number of parts, thus resulting in low power consumption. An electrocardiogram amplifier built according to the proposed design achieves a CMRR of 123 dB at 50 Hz.     

3．1～10．6GHz超宽带低噪声放大器的设计

基于SIMC0．18μmRFCMOS工艺技术,设计了可用于3．1—10．6GHzMB—OFDM超宽带接收机射频前端的CMOS低噪声放大器（LNA）。该LNA采用三级结构：第一级是共栅放大器,主要用来进行输入端的匹配;第二级是共源共栅放大器,用来在低频段提供较高的增益;第三级依然为共源共栅结构,用来在高频段提供较高的增益,从而补偿整个频带的增益使得增益平坦度更好。仿真结果表明：在电源电压为1．8v的条件下,所设计的LNA在3．1～10．6GHz的频带范围内增益（521）为20dB左右,具有很好的增益平坦性f±0．4dB）,回波损耗S11、S22均小于-10dB,噪声系数为4．5dB左右,IIP3为-5dBm,PIdB为0dBm。     

应用于TD-SCDMA移动终端的单片InGaP/GaAs HBT功率放大器

报道了用于TD-SCDMA移动终端的高效率、高线性度HBT功率放大器的研制.该单片功率放大器采用两级放大结构,内部集成了输入匹配、级问匹配网络以及有源偏置电路,总芯片面积仅为0.91mmX 0.98mm.该功率放大器采用单电源3.4V供电,在高、低功率模式下,PAE分别为43%和116%,增益达到了28.5以及24dB.当输入QPSK调制信号时,在低输出功率以及高输出功率状态下,1.6MHz/3.2MHz中心频偏处,ACPR分别低于-45dBc/-56dBc和-39dBc/-50dBc.本芯片尺寸小,电压稳定性高,性能优越,为低成本化的大规模生产提供了能性.     

433MHz ASK接收机射频前端电路设计

设计了一款应用在433MHz ASK接收机中的射频前端电路。在考虑了封装以及ESD保护电路的寄生效应的同时,从噪声、匹配、增益和线性度等方面详细讨论了低噪声放大器和下混频器的电路设计。采用0.18μm CMOS工艺,在1.8V的电源电压下射频前端电路消耗电流10.09 mA。主要的测试结果如下:低噪声放大器的噪声系数、增益、输入P1dB压缩点分别为1.35 dB、17.43 dB、-8.90dBm;下混频器的噪声系数、电压增益、输入P1dB压缩点分别为7.57dB、10.35dB、-4.83dBm。     

A 5-GHz highly integrated receiver front-end

In this paper a radio front-end for a IEEE 802.11a and HIPERLAN2 sliding-IF receiver is presented. The circuit, implemented in a low-cost 46-GHz-f _T silicon bipolar process, includes a variable-gain low noise amplifier and a double-balanced mixer. Thanks to monolithic LC filters and on-chip single-ended-to-differential conversion of the RF signal, the proposed solution does not require the expensive image rejection filter and an external input balun. The receiver front-end exhibits a 4.3-dB noise figure and a power gain of 21 dB, providing an image rejection ratio higher than 50 dB. By using a 1-bit gain control, it achieves an input 1-dB compression point of −11 dBm, while drawing only 22 mA from a 3-V supply voltage.     

Integrated AlGaAs/GaAs HBT high slew-rate and wide band operationalamplifier

We report the design, fabrication, and test results of a wide band and high slew-rate voltage-mode operational amplifier using AlGaAs/GaAs HBT's. To select higher carbon doping concentration is more effective in reducing base resistance, and lower emitter doping concentration possess a smaller input capacitance to improve the device speed. The HBT operational amplifier has provided 500 V/μs high slew-rate, only 8 ns setting time and about 2 GHz unity-gain frequency. Common mode rejection ratio (CMRR) values of this operational amplifier are in the order of 70 dB with a small DC input voltage offset 5 mV, and the open-loop gain is about 40 dB     

Design of 3.1–10.6 GHz ultra-wideband CMOS low noise amplifier with current reuse technique

A new low complexity ultra-wideband 3.1–10.6 GHz low noise amplifier (LNA), designed in a chartered 0.18 μm RFCMOS technology, is presented in this paper. The ultra-wideband LNA only consists of two simple amplifiers with an inter-stage inductor connected. The first stage utilizing a resistive current reuse and dual inductive degeneration techniques is used to attain a wideband input matching and low noise figure. A common source amplifier with inductive peaking technique as the second stage achieves high flat gain and wide the −3 dB bandwidth of the overall amplifier simultaneously. The implemented ultra-wideband LNA presents a maximum power gain of 15.6 dB, a high reverse isolation of −45 dB and a good input/output return losses are better than −10 dB in the frequency range of 3.1–10.6 GHz. An excellent noise figure (NF) of 2.8–4.7 dB was obtained in the required band with a power dissipation of 14.1 mW under a supply voltage of 1.5 V. An input-referred third-order intercept point (IIP3) is −7.1 dBm at 6 GHz. The chip area including testing pads is only 0.8 mm × 0.9 mm.