A 27-mW CMOS fractional-N synthesizer using digital compensationfor 2.5-Mb/s GFSK modulation

A digital compensation method and key circuits are presented that allow fractional-N synthesizers to be modulated at data rates greatly exceeding their bandwidth. Using this technique, a 1.8-GHz transmitter capable of digital frequency modulation at 2.5 Mb/s can be achieved with only two components: a frequency synthesizer and a digital transmit filter. A prototype transmitter was constructed to provide proof of concept of the method; its primary component is a custom fractional-N synthesizer fabricated in a 0.6-μm CMOS process that consumes 27 mW. Key circuits on the custom IC are an on-chip loop filter that requires no tuning or external components, a digital MASH Σ-Δ modulator that achieves low power operation through pipelining, and an asynchronous, 64-modulus divider (prescaler). Measurements from the prototype indicate that it meets performance requirements of the digital enhanced cordless telecommunications (DECT) standard     

A 0.65-V 2.5-GHz Fractional-N Synthesizer With Two-Point 2-Mb/s GFSK Data Modulation

We present ultra-low-voltage circuit design techniques for a fractional-N RF synthesizer with two-point modulation which was realized in 90-nm CMOS using only regular ${rm V}_{rm T}$ devices.; the voltage controlled oscillator, phase-frequency detector and charge pump operate from a 0.5 $~$V supply while the divider uses a 0.65$~$V supply. The frequency synthesizer achieves a phase noise better than $-$120 dBc/Hz at 3 MHz, while consuming 6 mW. A calibration technique to equalize the gain between the two modulation ports is introduced and enables phase/frequency modulation beyond the loop bandwidth of the phase-locked loop. Measurement results for 2-Mb/s GFSK modulation are presented.      

A GMSK modulator using a ΔΣ frequencydiscriminator-based synthesizer

This paper describes a new transmitter architecture suitable for wideband GMSK modulation. The technique uses direct modulation of ΔΣ frequency discriminator (ΔΣFD)-based synthesizer to produce the modulated RF signal without any up-conversion. Digital equalization is used to extend the modulation data rate far beyond the synthesizer closed-loop BW. A prototype 1.9-GHz GSM transmitter was constructed consisting of a ΔΣFD-based synthesizer and a digital transmit filter. The synthesizer consists of an 0.8-μm BiCMOS ΔΣFD chip, a digital signal processor FPGA, and an off-chip D/A converter, filter, and VCO. Measured results, using 271-kbit/s GSM modulation, demonstrate data rates well in excess of the 30-kHz synthesizer closed-loop BW are possible with digital equalization. Without modulation, the synthesizer exhibits a -76-dBc spurious noise level and a close-in phase noise of -74 dBc/Hz     

应用于2Mb/s GMSK调制的CMOS低功耗全差分Sigma-Delta频率综合器

设计了应用于GMSK调制,工作在2.4GHz,CMOS全差分的∑-△频率综合器.调制器中采用预补偿的分数N锁相环.推导了Ⅱ型三阶锁相环的传输函数,并指出影响环路传输函数的重要参数.介绍了校准重要的环路参数的方法.锁相环设计中采用差分调节的LC压控振荡器和全差分的电荷泵.设计的电路利用0.18μm 1P6M CMOS工艺进行仿真.由于锁相环的组成模块中采用了低功耗设计,锁相环的功耗仅为11mW左右,调制器的数据率达到2Mb/s.     

A 960-Mb/s/pin interface for skew-tolerant bus using low jitter PLL

This paper describes an I/O scheme for use in a high-speed bus which eliminates setup and hold time requirements between clock and data by using an oversampling method. The I/O circuit uses a low jitter phase-locked loop (PLL) which suppresses the effect of supply noise. Measured results show peak-to-peak jitter of 150 ps and r.m.s. jitter of 15.7 ps on the clock line. Two experimental chips with 4-pin interface have been fabricated with a 0.6 μm CMOS technology, which exhibits the bandwidth of 960 Mb/s per pin     

Higher order Σ-Δ modulation encoding for design ofmultiplierless FIR filters

A technique is presented for the design of multiplierless FIR filters with canonical signed digit (CSD) coefficients based on higher-order Σ-Δ modulation with a CSD quantiser (Σ-Δ-CSD). The proposed algorithm requires little computational resources and is capable of designing more types of filters and providing better performance than the previously proposed first-order method     

All-digital reverse modulation architecture based carrier recoveryimplementation for GMSK and compatible FQPSK

A carrier recovery circuit implementation with an all-digital reverse modulation approach for coherent detection in the GSM/GMSK system as well as the GMSK compatible improved efficiency cross-correlated FQPSK system is presented. The proposed carrier recovery implementation utilizes all-digital reverse modulation circuit in a feedback loop to remove the modulated signal from the received intermediate frequency (IF) signal and to estimate the phase error of this carrier signal using a phase-locked loop (PLL). The digital reverse modulation approach avoids the multipliers required in an analog reverse modulation design, so that it can be implemented in a single chip FPGA. Hardware implementation of the coherent detection demonstrates that cross-correlated FQPSK is completely compatible with GMSK in the system performance and the receiver structure for GSM. Experimental performance evaluations show that the proposed carrier recovery circuit provides a Bit Error Rate (BER) performance within 0.3 dB in a non-linearly amplified channel corrupted by additive white Gaussian noise (AWCN) as compared with the simulated performance of the GSM/GMSK system     

A 400-Ms/s frequency translating bandpass sigma-delta modulator

A bandpass Σ-Δ modulator is described in this paper that uses frequency translation inside the Σ-Δ modulator loop to take advantage of the attributes of both continuous-time and discrete-time circuits. A CMOS direct-conversion modulator digitizes a 200 kHz intermediate-frequency signal centered at 100 MHz and produces baseband I/Q outputs with a peak signal-to-noise ratio of 54 dB. Images due to I/Q mismatches are suppressed by 50 dB. This 0.35-μm digital CMOS chip operates from a 2.7/3.3-V supply, dissipates 330 mW, and occupies 3.2 mm²     

A 3-V, 0.35-/spl mu/m CMOS Bluetooth receiver IC

A fully integrated CMOS low-IF Bluetooth receiver is presented. The receiver consists of a radio frequency (RF) front end, a phase-locked loop (PLL), an active complex filter, a Gaussian frequency shift keying (GFSK) demodulator, and a frequency offset cancellation circuit. The highlights of the receiver include a low-power active complex filter with a nonconventional tuning scheme and a high-performance mixed-mode GFSK demodulator. The chip was fabricated on a 6.25-mm/sup 2/ die using TSMC 0.35-/spl mu/m standard CMOS process. -82 dBm sensitivity at 1e-3 bit error rate, -10 dBm IIP3, and 15 dB noise figure were achieved in the measurements. The receiver active current is about 65 mA from a 3-V power supply.     

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.     

Fractional Multi‐bit Differential Detection Technique for Continuous Phase Modulation

A new low‐complexity differential detection technique, fractional multi‐bit differential detection (FMDD), is proposed in order to improve the performance of continuous phase modulation (CPM) signals such as Gaussian minimum shift keying (GMSK) and Gaussian frequency shift keying (GFSK). In comparison to conventional one‐bit differential detected (1DD) GFSK, the FMDD‐employed GFSK provides a signal‐to‐noise ratio advantage of up to 1.8 dB in an AWGN channel. Thus, the bit‐error rate performance of the proposed FMDD is brought close to that of an ideal coherent detection while avoiding the implementation complexity associated with the carrier recovery. In the adjacent channel interference environment, FMDD achieves an even larger SNR advantage compared to 1DD.     

A 17-mW transmitter and frequency synthesizer for 900-MHz GSM fully integrated in 0.35-/spl mu/m CMOS

A fractional-N phase-locked loop (PLL) serves as a Gaussian minimum-shift keying (GMSK) transmitter and a receive frequency synthesizer for GSM. The entire transmitter/synthesizer is fully integrated in 0.35-/spl mu/m CMOS and consumes 17.4 and 12 mW from 2.5 V in the transmit and receive modes, respectively, including an on-chip voltage-controlled oscillator. The circuit meets GSM specifications on modulation accuracy in transmit mode, and measured phase noise from the closed-loop PLL is -148 dBc/Hz and -162 dBc/Hz, respectively, at 3- and 20-MHz offset. Worst case spur at 13-MHz offset is -77 dBc.     

A Mixed-Loop CMOS Analog GFSK Modulator With Tunable Modulation Index

A new low-power analog Gaussian frequency-shift keying (GFSK) modulator is proposed and implemented in 0.18-CMOS process based on an analog computer implementation of the FM differential equation. The mixed-loop modulation approach is proposed to achieve high data rate and stable carrier frequency. The core of the GFSK modulator is a tunable harmonic oscillator consisting of two G_m-C integrators, whose center frequency can be adjusted by using the on-chip tunable phase-locked-loop (PLL) technique. A simple nonlinear resistor is used to maintain the constant output amplitude. The modulator operates at the center frequency of 2 MHz with the 0.1-0.55 tunable modulation index at 1-Mbps data rate. The modulator draws about 1.8 mA from the 1.8-V power supply and could achieve 2-Mbps data rate with the total harmonic distortion less than 3%.     

A 2-V, 1.8-GHz BJT phase-locked loop

This paper describes the design of a bipolar junction transistor phase-locked loop (PLL) for ΣΔ fractional-N frequency-synthesis applications. Implemented in a 0.8-μm BiCMOS technology, the PLL can operate up to 1.8 GHz while consuming 225 mW of power from a single -2-V supply. The entire LC-tuned negative-resistance variable-frequency oscillator is integrated on the same chip. A differential low-voltage current-mode logic circuit configuration is used in most of the PLL's functional blocks to minimize phase jitter and achieve low-voltage operation. The multimodulus frequency divider is designed to support multibit digital modulation. The new phase and frequency detector and loop filter contain only npn transistors and resistors and thus achieve excellent resolution in phase comparison. When phase locked to a 53.4-MHz reference clock, the measured phase noise of the 16-GHz output is -91 dBc/Hz at 10-kHz offset. The frequency switching time from 1.677 to 1.797 GHz is 150 μs. Die size is 4300×4000 μm², including the passive loop filter     

Σ-Δ插值型A/D转换器的结构优化设计

该文提出了一种新的通用高阶稳定的∑-△插值型A/D转换器的优化设计算法.该算法采用状态空间下通用的插值型结构,研究了设计原理和设计的详细过程,给出了传输函数变换和稳定条件,实现了零点优化和巴特沃思极点的噪声传递函数.在结构系数的实现中,采用能量增量最小的优化算法,使A/D转换器具有更佳的稳定性能.最后,通过例子验证了该方法的有效性.     

A 2-Mb/s 256-state 10-mW rate-1/3 Viterbi decoder

This paper presents a low-power bit-serial Viterbi decoder chip with the code rate r=1/3 and the constraint length K=9 (256 states) for next generation wireless communication applications. The architecture of the add-compare-select (ACS) module is based on the bit-serial arithmetic and implemented with the pass transistor logic circuit. A cluster-based ACS placement and state metric routing topology is described for the 256 bit-serial ACS units, which achieves very high area efficiency. In the trace-back operation, a power efficient trace-back scheme, allowing higher memory read access rate than memory write in a time-multiplexing method, is implemented to reduce the number of iterations required to generate a decoded output. In addition, a low-power application-specific memory suitable for the function of survivor path memory has also been developed. The chip's core, implemented using 0.5-μm CMOS technology, contains approximately 200 K transistors and occupies 2.46 mm by 4.17 mm area. This chip can achieve the decode rate of 20 Mb/s under 3.3 V and 2 Mb/s under 1.8 V. The measured power dissipation at 2 Mb/s under 1.8 V is only about 9.8 mW. The Viterbi decoder presented here can be applied to next generation wide-band code division multiple access (W-CDMA) systems     

A monolithic 156 Mb/s clock and data recovery PLL circuit using thesample-and-hold technique

The PLL circuit described here performs the function of data and clock recovery for random data patterns by using a sample-and-hold technique, and four component circuits (a phase comparator, a delay circuit, a voltage-controlled oscillator, and a S/H switch with a low-pass-filter) were specially designed to further stabilize the PLL operation. A test chip fabricated using Si bipolar process technology demonstrated error-free operation with an input of 2²³-1 PRBS data at 156 Mb/s. The rms data pattern jitter was reduced to only 1.2 degrees with only an external power supply bypass capacitor     

A 622-Mb/s bit/frame synchronizer for high-speed backplane datacommunication

A compact 622-Mb/s/port bit/frame synchronizer is presented. Sampling equally-phased clocks from a phase-locked loop (PLL) at the data transition edges, the bit synchronizer selects the optimum one as the extracted clock. An elastic serial-to-parallel converter is used for the frame synchronization. The circuit is designed for a 32-port ATM switch chip, achieving 622-Mb/s port capacity by four parallel 156-Mb/s bits. Using 0.5-μm CMOS technology, the circuit was verified by simulations. The bit synchronizer consumes only 15 mW under typical conditions     

A 3.5 in 230 Mbytes read-channel chip set for magneto-optical diskdrives

A read-channel chip set for rewritable 3.5 in 230 Mbytes magneto-optical disk drives (MOD) is presented. The front-end chip includes an automatic gain control (AGC) circuit, a programmable six-pole two-zero equiripple filter/equalizer, a DC restore circuit, and pulse detectors. The back-end contains a frequency synthesizer phase-locked loop (PLL) and a data separator PLL with 3:1 operating range to support a constant density recording with 8-24 Mb/s data rate (or code rate of 16 to 48 Mb/s) in (2, 7) run-length limited (RLL) encoding format. The architecture of the chip provides high degree of programmability through a serial microprocessor interface, fast switching (<1 μs) between sector mark and data detector modes, and four levels of power management in a 1.5 μm 4 GHz BiCMOS process. With a nominal power supply of 5 V, the chip set dissipates 600 mW during normal operation and 1 mW during sleep mode     

A 40 Gb/s Clock and Data Recovery Module with Improved Phase‐Locked Loop Circuits

A 40 Gb/s clock and data recovery (CDR) module for a fiber‐optic receiver with improved phase‐locked loop (PLL) circuits has been successfully implemented. The PLL of the CDR module employs an improved D‐type flip‐flop frequency acquisition circuit, which helps to stabilize the CDR performance, to obtain faster frequency acquisition, and to reduce the time of recovering the lock state in the event of losing the lock state. The measured RMS jitter of the clock signal recovered from 40 Gb/s pseudo‐random binary sequence (2³¹‐1) data by the improved PLL clock recovery module is 210 fs. The CDR module also integrates a 40 Gb/s D‐FF decision circuit, demonstrating that it can produce clean retimed data using the recovered clock.