2.4GHz 0.35-μm CMOS全集成线性功率放大器设计

片上系统射频功率放大器是射频前端的重要单元.通过分析和对比各类功率放大器的特点,电路采用SMIC0.35-μm CMOS工艺设计2.4 GHz WLAN全集成线性功率放大器.论文中设计的功率放大器采用不同结构的两级放大,驱动级采用共源共栅A类结构组成,输出级采用共源级大MOSFET管组成.电路采用SMIC 0.35-μ...     

A 0.25-/spl mu/m 20-dBm 2.4-GHz CMOS power amplifier with an integrated diode linearizer

A 2.4-GHz CMOS power amplifier (PA) with an output power 20 dBm using 0.25-/spl mu/m 1P5M standard CMOS process is presented. The PA uses an integrated diode connected NMOS transistor as a diode linearizer. It is believed that this is the first reported use of the diode linearization technique in CMOS PA design. It shows effective improvement in linearity from gain compression and ACPR measured results. Measurements are performed by using an FR-4 PCB test fixture. The fabricated power amplifier exhibits an output power of 20 dBm and a power-added efficiency as high as 28%. The obtained PA performances demonstrate the standard CMOS process potential for medium power RF amplification at 2.4 GHz wireless communication band.     

High‐Efficiency CMOS Power Amplifier Using Uneven Bias for Wireless LAN Application

This paper proposes a high‐efficiency power amplifier (PA) with uneven bias. The proposed amplifier consists of a driver amplifier, power stages of the main amplifier with class AB bias, and an auxiliary amplifier with class C bias. Unlike other CMOS PAs, the amplifier adopts a current‐mode transformer‐based combiner to reduce the output stage loss and size. As a result, the amplifier can improve the efficiency and reduce the quiescent current. The fully integrated CMOS PA is implemented using the commercial Taiwan Semiconductor Manufacturing Company 0.18‐μm RF‐CMOS process with a supply voltage of 3.3 V. The measured gain, P_1dB, and efficiency at P_1dB are 29 dB, 28.1 dBm, and 37.9%, respectively. When the PA is tested with 54 Mbps of an 802.11g WLAN orthogonal frequency division multiplexing signal, a 25‐dB error vector magnitude compliant output power of 22 dBm and a 21.5% efficiency can be obtained.     

A 2.45-GHz 0.13-μm CMOS PA With Parallel Amplification

In this paper, a fully integrated 0.13-mum CMOS RF power amplifier for Bluetooth is presented. Four differential amplifiers are placed on a single chip and their outputs are combined with an on-chip LC balun structure. This technique allows to have a low impedance transformation ratio for each individual amplifier, and thus a lower power loss. The amplifier achieves a measured output power of 23 dBm at a supply voltage of 1.5 V and a drain efficiency of 35% and a global efficiency of 29%. The parallel amplification topology allows to efficiently control the output power which results in an efficiency improvement when the output power is reduced     

2.4GHz全集成CMOS Doherty功率放大器

采用0.18μm CMOS工艺设计并制作了一个2.4 GHz全集成CMOS Doherty功率放大器.着重考虑了片上螺旋电感的回流路径对电感模型的影响,并在设计中使用了一种新颖的螺旋电感版图结构来避免回流路径的影响.实测结果表明该功率放大器增益达到16dB,1dB压缩点为20.5dBm,峰值输出功率和对应功率附加效率分别为21.2dBm和20.4％,整个芯片面积为2.8mm×1.7mm.     

60 G Hz 11 dBm CMOS功率放大器设计

近年来60 GHz附近的一个连续频段可以自由使用,这为短距离的无线个域网等高速率传输的应用提供了条件.设计了一个工作在60 GHz的CMOS功率放大器.采用台积电0.13μmRF-CMOS工艺设计制造,芯片面积为0.35mm × 0.4 mm,最大线性输出功率为11 dBm,增益为9.7 dB,漏极增加效率(η_(PAE))为9.1%.达到应用在通信距离为10 m的无线个域网(WPAN)射频电路中的要求.设计中采用了厚栅氧化层工艺器件和Load-Pull方法设计最优化输出阻抗z_(opt),以提高输出功率.该方法能较大提高CMOS功率放大器的输出功率,可以应用到各种CMOS功率放大器设计中.     

移动数字电视接收机中宽带RF RSSI的设计

基于UMC 0.18 μm RF CMOS工艺,设计并实现了一个应用于移动数字电视接收机射频前端的接收信号强度指示仪(RF RSSI).提出了一种全新的功率检测电路,相对于传统的非平衡源级耦合对整流器,具有设计简单、功耗低以及良好的宽带功率指示功能;电路中前置放大器采用恒定跨导(G<,m>)偏置技术,输出放大器为三运放...     

下一代移动通信LTE中功率放大器芯片设计

基于0.18μm SiGe BiCMOS工艺,设计了一种应用于下一代移动通信3GPP LTE TDD2.6 GHz频段(Band38)的射频功率放大器(PA)芯片。射频功率放大器采用共发射极3级级联的全差分结构,提高了输出电压摆幅,减小了功率晶体管的集电极电流,且降低了寄生的键合线电感。在预放大级和中间放大级、功率级中分别设计了电阻偏置和有源偏置两种偏置电路以提高线性度性能,并通过MOS开关管实现功率控制功能。测试结果表明:在2.57～2.62 GHz工作频段内,正向增益S21大于30.5 dB,输入回波损耗S11和输出回波损耗S22分别均小于-13 dB,功率增益大于31 dB,输出1 dB压缩点功率达28.6 dBm,功率附加效率为18%。     

基于0.13μm CMOS的WiFi功率放大器设计

基于TSMC 0.13 μm CMOS工艺,设计了一款适用于无线保真(WiFi)收发机的发射端、工作在2.4 GHz且增益可控的三级级联功率放大器.驱动级采用单管结构,后两级采用共源共栅(MOSFET)结构.利用调节共源共栅晶体管栅极的电容来改变栅极电压的相位,进而弥补了共源共栅结构的劣势,增加了整个系统的线性度和增益.另外,使用外部数字信号控制每级偏置的大小来适应不同的输出需求.整个结构采用电源电压:第一级为1.8V,后两级为3.3V,芯片面积为1.93 mm×1.4 mm.利用Candence Spectre RF软件工具对所设计的功率放大器进行仿真.结果表明,在2.4 GHz的工作频点,功率放大器的饱和输出功率为24.9 dBm,最大功率附加效率为22％,小信号增益达到28 dB.     

A 2.4-GHz 0.18-/spl mu/m CMOS self-biased cascode power amplifier

A two-stage self-biased cascode power amplifier in 0.18-/spl mu/m CMOS process for Class-1 Bluetooth application is presented. The power amplifier provides 23-dBm output power with a power-added efficiency (PAE) of 42% at 2.4 GHz. It has a small signal gain of 38 dB and a large signal gain of 31 dB at saturation. This is the highest gain reported for a two-stage design in CMOS at the 0.8-2.4-GHz frequency range. A novel self-biasing and bootstrapping technique is presented that relaxes the restriction due to hot carrier degradation in power amplifiers and alleviates the need to use thick-oxide transistors that have poor RF performance compared with the standard transistors available in the same process. The power amplifier shows no performance degradation after ten days of continuous operation under maximum output power at 2.4-V supply. It is demonstrated that a sliding bias technique can be used to both significantly improve the PAE at mid-power range and linearize the power amplifier. By using the sliding bias technique, the PAE at 16 dBm is increased from 6% to 19%, and the gain variation over the entire power range is reduced from 7 to 0.6 dB.     

A low-power highly linear cascoded multiple-gated transistor CMOS RF amplifier with 10 dB IP3 improvement

A low-power highly linear CMOS RF amplifier circuit composed of a Multiple-Gated common-source FET TRansistor (MGTR) in cascode configuration is reported. In a MGTR amplifier, linearity is improved by using transconductance linearization which can be achieved by canceling the negative peak value of g/sub m/" of the main transistor with the positive one in the auxiliary transistor having a different size and gate drive combined in parallel. This enhancement, however, is limited by the distortion originated from the combined influence of g/sub m/' and harmonic feedback, which can greatly be reduced by the cascoding MGTR output. IP3 improvement as large as 10 dB has been obtained from an experimental RF amplifier designed at 900 MHz and fabricated using 0.35 /spl mu/m BiCMOS technology using only CMOS at a similar power consumption and gain as those obtainable from conventional cascode single gate transistor amplifiers.     

A low-power highly linear cascoded multiple-gated transistor CMOS RF amplifier with 10 dB IP3 improvement (Revised)

A low-power highly linear CMOS RF amplifier circuit composed of a Multiple-Gated common-source FET TRansistor (MGTR) in cascode configuration is reported. In an MGTR amplifier, linearity is improved by using transconductance linearization which can be achieved by canceling the negative peak value of g/sub m/" of the main transistor with the positive one in the auxiliary transistor having a different size and gate drive combined in parallel. This enhancement, however, is limited by the distortion originated from the combined influence of g/sub m/' and harmonic feedback, which can greatly be reduced by the cascoding MGTR output. IP3 improvement as large as 10 dB has been obtained from an experimental RF amplifier designed at 900 MHz and fabricated using 0.35 /spl mu/m BiCMOS technology using only CMOS at a similar power consumption and gain as those obtainable from conventional cascode single gate transistor amplifiers.     

1.9GHz0.18μm CMOS低噪声放大器的设计

针对1.9GHzPHS和DECT无线接入系统的应用,提出了一种可工作于1.2V电压的基于源级电感负反馈共源共栅结构而改进的CMOS低噪声放大器,并对其电路结构、噪声及线性特性等主要性能进行分析。并与传统的低噪声放大器进行对比,该电路采用两级放大结构,通过加入电容和电感负反馈可以分别实现低功耗约束下的噪声优化和高的线性度。采用TSMC0.18μm CMOS工艺模型设计与验证,实验结果表明：该低噪声放大器能很好满足要求,且具有1.4dB的噪声系数和好的线性度,输入1dB压缩点-7.8dBm,增益11dB,功耗11mW。     

一种具有精确增益控制的CMOS可编程增益放大器

采用0.13μm RF CMOS工艺,设计了一款具有精确增益步长控制的宽带可编程增益放大器.在传统电阻网络衰减器的基础上,提出了一种新的增益控制方法.该方法采用两个互相重叠的反馈环路,通过改变环路中跨导的比值以实现精细的增益步长控制.测试结果表明,当电源电压为1.2V时,功耗为24 mW,-3 dB带宽为600MHz....     

2.1GHz CMOS低噪声放大器

采用上海华虹NEC0.35μm标准CMOS工艺进行RFCMOS窄带低噪声放大器的设计和制作。测试结果表明,在2.1GHz时,输入驻波比1.1,输出驻波比1.5,增益18dB,噪声系数2.7dB,P-1dB输出功率9dBm。     

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 1.75-GHz polar modulated CMOS RF power amplifier for GSM-EDGE

This work presents a fully integrated linearized CMOS RF amplifier, integrated in a 0.18-/spl mu/m CMOS process. The amplifier is implemented on a single chip, requiring no external matching or tuning networks. Peak output power is 27 dBm with a power-added efficiency (PAE) of 34%. The amplitude modulator, implemented on the same chip as the RF amplifier, modulates the supply voltage of the RF amplifier. This results in a power efficient amplification of nonconstant envelope RF signals. The RF power amplifier and amplitude modulator are optimized for the amplification of EDGE signals. The EDGE spectral mask and EVM requirements are met over a wide power range. The maximum EDGE output power is 23.8 dBm and meets the class E3 power requirement of 22 dBm. The corresponding output spectrum at 400 and 600 kHz frequency offset is -59 dB and -70 dB. The EVM has an RMS value of 1.60% and a peak value of 5.87%.     

A 900 MHz Zero‐IF RF Transceiver for IEEE 802.15.4g SUN OFDM Systems

This paper presents a 900 MHz zero‐IF RF transceiver for IEEE 802.15.4g Smart Utility Networks OFDM systems. The proposed RF transceiver comprises an RF front end, a Tx baseband analog circuit, an Rx baseband analog circuit, and a ΔΣ fractional‐N frequency synthesizer. In the RF front end, re‐use of a matching network reduces the chip size of the RF transceiver. Since a T/Rx switch is implemented only at the input of the low‐noise amplifier, the driver amplifier can deliver its output power to an antenna without any signal loss; thus, leading to a low dc power consumption. The proposed current‐driven passive mixer in Rx and voltage‐mode passive mixer in Tx can mitigate the IQ crosstalk problem, while maintaining 50% duty‐cycle in local oscillator clocks. The overall Rx‐baseband circuits can provide a voltage gain of 70 dB with a 1 dB gain control step. The proposed RF transceiver is implemented in a 0.18 μm CMOS technology and consumes 37 mA in Tx mode and 38 mA in Rx mode from a 1.8 V supply voltage. The fabricated chip shows a Tx average power of ?2 dBm, a sensitivity level of ?103 dBm at 100 Kbps with , an Rx input P_1dB of ?11 dBm, and an Rx input IP3 of ?2.3 dBm.     

An RF power amplifier with inter-metal-shuffled capacitor for inter-stage matching in a digital CMOS process

One challenge of the implementation of fully-integrated RF power amplifiers into a deep submicro digital CMOS process is that no capacitor is available, especially no high density capacitor. To address this problem, a twostage class-AB power amplifier with inter-stage matching realized by an inter-metal coupling capacitor is designed in a 180-nm digital CMOS process. This paper compares three structures of inter-metal coupling capacitors with metal-insulator-metal (MIM) capacitor regarding their capacitor density. Detailed simulations are carried out for the leakage, the voltage dependency, the temperature dependency, and the quality factor between an inter-metal shuffled (IMS) capacitor and an MIM capacitor. Finally, an IMS capacitor is chosen to perform the inter-stage matching.The techniques are validated via the design and implement of a two-stage class-AB RF power amplifier for an UHF RFID application. The PA occupies 370 X 200 μm2 without pads in the 180-nm digital CMOS process and outputs 21.1 dBm with 40% drain efficiency and 28.1 dB power gain at 915 MHz from a single 3.3 V power supply.     

Design method for CMOS current-source modes power amplifiers based on PAE optimization

An efficient method for CMOS current-source modes (A, B, AB, C classes) Power Amplifier (PA) design for low-power applications is presented. This method allows to set the conduction angle α and the transistor size W/L in order to maximize the PAE. In a first step, an analytical approach, built from a simple transistor model, gives a first approximation of the optimum α and W/L. In a second step and from the analytical results, a simulation approach, illustrated with a 0.28μm CMOS foundry design-kit, allows to precisely determine the optimum conduction angle and the transistor size. A PA designed with this method at 2.45 GHz for a class 2 Bluetooth application shows a 41% PAE and a surface consumption of 0.28 mm² for an output power of 4 dBm.