具有自动频率校准的宽频率范围Σ-Δ小数频率综合器

A wide range fractional-N frequency synthesizer in 0.18μm RF CMOS technology is implemented. A switched-capacitors bank LC-tank VCO and an adaptive frequency calibration technique are used to expand the frequency range.A 16-bit third-order sigma-delta modulator with dither is used to randomize the fractional spur. The active area is 0.6 mm~2.The experimental results show the proposed frequency synthesizer consumes 4.3 raA from a single 1.8 V supply voltage except for buffers.The frequency range is 1.44-2.11 GHz and the frequency resolution is less than 0.4 kHz.The phase noise is -94 dBc/Hz @ 100 kHz and -121 dBc/Hz @ 1 MHz at the output of the prescaler with a loop bandwidth of approximately 120 kHz.The performance meets the requirements for the multi-band and multi-mode transceiver applications.     

高频谱纯度的小数分频频率合成器

小数分频频率合成器输出频率分辨率高,换频速度快。但合成信号频谱中存在着固有而严重的相位杂散,即小数杂散。本文分析了小数杂散产生的机理,推导了小数杂散的数学表达式,并首次给出了三位小数时实测的小数杂散大小。文中还给出了一种高频谱纯度的小数分频频率合成器系统框图及性能指标。数据表明,本文所用的相位补偿法在合成器整个输出范围内,对小数杂散有45dB以上的抑制。     

A 2.4-GHz monolithic fractional-N frequency synthesizer with robust phase-switching prescaler and loop capacitance multiplier

The design of a 2.4-GHz fully integrated /spl Sigma//spl Delta/ fractional-N frequency synthesizer in a 0.35-/spl mu/m CMOS process is presented. The design focuses on the prescaler and the loop filter, which are often the speed and the integration bottlenecks of the phase-locked loop (PLL), respectively. A 1.5-V 3-mW inherently glitch-free phase-switching prescaler is proposed. It is based on eight lower frequency 45/spl deg/-spaced phases and a reversed phase-switching sequence. The large integrating capacitor in the loop filter was integrated on chip via a simple capacitance multiplier that saves silicon area, consumes only 0.2 mW, and introduces negligible noise. The synthesizer has a 9.4% frequency tuning range from 2.23 to 2.45 GHz. It dissipates 16 mW and takes an active area of 0.35 mm/sup 2/ excluding the 0.5-mm/sup 2/ digital /spl Sigma//spl Delta/ modulator.     

A constant loop bandwidth in delta sigma fractional-N PLL frequency synthesizer with phase noise cancellation

This work presents the design of a new and unique design technique of constant loop bandwidth and phase-noise cancellation in a wideband ΔΣ fractional-N PLL frequency synthesizer. Phase noise performance of the proposed ΔΣ fractional-N PLL frequency synthesizer has been verified using CppSim simulator with the help of transistor level simulation results in Cadence SpecctreRF. Transient response of the proposed ΔΣ fractional-N PLL has been verified in transistor level simulation using Cadence SpectreRF in 0.13 μm standard CMOS process. The proposed phase-noise cancellation and constant loop bandwidth in wideband ΔΣ fractional-N PLL reduces the out of band phase noise by 18 dBc/Hz at 2 MHz offset frequency for a closed loop bandwidth of 1 MHz, when I_CP,max is equal to 2.6 mA. PLL locking time has been reduced with phase-noise cancellation and a constant loop bandwidth calibration circuits using the proposed CP unit current cell for the mismatch compensated PFD/DAC in wideband ΔΣ fractional-N PLL frequency synthesizer. Optimum phase noise performance can be achieved with the help of proposed design technique. Proposed ΔΣ fractional-N PLL frequency synthesizer is locked within 14.0 μs with an automatic frequency control circuit of the LC VCO and a constant loop bandwidth calibration circuit through the use of proposed CP unit current cell for the mismatch compensated PFD/DAC for the phase-noise cancellation in worst case condition of K_VFC = 10 and K_LBC = 150. Our new design technique can be extensively integrated for wideband fractional-N PLL for new type of wireless communication paradigm using the thinnest channel subharmonic transistor and low power devices, and it has the potential to open a new era of fractional-N PLLs for wideband application.     

A fractional-N frequency synthesizer for single-chip UHF RFID reader

A novel fractional-N frequency synthesizer which is based on delta sigma modulator (DSM) and specialized for single-chip UHF 860-to-960 MHz band radio frequency identification (RFID) reader is proposed in this paper. The fractional-N synthesizer is implemented in 0.18 μm CMOS process. The phase noise of the fractional-N synthesizer is approximately ?109 and ?129 dBc/Hz at 200 kHz and 1 MHz offset from 900 MHz operating frequency while drawing 9.6 mA from 1.8 V power supply. The synthesizer is evaluated by implementing it in a direct conversion RF front-end. The front-end features a noise figure of 3.5 dB and an input-referred third-order intercept point of 5 dBm.     

A high-frequency CMOS multi-modulus divider for PLL frequency synthesizers

A high-frequency divide-by-256–271 programmable divider is presented with the improved timing of the multi-modulus divider structure and the high-speed embedded flip-flops. The D flip-flop and logic flip-flop are proposed by using a fast pipeline technique, which contains single-phase, edge-triggered, ratioed, and high-speed technologies. The circuits achieve high-speed by reducing the capacitive load and sharing the delay between the combination logic blocks and the storage elements. By the way, it is suitable for realizing high-speed synchronous counters. The programmable divider using proposed flip-flops is measured in 0.25-μm CMOS technology with the operating clock frequency reaching as high as 4.7 GHz under the supply voltage of 3V.     

A 1.8-GHz CMOS fractional-N frequency synthesizer with randomized multiphase VCO

A 1.8 GHz fractional-N frequency synthesizer implemented in 0.6 /spl mu/m CMOS with an on-chip multiphase voltage-controlled oscillator (VCO) exhibits no spurs resulting from phase interpolation. The proposed architecture randomly selects output phases of a multiphase VCO for fractional frequency division to eliminate spurious tones. Measured phase noise at 1.715 GHz is lower than -80 dBc/Hz within a 20 kHz loop bandwidth and -118 dBc/Hz at 1 MHz offset with no fractional spurs above -70 dBc/Hz. The synthesizer has a frequency resolution step smaller than 10 Hz. The chip consumes 52 mW at 3.3 V and occupies 3.7 mm/spl times/2.9 mm.     

A fully integrated CMOS frequency synthesizer with charge-averagingcharge pump and dual-path loop filter for PCS- and cellular-CDMAwireless systems

A fully integrated CMOS frequency synthesizer for PCS- and cellular-CDMA systems is integrated in a 0.35-μm CMOS technology. The proposed charge-averaging charge pump scheme suppresses fractional spurs to the level of noise, and the improved architecture of the dual-path loop filter makes it possible to implement a large time constant on a chip. With current-feedback bias and coarse tuning, a voltage-controlled oscillator (VCO) enables constant power and low gain of the VCO. Power dissipation is 60 mW with a 3.0-V supply. The proposed frequency synthesizer provides 10-kHz channel spacing with phase noise of -121 dBc/Hz in the PCS band and -127 dBc/Hz in the cellular band, both at 1-MHz offset frequency     

用于无线传感器网络节点的小数分频频率综合器

This paper presents a fractional-N frequency synthesizer for wireless sensor network(WSN) nodes. The proposed frequency synthesizer adopts a phase locked loop(PLL) based structure, which employs an LC voltagecontrolled oscillator(VCO) with small VCO gain(KVCO) and frequency step(fstep) variations, a charge pump(CP)with current changing in proportion with the division ratio and a 20-bit △∑ modulator, etc. To realize constant KVCO and fstep, a novel capacitor sub-bands grouping method is proposed. The VCO sub-groups’ sizes are arranged according to the maximal allowed KVCOvariation of the system. Besides, a current mode logic divide-by-2 circuit with inside-loop buffers ensures the synthesizer generates I/Q quadrature signals robustly. This synthesizer is implemented in a 0.13 m CMOS process. Measurement results show that the frequency synthesizer has a frequency span from 2.07 to 3.11 GHz and the typical phase noise is 86:34 d Bc/Hz at 100 k Hz offset and 114:17 d Bc/Hz at 1 MHz offset with a loop bandwidth of about 200 k Hz, which meet the WSN nodes’ requirements.     

A 13.5-mW 5-GHz frequency synthesizer with dynamic-logic frequency divider

The adoption of dynamic dividers in CMOS phase-locked loops for multigigahertz applications allows to reduce the power consumption substantially without impairing the phase noise and the power supply sensitivity of the phase-locked loop (PLL). A 5-GHz frequency synthesizer integrated in a 0.25-/spl mu/m CMOS technology demonstrates a total power consumption of 13.5 mW. The frequency divider combines the conventional and the extended true-single-phase-clock logics. The oscillator employs a rail-to-rail topology in order to ensure a proper divider function. This PLL intended for wireless LAN applications can synthesize frequencies between 5.14 and 5.70 GHz in steps of 20 MHz. The reference spurs at 10-MHz offset are as low as -70 dBc and the phase noise is lower than -116 dBc/Hz at 1 MHz over the whole tuning range.     

Behavioral modeling and simulation of fractional-N frequency synthesizer

A set of behavioral voltage-domain verilogA/verilog models is proposed in the paper, based on mathematical models of building blocks and some simulation strategies. The models include nonlinear effects of building blocks and can accurately predict the dynamic or stable characteristic of the closed loop. A three-order ΣΔ fractional-N PLL based frequency synthesizer with a 1.9 GHz central output frequency is implemented with the presented way. Cadence SpectreVerilog simulation results show that the behavioral modeling can provide a great speed-up over the transistor-level simulation. Correspondingly, the phase noise, spurious tones and loop locked time can also be accurately predicted, so it is helpful to optimization design based on system-level.     

A fractional spur suppression technique in the fractional-N frequency synthesizer

A fractional spur suppression technique is presented based on the principle of spur generation, which makes the phase between the divider output and the reference be permanently coherent like integer-N frequency synthesizer, so a real lock is achieved. The spurious tones are strongly reduced without sacrificing the PLL bandwidth. The detailed scheme and corresponding key building blocks are deeply discussed. A 1.9 GHz frequency synthesizer with a 100 kHz bandwidth is implemented with the proposed way. SpectreVerilog simulation results show that the technique can reduce over 10 dBc/Hz spurious tones. So it is suitable for high spectral purity frequency synthesizer.     

A 14-b direct digital frequency synthesizer with sigma-delta noise shaping

This paper describes a 14-b direct digital frequency synthesizer (DDFS) utilizing a sigma-delta noise shaping technique to reduce spurs arising from phase truncation. A new phase accumulator architecture adopting a second-order sigma-delta modulator is proposed. The sigma-delta noise shaping eliminates periodicity inherent in the phase truncation error. With the proposed phase accumulator, the significant spurs are reduced, and the spectral characteristics of the DDFS are then determined by finite precision of sine-amplitude output. A prototype DDFS IC in 0.25-/spl mu/m CMOS was fabricated on 0.12-mm/sup 2/ die area. The measured spurious-free dynamic range (SFDR) is greater than 110 dB for 16-b phase value and 14-b sine-amplitude output. The fabricated IC consumes 100 mW with a 2.5-V supply, and correctly operates up to 250 MHz.     

A ring oscillator based frequency synthesizer without using frequency divider

A novel indirect frequency synthesizer (FS) circuit comprising a multiplexer (MUX) controlled ring oscillator (RO) and a Hogge phase detector has been proposed. The circuit will synthesize signals having better spectral purity and will consume less power compared to conventional indirect FS circuits. The MUX controlled RO will provide higher flexibility in frequency control and the voltage controlled oscillator (VCO) sensitivity can be varied easily to keep loop gain fixed for different values of synthesized signal frequencies. Hardware experimental results have been given to establish theoretical anticipations.     

A constant loop bandwidth fractional-N frequency synthesizer for GNSS receivers

正A constant loop bandwidth fractional-TV frequency synthesizer for portable civilian global navigation satellite system(GNSS) receivers implemented in a 130 nm 1P6M CMOS process is introduced.Via discrete working regions,the LC-VCO obtains a wide tuning range with a simple structure and small VCO gain.Spur suppression technology is proposed to minimize the phase offset introduced by PFD and charge pumps.The optimized bandwidth is maintained by an auto loop calibration module to adjust the charge pump current when the PLL output frequency changes or the temperature varies.Measurement results show that this synthesizer attains an in-band phase noise lower than -93 dBc at a 10 kHz offset and a spur less than -70 dBc;the bandwidth varies by±3%for all the GNSS signals.The whole synthesizer consumes 4.5 mA current from a 1 V supply,and its area(without the LO tested buffer) is 0.5 mm~2.     

用于WCDMA/ Bluetooth/ZigBee的分数频率综合器

本文用0.18μm RF-CMOS的工艺实现了一个用于WCDMA/Bluetooth/ZigBee的三模分数频率综合器,该综合器用了一个带噪声滤波的压控振荡器,且三种模式下带内相位噪声小于-80dBc/Hz 而1MHz的频偏处相位噪声则小于-115dBc/Hz. 该频率综合器在1.8V的供电电压下消耗电流21mA.三种模式下硬件共享大,面积小,仅为1.5mm×1.4mm. 本文给出了系统结构,电路设计及测试结果.     

A fractional-N frequency synthesizer for WCDMA/Bluetooth/ZigBee applications

esented.     

An analytical phase noise model of charge pump mismatch in sigma-delta frequency synthesizer

Although some papers have qualitatively analyzed the effect of charge pump mismatch on phase noise and spurs in sigma-delta fractional-N frequency synthesizer, few of them have addressed this topic quantitatively. An analytical model is proposed in this paper to describe the behavior of charge pump mismatch and the corresponding phase noise. Numerical simulation shows that this model is of high accuracy and can be applied to the analysis of in-band phase induced by the charge pump mismatch in sigma-delta fractional-N PLL frequency synthesizer. Most importantly, this model discloses that 6 dB reduction of in-band phase noise due to charge pump mismatch can be achieved by halving the charge pump mismatch ratio. After studying the typical topologies of sigma-delta modulators (SDM), we proposed some strategies on the selection of SDM in frequency synthesizer design. Our analytical model also indicates that eliminating the charge pump mismatch is one major path towards the in-band phase noise reduction of the sigma-delta frequency synthesizer. Xiaojian Mao was born in Jiangsu Province, China, in 1978. He received the B.S. degree in electronic engineering from Jilin University, Changchun, China, in 2000. He is currently pursuing the Ph.D. degree in circuits and systems at Department of Electronic Engineering of Tsinghua University, Beijing, China. His current research includes frequency synthesizers and phase-locking and clock recovery for high-speed data communications. And His PhD thesis title is “Design and Analysis of Sigma-Delta Fractional-N PLL Frequency Synthesizer.” Huazhong Yang received BS, MS, and PhD Degrees in electronics engineering from Tsinghua University, Beijing, in 1989, 1993, and 1998, respectively. He is a Professor and Head of the Circuits and Systems Division in the Department of Electronic Engineering at Tsinghua University, Beijing. His research interests include CMOS radio-frequency integrated circuits, VLSI system structure for digital communications and media processing, low-voltage and low-power circuits, and computer-aided design methodologies for system integration. He has authored and co-authored 6 books and more than 100 journals and conference papers. He was the winner of Chinas National Palmary Young Researcher Award in 2000. Hui Wang received the B.S. degree from Department of Radio Electronics, from Tsinghua University, Beijing, China. She was a visiting scholar at Stanford University, CA, USA from February 1991 to September 1992. Currently she is a Professor of the Circuits and Systems Division in the Department of Electronic Engineering and the deputy dean of academic affairs office at Tsinghua University, Beijing, China. Her research interests include modeling and simulation of radio-frequency CMOS integrated circuits, automatic design methodology for low voltage and low-power integrated circuits, and interconnect modeling and synthesis for deep submicron system-on-a-chip. She has authored and co-authored 4 books and over 70 papers. She was a primary research of TADS-C4 which gained a third-grade prize for the national progress in science and technology in China in 1993.     

A new PLL frequency synthesizer with high switching speed

A phase-locked loop (PLL) frequency synthesizer with high switching speed is proposed. Mobile communication networks are evolving towards microcellulars operating in narrowband TDMA and microwave bands to meet the rapidly increasing demands for both voice and data services. Therefore, synthesizers with high switching speed are required for the realization. However, it will be difficult for conventional synthesizers to provide switching times of shorter than 1 ms. The PLL synthesizer proposed is composed entirely of digital signal processors except for a voltage-controlled oscillator (VCO). The VCO control signal is derived by the subtraction of the linear reference phase and the feedback phase; therefore, it does not need the band-limited loop filter which limits the ability of the loop to switch fast. The experimental results show that it can provide switching times as short as 0.1 ms, which is 10²~10³ times higher than conventional PLL synthesizers, and spurs of less than -60 dB