A CMOS frequency synthesizer with an injection-locked frequencydivider for a 5-GHz wireless LAN receiver

A fully integrated 5-GHz phase-locked loop (PLL) based frequency synthesizer is designed in a 0.24 μm CMOS technology. The power consumption of the synthesizer is significantly reduced by using a tracking injection-locked frequency divider (ILFD) as the first frequency divider in the PLL feedback loop. On-chip spiral inductors with patterned ground shields are also optimized to reduce the VCO and ILFD power consumption and to maximize the locking range of the ILFD. The synthesizer consumes 25 mW of power of which only 3.8 mW is consumed by the VCO and the ILFD combined. The PLL has a bandwidth of 280 kHz and a phase noise of -101 dBc/Hz at 1 MHz offset frequency. The spurious sidebands at the center of adjacent channels are less than -54 dBc     

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 1.5-V 5.5-GHz CMOS phase-locked loop

A 1.5-V 5.5-GHz fully integrated phase-locked loop (PLL) has been implemented in a 0.25-μm foundry digital CMOS process. From a 5.5-GHz carrier, the in-band phase noise can be as low as -88 dBc/Hz at a 40-kHz offset, while the phase noise for the free-running VCO is -116 dBc/Hz at an 1-MHz offset. The VCO core current is 4.6 mA. The prescaler is implemented using a variation of the source-coupled logic (SCL) structure to reduce the switching noise, and thus to reduce the PLL side-band spurs. At -18 dBm signal power measured off chip, the switching noise coupled through substrate and metal interconnect generates spurs with power levels less than -99 dBm when the loop is open. A new charge-pump circuit is developed to reduce the current glitch at the output node. By incorporating a voltage doubler, the voltage dynamic range at the charge-pump output and thus the VCO control voltage range is increased from 1.3 to 2.6 V with immeasurable phase noise and spurious level degradation to the PLL. When the loop is closed, the power levels of side-band spurs at the offset frequency equal to the ~43-MHz reference frequency are < -69 dBc. The total power consumption of the PLL including that for the output buffers is ~23 mW     

基于电感电容振荡器的电荷泵锁相环的设计

设计并实现了一种采用电感电容振荡器的电荷泵锁相环,分析了锁相环中鉴频/鉴相器(PFD)、电荷泵(CP)、环路滤波器(LP)、电感电容压控振荡器(VCO)的电路结构和设计考虑。锁相环芯片采用0.13μm MS&RF CMOS工艺制造。测试结果表明,锁相环锁定的频率为5.6～6.9 GHz。在6.25 GHz时,参考杂散为-51.57 dBc;1 MHz频偏处相位噪声为-98.35 dBc/Hz;10 MHz频偏处相位噪声为-120.3 dBc/Hz;在1.2 V/3.3 V电源电压下,锁相环的功耗为51.6 mW。芯片总面积为1.334 mm2。     

A 4.3-GHz VCO with 2-GHz tuning range and low phase noise

A voltage-controlled oscillator (VCO) based on double cross-coupled multivibrator structure with a center frequency of 4.3 GHz and a tuning range of 2 GHz has been designed and implemented in standard 0.35 μm BiCMOS technology. The measured phase noise is 113 dBc/Hz at 600-kHz offset frequency from the carrier. The VCO draws 14.6 mA from the 2.5-V supply     

A 900-MHz 2.5-mA CMOS frequency synthesizer with an automatic SCtuning loop

A 900-MHz phase-locked loop frequency synthesizer implemented in a 0.6-μm CMOS technology is developed for the wireless integrated network sensors applications. It incorporates an automatic switched-capacitor (SC) discrete-tuning loop to extend the overall frequency tuning range to 20%, while the VCO gain (K_VCO) resulting from the CMOS varactor continuous-tuning is kept low at only 20 MHz/V in order to improve the reference spurs and noise performance. This frequency synthesizer achieves a phase noise of -102 dBc/Hz at 100 kHz offset frequency and reference spurs below -55 dBc. The synthesizer, including an on-chip VCO, dissipates only 2.5 mA from a 3-V supply     

A 25-GHz ultra-low phase noise InGaP/GaAs HBT VCO

A 25-GHz monolithic voltage controlled oscillator (VCO) has been designed and fabricated in a commercial InGaP/GaAs heterojunction bipolar transistor (HBT) process. This balanced VCO has a novel topology using a feedback /spl pi/-network and a common-emitter transistor configuration. Ultra-low phase noise is achieved: -106 dBc/Hz and -130 dBc/Hz at 100kHz and 1-MHz offset frequency, respectively. To the authors' knowledge, this is the lowest phase noise achieved in a monolithic microwave integrated circuit (MMIC) VCO at such high frequency. The single-ended output power is -1 dBm. It can be tuned between 25.33GHz and 25.75GHz using the base-collector junction capacitor of the HBT as a varactor. The dc power consumption is 90mW for a 9-V supply. An excellent figure-of-merit of -195 dBc/Hz is obtained.     

一种基于偏移源的频率合成技术分析

针对一种基于偏移源的频率合成技术,建立了锁相环(PLL)线性模型,对相位噪声和杂散信号性能进行分析。从分析结果看,在锁相环反馈支路中使用一个偏移源将压控振荡器(VCO)输出信号下混频至一个较低的中频,从而将锁相环的环路分频比大大降低,使改善后的锁相环噪底达到-135 dBc/Hz。介绍了偏移源和主环的关键合成技术,结合工程应用设计的基于偏移源的C频段频率合成器,相位噪声偏离载波10 kHz处≤-99 dBc/Hz,偏离载波100 kHz处≤-116 dBc/Hz,杂散小于-70 dBc。     

A /spl Sigma/-/spl Delta/ fractional-N frequency synthesizer using a wide-band integrated VCO and a fast AFC technique for GSM/GPRS/WCDMA applications

A fractional-N frequency synthesizer (FNFS) in a 0.5-/spl mu/m SiGe BiCMOS technology is implemented. In order to operate in a wide-band frequency range, a switched-capacitors bank LC tank voltage-controlled oscillator (VCO) and an adaptive frequency calibration (AFC) technique are used. The measured VCO tuning range is as wide as 600 MHz (40%) from 1.15 to 1.75 GHz with a tuning sensitivity from 5.2 to 17.5 MHz/V. A 3-bit fourth-order /spl Sigma/-/spl Delta/ modulator is used to reduce out-of-band phase noise and to meet a frequency resolution of less than 3 Hz as well as agile switching time. The experimental results show -80 dBc/Hz in-band phase noise within the loop bandwidth of 25 kHz and -129 dBc/Hz out-of-band phase noise at 400-kHz offset frequency. The fractional spurious is less than -70 dBc/Hz at 300-kHz offset frequency and the reference spur is -75 dBc/Hz. The lock time is less than 150 /spl mu/s. The proposed synthesizer consumes 19.5 mA from a single 2.8-V supply voltage and meets the requirements of GSM/GPRS/WCDMA applications.     

A 900-MHz 1.5-V CMOS voltage-controlled oscillator using switched resonators with a wide tuning range

A 900-MHz fully integrated VCO was fabricated in a 0.18-/spl mu/m foundry CMOS process. Under 1.5 V power supply, this VCO can be tuned from 667 MHz to 1156 MHz which corresponds to a 53.6% tuning range. The VCO has nearly constant phase noise over the whole tuning frequency, credit to the switched resonators used in this VCO. The phase noise at a 600 kHz offset is -123.1 dBc/Hz at 1125 MHz center frequency and -124.2 dBc/Hz at 667 MHz center frequency.     

Cross-coupled differential oscillator MMICs with low phase-noiseperformance

LC-tank oscillators in the 5~6 GHz frequency range have been designed and implemented in a commercial 0.6 μm GaAs MESFET technology. One is a voltage-controlled oscillator (VCO), and the other is an oscillator without a controlling element. The output frequency range of the VCO is from 5.44 to 6.14 GHz, and the measured phase-noise is -101.67 dBc/Hz at an offset frequency of 600 KHz from the 5.44 GHz carrier. The phase-noise of the 6.44 GHz oscillator is -108 dBc/Hz at an offset frequency of 600 KHz, and the phase-noise curve, in the offset frequency range between 100 KHz and 1 MHz, shows a -20 dB/decade slope. These phase-noise characteristics are comparable to, or better than, those of the reported 5~6 GHz-band CMOS oscillators. To our knowledge, this is the first GaAs MESFET-based oscillator which has a cross-coupled differential topology and a capacitive coupling feedback to suppress the up-conversion of 1/f noise. Also, it is first reported that the GaAs MESFET-based oscillator shows 1/f² phase-noise behavior across the offset frequency range from 100 KHz to 1 MHz     

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     

A Low Supply Voltage VCO Implemented by a Single Common-Source 90 nm CMOS Transistor

A novel voltage controlled oscillation (VCO) topology using 90-m CMOS technology is demonstrated. The common-source PMOS single transistor integrated with an inductor leads to negative resistance for the VCO that minimizes the transistor size and decreases the flicker noise sources. To our knowledge, the topology of the core VCO is the most compact configuration ever reported. The fabricated VCO consumes 6.26mW with a supply voltage of 1 V and has a 1.68times1.41 mm² chip area, including the ESD protection circuit. At 1.77 GHz, PMOS VCO features an output power in the range of -5.2 dBm, and exhibits a phase noise of -94 dBc/Hz at the offset frequency of 300 kHz and -107 dBc/Hz at 1MHz     

A 2 V 1.8 GHz fully integrated CMOS dual-loop frequency synthesizer

A 2 V 1.8 GHz fully integrated CMOS dual-loop frequency synthesizer is designed in a standard 0.5 /spl mu/m digital CMOS process for wireless communication. The voltage-controlled oscillator (VCO) required for the low-frequency loop is designed using a ring-type VCO and achieves a tuning range of 89% from 356 to 931 MHz and a phase noise of -109.2 dBc/Hz at 600 kHz offset from 856 MHz. With an active chip area of 2000/spl times/1000 /spl mu/m/sup 2/ and at a 2 V supply voltage, the whole synthesizer achieves a tuning range from 1.8492 to 1.8698 GHz in 200 kHz steps with a measured phase noise of -112 dBc/Hz at 600 kHz offset from 1.86 GHz. The measured settling time is 128 /spl mu/s and the total power consumption is 95 mW.     

A low-phase-noise and low-power multiband CMOS voltage-controlled oscillator

A low voltage multiband all-pMOS VCO was fabricated in a 0.18-/spl mu/m CMOS process. By using a combination of inductor and capacitor switching, four band (2.4, 2.5, 4.7, and 5 GHz) operation was realized using a single VCO. The VCO with an 1-V power supply has phase noises at 1-MHz offset from a 4.7-GHz carrier of -126 dBc/Hz and -134 dBc/Hz from a 2.4-GHz carrier. The VCO consumes 4.6 mW at 2.4 and 2.5 GHz, and 6 mW at 4.7 and 5 GHz, respectively. At 4.7 GHz, the VCO also achieves -80 dBc/Hz phase noise at 10-kHz offset with 2 mW power consumption.     

A 108-GHz InP-HBT monolithic push-push VCO with low phase noise andwide tuning bandwidth

This paper reports on what is believed to be the highest frequency bipolar voltage-controlled oscillator (VCO) monolithic microwave integrated circuit (MMIC) so far reported. The W-band VCO is based on a push-push oscillator topology, which employs InP HBT technology with peak f_T's and f_max's of 75 and 200 GHz, respectively. The W-band VCO produces a maximum oscillating frequency of 108 GHz and delivers an output power of +0.92 dBm into 50 Ω. The VCO also obtains a tuning bandwidth of 2.73 GHz or 2.6% using a monolithic varactor. A phase noise of -88 dBc/Hz and -109 dBc/Hz is achieved at 1- and 10-MHz offsets, respectively, and is believed to be the lowest phase noise reported for a monolithic W-band VCO. The push-push VCO design approach demonstrated in this work enables higher VCO frequency operation, lower noise performance, and smaller size, which is attractive for millimeter-wave frequency source applications     

使用三位三阶Δ∑调制器的集成1GHz小数频率合成器

本文实现了一个采用三位三阶Δ∑调制器的高频谱纯度集成小数频率合成器.该频率合成器采用了模拟调谐和数字调谐组合技术来提高相位噪声性能,优化的电源组合可以避免各个模块之间的相互干扰,并且提高鉴频鉴相器的线性度和提高振荡器的调谐范围.通过采用尾电流源滤波技术和减小振荡器的调谐系数,在片压控振荡器具有很低的相位噪声,而通过采用开关电容阵列,该压控振荡器达到了大约100MHz的调谐范围,该开关电容阵列由在片数字调谐系统进行控制.该频率合成器已经采用0.18μm CMOS工艺实现,仿真结果表明,该频率频率合成器的环路带宽约为14kHz,最大带内相位噪声约为-106dBc/Hz;在偏离载波频率100kHz处的相位噪声小于-120dBc/Hz,具有很高的频谱纯度.该频率合成器还具有很快的反应速度,其锁定时间约为160μs.     

Power efficient Ka-band low phase noise VCO in 0.13 μm CMOS

A 27 GHz cross-coupled LC voltage controlled oscillator (VCO) using a standard 0.13 mum CMOS technology is presented. The VCO using a high-Q LC resonator with a micro-strip inductor (mu-strip L) provides a phase noise of -113 dBc/Hz at a 1 MHz offset frequency. The figure - of-merit (FoM) is -194.6 dBc/Hz. To obtain high output power, it also uses a common source amplifier as a buffer and it shows the output power of -3.5 dBm at an oscillation frequency of 26.89 GHz. This is believed to be the lowest phase noise and FoM with the highest output power of a millimetre-wave VCO in CMOS technology.     

Novel 53/106 GHz Dual-Band MMW LC Oscillator Implemented in SiGe BiCMOS Technology

In this Paper, we present a fully integrated millimeter wave LC voltage-controlled oscillator (VCO), which employs a novel topology, operating at dual-band frequency of 53.22 GHz-band and 106.44 GHz-band. The low-phase noise performance of ?107.3 dBc/Hz and ?106.1 dBc/Hz at the offset frequency of 600 kHz, ?111.8 dBc/Hz and ?110.6 dBc/Hz at the offset frequency of 1 MHz around 53.22 GHz and 106.44 GHz are achieved using IBM BiCMOS-6HP technology, respectively. Two tuning ranges, of 52.7 - 53.8 GHz and 105.4 - 107.6 GHz for the proposed LC VCO are obtained. The output voltage swing of this VCO is around 1.8 V_p-p at the operation frequency of 53.22 GHz and 0.45 V_p-p at 106.44 GHz; the total power consumption is about 16.5 mW. To our knowledge, this is the first oscillator which operates at dual-band frequency above 50 GHz with the best preformance.     

A 14-GHz 256/257 dual-modulus prescaler with secondary feedback and its application to a monolithic CMOS 10.4-GHz phase-locked loop

A 14-GHz 256/257 dual-modulus prescaler is implemented using secondary feedback in the synchronous 4/5 divider on a 0.18-/spl mu/m foundry CMOS process. The dual-modulus scheme utilizes a 4/5 synchronous counter which adopts a traditional MOS current mode logic clocked D flip-flop. The secondary feedback paths limit signal swing to achieve high-speed operation. The maximum operating frequency of the prescaler is 14 GHz at V/sub DD/=1.8 V. Utilizing the prescaler, a 10.4-GHz monolithic phase-locked loop (PLL) is demonstrated. The voltage-controlled oscillator (VCO) operates between 9.7-10.4 GHz. The tuning range of the VCO is 690 MHz. The phase noise of the PLL and VCO at a 3-MHz offset with I/sub vco/=4.9 mA is -117 and -119 dBc/Hz, respectively. At the current consumption of I/sub vco/=8.1 mA, the phase noise is -122 and -122 dBc/Hz, respectively. The PLL output phase noise at a 50-kHz offset is -80 dBc/Hz. The PLL consumes /spl sim/31 mA at V/sub DD/=1.8 V.