A 5-GHz-band multifunctional BiCMOS transceiver chip for GMSKmodulation wireless systems

This paper reports the first multifunctional 0.4-μm BiCMOS-based transceiver chip developed for 5-GHz-band Gaussian minimum-shift keying modulation wireless systems. The chip integrates a low-noise radio-frequency amplifier, a down-mixer, and an intermediate-frequency (IF) amplifier in the down-converter path; an IF amplifier, a limiter, an up-mixer, and a buffer amplifier in the up-converter path; and a frequency doubler and a local oscillator amplifier in the local oscillator path. The chip featuring gain attenuation as well as standby mode operation uses a single 2.6-5.2-V bias voltage and dissipates 56 mW in receive mode and 66 mW in transmit mode. The transceiver chip size is 3.0×2.4 mm²     

A 2.7-V GSM RF transceiver IC

A 2.7-V RF transceiver IC is intended for small, low-cost global system for mobile communications (GSM) handsets. This chip includes a quadrature modulator (QMOD) and an offset phase locked loop (OPLL) in the transmit path and a dual IF receiver that consists of a low noise amplifier (LNA) with an active-bias circuit, two Gilbert-cell mixers, a programmable gain linear amplifier (PGA), and a quadrature demodulator (QDEM). The IC also contains frequency dividers with a very high frequency voltage controlled oscillator (VHF-VCO) to simplify the receiver design. The system evaluation results are the phase error of 2.7° r.m.s. and the noise transmitted in the GSM receiving band of -163 dBc/Hz for transmitters and the reference sensitivity of -105 dBm for receivers. Power-control functions are provided for independent transmit and receive operation. The IC is implemented by using bipolar technology with f_T=15 GHz, r'_bb=150 Ω, and 0.6-μm features     

InAlAs/InGaAs HBT X-band double-balanced upconverter

We report on an InAlAs/InGaAs HBT Gilbert cell double-balanced mixer which upconverts a 3 GHz IF signal to an RF frequency of 5-12 GHz. The mixer cell achieves a conversion loss of between 0.8 dB and 2.6 dB from 5 to 12 GHz. The LO-RF and IF-RF isolations are better than 30 dB at an LO drive of +5 dBm across the RF band. A pre-distortion circuit is used to increase the linear input power range of the LO port to above +5 dBm. Discrete amplifiers designed for the IF and RF frequency ports make up the complete upconverter architecture which achieves a conversion gain of 40 dB for an RF output bandwidth of 10 GHz. The upconverter chip set fabricated with InAlAs/InGaAs HBT's demonstrates the widest gain-bandwidth performance of a Gilbert cell based upconverter compared to previous GaAs and InP HBT or Si-bipolar IC's     

A 1.8-V operation RF CMOS transceiver for 2.4-GHz-band GFSK applications

This paper describes a single-chip RF transceiver LSI for 2.4-GHz-band Gaussian frequency shift-keying applications, such as Bluetooth. This chip uses a 0.18-/spl mu/m bulk CMOS process for lower current consumption. The LSI consists of almost all the required RF and IF building blocks: a transmit/receive antenna switch, a power amplifier, a low noise amplifier, an image rejection mixer, channel-selection filters, a limiter, a received signal strength indicator, a frequency discriminator, a voltage controlled oscillator, and a phase-locked loop synthesizer. The bandpass filter for channel selection was difficult to achieve since it operates at a low supply voltage. However, because large interference is roughly rejected at the output of the image rejection mixer and a wide-input-range bandpass filter with an optimized input bias is realized, the transceiver can operate at a supply voltage of 1.8 V. In the IF section, we adopted a circuit design using the minimum number of passive elements, resistors and capacitors, for a lower chip area of 10.2 mm/sup 2/.     

A Dual‐Mode 2.4‐GHz CMOS Transceiver for High‐Rate Bluetooth Systems

This paper reports on our development of a dual‐mode transceiver for a CMOS high‐rate Bluetooth system‐on‐chip solution. The transceiver includes most of the radio building blocks such as an active complex filter, a Gaussian frequency shift keying (GFSK) demodulator, a variable gain amplifier (VGA), a dc offset cancellation circuit, a quadrature local oscillator (LO) generator, and an RF front‐end. It is designed for both the normal‐rate Bluetooth with an instantaneous bit rate of 1 Mb/s and the high‐rate Bluetooth of up to 12 Mb/s. The receiver employs a dualconversion combined with a baseband dual‐path architecture for resolving many problems such as flicker noise, dc offset, and power consumption of the dual‐mode system. The transceiver requires none of the external image‐rejection and intermediate frequency (IF) channel filters by using an LO of 1.6 GHz and the fifth order on‐chip filters. The chip is fabricated on a 6.5‐mm² die using a standard 0.25‐μm CMOS technology. Experimental results show an in‐band image‐rejection ratio of 40 dB, an IIP3 of ?5 dBm, and a sensitivity of ?77 dBm for the Bluetooth mode when the losses from the external components are compensated. It consumes 42 mA in receive π/4‐diffrential quadrature phase‐shift keying (π/4‐DQPSK) mode of 8 Mb/s, 35 mA in receive GFSK mode of 1 Mb/s, and 32 mA in transmit mode from a 2.5‐V supply. These results indicate that the architecture and circuits are adaptable to the implementation of a low‐cost, multi‐mode, high‐speed wireless personal area network.     

A polar modulator transmitter for GSM/EDGE

This 0.5-/spl mu/m SiGe BiCMOS polar modulator IC adds EDGE transmit capability to a GSM transceiver IC without any RF filters. Envelope information is extracted from the transmit IF and applied to the phase-modulated carrier in an RF variable gain amplifier which follows the integrated transmit VCO. The dual-band IC supports all four GSM bands. In EDGE mode, the IC produces more than 1 dBm of output power with more than 6 dB of margin to the transmit spectrum mask and less than 3% rms phase error. In GSM mode, more than 7 dBm of output power is produced with noise in the receive band less than -164 dBc/Hz.     

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.     

A 77-GHz Phased-Array Transceiver With On-Chip Antennas in Silicon: Receiver and Antennas

In this paper, we present the receiver and the on-chip antenna sections of a fully integrated 77-GHz four-element phased-array transceiver with on-chip antennas in silicon. The receiver section of the chip includes the complete down-conversion path comprising low-noise amplifier (LNA), frequency synthesizer, phase rotators, combining amplifiers, and on-chip dipole antennas. The signal combining is performed using a novel distributed active combining amplifier at an IF of 26 GHz. In the LO path, the output of the 52-GHz VCO is routed to different elements and can be phase shifted locally by the phase rotators. A silicon lens on the backside is used to reduce the loss due to the surface-wave power of the silicon substrate. Our measurements show a single-element LNA gain of 23 dB and a noise figure of 6.0dB. Each of the four receive paths has a gain of 37 dB and a noise figure of 8.0 dB. Each on-chip antenna has a gain of +2 dBi     

雷达中频放大器的线性对数双特性设计

雷达数字中频接收机需要一个线性中频预放大电路和一个监测用的对数中频放大器。采用射频变压器形成输入匹配网络,采用高性能低噪声宽带差分放大器AD8350作为线性放大器件,采用双调谐回路作为选频网络,采用魔T电路构成功率分配网络,采用高动态范围宽带对数放大器AD8309作为对数放大器件,设计了一个兼具线性和对数特性的中频放大器。实验表明,该放大器中频输入输出阻抗50Ω,中心频率30 MHz,带宽4 MHz。线性通道增益为18 dB,输出动态范围达98 dB(1 dB压缩点-90 dBm和+8 dBm)。对数通道中,在输入功率为-68 dBm～-8 dBm时,对数放大器输出电压范围对应为0.19 V～2.06 V。     

A 1.1 V 6.2 mW,wideband RF front-end for 0 dBm blocker tolerant receivers in 90 nm CMOS

This paper presents the design and implementation of a low power, highly linear, wideband RF front-end in 90 nm CMOS. The architecture consists of an inverter-like common gate low noise amplifier followed by a passive ring mixer. The proposed architecture achieves a high linearity in a wide band (0.5–6 GHz) at very low power. Therefore, it is a suitable choice for software defined radio (SDR) receivers. The chip measurement results indicate that the inverter-like common gate input stage has a broadband input match achieving S11 below −8.8 dB up to 6 GHz. The measured single sideband noise figure at an LO frequency of 3 GHz and an IF of 10 MHz is 6.25 dB. The front-end achieves a voltage conversion gain of 4.5 dB at 1 GHz with 3 dB bandwidth of more than 6 GHz. The measured input referred 1 dB compression point is +1.5 dBm while the IIP3 is +11.73 dBm and the IIP2 is +26.23 dBm respectively at an LO frequency of 2 GHz. The RF front-end consumes 6.2 mW from a 1.1 V supply with an active chip area of 0.0856 mm².     

A 2.4-GHz ISM-Band Sliding-IF Receiver With a 0.5-V Supply

We report an ultra-low-voltage RF receiver for applications in the 2.4 GHz band, designed in a 90 nm CMOS technology. The sliding-IF receiver prototype includes an LNA, an image-reject LC filter with single-ended to differential conversion, an RF mixer, an LC IF filter, a quadrature IF mixer, RF and IF LO buffers, and an I/Q baseband section with a VGA and a low-pass channel-select filter in each path, all integrated on-chip. It has a programmable overall gain of 30 dB, noise figure of 18 dB, out-of-channel IIP3 of -22 dBm. The 3.4 mm² chip consumes 8.5 mW from a 0.5 V supply.     

用于IEEE802．11b／g WLAN直接下变频接收机的射频前端设计

介绍了一种应用于IEEE802．11b／g无线局域网接收机射频前端的设计。基于直接下变频的系统架构。接收机集成了低噪声放大器、I／Q下变频器、去直流偏移滤波器、基带放大器和信道选择滤波器。电路采用TSMC0．18μm CMOS工艺设计,工作在2．4GHz ISM（工业、科学和医疗）频段,实现的低噪声放大器噪声系数为0．84dB,增益为16dB,S11低于-15dB,功耗为13mW;I／Q下变频器电压增益为2dB,输入1dB压缩点为-1 dBm,噪声系数为13dB,功耗低于10mw。整个接收机射频前端仿真得到的噪声系数为3．5dB,IIP3为-8dBm,IP2大于30dBm,电压增益为31dB,功耗为32mW。     

A 60-GHz Phased Array Receiver Front-End in 0.13-$mu {hbox{m}}$ CMOS Technology

This paper presents a fully integrated dual-antenna phased-array RF front-end receiver architecture for 60-GHz broadband wireless applications. It contains two differential receiver chains, each receiver path consists of an on-chip balun, ag_m-boosted current-reuse low-noise amplifier (LNA), a sub-harmonic dual-gate down-conversion mixer, an IF mixer, and a baseband gain stage. An active all-pass filter is employed to adjust the phase shift of each LO signal. Associated with the proposed dual conversion topology, the phase shift of the LO signal can be scaled to one-third. Differential circuitry is adopted to achieve good common-mode rejection. The g_m-boosted current-reuse differential LNA mitigates the noise, gain, robustness, stability, and integration challenges. The sub-harmonic dual-gate down-conversion mixer prevents the third harmonic issue in LO as well. Realized in a 0.13-mum 1P8M RF CMOS technology, the chip occupies an active area of 1.1 times 1.2 mm². The measured conversion gain and input P1 dB of the single receiver path are 30 dB and -27 dBm , respectively. The measured noise figure at 100 MHz baseband output is around 10 dB. The measured phased array in the receiver achieves a total gain of 34.5 dB and theoretically improves the receiver SNR by 4.5 dB. The proposed 60 GHz receiver dissipates 44 mW from a 1.2 V supply voltage. The whole two-channel receiver, including the vector modulator circuits for built-in testing, consumes 93 mW from a 1.2 V supply voltage.     

W波段集成化收发组件设计北大核心CSCD

基于混合微波集成电路技术(HMIC)设计了一种W波段小型化高频收发组件。该收发组件由固态发射机、环形器和接收机三部分组成。发射支路输入信号经过倍频放大后进入二选一开关,输出到天线自检口或经由环形器输出。为了实现高输出功率,该组件采用功率合成的设计思想,通过3 dB波导桥结构实现对两路功放的合成,解决了单个单片功率放大器的输出功率有限的问题。所设计的收发组件整体尺寸为125 mm×90 mm×26.5 mm。实测结果表明,在90~96 GHz工作频带范围内,遥测电压4.23 V。该收发组件的发射部分输出功率范围为33.6~35.4 dBm,开关隔离度大于110 dB;接收部分增益范围为30.2~33 dB,噪声系数小于6.5 dB。该组件具备良好的射频性能,同时实现了高集成度、大功率、高增益、高隔离度的要求。     

A 0.13 μm CMOS UWB RF Transmitter with an On‐Chip T/R Switch

This paper presents a fully integrated 0.13 μm CMOS MB‐OFDM UWB transmitter chain (mode 1). The proposed transmitter consists of a low‐pass filter, a variable gain amplifier, a voltage‐to‐current converter, an I/Q up‐mixer, a differential‐to‐single‐ended converter, a driver amplifier, and a transmit/receive (T/R) switch. The proposed T/R switch shows an insertion loss of less than 1.5 dB and a Tx/Rx port isolation of more than 27 dB over a 3 GHz to 5 GHz frequency range. All RF/analog circuits have been designed to achieve high linearity and wide bandwidth. The proposed transmitter is implemented using IBM 0.13 μm CMOS technology. The fabricated transmitter shows a ?3 dB bandwidth of 550 MHz at each sub‐band center frequency with gain flatness less than 1.5 dB. It also shows a power gain of 0.5 dB, a maximum output power level of 0 dBm, and output IP3 of +9.3 dBm. It consumes a total of 54 mA from a 1.5 V supply.     

A Fully Integrated 60GHz Four Channel CMOS Receiver with 7GHz Ultra-Wide Bandwidth for IEEE 802.11ad Standard

In this paper, a fully integrated CMOS receiver frontend for high-speed short range wireless applications centering at 60GHz millimeter wave （mmW） band is designed and implemented in 90nm CMOS technology. The 60GHz receiver is designed based on the super-heterodyne architecture consisting of a low noise amplifier （LNA） with inter-stage peaking technique, a single- balanced RF mixer, an IF amplifier, and a double-balanced I/Q down-conversion IF mixer. The proposed 60GHz receiver frontend derives from the sliding-IF structure and is designed with 7GHz ultra-wide bandwidth around 60GHz, supporting four 2.16GHz receiving channels from IEEE 802.1lad standard for next generation high speed Wi- Fi applications. Measured results show that the entire receiver achieves a peak gain of 12dB and an input 1-dB compression point of -14.SdBm, with a noise figure of lower than 7dB, while consumes a total DC current of only 60mA from a 1.2V voltage supply.     

A 2.5-GHz BiCMOS transceiver for wireless LAN's

A BiCMOS transceiver intended for spread spectrum applications in the 2.4-2.5 GHz band is described. The IC contains a low-noise amplifier (LNA) with 14 dB gain and 2.2 dB NF in its high-gain mode, a downconversion mixer with 8 dB gain and 11 dB NF, and an upconversion mixer with 17 dB gain and P_{-1 dB} of +3 dBm out. An on-chip local oscillator (LO) buffer accepts LO drive of -10 dBm with a half-frequency option allowed by an on-chip frequency doubler. Power consumption from a single 3-V supply is 34 mA in transmit mode, 21 mA in receive mode, and 1 μA in sleep mode     

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 3.1-4.8 GHz CMOS receiver for MB-OFDM UWB

An integrated fully differential ultra-wideband CMOS receiver for 3.1-4.8 GHz MB-OFDM systems is presented. A gain controllable low noise amplifier and a merged quadrature mixer are integrated as the RF front-end. Five order Gm-C type low pass filters and VGAs are also integrated for both I and Q IF paths in the receiver. The ESD protected chip is fabricated in a Jazz 0.18 μm RF CMOS process and achieves a maximum total voltage gain of 65 dB, an AGC range of 45 dB with about 6 dB/step, an averaged total noise figure of 6.4 to 8.8 dB over 3 bands and an in-band lIP3 of-5.1 dBm. The receiver occupies 2.3 mm2 and consumes 110 mA from a 1.8 V supply including test buffers and a digital module.