应用于60-GHz无线通信的全差分锁相环频率综合器

A 40-GHz phase-locked loop(PLL) frequency synthesizer for 60-GHz wireless communication applications is presented. The electrical characteristics of the passive components in the VCO and LO buffers are accurately extracted with an electromagnetic simulator HFSS. A differential tuning technique is utilized in the voltage controlled oscillator(VCO) to achieve higher common-mode noise rejection and better phase noise performance. The VCO and the divider chain are powered by a 1.0 V supply while the phase-frequency detector(PFD)and the charge pump(CP) are powered by a 2.5 V supply to improve the linearity. The measurement results show that the total frequency locking range of the frequency synthesizer is from 37 to 41 GHz, and the phase noise from a 40 GHz carrier is –97.2 d Bc/Hz at 1 MHz offset. Implemented in 65 nm CMOS, the synthesizer consumes a DC power of 62 m W, including all the buffers.     

GHz band frequency hopping PLL-based frequency synthesizers

In this paper we describe a full-integrated circuit containing all building blocks of a completed PLL-based synthesizer except for low pass filter（LPF）. The frequency synthesizer is designed for a frequency hopping （FH） transceiver operating up to 1.5 GHz as a local oscillator. The architecture of Voltage Controlled Oscillator （VCO） is optimized to get better performance, and a phase noise of -111.85-dBc/Hz @ 1 MHz and a tuning range of 250 MHz are gained at a centre frequency of 1.35 GHz. A novel Dual-Modulus Prescaler（DMP） is designed to achieve a very low jitter and a lower power. The settling time of PLL is 80 μs while the reference frequency is 400 KHz. This monolithic frequency synthesizer is to integrate all main building blocks of PLL except for the low pass filter, with a maximum VCO output frequency of 1.5 GHz, and is fabricated with a 0.18 μm mixed signal CMOS process. Low power dissipation, low phase noise, large tuning range and fast settling time are gained in this design.     

压控振荡器相位噪声、功耗和频率调谐特性的设计优化

To meet the requirements of the low power Zigbee system, VCO design optimizations of phase noise, power consumption and frequency tuning are discussed in this paper. Both flicker noise of tail bias transistors and up-conversion of flicker noise from cross-coupled pair are reduced by improved self-switched biasing technology, leading to low close-in phase noise. Low power is achieved by low supply voltage and triode region biasing. To linearly tune the frequency and get constant gain, distributed varactor structure is adopted. The proposed VCO is fabricated in SMIC 0.18-μm CMOS process. The measured linear tuning range is from 2.38 to 2.61 GHz. The oscillator exhibits low phase noise of -77.5 dBc/Hz and -122.8 dBc/Hz at 10 kHz and 1 MHz offset, respectively, at 2.55 GHz oscillation frequency while dissipating 2.7 mA from 1.2 V supply voltage, which well meet design specifications.     

一种应用于GNSS接收机的低噪声和低杂散频率综合器

A low phase noise and low spur phase locked loop （PLL） frequency synthesizer for use in global navigation satellite system （GNSS） receivers is proposed. To get a low spur, the symmetrical structure of the phase frequency detector （PFD） produces four control signals, which can reach the charge pump （CP） simultaneously, and an improved CP is realized to minimize the charge sharing and the charge injection and make the current matched. Additionally, the delay is controllable owing to the programmable PFD, so the dead zone of the CP can be eliminated. The output frequency of the VCO can be adjusted continuously and precisely by using a programmable LC-TANK. The phase noise of the VCO is lowered by using appropriate MOS sizes. The proposed PLL frequency synthesizer is fabricated in a 0.18 μm mixed-signal CMOS process. The measured phase noise at 1 MHz offset from the center frequency is -127.65 dBc/Hz and the reference spur is -73.58 dBc.     

一种基于环形振荡器的双环路锁相环

A dual-loop phase-locked loop（PLL）for wideband operation is proposed.The dual-loop architecture combines a coarse-tuning loop with a fine-tuning one,enabling a wide tuning range and low voltage-controlled oscillator（VCO）gain without poisoning phase noise and reference spur suppression performance.An analysis of the phase noise and reference spur of the dual-loop PLL is emphasized.A novel multiple-pass ring VCO is designed for the dual-loop application.It utilizes both voltage-control and current-control simultaneously in the delay cell. The PLL is fabricated in Jazz 0.18-μm RF CMOS technology.The measured tuning range is from 4.2 to 5.9 GHz.It achieves a low phase noise of–99 dBc/Hz@1 MHz offset from a 5.5 GHz carrier.     

一种应用于频率综合器的全差分电荷泵的设计与噪声分析

A fully-differential charge pump（FDCP）with perfect current matching and low output current noise is realized for phase-locked loops（PLLs）.An easily stable common-mode feedback（CMFB）circuit which can handle high input voltage swing is proposed.Current mismatch and current noise contribution from the CMFB circuit is minimized.In order to optimize PLL phase noise,the output current noise of the FDCP is analyzed in detail and calculated with the sampling principle.The calculation result agrees well with the simulation.Based on the noise analysis,many methods to lower output current noise of the FDCP are discussed.The fully-differential charge pump is integrated into a 1–2 GHz frequency synthesizer and fabricated in an SMIC CMOS 0.18μm process.The measured output reference spur is–64 dBc to–69 dBc.The in-band and out-band phase noise is–95 dBc/Hz at 3 kHz frequency offset and–123 dBc/Hz at 1 MHz frequency offset respectively.     

一种应用于无线局域网具有3.01-3.82 GHz频率范围和6.29%调谐增益变化的CMOS LC压控振荡器

A wideband low-phase-noise LC voltage-controlled oscillator （VCO） with low VCO gain （Kvco） vari- ation for WLAN fractional-N frequency synthesizer application is proposed and designed on a 0.13-μm CMOS process. In order to achieve a low Kvco variation, an extra switched varactor array was added to the LC tank with the conventional switched capacitor array. Based on the proposed switched varactor array compensation technique, the measured Kvco is 43 MHz/V with only 6.29% variation across the entire tuning range. The proposed VCO provides a tuning range of 23.7% from 3.01 to 3.82 GHz, while consuming 9 mA of quiescent current from a 2.3 V supply. The VCO shows a low phase noise of-121.94 dBc/Hz at 1 MHz offset, from the 3.6 GHz carrier.     

一种可实现锁相环快速自校准的VCO子带选择电路

A novel voltage controlled oscillator （VCO） sub-band selection circuit to achieve fast phase locked loop （PLL） calibration is presented, which reduces the calibration time by measuring the period difference directly and accomplishing an efficient search for an optimum VCO sub-band. The sub-band selection circuit was implemented in a 0.18 μm CMOS logic process with a PLL using an 8 sub-band VCO. The measured calibration time is less than 3 μs in a VCO frequency range from 600 MHz to 2 GHz. The proposed circuit consumes 0.64 mA at most.     

一种三阶环形压控振荡器的分析设计

This paper describes a large tuning range low phase noise voltage-controlled ring oscillator(ring VCO)based on a different cascade voltage logic delay cell with current-source load to change the current of output node.The method for optimization is presented.Furthermore,the analysis of performance of the proposed ring VCO is confirmed by the measurement results.The three-stage proposed ring VCO was fabricated in the 180-nm CMOS process of SMIC.The measurement results show that the oscillator frequency of the ring VCO is from 0.770 to5.286 GHz and the phase noise is 97.93 dBc/Hz at an offset of 1 MHz from 5.268 GHz with a total power of15.1 mW from a 1.8 V supply while occupying only 0.00175 mm2of the core die area.     

具有工艺补偿和毛刺消除功能的快速锁定频率预置锁相环频率综合器

This paper proposes a fast-settling frequency-presetting PLL frequency synthesizer. A mixedsignal VCO and a digital processor are developed to accurately preset the frequency of VCO and greatly reduce the settling time. An auxiliary tuning loop is introduced in order to reduce reference spur caused by leakage current. The digital processor can automatically compensate presetting frequency variation with process and temperature, and control the operation of the auxiliary tuning loop. A 1.2 GHz integer-N synthesizer with 1 MHz reference input was implemented in a 0.18 μm process. The measured results demonstrate that the typical settling time of the synthesizer is less than 3 μs, and the phase noise is –108 dBc/Hz@1MHz. The reference spur is –52 dBc.     

一种宽带低相噪频率合成器的设计方法研究

提出了一种宽带低相噪频率合成器的设计方法.采用了数字锁相技术,该锁相技术主要由锁相环（phase locked loop,PLL）芯片、有源环路滤波器、宽带压控振荡器和外置宽带分频器等构成,实现了10~20 GHz范围内任意频率输出,具有输出频率宽、相位噪声低、集成度高、功耗低和成本低等优点.最后对该PLL电路杂散抑制和相位噪声的指标进行了测试,测试结果表明该PLL输出10 GHz时相位噪声优于-109 dBc/Hz@1 kHz,该指标与直接式频率合成器实现的指标相当.     

一个自调谐,自适应的1.9GHz分数/整数频率综合器

本文提出了一个具有自调谐,自适应功能的1.9GHz的分数/整数锁相环频率综合器.该频率综合器采用模拟调谐和数字调谐相结合的技术来提高相位噪声性能.自适应环路被用来实现带宽自动调整,可以缩短环路的建立时间.通过打开或者关断 ΣΔ 调制器的输出来实现分数和整数分频两种工作模式,仅用一个可编程计数器实现吞脉冲分频器的功能.采用偏置滤波技术以及差分电感,在片压控振荡器具有很低的相位噪声;通过采用开关电容阵列,该压控振荡器可以工作在1.7GHz~2.1GHz的调谐范围.该频率综合器采用0.18 μ m,1.8V SMIC CMOS工艺实现.SpectreVerilog仿真表明:该频率综合器的环路带宽约为100kHz,在600kHz处的相位噪声优于-123dBc/Hz,具有小于15 μ s的锁定时间.     

A CMOS self-calibrating frequency synthesizer

A programmable phase-locked-loop (PLL)-based frequency synthesizer, capable of automatically adjusting the nominal center frequency of the voltage-controlled oscillator (VCO) to an optimum value is described. In fully integrated PLLs, the VCO output frequency should be tunable over a wide range of frequencies, covering the desired range of the synthesizer output frequencies, for all processing variations and operating conditions. A wide tuning range realized by making the VCO gain K_o large has the unwanted effect of increasing the phase noise at the output of the VCO, and hence the PLL as well. In this work, the wide tuning range is realized by digital control, with process variability managed through self-calibration. The PLL is only required to pull the oscillator output frequency to account for the digital quantization, temperature variations, and some margin. This allows the K _o to be small, with better noise performance resulting. The prototype self-calibrating frequency synthesizer, capable of operating from 80 MHz to 1 GHz, demonstrates a measured absolute jitter of 20-ps rms at 480-MHz operating frequency. The prototype IC is fabricated in a 0.35-μm 3-V digital CMOS process     

A 1-V 9.7-mW CMOS Frequency Synthesizer for IEEE 802.11a Transceivers

A 1-V CMOS frequency synthesizer is proposed for wireless local area network 802.11a transceivers using a novel transformer-feedback voltage-controlled oscillator (VCO) for low voltage and a stacked frequency divider for low power. Implemented in a 0.18-mum CMOS process and operated at 1-V supply, the VCO measures a phase noise of -140.5 dBc at an offset of 20 MHz with a center frequency of 4.26 GHz and a power consumption of 5.17 mW. Its tuning range is as wide as 920 MHz (23%). By integrating the VCO into a frequency synthesizer, a phase noise of -140.1 dBc/Hz at an offset of 20 MHz is measured at a center frequency of 4.26 GHz. Its output frequency can be changed from 4.112 to 4.352 GHz by switching the 3-bit modulus of the programmable divider. The synthesizer consumes only 9.7 mW and occupies a chip area of 1.28 mm².     

Single-VCO multi-band DTV frequency synthesizer with a divide-by-3 frequency divider for quadrature signal generation

A multi-band frequency synthesizer for In-phase and Quadrature (I/Q) LO signal generation in Digital TV tuners is presented. Using divisor numbers other than powers of 2 (2 ⁿ ) for quadrature generation, reduces the required frequency range of the VCO, hence the number of VCO circuits, in multi-band frequency synthesizers. In the proposed synthesizer, VHF, UHF and L-band frequencies are covered with only one VCO. This is achieved by using a novel divide-by-3 circuit which produces precise I/Q LO signals. The VCO tuning range in this design is 2,400–3,632 MHz which is covered by a 6-bit switched-capacitor bank. A fast adaptive frequency calibration block selects the closest VCO frequency to the target frequency by setting the coarse-tuning code prior to the start of phase lock. A programmable charge pump is used to reduce variations in PLL characteristics over the frequency range. The synthesizer has been fabricated in a 0.18 μm CMOS technology and the die area is 1.7 × 1.6 mm². It consumes 27 mA from a 1.8 V power supply. Measurement results show operation of the proposed divide-by-3 circuit over the entire VCO frequency range. The synthesizer quadrature output phase noise for UHF and VHF bands is <−131dBc/Hz at 1.45 MHz offset.     

一种UHF频段小数分频频率综合器设计与实现

基于130 nm CMOS工艺设计了一款特高频(UHF)频段的锁相环型小数分频频率综合器.电感电容式压控振荡器(LC VCO)片外调谐电感总值为2 nH时,其输出频率范围为1.06～1.24 GHz,调节调谐电感拓宽了频率输出范围,并利用开关电容阵列减小了压控振荡器的增益.使用电荷泵补偿电流优化了频率综合器的线性度与带内相位噪声.此外对电荷泵进行适当改进,确保了环路的稳定.测试结果表明,通过调节电荷泵补偿电流,频率综合器的带内相位噪声可优化3 dB以上,中心频率为1.12 GHz时,在1 kHz频偏处的带内相位噪声和1 MHz频偏处的带外相位噪声分别为-92.3和-120.9 dBc/Hz.最小频率分辨率为3 Hz,功耗为19.2 mW.     

一种9.8-mW 1.2-GHz CMOS 低噪声正交输出频率综合器

实现了一种基于标准0.18µm CMOS工艺的应用于北斗导航射频接收机的1.2GHz频率综合器。在频率综合器中采用了一种基于分布式偏置技术实现的低噪声高线性LC压控振荡器和一种基于源极耦合逻辑的高速低开关噪声正交输出二分频器,集成了基于与非触发器结构的高速8/9双模预分频器、无死区效应的延迟可编程的鉴频鉴相器和电流可编程的电荷泵。该频率综合器的输出频率范围从1.05到1.30GHz。当输出频率为1.21GHz 时,在100-kHz和1-MHz的频偏处相位噪声分别为-98.53dBc/Hz和-121.92dBc/Hz。工作电压为1.8V时,不包括输出Buffer的核心电路功耗为9.8mW。北斗射频接收机整体芯片面积为2.41.6 mm2。     

A technique to improve the linearization of frequency–voltage characteristic of LC-VCO

This paper presents a very low-power linearization technique to improve the linearity of frequency-voltage characteristic of LC-VCO (voltage controlled oscillator) using MOS varactor. This reduces the VCO gain (K _VCO) variation and its required value over the tuning voltage range. Low K _VCO improves noise and reference spur performances at the output of phase lock loop/frequency synthesizer (FS). Low K _VCO variation reduces FS loop stability problem. Using this VCO circuit, a fully on-chip integer-N frequency synthesizer has been fabricated in 0.18 μm epi-digital CMOS technology for 2.45 GHz ZigBee application. The measured VCO phase noise is ?115.76 and ?125.23 dBc/Hz at 1 and 3 MHz offset frequencies, respectively from 2.445 GHz carrier and the reference spur of the frequency synthesizer is ?68.62 dBc. The used supply voltage is 1.5 V.