A multimode 0.3-200-kb/s transceiver for the 433/868/915-MHz bands in 0.25-/spl mu/m CMOS

A fully integrated transceiver suitable for low-data-rate wireless telemetry and sensor networks operating in the license-free ISM frequency bands at 433, 868, or 915 MHz implemented in 0.25-/spl mu/m CMOS is presented. G/FSK, ASK, and OOK modulation formats are supported at data rates from 0.3 to 200 kb/s. The transceiver's analog building blocks include a low-noise amplifier, mixer, channel filter, received signal-strength indication, frequency synthesizer, voltage-controlled oscillator, and power amplifier. FSK demodulation is implemented using a novel digital complex-frequency correlator that operates over a wide modulation-index range and approximates matched filter detection performance. Automatic gain control, automatic frequency control, and symbol timing recovery loops are included on chip. Operating in the 915-MHz band in FSK mode at 9.6 kb/s, the receiver consumes 19.7 mA from a 3-V supply and achieves a sensitivity of -112.8dBm at 0.1% BER. The transmitter consumes 28.5 mA for an output power of 10 dBm and delivers up to 14 dBm.     

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     

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.     

A fully integrated UHF RFID reader SoC for handheld applications in the 0.18 μm CMOS process

A low cost fully integrated single-chip UHF radio frequency identification(RFID) reader SoC for short distance handheld applications is presented.The SoC integrates all building blocks—including an RF transceiver,a PLL frequency synthesizer,a digital baseband and an MCU—in a 0.18μm CMOS process.A high-linearity RX frontend is designed to handle the large self-interferer.A class-E power amplifier with high power efficiency is also integrated to fulfill the function of a UHF passive RFID reader.The measure...     

A 2.6-V, 44-MHz all-digital QPSK direct-sequence spread-spectrumtransceiver IC [wireless LANs]

In this paper, an all-digital differentially encoded quaternary phase shift keying (DEQPSK) direct sequence spread-spectrum (DSSS) transceiver is proposed. The transceiver consists of two parts: a baseband/IF spread-spectrum transmitter and a coherent intermediate frequency (IF) receiver. The center frequency of this IF receiver is 11 MHz and the sampling rate is 44 Msamples/s. Modulation/demodulation, carrier recovery, PN acquisition, and differential coding are all provided within a single chip. Functional optimization and architecture design were performed before layout implementation. The 0.8-μm N-well CMOS chip has a complexity of 56000 transistors with a core area of 3.5×3.5 mm². Power dissipation is 92 and 145 mW at 2.6 and 3.3 V, respectively     

A 1 V Wireless Transceiver for an Ultra-Low-Power SoC for Biotelemetry Applications

This paper presents a 1 V RF transceiver for biotelemetry and wireless body sensor network (WBSN) applications, realized as part of an ultra low power system-on-chip (SoC), the Sensiumtrade. The transceiver utilizes FSK/GFSK modulation at a data rate of 50 kbit/s to provide wireless connectivity between target sensor nodes and a central base-station node in a single-hop star network topology operating in the 862-870 MHz European short-range-device (SRD) and the 902-928 MHz North American Industrial, Scientific & Medical (ISM) frequency bands. Controlled by a proprietary media access controller (MAC) which is hardware implemented on chip, the transceiver operates half-duplex, achieving -102 dBm receiver input sensitivity (for 1E-3 raw bit error rate) and up to -7 dBm transmitter output power through a single antenna port. It consumes 2.1 mA during receive and up to 2.6 mA during transmit from a 0.9 to 1.5 V supply. It is fabricated in a 0.13 mum CMOS technology and occupies 7 mm² in a SoC die size of 4 times 4 mm².     

A 5-GHz direct-conversion CMOS transceiver utilizing automatic frequency control for the IEEE 802.11a wireless LAN standard

A fully integrated CMOS direct-conversion 5-GHz transceiver with automatic frequency control is implemented in a 0.18-/spl mu/m digital CMOS process and housed in an LPCC-48 package. This chip, along with a companion baseband chip, provides a complete 802.11a solution The transceiver consumes 150 mW in receive mode and 380 mW in transmit mode while transmitting +15-dBm output power. The receiver achieves a sensitivity of better than -93.7dBm and -73.9dBm for 6 Mb/s and 54 Mb/s, respectively (even using hard-decision decoding). The transceiver achieves a 4-dB receive noise figure and a +23-dBm transmitter saturated output power. The transmitter also achieves a transmit error vector magnitude of -33 dB. The IC occupies a total die area of 11.7 mm/sup 2/ and is packaged in a 48-pin LPCC package. The chip passes better than /spl plusmn/2.5-kV ESD performance. Various integrated self-contained or system-level calibration capabilities allow for high performance and high yield.     

低功耗低误码率的传感器网络节点芯片数字基带设计

本文针对无线传感器网络节点片上系统特点和需求,研究一种低功耗、高性能、低误码率的数字基带(Easibaseband),提出了一种复用加法器和乘法器的设计方法,实现了匹配滤波器,可节省硬件资源并提高系统性能;提出了一种自适应门限的自动增益控制方法,可配合软硬件协同的工作方式,节省接收机的功耗;提出了采用自适应门限的施密特触发器方式进行信号相位判决的方法,降低了解调误码率.本设计在Xilinx的Spartan-3E FPGA上验证并实现,测试结果表明,本收发机的数据传输率可达到111kb/s并支持ISM2.4GHz频段的射频芯片,比传统的并行滤波器节省了5/6的硬件资源,比不采用自动增益控制节省了10.8%的接收机功耗,在信噪比13dB时,误码率在10-4以下,远低于WiseNET的接收误码率.     

A 0.25-/spl mu/m CMOS quad-band GSM RF transceiver using an efficient LO frequency plan

This paper describes a single-chip CMOS quad-band (850/900/1800/1900 MHz) RF transceiver for GSM/GPRS applications. It is the most important design issue to maximize resource sharing and reuse in designing the multiband transceivers. In particular, reducing the number of voltage-controlled oscillators (VCOs) required for local oscillator (LO) frequency generation is very important because the VCO and phase-locked loop (PLL) circuits occupy a relatively large area. We propose a quad-band GSM transceiver architecture that employs a direct conversion receiver and an offset PLL transmitter, which requires only one VCO/PLL to generate LO signals by using an efficient LO frequency plan. In the receive path, four separate LNAs are used for each band, and two down-conversion mixers are used, one for the low bands (850/900 MHz) and the other for the high bands (1800/1900 MHz). A receiver baseband circuit is shared for all four bands because all of their channel spaces are the same. In the transmit path, most of the building blocks of the offset PLL, including a TX VCO and IF filters, are integrated. The quad-band GSM transceiver that was implemented in 0.25-/spl mu/m CMOS technology has a size of 3.3/spl times/3.2 mm/sup 2/, including its pad area. From the experimental results, we found that the receiver provides a maximum noise figure of 2.9 dB and a minimum IIP3 of -13.2dBm for the EGSM 900 band. The transmitter shows an rms phase error of 1.4/spl deg/ and meets the GSM spectral mask specification. The prototype chip consumes 56 and 58 mA at 2.8 V in the RX and TX modes, respectively.     

A direct-conversion WLAN transceiver baseband with DC offset compensation and carrier leakage reduction

A dual-band direct-conversion WLAN transceiver baseband compliant with the IEEE 802.11 a/b/g standards is described.Several critical techniques for receiver DC offset compensation and transmitter carrier leakage rejection calibration are presented that enable the direct-conversion architecture to meet all WLAN specifications.The receiver baseband VGA provides 62 dB gain range with steps of 2 dB and a DC offset cancellation circuit is introduced to remove the offset from layout and self-mixing.The calibra...     

An ultralow-power UHF transceiver integrated in a standard digitalCMOS process: transmitter

In the first part of the paper, also in this issue of the JOURNAL, the design of the frequency synthesizer and receiver section of an FSK transceiver was described. It operates in the 434-MHz ISM (Industrial, Scientific, Medical) band and is realized in a standard digital 0.5-μm CMOS process. This companion paper focuses on the realization of the transmitter section. It includes a power amplifier, an upconverter, and the circuit generating the baseband quadrature signals with a continuous phase modulation. The overall measured efficiency of the packaged circuit is higher than 38% for a 1.2-V supply and an output power reaching 10 dBm at 433 MHz. The system is designed to still operate at 1-V supply, delivering more than 1 mW with an efficiency higher than 15%     

Analysis and design of a frequency-hopped spread-spectrumtransceiver for wireless personal communications

Personal communications services (PCS) require low-power radio technologies. One such transceiver architecture employing frequency-hopped spread-spectrum techniques is presented. System features such as antenna diversity with equal-gain combining and sequential hop combining are incorporated into the transceiver design to achieve robust wireless digital data transmission over fading channels. A direct-conversion architecture from radio frequency (RF) to baseband reduces the overall power consumption by eliminating intermediate frequency (IF) components. High-rate frequency hopping with frequency-shift keying (FSK) modulation is implemented using a direct digital frequency synthesis technique. A multiplierless correlation FSK detector, suitable for direct-conversion receivers, has been designed for quadrature noncoherent detection. Robust acquisition algorithms based on energy detection and pattern matching and tracking architectures using digital phase-locked loops are also described for system synchronization. The proposed transceiver is well-suited for low-power PCS applications and other portable wireless communications     

低功耗人体通信射频收发器的设计

Human body communication is proposed as a promising body proximal communication technology for body sensor networks. To achieve low power and small volume in the sensor nodes, a Radio Frequency (RF) application-specific integrated circuit transceiver for Human Body Communication (HBC) is presented and the characteristics of HBC are investigated. A high data rate On-Off Keying (OOK)/Frequency-Shift Keying (FSK) modulation protocol and an OOK/FSK demodulator circuit are introduced in this paper, with a data-rate-to-carrier-frequency ratio up to 70% . A low noise amplifier is proposed to handle the dynamic range problem and improve the sensitivity of the receiver path. In addition, a low power automatic-gain-control system is realized using a novel architecture, thereby rendering the peak detector circuit and loop filter unnecessary. Finally, the complete chip is fabricated. Simulation results suggest receiver sensitivity to be -75 dBm. The transceiver shows an overall power consumption of 3.2 mW when data rate is 5 Mbps, delivering a P1 dBoutput power of -30 dBm.     

A 1.2 mW RDS receiver for portable applications

A 0.9 V 1.2 mA fully integrated radio data system (RDS) receiver for the 88-108 MHz FM broadcasting band is presented. Requiring only a few external components (matching network, VCO inductors, loop filter components), the receiver, which has been integrated in a standard digital 0.18 /spl mu/m CMOS technology, achieves a noise figure of 5 dB and a sensitivity of -86dBm. The circuit can be configured and the RDS data retrieved via an I/sup 2/C interface so that it can very simply be used as a peripheral in any portable application. A 250 kHz low-IF architecture has been devised to minimize the power dissipation of the baseband filters and FM demodulator. The frequency synthesizer consumes 250 /spl mu/A, the RF front-end 450 /spl mu/A while providing 40 dB of gain, the baseband filter and limiters 100 /spl mu/A, and the FM and BPSK analog demodulators 300 /spl mu/A. The chip area is 3.6 mm/sup 2/.     

A single-chip tri-band (2100, 1900, 850/800 MHz) WCDMA/HSDPA cellular transceiver

This paper describes the design and performance of the first tri-band (2100, 1900, 800/850 MHz) single-chip 3G cellular transceiver IC for worldwide use. The transceiver has been designed to meet all narrowband blocker, newly proposed Adjacent Channel II, and Category 10 HSDPA (High Speed Downlink Packet Access) requirements. The design is part of a reconfigurable reference platform for multi-band, multi-mode (GSM/EDGE + WCDMA) radios. The zero-IF receiver is comprised of a novel multi-band quadrature mixer, seventh-order baseband filtering, and a novel DC offset correction scheme, which exhibits no settling time or peak switching transients after gain steps. The receiver lineup is designed to optimize HSDPA throughput and minimize sensitivity to analog baseband filter bandwidth variations. The direct-launch transmitter is made up of a third-order baseband filter, an I/Q modulator with variable gain, an integrated transformer, an RF variable gain amplifier, and a power amplifier driver. At +9.5-dBm output power, the transmitter achieves an error vector magnitude (EVM) of 4%. Fractional-N synthesizers achieve fast lock times of 50 /spl mu/s (150 /spl mu/s) within 20 ppm (0.1 ppm). Automatically calibrated, integrated VCOs achieve a 1.6-GHz tuning range to facilitate coverage over all six 3GPP frequency bands. The IC draws 34 mA in receive (18-mA receiver plus 16-mA fractional-N PLL/VCO) and 50 to 62 mA in transmit (-76 dBm to +9.5 dBm), including PLL/VCO, using a 2.775-V supply voltage. The RF transceiver is integrated with the baseband signal processing and associated passives in a 165-pad package, resulting in the first tri-band 3G radio transceiver with a digital interface which requires no external components.     

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.     

一种高性能CMOS单片中频接收机

研制了一种CM O S低压低功耗中频接收机芯片,它包含混频器、限幅放大器、解调器以及场强指示、消音控制等模块,可用于短距离的FM/FSK信号的接收和解调。该接收机采用1st s ilicon 0.25μm CM O S工艺,芯片的测试结果表明整机接收灵敏度为-103 dBm,最高输入射频频率可以达到100 MH z,解调器的线性解调范围为±10 kH z,典型鉴频灵敏度为40 mV/kH z,输入FM信号(调频指数3,信号频率1 kH z)时解调信号的SFDR为41.3 dB。芯片的工作电源电压范围为2~4 V,工作电流3 mA,有效面积0.25 mm2。     

光纤多种业务传输系统

本文给出了一种实用的光纤多种业务传输系统设计。在此系统中,彩电用0～6MHz基带传输,语音用频率调制,其中心频率为6.5MHz。数据采用高频FSK调制,数据速率f_(?)≤19.2kb/s,副载频率为10.7MHz。     

A 434/868 MHz CMOS low-IF receiver with I/Q imbalance calibration for SRDs application

A receiver for SRDs implemented by the 0.35μm CMOS process is presented. The receiver, together with the ADC, power amplifier (PA), frequency synthesizer and digital baseband has been integrated into a single chip solution. Low cost and low power requirements are met by optimizing the receiver architecture and circuit topology. A simple mixed-signal mode I/Q imbalance calibration circuit is proposed to enhance the IRR (image rejection ratio) so as to raise the BER. From a single 3 V power supply, the receiver consumes 5.9 mA. The measurement result shows that the receiver achieves reference sensitivity of--60 dBm and a control gain of 60 dB. The S<,11> reaches-20 dB at 433 MHz and-10 dB at 868 MHz without off-chip impedance match network. The die area is only 2 mm2 including the bias circuit.     

一种FSK数字解调器的结构与芯片设计

设计了一种基于高性能频移键控(FSK)数字解调器的无线鼠标接收方芯片,该芯片整合了无线解调电路和接口控制电路,能够自动识别PS/2和USB接口。解调器采用一种新颖的全数字方案,包括抽取滤波器、数字锁相环(DPLL)、位时钟恢复和自动频率控制(AFC)等部分,可用于频移键控信号的解调。芯片采用SMIC0.35μmCMOS工艺流片,测试结果表明,解调器性能在Eb/No=8dB时,误码率为10-3,接收机灵敏度为-102dBm,同步范围≤±4.9%Rb(Rb为系统数据速率),AFC范围≤±32%Rb,这些特性完全符合无线鼠标接收机的要求。