A monolithic 3.1-4.8 GHz MB-OFDM UWB transceiver in 0.18-μm CMOS

A monolithic RF transceiver for an MB-OFDM UWB system in 3.1-4.8 GHz is presented.The transceiver adopts direct-conversion architecture and integrates all building blocks including a gain controllable wideband LNA,a I/Q merged quadrature mixer,a fifth-order Gm-C bi-quad Chebyshev LPF/VGA,a fast-settling frequency synthesizer with a poly-phase filter,a linear broadband up-conversion quadrature modulator,an active D2S converter and a variablegain power amplifier.The ESD protected transceiver is fabricated in Jazz Semiconductor's 0.18-μm RF CMOS with an area of 6.1 mm2 and draws a total current of 221 mA from 1.8-V supply.The receiver achieves a maximum voltage gain of 68 dB with a control range of 42 dB in 6 dB/Step,noise figures of 5.5-8.8 dB for three sub-bands,and an inband/out-band IIP3 better than-4 dBm/+9 dBm.The transmitter achieves an output power ranging from-10.7 to-3dBm with gain control,an output P1dB better than-7.7 dBm,a sideband rejection about 32.4 dBc,and LO suppression of 31.1 dBc.The hopping time among sub-bands is less than 2.05 ns.     

Single-Chip W-band SiGe HBT Transceivers and Receivers for Doppler Radar and Millimeter-Wave Imaging

This paper presents the first single-chip direct-conversion 77-85 GHz transceiver fabricated in SiGe HBT technology, intended for Doppler radar and millimeter-wave imaging, particularly within the automotive radar band of 77-81 GHz. A 1.3 mm times 0.9 mm 86-96 GHz receiver is also presented. The transceiver, fabricated in a 130 nm SiGe HBT technology with f_T/f_MAX of 230/300 GHz, consumes 780 mW, and occupies 1.3 mm times 0.9 mm of die area. Furthermore, it achieves 40 dB conversion gain in the receiver at 82 GHz, a 3 dB bandwidth extending from 77 to 85 GHz at 25degC, and covering the entire 77-81 GHz band up to 100degC, record 3.85 dB DSB noise figure measured at 82 GHz LO and 1 GHz IF, and an IP_1dB of -35 dBm. The transmitter provides + 11.5 dBm of saturated output power at 77 GHz, and a divide64 static frequency divider is included on-die. Successful detection of a Doppler shift of 30 Hz at a range of 6 m is shown. The 86-96 GHz receiver achieves 31 dB conversion gain, a 3 dB bandwidth of 10 GHz, and 5.2 dB DSB noise figure at 96 GHz LO and 1 GHz IF, and -99 dBc/Hz phase noise at 1 MHz offset. System-level layout and integration techniques that address the challenges of low-voltage transceiver implementation are also discussed.     

超宽带系统CMOS全集成射频收发器设计

本文介绍3.1-4.8GHz MB-OFDM系统的CMOS射频收发器。电路采用直接变频架构,由接收器、发射器和频率综合器组成。采用PGS隔离技术和其他隔离措施完成了单片射频收发器的版图布局。后仿真结果表明,接收链路可提供的最大增益为72dB,其52dB为可变增益,三个子频带内噪声系数介于5.2-7.8dB,带外IIP3不低于-3.4dBm。发射链路可提供的可控输出功率-8dBm到-2dBm,输出1dB压缩点不低于4dBm,输出信号边带抑制约44dBc,载波抑制不低于34dBc。频率综合器在三个频点间的跳变时间小于9ns。芯片采用Jazz0.18μm射频CMOS工艺设计,面积为6.1mm2。在1.8V电源电压下,总电流约221mA。     

An auto-I/Q calibrated CMOS transceiver for 802.11g

The CMOS transceiver IC exploits the superheterodyne architecture to implement a low-cost RF front-end with an auto-I/Q calibration function for IEEE 802.11g. The transceiver supports I/Q gain and phase mismatch auto tuning mechanisms at both the transmitting and receiving ends, which are able to reduce the phase mismatch to within 1/spl deg/ and gain mismatch to 0.1dB. Implemented in a 0.25 /spl mu/m CMOS process with 2.7 V supply voltage, the transceiver delivers a 5.1 dB receiver cascade noise figure, 7 dBm transmit, and a 1 dB compression point.     

A 3.1 GHz–8.0 GHz Single-Chip Transceiver for MB-OFDM UWB in 0.18-$mu$ m CMOS Process

This paper presents the design and integration of a fully-integrated dual-conversion zero-IF2 CMOS transceiver for 9-band MB-OFDM UWB systems from 3.1 GHz to 8.0 GHz. The transceiver integrates all building blocks including a variable-gain wideband LNA, a single combined mixer for both RF down-conversion in RX and up-conversion in TX, a fast-settling frequency synthesizer, and IQ ADCs and DACs. Fabricated in a standard 0.18- mum CMOS process, the receiver measures maximum S11 of - 13 dB, maximum NF of 8.25 dB, in-band IIP3 of better than -13.7 dBm, and variable gain from 25.3 to 84.0 dB. IQ path gain and phase mismatches of the receiver chain are measured to be 0.8 dB and 4 ^deg, respectively. The transmitter achieves a minimum output P-1 dB of -8.2 dBm, sideband rejection of better than -42.2 dBc, and LO leakage of smaller than - 46.5 dBc.     

A Low-Power Fullband 802.11a/b/g WLAN Transceiver With On-Chip PA

A low-power fullband 802.11a/b/g WLAN transceiver in 0.15-mum CMOS technology is described. The zero-IF transceiver achieves a receiver noise figure of 4.4/4 dB for the 2.4-GHz/5-GHz bands, respectively. The corresponding sensitivity at 54-Mb/s operation is -72 dBm for 802.11g and -74 dBm for 802.11a using actual PER measurement. An on-chip PA delivers 20 dBm output P1-dB. A new I/Q compensation scheme is implemented in local oscillator (LO) and an image rejection of better than 52 dB is observed. The transmitter delivers 10/1.5 dBm (2.4-/5-GHz) EVM-compliant output power for a 64-QAM OFDM signal at 54-Mb/s. The power consumption is 117/135 mW (1.8-V) in the receive mode and 570/233.1 mW in the transmit mode for 2.4/5 GHz, respectively. The low power consumption, high integration and robustness (-40 to 140degC) make this transceiver suitable for portable applications     

A single-chip 12.7 Mchips/s digital IF BPSK direct sequencespread-spectrum transceiver in 1.2 μm CMOS

This paper describes a fully integrated digital-spread spectrum transceiver chip fabricated through MOSIS in 1.2 μm CMOS. It includes a baseband spread spectrum transmitter and a coherent intermediate frequency (IF) receiver consisting of a Costas loop, an acquisition loop for the pseudo-noise (PN) sequence, and a clock recovery loop with a 406.4 MHz onchip numerically controlled oscillator (NCO). The transceiver is capable of operating at a maximum IF sampling rate of 50.8 MS/s and a maximum chip rate of 12.7 R Mchips/s (Mcps) with selectable data rates of 100, 200, 400, and 800 kbps. At the maximum operating speed of 50.8 R MS/s, it dissipates 1.1 W. In an additive white Gaussian noise channel the IF receiver achieves a receiver output SNR within 1 dB of theory and can acquire code with a wide range of input SNR from -17 dB to over 30 dB. The transceiver chip has been interfaced to an RF up/down converter to demonstrate a wireless voice/data/video link operating in the 902-928 MHz band     

A 2-V, 1-10 GHz BiCMOS transceiver chip for multimode wirelesscommunications networks

This paper concerns the design consideration, fabrication process, and performance results for an ultra-broadband, low-voltage, low-power, BiCMOS-based transceiver chip for cellular-satellite-LAN wireless communication networks. The transceiver chip incorporates an RF amplifier, a Gilbert down-mixer, and an IF amplifier in the receive path, and an IF amplifier, a Gilbert up-mixer, and an RF amplifier in the transmit path. For an RF frequency in the 1-10 GHz band and an IF frequency in the 100-1000 MHz band, the developed transceiver chip consumes less than 60 mW at 2 V, to yield a downconversion gain of 40 dB at 1 GHz and 10 dB at 10 GHz and an upconversion gain of 42 dB at 1 GHz and 11 dB at 10 GHz. To avoid possible start-up problems caused during “stand-by” to “enable” mode transition, a simple switching technique is employed for enabling either the receive or the transmit path, by changing the value of a reference voltage applied to both the down- and the up-mixers. While the developed transceiver chip exhibits the best performance for a dc supply voltage of 2 V, it shows a graceful degradation for a ±0.15 V voltage deviation. The transceiver's chip size is 1.04 mm×1.04 mm     

CDMA基站收发信机研制

主要介绍CDMA射频基站收发信机原理框图、指标及设计方法.完全符合IS－95标准的CDMA三扇区基站.接收机接收灵敏度－117dBm,噪声系数优于3dB;发射功率60W,三阶互调抑制大于45dB.     

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     

应用于IEEE 802.11b无线局域网系统的2.4GHzCMOS单片收发机射频前端

实现了一个应用于IEEE 802.11b无线局域网系统的2.4GHz CMOS单片收发机射频前端,它的接收机和发射机都采用了性能优良的超外差结构.该射频前端由五个模块组成:低噪声放大器、下变频器、上变频器、末前级和LO缓冲器.除了下变频器的输出采用了开漏级输出外,各模块的输入、输出端都在片匹配到50Ω.该射频前端已经采用0.18μm CMOS工艺实现.当低噪声放大器和下变频器直接级联时,测量到的噪声系数约为5.2dB,功率增益为12.5dB,输入1dB压缩点约为-18dBm,输入三阶交调点约为-7dBm.当上变频器和末前级直接级联时,测量到的噪声系数约为12.4dB,功率增益约为23.8dB,输出1dB压缩点约为1.5dBm,输出三阶交调点约为16dBm.接收机射频前端和发射机射频前端都采用1.8V电源,消耗的电流分别为13.6和27.6mA.     

采用电流复用拓扑的宽带收发一体多功能电路

基于标准的GaAs赝配高电子迁移率晶体管(PHEMT)单片微波集成电路(MMIC)工艺设计并制备了一款宽带收发一体多功能电路芯片.该多功能芯片包含了功率放大器、低噪声放大器和收发开关.放大器采用电流复用拓扑结构实现了低功耗的目标.收发开关采用浮地结构避免了使用负电源.芯片在14～ 24 GHz工作频率的实测结果显示:接收支路噪声系数小于3.0dB,增益大于18 dB,输入及输出电压驻波比(VSWR)均小于2.0,1 dB压缩点输出功率大于0 dBm,直流功耗为60 mW;发射支路增益大于21 dB,输入输出VSWR均小于1.8,1dB压缩点输出功率大于10 dBm,直流功耗为180 mW.芯片尺寸为2 600 μm×1 800 μm.该多功能收发电路的在片测试结果和仿真结果一致,性能达到了设计要求.     

Design of $X$ -Band RF CMOS Transceiver for FMCW Monopulse Radar

In this paper, an X-band CMOS single chip integrating 16 building blocks is developed for frequency modulation continuous wave radar application. The quadrature and monopulse transceiver consists of a voltage-controlled oscillator, amplifiers, Wilkinson power dividers, 90deg hybrid low-noise amplifiers, rat-race hybrid, a single-pole double-throw switch, an active bandpass filter (BPF), and mixers. The transceiver is fabricated in a standard mixed-signal/RF bulk 0.18-mum CMOS technology with a chip area of 2.6 mm 3.3 mm, including contact pads. The transceiver is implemented by meandered complementary-conducting-strip transmission lines demonstrating their capability of miniaturizing circuits such as 90deg hybrid and rat-race hybrid with 95% and 98% size reduction compared to the prototype designs, respectively. The active BPF consumes 4.5 mW achieving 0-dB insertion loss at the passband. The total power consumption of the transceiver is 0.35 W. Output power of the transmitter is 1 dBm with a 35-dB second harmonic suppression. Moreover, the on-chip isolations between T/R in this compacted transceiver are more than 60 dB. The measured receiver gain and NF are -4.5 and 11.5 dB, respectively. Finally, the obtained in-phase and quadrature signals demonstrate 0.6-dB amplitude and 7deg phase imbalance.     

5-GHz SiGe HBT monolithic radio transceiver with tunable filtering

A wide-band CDMA-compliant fully integrated 5-GHz radio transceiver was realized in SiGe heterojunction-bipolar-transistor technology with on-chip tunable voltage controlled oscillator (VCO) tracking filters. It allows for wide-band modulation schemes with bandwidth up to 20 MHz. The receiver has a single-ended single-sideband noise figure of 5.9 dB, more than 40 dB on-chip image rejection, an input compression point of -22 dBm, and larger than 70 dB local-oscillator-RF isolation. The phase noise of the on-chip VCO is -100 and -128 dBc/Hz at 100 kHz and 5 MHz offset from the carrier, respectively. The transmitter output compression point is +10 dBm. An image rejection better than 40 dB throughout the VCO tracking range has been demonstrated in the transmitter with all spurious signals 40 dB below the carrier. The differential transceiver draws 125 mA in transmit mode and 45 mA in receive mode from a 3.5-V supply     

A WiMedia/MBOA-Compliant CMOS RF Transceiver for UWB

A WiMedia/MBOA compliant RF transceiver for ultra-wideband data communication in the 3-5-GHz band is presented. The transceiver includes receiver, transmitter and synthesizer is completely integrated in 0.13-mum standard CMOS technology. The receiver uses a feedback-based low-noise amplifier (LNA) to obtain an RF gain of 4 to 37 dB and an overall measured noise figure of 3.6 to 4.1 dB over the 3-5-GHz band of interest. The transmitter supports an error vector magnitude (EVM) of -28 dB up to -4 dBm output power and meets the FCC and WiMedia mask specifications. The power consumption from a single supply voltage of 1.5 V is 237 mW for the receiver and 284 mW for the transmitter, both including the synthesizer     

An 863-870 MHz spread-spectrum FSK transceiver design for wireless sensor

Simulation results of a 863-870 MHz frequency-hopped spread-spectrum (FHSS) transceiver with binary frequency shift keying (BFSK) modulation at 20 kb/s for wireless sensor applications is presented.The transmit/receive RF front end contains a BFSK modulator, an upconversion mixer, a power amplifier (PA), and an 863-870 MHz band pass filter (BPF) at the transmitter side and a low-noise amplifier with down conversion mixer to zero-IF, a low-pass channel-select filter, a limiter and a BFSK demodulator at the receiver side. The various block parameters of the transmit/receive RF front end like noise figure (NF), gain, 1 dB compression point (P-1 dB), and IIP3 are simulated and optimized to meet low power and low cost transceiver specifications.The transmitter simulations show an output ACPR (adjacent channel power ratio) of −22 dBc, 3.3 dBm P-1 dB of PA, and transmitted power of 0 dBm. The receiver simulations show 51.1 dB conversion gain, −7 dBm IIP3, −15 dB return loss (S11), and 10 dB NF. Low power arctangent-differentiated BFSK demodulator has been chosen and the BER performance has been co simulated with the analog receiver. The complete receiver achieves a BER of 10⁻³ at 10.5 dB of EbtoNo. The transceiver simulations show an RMS frequency error of 1.45 kHz.     

一种用于900MHz射频识别(RFID)读写器芯片的1.8VCMOS直接变频接收机

设计了针对解决900MHz RFID读写器收发机芯片中本地载波干扰问题而优化的直接变频接收机,并在0.18μm 1P6M混合信号CMOS工艺上实现验证.设计中使用了一种串联反馈结构的基带放大器以达到同时实现无源混频器输出缓冲,直流消除以及信号放大的功能.实际测量显示,该接收机的输入1dB压缩点为-4dBm,当中频信号解调信噪比要求为10dB时,可达到的灵敏度为-70dBm.该接收机与整个收发机集成在同一块芯片中,使用1.8V电源电压,工作时静态电流为90mA.     

W波段FMCW介质透镜天线的研究

介绍一种W波段调频连续波（FMCW）体制的介质透镜天线,其结构形式简单,性能稳定可靠,解决了调频连续波的较高收发隔离度的要求,天线的收发隔离度可达58dB以上。天线副瓣电平可达-24dB,电压驻波比在1GHz带宽内小于1．5,600MHz带宽内小于1．3,天线效率在整个带宽内可以达到70％以上。     

A 2.7-V 900-MHz/1.9-GHz dual-band transceiver IC for digitalwireless communication

A 2.7-V 900-MHz/1.9-GHz dual-band transceiver IC consisting of receive, transmit, and local oscillator (LO) sections is presented. The transmit section achieves an unwanted sideband suppression of -43 dBc, LO leakage of -59 dBc, and third-order spurious rejection of -70 dBc. The transmit output noise level is -165 dBc/Hz at a 20-MHz offset from the carrier. The on-chip very high-frequency oscillator has a phase-noise level of -106 dBc/Hz at 100-kHz offset when operating at 800 MHz. The receive section has 36 dB of gain with 36 dB of gain range in 12-dB steps. The transceiver IC has been fabricated using a 25-GHz f_t silicon bipolar process and is designed to operate over a supply-voltage range of 2.7-5.0 V     

A Dual-Antenna Phased-Array UWB Transceiver in 0.18-μm CMOS

A dual-antenna ultra-wideband (UWB) transceiver in 0.18-mum CMOS for mode-1 OFDM applications employs the techniques of antenna diversity and integrated RF selectivity to improve robustness to interferers. Optimal selectivity in receiver and band flatness in transmitter are achieved by on-chip calibration of each band. The packaged device achieves an overall noise figure of 4.7 dB, an IIP3 of -0.8 dBm, a TX P1 dB of 3.1 dBm, and an error vector magnitude (EVM) of -27.2 dB for 480 Mb/s. The transmit output spectrum is fully compliant with FCC mask for UWB without any external bandpass filter