V-band harmonic injection-locked frequency divider using cross-coupled FETs

A V-band 1/2 frequency divider is developed using harmonic injection-locked oscillator. The cross-coupled field effect transistors (FETs) and low quality-factor microstrip resonator are employed as a wide-band oscillator to extend the locking bandwidth. The second harmonic of free-running oscillation signal is injected to the gates of cross-coupled FETs for high-sensitivity superharmonic injection locking. The fabricated microwave monolithic integrated circuit frequency divider using 0.15-/spl mu/m GaAs pHEMT process showed a maximum locking range of 7.4 GHz (from 65.1 to 72.5 GHz) under a low power dissipation of 100 mW. The maximum single-ended output power was as high as -3 dBm.     

A low phase noise PLL using Vackar VCO and a wide-locking range tunable divider for V-band signal generation in 65-nm CMOS

This paper presents a low phase noise integer-N phase-locked loop (PLL) for V-band signal generation. To enhance the frequency stability, we use a new class of Vackar voltage-controlled oscillator (VCO) in the PLL. The Vackar VCO achieves a low phase noise performance by effectively suppressing the AM-PM conversion. To properly align the locking range with the output of the VCO, a divider with wide locking range is realized by the current-mode logic (CML) D-flip-flops with tunable load. For spur reduction, an enhanced charge-pump structure is used to reject transient current glitches. With good static and dynamic current matching achieved in the charge pump, the reference spur is suppressed down to ?50 dBc. The designed PLL is implemented in a 65 nm RFCMOS process, and the measurement demonstrates a low phase noise signal up to 17 GHz. The in-band phase noise (at 1 MHz offset) and out-band phase noise (at 50 MHz offset) are ?103.6 and ?126.8 dBc/Hz, respectively. The PLL consumes 50.7 mW and occupies a chip area of 0.9 mm².     

A 2.4-GHz ring-oscillator-based CMOS frequency synthesizer with a fractional divider dual-PLL architecture

A 2.4-GHz frequency synthesizer was designed that uses a fractional divider to drive a dual-phase-locked-loop (PLL) structure, with both PLLs using only on-chip ring oscillators. The first-stage narrow-band PLL acts as a spur filter while the second-stage wide-band PLL suppresses VCO phase noise so that simultaneous suppression of phase noise and spur is achieved. A new low-power, low-noise, low-frequency ring oscillator is designed for this narrow-band PLL. The chip was designed in 0.35-/spl mu/m CMOS technology and achieves a phase noise of -97 dBc/Hz at 1-MHz offset and spurs of -55 dBc. The chip's output frequency varies from 2.4 to 2.5 GHz; the chip consumes 15 mA from a 3.3-V supply and occupies 3.7 mm/spl deg/.     

A 1-V 24-GHz 17.5-mW phase-locked loop in a 0.18-/spl mu/m CMOS process

A 1-V 24-GHz 17.5-mW fully integrated phase-locked loop employing a transformer-feedback voltage-controlled oscillator and a stacked divide-by-2 frequency divider for low voltage and low power is presented. Implemented in a 0.18-/spl mu/m CMOS process and operated at 24 GHz with a 1-V supply, the PLL measures in-band phase noise of -106.3 dBc at a frequency offset of 100 kHz and out-of-band phase noise of -119.1 dBc/Hz at a frequency offset of 10 MHz. The PLL dissipates 17.5 mW and occupies a core area of 0.55 mm/sup 2/.     

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.     

A 6.3-9-GHz CMOS fast settling PLL for MB-OFDM UWB applications

A CMOS phase-locked loop (PLL) which synthesizes frequencies between 6.336 and 8.976 GHz in steps of 528 MHz and settles in approximately 150 ns is presented. The proposed PLL can be employed as a building block for a frequency synthesizer which generates a seven-band hopping carrier for multiband orthogonal frequency division multiplexing (MB-OFDM) ultrawideband (UWB) radio. To achieve fast loop settling, integer-N architecture that operates with 528-MHz reference frequency is implemented and a wideband active-loop filter is integrated. An improved phase-frequency detector (PFD) is proposed for faster loop settling. To reduce reference sidebands, a feedback circuit using replica bias is implemented in the charge pump. I/Q carriers are generated by two cross-coupled LC VCOs. The output current of the charge pump is controlled to compensate for the VCO gain nonlinearity and a programmable frequency divider (12/spl les/N/spl les/17) that reliably operates at 9 GHz is designed. Fabricated in 0.18-/spl mu/m CMOS technology, the PLL consumes 32 mA from a 1.8-V supply and achieves phase noise of -109.6dBc/Hz at 1-MHz offset and spurs of -52 dBc.     

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     

V-band HJFET MMIC DROs with low phase noise, high power, and excellent temperature stability

This paper describes the development, along with detailed phase-noise analysis, of V-band monolithic-microwave integrated-circuit (MMIC) dielectric-resonator oscillators (DROs) achieving state-of-the-art performances. A TE/sub 01/spl delta//-mode Ba(Mg,Ta)O/sub 3/ cylindrical dielectric resonator (DR) is directly placed on a MMIC GaAs substrate to avoid the loss and uncertainty of bonding wires. A 0.15-/spl mu/m AlGaAs-InGaAs heterojunction field-effect transistor with optimized structure is developed as an active device. A design procedure proposed by the authors is employed, which allows us to analyze and optimize circuits in consideration for the output power, phase noise, and temperature stability. A developed DRO co-integrated with a buffer amplifier exhibits a low phase noise of -90 dBc/Hz at 100-kHz offset, a high output power of 10.0 dBm, and an excellent frequency stability of 1.6 ppm//spl deg/C at an oscillation frequency of 59.6 GHz, all of which are state-of-the-art performances reported for MMIC DROs above V-band. An experimental and theoretical analysis for the phase-noise-reduction effect of a DR is also addressed.     

A harmonic injection-locked frequency divider in 0.18-/spl mu/m SiGe BiCMOS

A harmonic injection-locked frequency divider for high-speed applications is presented in this letter. In order to enhance the bandwidth of the high-order frequency division, a positive feedback is employed in the design of the subharmonic mixer loop. The proposed circuit is implemented in a 0.18-/spl mu/m SiGe BiCMOS process. With a singled-ended super-harmonic input injection of 0dBm, the frequency divider exhibits a locking range of 350MHz (from 59.77 to 60.12GHz) for the divide-by-four frequency division while maintaining an output power of -16.6/spl plusmn/ 0.5dBm within the entire frequency range. The frequency divider core consumes a dc power of 50mW from a 3.6-V supply voltage.     

A 21-GHz 8-Modulus Prescaler and a 20-GHz Phase-Locked Loop Fabricated in 130-nm CMOS

A 1.5-V 256-263 8-modulus prescaler and a 1.5-V integer-N phase-locked loop (PLL) with eight different output frequencies have been implemented in a 0.13-mum foundry CMOS process. The synchronous divide-by-4/5 circuit uses current mode logic (CML) D-flip-flops with resistive loads to achieve 21-GHz maximum operating frequency at input power of 0 dBm. The divider is used to implement an 8-modulus prescaler consuming 6-mA current and 9-mW power. This extremely low power consumption is achieved by radically decreasing the sizes of transistors in the divider. Utilizing the prescaler, a charge-pump integer-N PLL has been demonstrated with 20-GHz output frequency. The in-band phase noise of the PLL at 60-kHz offset and out-of-band phase noise at 10-MHz offset are ~-80 dBc/Hz and -116.1 dBc/Hz, respectively. The locking range is from 20.05 to 21 GHz. The PLL consumes 15-mA current and 22.5-mW power from a 1.5-V power supply.     

A 1.8-GHz Spur-Cancelled Fractional-N Frequency Synthesizer With LMS-Based DAC Gain Calibration

A 1.8-GHz wideband DeltaSigma fractional-N frequency synthesizer achieves the phase noise performance of an integer-N synthesizer using a spur-cancellation digital-to-analog converter (DAC). The DAC gain is adaptively calibrated with a least-mean-square (LMS) sign-sign correlation algorithm for better than 1% DAC and charge pump (CP) gain matching. The proposed synthesizer phase-locked loop (PLL) is demonstrated with a wide 400-kHz loop bandwidth while using a low 14.3-MHz reference clock, and offers a better phase noise and bandwidth tradeoff. Using an 8-bit gain-calibrated DAC, DeltaSigma-shaped divider ratio noise is suppressed by as much as 30 dB. The second-order DeltaSigma fractional-N PLL exhibits in-band and integrated phase noises of -98 dBc/Hz and 0.8deg. The chip, fabricated in 0.18-mum CMOS, occupies 2 mm², and consumes 29 mW at 1.8-V supply. The spur cancellation and correlation function consumes 30% additional power     

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.     

用于高能物理实验电子读出芯片的低噪声锁相环芯片设计

基于TSMC 180 nm工艺设计并流片测试了一款用于高能物理实验的电子读出系统的低噪声、低功耗锁相环芯片。该芯片主要由鉴频鉴相器、电荷泵、环路滤波器、压控振荡器和分频器等子模块组成,在锁相环电荷泵模块中,使用共源共栅电流镜结构精准镜像电流以减小电流失配和用运放钳位电压进一步减小相位噪声。测试结果表明,该锁相环芯片在1.8 V电源电压、输入50 MHz参考时钟条件下,可稳定输出200 MHz的差分时钟信号,时钟均方根抖动为2.26 ps(0.45 mUI),相位噪声在1 MHz频偏处为-105.83 dBc/Hz。芯片整体功耗实测为23.4 mW,锁相环核心功耗为2.02 mW。     

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.     

A fast-hopping single-PLL 3-band MB-OFDM UWB synthesizer

This paper describes a 3-band (mode 1) multi-band-OFDM UWB synthesizer implemented in a 0.25-/spl mu/m SiGe BiCMOS process. The interference-robust, fast-hopping synthesizer uses one single-sideband (SSB) mixer for frequency shifting. A single phase-locked loop (PLL) generates the steady input signals for the SSB-mixer. Crucial in the design is a divide-by-5 frequency divider that generates quadrature signals at a frequency of 528 MHz. The 0.44 mm/sup 2/ fully integrated synthesizer consumes 52 mW from a 2.7 V supply. Out-of-band spurious tones are below -50 dBc, allowing co-operability with WLAN applications in the 2.4 GHz and 5 GHz range. The integrated phase noise is below 2/spl deg/ rms. The measured frequency transition time is well below the required 9.5 ns.     

A 5-GHz CMOS Frequency Synthesizer With an Injection-Locked Frequency Divider and Differential Switched Capacitors

A phase-locked loop (PLL)-based frequency synthesizer at 5 GHz is designed and fabricated in 0.18-${rm mu}hbox{m}$ CMOS technology. The power consumption of the synthesizer is significantly reduced by using an injection-locked frequency divider (ILFD) as the first frequency divider in the PLL feedback loop. The synthesizer chip consumes 18 mW of power, of which only 3.93 mW is consumed by the voltage-controlled oscillator (VCO) and the ILFD at 1.8-V supply voltage. The VCO has the phase noise of $-$ 104 dBc/Hz at 1-MHz offset and an output tuning range of 740 MHz. The chip size is 1.1 mm $times$ 0.95 mm.      

一种C波段小步进捷变频频率综合器的设计

本文介绍了一种小步进、低相噪、低杂散、捷变频锁相频率综合器的设计与实现,本设计选用超低相噪锁相环芯片,采用小数分频实现小步进,通过双锁相环“乒乓”工作实现捷变频,经过对环路参数的精心设计,较好的实现了相位噪声、杂散等技术指标。     

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 2.5-10-GHz clock multiplier unit with 0.22-ps RMS jitter in standard 0.18-/spl mu/m CMOS

This paper demonstrates a low-jitter clock multiplier unit that generates a 10-GHz output clock from a 2.5-GHz reference clock. An integrated 10-GHz LC oscillator is locked to the input clock, using a simple and fast phase detector circuit that overcomes the speed limitation of a conventional tri-state phase frequency detector due to the lack of an internal feedback loop. A frequency detector guarantees PLL locking without degenerating jitter performance. The clock multiplier is implemented in a standard 0.18-/spl mu/m CMOS process and achieves a jitter generation of 0.22 ps while consuming 100 mW power from a 1.8-V supply.     

A 50-GHz Phase-Locked Loop in 0.13-μ m CMOS

A 50-GHz charge pump phase-locked loop (PLL) utilizing an LC-oscillator-based injection-locked frequency divider (ILFD) was fabricated in 0.13-mum logic CMOS process. The PLL can be locked from 45.9 to 50.5 GHz and output power level is around -10 dBm. The operating frequency range is increased by tracking the self-oscillation frequencies of the voltage-controlled oscillator (VCO) and the frequency divider. The PLL including buffers consumes 57 mW from 1.5/0.8-V supplies. The phase noise at 50 kHz, 1 MHz, and 10 MHz offset from the carrier is -63.5, -72, and -99 dBc/Hz, respectively. The PLL also outputs second-order harmonics at frequencies between 91.8 and 101 GHz. The output frequency of 101 GHz is the highest for signals locked by a PLL fabricated using the silicon integrated circuits technology.