基于高次谐波体声波谐振器的微波振荡器设计

基于高次谐波体声波谐振器(HBAR)的高品质因数(Q)值和多模谐振特性,设计了Colpitts和Pierce两种形式的微波振荡器。采用HBAR与LC元件组成谐振回路的方法,与放大电路构成反馈环路直接基频输出微波频段信号。Colpitts振荡器输出信号频率为980 MHz,信号输出功率为-4.92dBm,信号相位噪声达-119.64dBc/Hz@10kHz;Pierce振荡电路输出信号频率达到2.962GHz,信号输出功率为-9.77dBm,信号相位噪声达-112.30dBc/Hz@10kHz。     

A 5.9-GHz voltage-controlled ring oscillator in 0.18-/spl mu/m CMOS

This paper presents the design of three- and nine-stage voltage-controlled ring oscillators that were fabricated in TSMC 0.18-/spl mu/m CMOS technology with oscillation frequencies up to 5.9 GHz. The circuits use a multiple-pass loop architecture and delay stages with cross-coupled FETs to aid in the switching speed and to improve the noise parameters. Measurements show that the oscillators have linear frequency-voltage characteristics over a wide tuning range, with the three- and nine-stage rings resulting in frequency ranges of 5.16-5.93 GHz and 1.1-1.86 GHz, respectively. The measured phase noise of the nine-stage ring oscillator was -105.5 dBc/Hz at a 1-MHz offset from a 1.81-GHz center frequency, whereas the value for the three-stage ring oscillator was simulated to be -99.5 dBc/Hz at a 1-MHz offset from a 5.79-GHz center frequency.     

A low-noise, 900-MHz VCO in 0.6-μm CMOS

This paper describes a low-noise, 900-MHz, voltage-controlled oscillator (VCO) fabricated in a 0.6-μm CMOS technology. The VCO consists of four-stage fully differential delay cells performing full switching. It utilizes dual-delay path techniques to achieve high oscillation frequency and obtain a wide tuning range. The VCO operates at 750 MHz to 1.2 GHz, and the tuning range is as large as 50%. The measured results of the phase noise are -101 dBc/Hz at 100-kHz offset and -117 dBc/Hz at 600-kHz offset from the carrier frequency. This value is comparable to that of LC-based integrated oscillators. The oscillator consumes 10 mA from a 3.0-V power supply. A prototype frequency synthesizer with the VCO is also implemented in the same technology, and the measured phase noise of the synthesizer is -113 dSc/Hz at 100-kHz offset     

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 22-GHz push-push CMOS oscillator using micromachined inductors

This letter presents a low phase noise 0.35-/spl mu/m CMOS push-push oscillator utilizing micromachined inductors. This oscillator results in an improvement in phase noise compared with the previously published Si-based voltage-controlled oscillators (VCOs) around 20GHz. With the high-Q inductors introduced by the micromachined structure, the oscillator achieves an oscillating frequency of 22.2GHz while exhibiting an output power of -7.5dBm with a phase noise of -110.1dBc/Hz at 1-MHz offset. This work also demonstrates the highest operating frequency among previously published Si-based VCOs using micromachined structures.     

A 140-GHz fundamental mode voltage-controlled oscillator in 90-nm CMOS technology

Fundamental mode voltage-controlled oscillators in F-band (90-140GHz) were fabricated using the UMC 90-nm logic CMOS process. The maximum operating frequencies of these three oscillators are 110, 123, and 140GHz, respectively. The 140-GHz voltage controlled oscillator provides -22 to -19-dBm output power, a frequency tuning range of 1.2GHz and phase noise of -85dBc/Hz at 2-MHz offset from the carrier, while consuming 8mA from a 1.2-V supply.     

A monolithically integrated 190-GHz SiGe push-push oscillator

In this letter, we present a fully monolithically integrated G-band push-push oscillator. The device is fabricated in a production-near SiGe:C bipolar technology. The transistors used in this work show a maximum transit frequency f/sub T/= 200GHz and a maximum frequency of oscillation fmax= 275GHz. The passive circuitry is realized by integrated transmission-line components, metal-insulator-metal (MIM)-capacitors and TaN resistors. The frequency of the output signal can be tuned between 183.3GHz and 190.5GHz, the maximum output power of the oscillator is -4.5dBm and the measured minimum single sideband phase noise is -73dBc/Hz at 1-MHz offset frequency. This represents the highest output frequency for oscillators using heterojunction bipolar transistor technology and published up to now.     

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.     

Transmission-line stabilized monolithic oscillators

A novel technique for frequency stabilization and phase-noise reduction of monolithic oscillators is presented in this paper. It employs simple transmission-line resonators, which are many wavelengths long to increase the oscillator quality factor. Monolithic oscillators at 20 and 40 GHz are realized for the application of this technique. Phase noise reduction of more than 20 dB was achieved for both oscillators. The single-sideband phase noise obtained was -100 dBc/Hz at 100-kHz offset for the 20-GHz oscillator and -90 dBc/Hz at 1-MHz offset for the 40-GHz oscillator. The approach is implemented by using readily available transmission lines, which are open- or short-circuited at one end and connected to the monolithic-microwave integrated-circuit (MMIC) oscillator at the other end. Thus, it presents significant potential in the development of low-cost MMIC oscillators with enhanced noise performance     

Quasi-planar K-band push-push low phase noise oscillator stabilized by cavity resonator

The results of developing a K-band (24 GHz) push-push low phase noise transistor oscillator have been presented. This oscillator is stabilized by a rectangular resonant metallic cavity. The power level of output signal is ?9.5 dBm, the fundamental harmonic suppression is 21 dB. Single sideband (SSB) phase noise spectral density of ?98 dBc/Hz at 10 kHz and ?128 dBc/Hz at 100 kHz offset from the carrier frequency is at the level of dielectric resonator oscillators (DRO) scaled to the same frequency. The oscillator features a compact size, low cost quazi-planar design and it is built using commercially available off the shelf parts.     

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/.     

Low-Phase Noise Hartley Differential CMOS Voltage Controlled Oscillator

This letter presents a novel Hartley low phase noise differential CMOS voltage-controlled oscillator (VCO). The low noise CMOS VCO has been implemented with the TSMC 0.18-mum 1P6M CMOS technology and adopts full PMOS to achieve a better phase noise performance. The VCO operates from 4.02 to 4.5GHz with 11.3% tuning range. The measured phase noise at 1-MHz offset is about -119dBc/Hz at 4.02GHz and 122dBc/Hz at 4.5GHz. The power consumption of the VCO core is 6.75mW     

CMOS Colpitts Quadrature VCO Using the Body Injection-Locked Coupling Technique

This paper presents a new low phase noise quadrature voltage-controlled oscillator (QVCO), which consists of two differential complementary Colpitts voltage-controlled oscillators (VCOs) with a tail inductor. The output of the tail inductor in one differential VCO is injected to the bodies of the nMOSFETs in the other differential VCO and vice versa. The proposed CMOS QVCO has been implemented with the TSMC 0.18 mum CMOS technology and the die area is 0.725 times 0.839 mm². At the supply voltage of 1.1 V, the total power consumption is 9.9 mW. The free-running frequency of the QVCO is tunable from 5.26 GHz to 5.477 GHz as the tuning voltage is varied from 0.0 V to 1.1 V. The measured phase noise at 1 MHz frequency offset is -124.36 dBc/Hz at the oscillation frequency of 5.44 GHz and the figure of merit (FOM) of the proposed QVCO is -189.1 dBc/Hz.     

K- and Q-bands CMOS frequency sources with X-band quadrature VCO

Fully integrated 10-, 20-, and 40-GHz frequency sources are presented, which are implemented with a 0.18-/spl mu/m CMOS process. A 10-GHz quadrature voltage-controlled oscillator (QVCO) is designed to have output with a low dc level, which can be effectively followed by a frequency multiplier. The proposed multipliers generate signals of 20 and 40 GHz using the harmonics of the QVCO. To have more harmonic power, a frequency doubler with pinchoff clipping is used without any buffers or dc-level shifters. The QVCO has a low phase noise of -118.67 dBc/Hz at a 1-MHz offset frequency with a 1.8-V power supply. The transistor size effect on phase noise is investigated. The frequency doubler has a low phase noise of -111.67 dBc/Hz at a 1-MHz offset frequency is measured, which is 7 dB higher than a phase noise of the QVCO. The doubler can be tuned between 19.8-22 GHz and the output is -6.83 dBm. A fourth-order frequency multiplier, which is used to obtain 40-GHz outputs, shows a phase noise of -102.0 dBc/Hz at 1-MHz offset frequency with the output power of -18.0 dBm. A large tuning range of 39.3-43.67 GHz (10%) is observed.     

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 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.     

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.     

An Analysis of 1/f2 Phase Noise in Bipolar Colpitts Oscillators (With a Digression on Bipolar Differential-Pair LC Oscillators)

This work presents an analysis of phase noise in the 1/f² region displayed by both single-ended and differential bipolar Colpitts oscillators. Very accurate and rigorous symbolic phase noise expressions are derived, enabling a deeper insight into the major mechanisms of phase noise generation, and providing new tools for design optimization. Phase noise expressions for the cross-coupled differential-pair LC-tank oscillator are derived as well. The theoretical analysis is validated on a 3 GHz differential bipolar Colpitts VCO implemented in a 0.35 mum SiGe process. Measurements show a phase noise of -123 dBc/Hz or less at 1MHz offset frequency from the 2.8-3.1 GHz carrier, for a phase noise figure-of-merit of at least 183 dBc/Hz across the tuning range. A very good agreement between theory, numerical simulations, and measurements is observed     

A Ka-band micromachined low-phase-noise oscillator

A low-phase-noise 28.65 GHz oscillator has been demonstrated using a planar resonator. The resonator is micromachined close to the transistor and has an unloaded Q of 460. The oscillator uses a commercially available high electron mobility transistor (HEMT) for the active device, and results in an output power of 0.6 dBm with a 5.7% DC-RF efficiency. The measured phase noise is -92 dBc/Hz at a 100 kHz offset frequency and -122 dBc/Hz at 1 MHz offset frequency. This is compared with a low-Q planar design showing a 10 dB improvement in phase noise. The micromachined resonator is competitive with other hybrid nonplanar technologies, such as dielectric resonators     

基于Phase-Refining技术的微波宽带频率合成器

为改善宽带频率合成器的相位噪声,提出一种基于Phase-Refining技术的微波宽带频率合成器结构与一种对其相位噪声的准确分析方法。首先,根据线性传递函数与叠加原理得到该频率合成器的相位噪声解析模型,通过对振荡器实测相位噪声谱型进行曲线拟合并带入模型中来准确预测其相位噪声性能。分析表明,在级联偏置锁相环中,整个输出频率范围内都可通过将反馈分频比最小化来改善其环路带宽内的相位噪声。实验结果表明,该频率合成器的输出频率范围为2.1~5.6 GHz,频率步进为1 Hz,当输出为2.1 GHz与5.6 GHz时,在频偏10 kHz处的相位噪声分别为-114.7 dBc/Hz与-108.2 dBc/Hz,其相位噪声测试结果与分析计算结果相吻合。