A Wideband CMOS Low Noise Amplifier Employing Noise and IM2 Distortion Cancellation for a Digital TV Tuner

A wideband CMOS low noise amplifier (LNA) with single-ended input and output employing noise and IM2 distortion cancellation for a digital terrestrial and cable TV tuner is presented. By adopting a noise canceling structure combining a common source amplifier and a common gate amplifier by current amplification, the LNA obtains a low noise figure and high IIP3. IIP2 as well as IIP3 of the LNA is important in broadband systems, especially digital terrestrial and cable TV applications. Accordingly, in order to overcome the poor IIP2 performance of conventional LNAs with single-ended input and output and avoid the use of external and bulky passive transformers along with high sensitivity, an IM2 distortion cancellation technique exploiting the complementary RF performance of NMOS and PMOS while retaining thermal noise canceling is adopted in the LNA. The proposed LNA is implemented in a 0.18 $muhbox{m}$ CMOS process and achieves a power gain of 14 dB, an average noise figure of 3 dB, an IIP3 of 3 dBm, an IIP2 of 44 dBm at maximum gain, and S11 of under ${- 9}~{rm dB}$ in a frequency range from 50 MHz to 880 MHz. The power consumption is 34.8 mW at 2.2 V and the chip area is 0.16 ${rm mm}^{2}$.      

A 0.18μm CMOS Gilbert low noise mixer with noise cancellation

正This paper presents a broadband Gilbert low noise mixer implemented with noise cancellation technique operating between 10 MHz and 0.9 GHz.The Gilbert mixer is known for its perfect port isolation and bad noise performance.The noise cancellation technique of LNA can be applied here to have a better NF.The chip is implemented in SMIC 0.18μm CMOS technology.Measurement shows that the proposed low noise mixer has a 13.7-19.5 dB voltage gain from 10 MHz to 0.9 GHz,an average noise figure of 5 dB and a minimum value of 4.3 dB.The core area is 0.6 x 0.45 mm~2.     

A sub-mW 2.9-dB noise figure Inductor-less low noise amplifier for wireless sensor network applications

In this paper, a low power differential inductor-less Common Gate Low Noise Amplifier (CG-LNA) is presented for Wireless Sensor Network (WSN) applications. New Shunt feedback is employed with noise cancellation and Dual Capacitive Cross Coupling (DCCC) techniques to improve the performance of common gate structures in terms of gain, Noise Figure (NF) and power consumption. The shunt feedback path boosts the input conductance of the LNA in current reuse scheme. Both shunt feedback and current reuse bring power dissipation down considerably. In addition, the positive feedback is utilized to cancel the thermal noise of the input transistor. The proposed LNA is designed and simulated in 0.18 µm TSMC CMOS technology. Post layout Simulation results indicate a voltage gain of 16.5 dB with −3 dB bandwidth of 100 MHz–3 GHz. Also third order Input Intercept Point (IIP3) is equal to + 1 dBm. The minimum NF is 2.8 dB and the value of NF at 2.4 GHz is 2.9 dB. S11 is better than −13 dB in whole frequency range. The core LNA consumes 985 µW from a 1.8 V DC voltage supply.     

Post-linearization of cascode CMOS low noise amplifier using folded PMOS IMD sinker

A post-linearization technique for the cascode complementary metal oxide semiconductor (CMOS) low noise amplifier (LNA) is presented. The proposed method uses an additional folded cascode positive-channel metal oxide semiconductor field-effect transistor for sinking the third-order intermodulation distortion (IMD3) current generated by the common source stage, while minimizing the degradation of gain and noise figure. This technique is applied to enhance the linearity of CMOS LNA using 0.18-/spl mu/m technology. The LNA achieved +13.3-dBm IIP3 with 12.8-dB gain, 1.4dB NF at 2GHz consuming 8mA from a 1.8-V supply.     

3–10-GHz Ultra-Wideband Low-Noise Amplifier Utilizing Miller Effect and Inductive Shunt–Shunt Feedback Technique

In this paper, we demonstrate an SiGe HBT ultra-wideband (UWB) low-noise amplifier (LNA), achieved by a newly proposed methodology, which takes advantage of the Miller effect for UWB input impedance matching and the inductive shunt-shunt feedback technique for bandwidth extension by pole-zero cancellation. The SiGe UWB LNA dissipates 25.8-mW power and achieves S₁₁ below -10 dB for frequencies from 3 to 14 GHz (except for a small range from 10 to 11 GHz, which is below -9 dB), flat S₂₁ of 24.6 plusmn 1.5 dB for frequencies from 3 to 11.6 GHz, noise figure of 2.5 and 5.8 dB at 3 and 10 GHz, respectively, and good phase linearity property (group-delay variation is only plusmn28 ps across the entire band). The measured 1-dB compression point (P₁ dB) and input third-order intermodulation point are -25.5 and -17 dBm, respectively, at 5.4 GHz.     

Linearity improvement of cascode low-noise amplifiers using double DS method with a tuned inductor

We propose a highly linear low-noise amplifier (LNA) using the double derivative superposition method with a tuned inductor. This topology has an auxiliary common gate stage of the cascode amplifier to cancel each third-order intermodulation distortion (IMD3) component and can provide a high third-order input intercept point (IIP3) for the 5.25 GHz frequency band. From the simulation results using the TSMC 0.18 μm RF CMOS process, the IIP3 in the proposed cascode LNAs can be improved by 9 dB, compared with the conventional derivative superposition method. The proposed LNA achieves an IIP3 of + 15 dBm with a gain of 10.5 dB, a noise figure of 2.4 dB, and a power consumption of 6 mA at 1.5 V.     

一款130～140GHz MMIC低噪声放大器

基于90 nm栅长的InP高电子迁移率晶体管(HEMT)工艺,研制了一款工作于130 ～140 GHz的MMIC低噪声放大器(LNA).该款放大器采用三级级联的双电源拓扑结构,第一级电路在确保较低的输入回波损耗的同时优化了放大器的噪声,后两级则采用最大增益的匹配方式,保证了放大器具有良好的增益平坦度和较小的输出回波损耗.在片测试结果表明,在栅、漏极偏置电压分别为-0.25 V和3V的工作条件下,该放大器在130～ 140 GHz工作频带内噪声系数小于6.5 dB,增益为18 dB±1.5 dB,输入电压驻波比小于2:1,输出电压驻波比小于3:1.芯片面积为1.70 mm×1.10 mm.该低噪声放大器有望应用于D波段的收发系统中.     

应用于S波段的高线性低噪声放大器

采用E-mode 0.25um GaAs pHEMT工艺,2.0mm × 2.0mm 8-pin双侧引脚扁平封装,设计了一款应用于S波段的噪声系数低于0.5dB的低噪声放大器。通过采用共源共栅结构、有源偏置网络和多重反馈网络等技术改进了电路结构,该放大器具有低噪声,高增益,高线性等特点,是手持终端应用上理想的一款低噪声放大器。测试结果表明在2.3-2.7GHz内,增益大于18dB,输入回波损耗小于-10dB,输出回波损耗小于-16dB,输出三阶交调点大于36dB。     

A low-current and low-distortion wideband amplifier using 0.2-μmgate MODFET fabricated by using phase-shift lithography

We have developed a wide-band amplifier that can keep a gain over 10 dB at an operation current of 10 mA from 100 MHz to 3 GHz. The fabricated integrated circuit (IC) achieved a high-output third-order intercept point of 30 dBm and low noise figure of 1.6 dB at 800 MHz, respectively. The present IC employs a MODFET with 0.2-μm gate fabricated by using a phase-shift lithography technique     

Erratum to: Using Improved Product-Coded Modulation Codes to Reduce the Peak-to-Average Power Ratio in Single-Carrier Frequency Division Multiple Access Systems

A new ultra-wideband common gate low noise amplifier (LNA) for 3–6 GHz WLAN and WPAN applications is presented in which a current reused noise canceling structure utilized in the first stage not only provides a suitable noise performance, but also enhances the linearity characteristics of the LNA in a power efficient manner needed by WLAN/WPAN applications. The overall structure of the proposed LNA, consisting of three stages, namely input matching common gate stage with noise canceling, gain stage, and buffer one, is designed, laid out, and analyzed in 0.18 µm RF CMOS process. The LNA has a noise figure of 3.5–3.6 dB, a high and flat power gain of 20.27 ± 0.13 dB, and input and output losses of better than ?11 and ?14 dB, respectively, over the entire frequency band of 3–5 GHz, while these parameters are 3.5 dB, 20.75 ± 0.25 dB, ?15 and ?9 dB for the frequency band of 5–6 GHz, respectively. IIP2 and IIP3 of the proposed topology are equal to 25.9 and ?1.85 dBm, respectively, at 4 GHz frequency. The proposed LNA has 15.3 mW power dissipation from a 1.8 V supply.     

Post-linearization with image rejection for high IIP3 and image-rejection ratio of a 17 GHz CMOS low noise amplifier

This study develops a post-linearization technique to simultaneously improve the input third-order intercept point (IIP3) and image-rejection ratio (IRR) of a 17 GHz low noise amplifier (LNA) in a 0.18 μm standard CMOS process. A third-order intermodulation distortion (IMD3) compensator constructed by a second-order notch filter was proposed to achieve both high linearity and image reject (IR) of the cascode LNA. The correlation between the post-linearization and IR techniques is analyzed and discussed. The measured LNA achieved a gain of 16.5 dB, a noise figure (NF) of 4.58 dB, an IIP3 of 0 dBm, and an IRR from 68 to 78 dB. The improvements of IIP3 and IRR are 11.7 and 46 dB, respectively, better than that of the LNA without the notch filter. The proposed IR LNA with total current dissipation of 4.8 mA under 1.8 V supply voltage and notch filter only dissipate a DC power of 2 mW.     

A 1.2-V Highly Linear Balanced Noise-Cancelling LNA in 0.13-μm CMOS

In this paper, a current-to-voltage combiner is proposed to realize a highly linear, balanced noise-cancelling low-noise amplifier (LNA) capable of low-voltage operation. The current-to-voltage combiner, implemented in the load of the amplifier, converts the output currents of the parallel common-gate (CG) and common-source (CS) stages of the LNA to voltages, equalizes the amplitudes of the voltages, and combines the voltages to a single output voltage. Since only a CS stage and passive components are employed to cancel the noise and distortion due to the CG input impedance matching circuit, high linearity is achieved in spite of the low supply voltage of 1.2 V. The LNA achieves a noise figure (NF) of 3.0 dB at 2.1 GHz with an input-referred third-order intercept point (IIP3) of +10.5 dBm while consuming 10.5 mA from a 1.2-V supply. The amplifier is fabricated in 0.13-mum CMOS process.     

A wideband LNA employing gate-inductive-peaking and noise-canceling techniques in 0.18μm CMOS

正This paper presents a wideband low noise amplifier(LNA) for multi-standard radio applications.The low noise characteristic is achieved by the noise-canceling technique while the bandwidth is enhanced by gateinductive -peaking technique.High-frequency noise performance is consequently improved by the flattened gain over the entire operating frequency band.Fabricated in 0.18μm CMOS process,the LNA achieves 2.5 GHz of -3 dB bandwidth and 16 dB of gain.The gain variation is within±0.8 dB from 300 MHz to 2.2 GHz.The measured noise figure(NF) and average HP3 are 3.4 dB and -2 dBm,respectively.The proposed LNA occupies 0.39 mm2 core chip area.Operating at 1.8 V,the LNA drains a current of 11.7 mA.     

一个应用于探测生理信号SoC中的CMOS全集成高线性度低噪声上变频器设计

本文设计一款用于探测生理信号SoC芯片中的5GHz双边带上变频器.该混频器基于传统的吉尔伯特单元,采用交流耦合current-bleeding结构以及三阶非线性失真抵消技术抑制非线性.通过将跨导级晶体管偏置在不同的工作区域(transconductance-boost结构),使得带内变频损失小于5dB而IIP3介于22.3dBm到39.8dBm,而且双边带噪声指数小于8.2dB.应用全差分结构和感性源极钝化,再次抑制了二阶以及三阶失真.全部上变频器在1.2V供电条件下总功耗为8.4mW.     

Noise current feedforward for noise cancellation in the wideband transformer shunt feedback low noise amplifier

A noise current feedforward (NCF) technique for noise cancellation in the wideband transformer shunt feedback (TSF) low noise amplifier (LNA) is proposed. The NCF can detect and cancel the thermal noise of the TSF network. It is also suitable to cancel those noise contributed by the passive unilateral shunt feedback networks in common current mode LNAs. Implemented in SMIC 0.18 μm CMOS process and operated in the typical radio astronomy frequency range from 0.6 GHz to 1.6 GHz, the TSF LNA that employs the NCF shows approximately 0.2–0.5 dB lower noise figure than the overwhelming resistive shunt feedback LNA that exploits a conventional noise voltage feedforward technique when consuming the same power.     

S-band low noise amplifier using 1μm InGaAs/InAlAs/InP pHEMT

正This paper discusses the design of a wideband low noise amplifier(LNA) in which specific architecture decisions were made in consideration of system-on-chip implementation for radio-astronomy applications.The LNA design is based on a novel ultra-low noise InGaAs/InAlAs/InP pHEMT.Linear and non-linear modelling of this pHEMT has been used to design an LNA operating from 2 to 4 GHz.A common-drain in cascade with a common source inductive degeneration,broadband LNA topology is proposed for wideband applications.The proposed configuration achieved a maximum gain of 27 dB and a noise figure of 0.3 dB with a good input and output return loss(S_(11)—10 dB,S_(22)—11 dB).This LNA exhibits an input 1-dB compression point of-18 dBm,a third order input intercept point of 0 dBm and consumes 85 mW of power from a 1.8 V supply.     

S-band low noise amplifier using 1 μm InGaAs/InAlAs/InP pHEMT

This paper discusses the design of a wideband low noise amplifier (LNA) in which specific architecture decisions were made in consideration of system-on-chip implementation for radio-astronomy applications. The LNA design is based on a novel ultra-low noise InGaAs/InAlAs/InP pHEMT. Linear and non-linear modelling of this pHEMT has been used to design an LNA operating from 2 to 4 GHz. A common-drain in cascade with a common source inductive degeneration, broadband LNA topology is proposed for wideband applications. The proposed configuration achieved a maximum gain of 27 dB and a noise figure of 0.3 dB with a good input and output return loss (S₁₁ < -10 dB, S₂₂ < -11 dB). This LNA exhibits an input 1-dB compression point of -18 dBm, a third order input intercept point of 0 dBm and consumes 85 mW of power from a 1.8 V supply.     

带有ESD保护,900MHz/2.4 GHz Dual-BandCMOS LNA的设计

设计了一个可以同时工作在900 MHz和2.4 GHz的双频带(Dual-Band)低噪声放大器(LNA).相对于使用并行(parallel)结构LNA的双频带解决方案,同时工作(concurrent)结构的双频带LNA更能节省面积和减少功耗.此LNA在900MHz和2.4 GHz两频带同时提供窄带增益和良好匹配.该双频带LNA使用TSMC 0.25 μm 1P5M RF CMOS工艺.工作在900MHz时,电压增益、噪声系数(Noise Figure)分别是21 dB、2.9 dB;工作在2.4 GHz时,电压增益、噪声系数分别是25dB、2.8 dB,在电源电压为2.5 V时,该LNA的功耗为12.5mW,面积为1.1mm×0.9 mm.使用新颖的静电防护(ESD)结构使得在外围PAD上的保护二极管面积仅为8 μm×8 μm时,静电防护能力可达2 kV(人体模型)     

Noise-canceling and IP3 improved CMOS RF front-end for DRM/DAB/DVB-H applications

A CMOS RF (radio frequency) front-end for digital radio broadcasting applications is presented that contains a wideband LNA, I/Q-mixers and VGAs, supporting other various wireless communication standards in the ultra-wide frequency band from 200 kHz to 2 GHz as well. Improvement of the NF (noise figure) and IP3 (third-order intermodulation distortion) is attained without significant degradation of other performances like voltage gain and power consumption. The NF is minimized by noise-canceling technology, and the IP3 is improved by using differential multiple gate transistors (DMGTR). The dB-in-linear VGA (variable gain amplifier) exploits a single PMOS to achieve exponential gain control. The circuit is fabricated in 0.18-μm CMOS technology. The S_(11) of the RF front-end is lower than -11.4 dB over the whole band of 200 kHz-2 GHz. The variable gain range is 12-42 dB at 0.25 GHz and 4-36 dB at 2 GHz. The DSB NF at maximum gain is 3.1-6.1 dB. The IIP3 at middle gain is -4.7 to 0.2 dBm. It consumes a DC power of only 36 mW at 1.8 V supply.     

A merged CMOS LNA and mixer for a WCDMA receiver

A low-noise amplifier (LNA) and mixer circuit in 0.35-/spl mu/m CMOS operates at 2.1 GHz. Merging the LNA and mixer lowers the number of transistors in the signal path and thereby also the nonlinearity and power consumption. The circuit meets the specifications for a direct conversion wide-band code-division multiple access (WCDMA) receiver. Its noise figure is 3.4 dB (5kHz to 5MHz), the total conversion gain is 23 dB, the third-order input-referred intercept point is -1.5 dBm, and the local oscillator leakage to the antenna is less than -71 dBm. The fully differential circuit takes 8 mA from a 2.7-V supply.