Millimeter-wave voltage-controlled oscillators in 0.13-/spl mu/m CMOS technology

This paper describes the design of CMOS millimeter-wave voltage controlled oscillators. Varactor, transistor, and inductor designs are optimized to reduce the parasitic capacitances. An investigation of tradeoff between quality factor and tuning range for MOS varactors at 24 GHz has shown that the polysilicon gate lengths between 0.18 and 0.24 /spl mu/m result both good quality factor (>12) and C/sub max//C/sub min/ ratio (/spl sim/3) in the 0.13-/spl mu/m CMOS process used for the study. The components were utilized to realize a VCO operating around 60 GHz with a tuning range of 5.8 GHz. A 99-GHz VCO with a tuning range of 2.5 GHz, phase noise of -102.7 dBc/Hz at 10-MHz offset and power consumption of 7-15mW from a 1.5-V supply and a 105-GHz VCO are also demonstrated. This is the CMOS circuit with the highest fundamental operating frequency. The lumped element approach can be used even for VCOs operating near 100-GHz and it results a smaller circuit area.     

Design of wide-band CMOS VCO for multiband wireless LAN applications

In this paper, a general design methodology of low-voltage wide-band voltage-controlled oscillator (VCO) suitable for wireless LAN (WLAN) application is described. The applications of high-quality passives for the resonator are introduced: 1) a single-loop horseshoe inductor with Q > 20 between 2 and 5 GHz for good phase noise performance; and 2) accumulation MOS (AMOS) varactors with C/sub max//C/sub min/ ratio of 6 to provide wide-band tuning capability at low-voltage supply. The adverse effect of AMOS varactors due to high sensitivity is examined. Amendment using bandswitching topology is suggested, and a phase noise improvement of 7 dB is measured to prove the concept. The measured VCO operates on a 1-V supply with a wide tuning range of 58.7% between 3.0 and 5.6 GHz when tuned between /spl plusmn/0.7 V. The phase noise is -120 dBc/Hz at 3.0 GHz, and -114.5 dBc/Hz at 5.6 GHz, with the nominal power dissipation between 2 and 3 mW across the whole tuning range. The best phase noise at 1-MHz offset is -124 dBc/Hz at the frequency of 3 GHz, a supply voltage of 1.4 V, and power dissipation of 8.4 mW. When the supply is reduced to 0.83 V, the VCO dissipates less than 1 mW at 5.6 GHz. Using this design methodology, the feasibility of generating two local oscillator frequencies (2.4-GHz ISM and 5-GHz U-NII) for WLAN transceiver using a single VCO with only one monolithic inductor is demonstrated. The VCO is fabricated in a 0.13-/spl mu/m partially depleted silicon-on-insulator CMOS process.     

A 1.9-GHz CMOS VCO with micromachined electromechanically tunablecapacitors

This paper presents a 1.9-GHz CMOS voltage-controlled oscillator (VCO) where the resonant circuit consists of micromachined electromechnically tunable capacitors and a bonding wire inductor. The tunable capacitors were implemented in a MUMP's polysilicon surface micromachining process. These devices have a nominal capacitance of 2.1 pF and a quality factor (Q-factor) of 9.3 at 1.9 GHz. The capacitance is variable from 2.1 pF to 2.9 pF within a 4-V control, voltage range. The active circuits were fabricated in a 0.5-μm CMOS process. The VCO was assembled in a ceramic package where the MUMP's and CMOS dice were bonded together. The experimental VCO achieves a phase noise of -98 dBc/Hz and -126 dBc/Hz at 100 kHz and 600 kHz offsets from the carrier, respectively. The tuning range of the VCO is 9%. The VCO circuit and the output buffer consume 15 mW and 30 mW from a 2.7-V power supply, respectively     

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.     

5-GHz CMOS LC VCOs with wide tuning ranges

A 4.8-GHz LC voltage-controlled oscillator (VCO) optimized for maximum tuning range was designed and fabricated using 0.25-/spl mu/m 1P5M CMOS process. The optimized design used an inverse proportionality between the two parasitic capacitances of the inductor and the MOS transistors for minimizing the parasitic capacitance at the oscillation node. The fabricated LC VCO has a wide tuning range of 20.3% from 4.32 GHz to 5.3 GHz with a power dissipation of 7.3 mW. This tuning range performance is comparable to, or better than, those of the reported CMOS LC VCOs in 5-GHz band. The measured phase noise is -82 dBc/Hz and -114.6 dBc/Hz at 100 KHz and 1-MHz offset, respectively.     

9.3-10.4-GHz-band cross-coupled complementary oscillator with low phase-noise performance

A fully integrated 10-GHz-band voltage-controlled oscillator (VCO) has been designed and fabricated using commercial 0.18-/spl mu/m CMOS technology. The complementary cross-coupled differential topology is adopted in the design. The measured phase-noise is around -89 dBc/Hz at the offset frequency of 100 kHz from the center frequency of 9.83 GHz, the output frequency tuning range of the fabricated VCO is 1.1 GHz ranging from 9.3 to 10.4 GHz, and the power consumption of the core VCO circuit is 5.8 mW. The design is the first one that adopts the complementary cross-coupled circuit structure for 10-GHz-band oscillators, and whose performances of the VCO are the best ones for 10-GHz-band oscillators, compared with the 10-GHz-band CMOS oscillators reported earlier.     

Wide tuning-range CMOS VCO based on a tunable active inductor

In this paper, a wide tuning-range CMOS voltage-controlled oscillator (VCO) with high output power using an active inductor circuit is presented. In this VCO design, the coarse frequency is achieved by tuning the integrated active inductor. The circuit has been simulated using a 0.18-µm CMOS fabrication process and presents output frequency range from 100 MHz to 2.5 GHz, resulting in a tuning range of 96%. The phase noise is –85 dBc/Hz at a 1 MHz frequency offset. The output power is from –3 dBm at 2.55 GHz to +14 dBm at 167 MHz. The active inductor power dissipation is 6.5 mW and the total power consumption is 16.27 mW when operating on a 1.8 V supply voltage. By comparing this active inductor architecture VCO with general VCO topology, the result shows that this topology, which employs the proposed active inductor, produces a better performance.     

A fully integrated 5.8 GHz U-NII band 0.18-/spl mu/m CMOS VCO

A fully integrated 5.8 GHz CMOS L-C tank voltage-controlled oscillator (VCO) using a 0.18-/spl mu/m 1P6M standard CMOS process for 5 GHz U-NII band WLAN application is presented. The VCO core circuit uses only PMOS to pursue a better phase noise performance since it has less 1/f noise than NMOS. The measurement is performed by using a FR-4 PCB test fixture. The output frequency of the VCO is from 5860 to 6026 MHz with a 166 MHz tuning range and the phase noise is -96.9 dBc/Hz at 300 kHz (or -110 dBc/Hz at 1 MHz) with V ctrl = 0 V. The power consumption of the VCO excluding buffer amplifiers is 8.1 mW at V/sub DD/ = 1.8 V and the output power is -4 dBm.     

A 5-GHz low phase noise differential colpitts CMOS VCO

A low noise 5-GHz differential Colpitts CMOS voltage-controlled oscillator (VCO) is proposed in this letter. The Colpitts VCO core adopts only PMOS in a 0.18-/spl mu/m CMOS technology to achieve a better phase noise performance since PMOS has lower 1/f noise than NMOS. The VCO operates from 4.61 to 5 GHz with 8.3% tuning range. The measured phase noise at 1-MHz offset is -120.42 dBc/Hz at 5 GHz and -120.99 dBc/Hz at 4.61 GHz. The power consumption of the VCO core is only 3 mW. To the authors' knowledge, this differential Colpitts CMOS VCO achieves the best figure of merit (FOM) of 189.6 dB at 5-GHz band.     

A low-voltage 40-GHz complementary VCO with 15% frequency tuning range in SOI CMOS technology

The design of a low-voltage 40-GHz complementary voltage-controlled oscillator (VCO) with 15% frequency tuning range fabricated in 0.13-/spl mu/m partially depleted silicon-on-insulator (SOI) CMOS technology is reported. Technological advantages of SOI over bulk CMOS are demonstrated, and the accumulation MOS (AMOS) varactor limitations on frequency tuning range are addressed. At 1.5-V supply, the VCO core and each output buffer consumes 11.25 mW and 3 mW of power, respectively. The measured phase noise at 40-GHz is -109.73 dBc/Hz at 4-MHz offset from the carrier, and the output power is -8 dBm. VCO performance using high resistivity substrate (/spl sim/300-/spl Omega//spl middot/cm) has the same frequency tuning range but 2 dB better phase noise compared with using low resistivity substrate (10 /spl Omega//spl middot/cm). The VCO occupies a chip area of only 100 /spl mu/m by 100 /spl mu/m (excluding pads).     

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.     

Wafer-level packaging technology for high-Q on-chip inductors and transmission lines

In the current trend toward portable applications, high-Q integrated inductors have gained considerable importance. Hence, much effort has been spent to increase the performance of on-chip Si inductors. In this paper, wafer-level packaging (WLP) techniques have been used to integrate state-of-the-art high-Q on-chip inductors on top of a five-levels-of-metal Cu damascene back-end of line (BEOL) silicon process using 20-/spl Omega//spl middot/cm Si wafers. The inductors are realized above passivation using thick post-processed low-K dielectric benzocyclobutene (BCB) and Cu layers. For a BCB-Cu thickness of 16 /spl mu/m/10 /spl mu/m, a peak single-ended Q factor of 38 at 4.7 GHz has been measured for a 1-nH inductor with a resonance frequency of 28 GHz. Removing substrate contacts slightly increases the performance, though a more significant improvement has been obtained by combining post-processed passives with patterned ground shields: for a 2.3-nH above integrated-circuit (above-IC) inductor, a 115% increase in Q/sub BW//sup max/ (37.5 versus 17.5) and a 192% increase in resonance frequency (F/sub res/: 12 GHz versus 5 GHz) have been obtained as compared to the equivalent BEOL realization with a patterned ground shield. Next to inductors, high-quality on-chip transmission lines may be realized in the WLP layers. Losses below -0.2 dB/mm at 25 GHz have been measured for 50-/spl Omega/ post-processed coplanar-waveguide lines, above-IC thin-film microstrip lines have measured losses below -0.12 dB/mm at 25 GHz.     

Q-factor definition and evaluation for spiral inductors fabricated using wafer-level CSP technology

A novel Q-factor definition and evaluation method are proposed for low-loss high-Q spiral inductors fabricated by using the wafer-level chip-size package (WLP) on silicon substrates, where the copper wiring technology with a polyimide isolation layer is used. In conventional Q-factor evaluation for inductors, a short-circuited load condition is used, where the Q factor is represented by using Y-parameters as Q=Im{1/Y/sub 11/}/Re{1/Y/sub 11/}. This conventional method provides a Q factor of 20 with 2-5-nH inductance around 3.9 GHz. However, since structures for the spiral inductors are asymmetrical, the short-circuited load condition and short-circuited source condition give different Q values, respectively. The Q-value differences of approximately 100% have often been observed in the WLP. The differences mainly come from differences in loss estimation. In a novel method, a complex conjugate impedance-matching condition is retained both at an input port and an output port of the inductor. The maximum available power gain (G/sub AMAX/) is introduced to evaluate the energy loss in one cycle. This condition provides a unique insertion loss of passive devices. Thus, the difference of the Q factor depends only on the difference of magnetic and electric energy. The difference of the Q value is reduced.     

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 0.6 V, 4.32 mW, 68 GHz Low Phase-Noise VCO With Intrinsic-Tuned Technique in 0.13 $mu$m CMOS

An intrinsic-tuned, 68 GHz voltage controlled oscillator (VCO) without an extra on-chip accumulation-mode metal oxide semiconductor (MOS)-varactor is demonstrated in a standard, 0.13 mum CMOS technology. This VCO exhibits phase noises of -98.4 dBc/Hz and -115.2 dBc/Hz at 1 and 10 MHz offset, respectively, along with a tuning range of 4.5 % even under a small power consumption of 4.32 mW. Besides, the highest figure-of-merit (taking frequency tuning range into account) of -182 dBc/Hz under the 1 MHz offset condition is achieved among all previously reported >60 GHz CMOS-based VCOs, which is attributed to the proposed intrinsic tuning mechanism.     

A Wide Tuning Range Voltage Controlled Oscillator with a High Tunable Active Inductor

This paper presents a wide tuning range CMOS voltage controlled oscillator (VCO) with a high-tunable active inductor circuit. In this VCO circuit, the coarse frequency is achieved by tuning the integrated active inductor circuit. The VCO circuit is designed in 0.18  \(\upmu \hbox {m}\) CMOS process and simulated with Cadence Spectra. The simulation results show the frequency tuning range from 120 MHz to 2 GHz resulting in a tuning range of 94 %. The phase noise variation is from \(-\) 80 to \(-\) 90 dBc/Hz at a 1 MHz frequency offset, and output power variation is from \(-\) 4.7 to \(+\) 11.5 dBm. The active inductor power consumption is 2.2 mW and the total power dissipation is 7 mW from a 1.8 V DC power supply. By comparing the proposed VCO circuit with the general VCO topology, the results show that this VCO architecture by using the novel, high-tunable and low power active inductor circuit, presents a better performance regarding low chip size, low power consumption, high tuning range and high output power.     

A 21.5/43-GHz dual-frequency balanced Colpitts VCO in SiGe technology

A balanced Colpitts voltage-controlled oscillator (VCO) is designed and fabricated in a commercially available 0.25-/spl mu/m SiGe BiCMOS process. It has the characteristics of the push-push VCO, i.e., the VCO has simultaneously a differential output at a fundamental frequency of 21.5 GHz and a single-ended output at the second harmonic frequency of 43 GHz. A differential tuning technique is applied to reduce the phase noise. The measured phase noise at 1-MHz offset is -113 dBc/Hz at 21.5 GHz and -107 dBc/Hz at 43 GHz. The corresponding output power is about -6 and -17 dBm, respectively, with a 5% tuning range and a 130-mW dc power consumption.     

192 GHz push-push VCO in 0.13 /spl mu/m CMOS

A 192 GHz cross-coupled push-push voltage controlled oscillator (VCO) is fabricated using the UMC 0.13 /spl mu/m CMOS logic process. The VCO can be tuned from 191.4 to 192.7 GHz. The VCO provides output power of /spl sim/-20 dBm and phase noise of /spl sim/-100 dBc/Hz at 10 MHz offset, while consuming 11 mA from a 1.5 V supply.     

一种用于双波段GPS接收机的低功耗宽带CMOS频率合成器

提出了一种用于双波段GPS接收机的宽带CMOS频率合成器.该GPS接收机芯片已经在标准O.18μm射频CMOS工艺线上流片成功,并通过整体功能测试.其中压控振荡器可调振荡频率的覆盖范围设计为2～3.6GHz,覆盖了L1,L2波段的两倍频的频率点.并留有足够的裕量以确保在工艺角和温度变化较大时能覆盖所需频率.芯片测试结果显示,该频率综合器在L1波段正常工作时的功耗仅为5.6mW,此时的带内相位噪声小于-82dBc/Hz,带外相位噪声在距离3.142G载波1M频偏处约为-112dBc/Hz,这些指标很好地满足了GPS接收芯片的性能要求.     

A K-band InGaP/GaAs HBT balanced MMIC VCO

A fully integrated K-band balanced voltage controlled oscillator (VCO) is presented. The VCO is realized using a commercially available InGaP/GaAs heterojunction bipolar transistor (HBT) technology with an f/sub T/ of 60 GHz and an f/sub MAX/ of 110 GHz. To generate negative resistance at mm-wave frequencies, common base inductive feedback topology is used. The VCO provides an oscillation frequency from 21.90 GHz to 22.33 GHz. The frequency tuning range is about 430 MHz. The peak output power is -0.3 dBm. The phase noise is -108.2 dBc/Hz at 1 MHz offset at an operating frequency of 22.33 GHz. The chip area is 0.84/spl times/1.00 mm/sup 2/.