Low-power CMOS LC QVCO using zero-biased transistor coupling of MWCNT network-based VCO structure

This paper presents design, analysis and implementation of a 2.4 GHz QVCO (Quadrature Voltage Controlled Oscillator), for low-power, low-voltage applications. Cross coupled LC VCO (Inductor–Capacitor Voltage Controlled Oscillator) topology realized using integration of a micro-scaled capacitor and a MWCNT (Multi-Wall Carbon Nano-Tube) network based inductor together with the CMOS circuits is utilized together with MOS transistors as coupling elements to realize QVCO. With the passive coupling achieved from the MOS transistors, power consumption is minimized while maintaining a small chip area. The variable capacitors and the inductors are designed using ANSYS and imported through DAC components in ADS (Advanced Design software). Accurate simulation of the QVCO is performed in the software environments and the results are provided. The measurement results show that the QVCO provides quadrature signals at 2.4 GHz and achieves a phase noise of −130 dBc/Hz 1 MHz away from the carrier frequency. The VCO produces frequency tuning from 2.1 GHz to 2.60 GHz (20.83%) with a control voltage varying from 0 to 0.3 V. It achieves a peak to peak voltage of 0.59 V with an ultra low power consumption of 3.8 mW from a 0.6 V supply voltage. The output power level of the QVCO is −10 dBm, with an improved quality factor of 45. The phase error of the QVCO is measured as 3.1°.     

Floating active inductor based Class-C VCO with 8 digitally tuned sub-bands

A fully integrated floating active inductor based voltage-controlled oscillator (VCO) is presented. The active inductor employs voltage differencing transconductance amplifier (VDTA) as a building block. The designed VCO achieves frequency tuning by varying the bias current through the VDTA and utilizes a Class-C topology for improving the phase noise performance. The inductor-less VCO is designed and implemented in a 45-nm CMOS process and its performance is estimated using Virtuoso ADE of Cadence. Operating at a supply voltage of ±1 V, the proposed VCO consumes 0.44–1.1 mW corresponding to the oscillation frequency of 1.1–1.8 GHz thereby exhibiting a tuning range of 48.27%. The phase noise of the VCO lies in the range of −94.12 to −98.37 dBc/Hz at 1 MHz offset resulting in a FOM of −172.14 to −176.69 dBc/Hz.     

Wide-tuning-range,low-phase-noise quadrature ring oscillator exploiting a novel noise canceling technique

This paper presents a novel noise-canceling technique, which is used to improve the phase noise of a two-stage quadrature ring oscillator. The thermal noise canceling circuitry is used to cancel the channel thermal noise of the output transistors in each stage of the oscillator. Simulations using TSMC 0.13 μm CMOS technology show a wide frequency tuning range of 315 MHz to 6.64 GHz and ?97.5 dBc/Hz at 1 MHz offset from 4.7 GHz for changing supply from 0.5 V to 1.6 V. The power consumption is obtained to be 14.8 mW. The proposed oscillator can be used in applications such as ultra-wideband systems, and multiband and multimode receivers.     

MISO current mode bi-quadratic filter employing high performance inverting second generation current conveyor circuit

This paper presents static and dynamic studies of a new CMOS realization for the inverting second generation current conveyor circuit (ICCII). The proposed design offers enhanced functionalities compared to ICCII circuits previously presented in the literature. It is characterized by a rail to rail dynamic range with high accuracy, a low parasitic resistor at terminal X (1.6 Ω) and low power consumption (0.31 mW) with wide current mode (3.32 GHz) and voltage mode (3.9 GHz) bandwidths.Furthermore, a new MISO current mode bi-quadratic filter based on using ICCII circuits as active elements is proposed. This filter can realize all standard filter responses without changing the circuit topology. It is characterized by active and passive sensitivities less than unity and an adjustment independently between pole frequency and quality factor. The operating frequency limit of this filter is about 0.8 GHz with 0.674 mW power consumption.The proposed current conveyor circuits and bi-quadratic filter are tested by TSPICE using CMOS 0.18 µm TSMC technology with ±0.8 V supply voltage to verify the theoretical results.     

Dual-resonance concurrent oscillator

This paper studies a new dual-band CMOS class-C voltage-controlled oscillator (VCO). The oscillator consists of a dual-resonance LC resonator in shunt with two pairs of capacitive cross-coupled nMOSFETs. The proposed oscillator has been implemented with the TSMC 0.18 μm CMOS technology, and it shows a frequency tuning range with two frequency bands and a small tuning hysteresis is measured. The oscillator can generate differential signals at 2.4 GHz and 6.9 GHz and it also can generate concurrent frequency oscillation while the circuit is biased around the bias with frequency tuning hysteresis. With the supply voltage of V_DD = 1.1 V, the VCO-core current and power consumption of the oscillator are 2.90 mA and 3.19 mW, respectively. The die area of the class-C oscillator is 0.9 × 0.97 mm². Overvoltage stress is applied to the oscillator, measurement indicates the concurrent oscillation is sensitive to overvoltage stress.     

A 5-GHz LC VCO with digital AAC and AFBS for 2.4 GHz ZigBee transceiver applications

A 5 GHz LC VCO (voltage-controlled oscillator) with automatic amplitude control (AAC) and automatic frequency-band selection (AFBS) for 2.4 GHz ZigBee transceivers is presented. Instead of continuous feedback loop, an alternative amplitude calibration scheme is proposed in this paper to alleviate the deficiencies inherent in the conventional approach. It helps to keep the VCO at optimum amplitude to avoid saturation of the cross-coupled transistors and therefore stabilizes the phase noise performance over process, voltage and temperature variations. For the ZigBee application with 16 frequency channels, a coarse tuning loop is added in this work to implement the frequency-band selection using the AFBS mechanism. The VCO core and the digital AAC, AFBS modules have been fully integrated in a 2.4 GHz ZigBee transceiver which was fabricated in a 0.18 μm RF-CMOS technology. The current consumption is 4.7 mA at 4.85 GHz with 1.8 V power supply and a chip area of about 0.285 mm² is occupied. The VCO is capable of operating from 4.67 GHz to 5.18 GHz and the measured phase-noise level is –120 dBc/Hz at 1 MHz offset from a 4.85 GHz carrier. The tuning sensitivity K_VCO of the VCO is about 78 MHz/V with 0.9 V control voltage.     

Improving linearity in MOS varactor based VCOs by means of the output quiescent bias point

This paper presents a CMOS based LC tank VCO topology improving the tuning range linearity. The VCO tuning range is linearized with PMOS varactors which remain in the inversion region for an extended range of the control voltage. This is achieved with the design of the quiescent operating point in the VCO's output nodes with a value close to the voltage rails, letting the varactors to behave quasi linearly in the achievable VCO tuning range. The experimental results of a VCO in a CMOS 0.35 µm process show a linear tuning range improvement of 75% of the control voltage in the (1.43–1.55) GHz range, with a minimum VCO gain variation compared to similar architectures. The results show a phase noise improvement from −94 dBc/Hz to −124 dBc/Hz @600 kHz offset from the carrier with an overall reduced amplitude noise for the VCO.     

A tunable CMOS Wilkinson power divider using active inductors

This paper presents the design and implementation of a tunable CMOS Wilkinson power divider using active inductors. Compared to a conventional active inductor topology, the proposed active inductor features higher inductance tuning range, higher self-resonant frequency, and lower power consumption by introducing two additional transistors. Benefitting from the superior inductor, the low-loss Wilkinson power divider is practical while maintaining a wide tuning range. The design consuming 10.2 mW demonstrates an insertion loss of 0.67 dB, a return loss of 27 dB, and an isolation of 22.6 dB at 8 GHz. Moreover, the tuning range of the circuit is between 5.8 GHz and 10.4 GHz, rendering a 4.6 GHz bandwidth. The active chip size of the lumped design is merely 0.25 mm × 0.15 mm.     

A low phase noise and low power 3–5 GHz frequency synthesizer in 0.18 µm CMOS technology

A low power frequency synthesizer for WLAN applications is proposed in this paper. The NMOS transistor-feedback voltage controlled oscillator (VCO) is designed for the purpose of decreasing phase noise. TSPC frequency divider is designed for widening the frequency range with keeping low the power consumption. The phase frequency detector (PFD) with XOR delay cell is designed to have the low blind and dead zone, also for neutralizing the charge pump (CP) output currents; the high gain operational amplifier and miller capacitors are applied to the circuit. The frequency synthesizer is simulated in 0.18 µm CMOS technology while it works at 1.8 V supply voltage. The VCO has a phase noise of −136 dBc/Hz at 1 MHz offset. It has 10.2% tuning range. With existence of a frequency divider in the frequency synthesizer loop the output frequency of the VCO can be divided into the maximum ratio of 18. It is considered that the power consumption of the frequency synthesizer is 4 mW and the chip area is 10,400 µm².     

Oscillation-controlled CMOS ring oscillator for wireless sensor systems

This paper presents a ring oscillator with the function of the oscillation controlled for wireless sensor systems (WSSs). The proposed oscillator consists of a NAND gate, 4 inverters, and 1-, 3-, 9-times buffer stage. Operation of it is controlled by the NAND gate. The oscillator can reduce the power loss because the oscillator is oscillated during only high level input. The proposed oscillator was designed and fabricated by 2.5 μm CMOS technology, through which it is possible to realize a WSS on a single chip because a sensor and an oscillator can be fabricated concurrently.The frequency tuning range of the oscillator was found to be approximately 90–152 MHz and the output power of the oscillator was ?8.42 dBm. The measured phase noise is ?99.35 and ?102.59 dBc/Hz at 1 and 5 MHz offsets, respectively, from the carrier of 152 MHz. Power consumption of the oscillator is determined by the duty cycle of the input signal pulse, and the range of power consumption was measured as 1.5–45 mW at the duty cycle of 1.0.     

A design methodology for integrated inductor-based DC–DC converters

A design methodology for monolithic integration of inductor based DC–DC converters is proposed in this paper. A power loss model of the power stage, including the drive circuits, is defined in order to optimize efficiency. Based on this model and taking as reference a 0.35 μm CMOS process, a buck converter was designed and fabricated. For a given set of operating conditions the defined power loss model allows to optimize the design parameters for the power stage, including the gate-driver tapering factor and the width of the power MOSFETs. Experimental results obtained from a buck converter at 100 MHz switching frequency are presented to validate the proposed methodology.     

Impact of technology scaling on the tuning range and phase noise of mm-wave CMOS LC-VCOs

The impact of CMOS technology scaling, on the tuning range and phase noise performance of mm-wave LC voltage controlled oscillators (LC-VCOs) is presented. As a preliminary step, the fundamental LC-VCO elements (i) tank inductor, (ii) fixed and variable capacitor elements, and (iii) cross-coupled transistor pair are analytically modeled across the frequency range 10–50 GHz. These models are then exploited to analyze the tuning range and phase noise revealing the ultimate performance bounds for simultaneously achieving low phase noise and wide tuning range in mm-wave CMOS LC-VCOs across the CMOS technology scaling (from 130 nm down to 45 nm) are explored. The analysis demonstrates the improvement of the maximum achievable tuning range, phase noise, and figures-of-merit (FoM and FoM_T) with the technology down scaling. Finally, the performance trend of the mm-wave CMOS LC-VCOs implemented using both thin and thick gate cross-coupled pair is compared. The analysis indicates that thick gate cross-coupled pair VCOs achieve better phase noise at the expense of power consumption and maximum tuning range.     

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 resistive-feedback LNA in 65 nm CMOS with a gate inductor for bandwidth extension

In order to get a wideband and flat gain, a resistive-feedback LNA using a gate inductor to extend bandwidth is proposed in this paper. This LNA is based on an improved resistive-feedback topology with a source follower feedback to match input. A relative small inductor is connected in series to transistor׳s gate, which boosts transistor׳s effective transconductance, compensates gain loss and then leads the proposed LNA with a flat gain and wider bandwidth. Moreover, the LNA׳s noise is partially inhibited by the gate inductor, especially at high frequency. Realized in standard 65-nm CMOS process, this LNA dissipates 12 mW from a 1.5-V supply while its core area is 0.076 mm². Across 0.4–10.6 GHz band, the proposed LNA provides 9.5±0.9 dB power gain (S₂₁), better than −11-dB input matching, 3.5-dB minimum noise figure, and higher than −17.2-dBm P_1 dB.     

A high-gain low-power 2–14 GHz ultra-wide-band CMOS LNA for wireless receivers

In this paper, a 2–14 GHz CMOS LNA for ultra-wide-band (UWB) wireless systems is presented. To achieve a good and flat high power gain along with a low noise figure and a high input return loss, the proposed LNA adopts a capacitive cross-coupling common-gate (CG) topology with extra cascaded transistors and inductance. Over the entire 2–14 GHz bandwidth, it exhibits a return loss less than ?10 dB and a small-signal gain of 9 dB. With an input intercept point of ?3 dBm at 5 GHz, it consumes only 9 mW from a 1.5 V supply voltage.     

Low-loss active inductor with independently adjustable self-resonance frequency and quality factor parameters

This work presents a new low-loss active inductor whose self-resonance frequency and quality factor parameters can be adjusted independently from each other. In order to achieve this property, a new input topology has been employed which consists of cascode structure with a diode connected transistor. Furthermore, the proposed input topology makes the device robust in terms of its performance over variation in process, voltage and temperature. Additionally, RC feedback is used to cancel series-loss resistance of the active inductor, which allows self-resonant enhancement as well. Schematic and post-layout simulation results show the theoretical validity of the design. To validate the design feasibility for process, voltage and temperature changes, Monte Carlo and temperature analysis are done. Suggested structure shows inductor behavior in the frequency range of 0.3–11.3 GHz. Maximum quality factor is obtained as high as 2.1k at 5.9 GHz. Total power consumption is as low as 1 mW with 1.8 V power supply.     

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     

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.     

A UWB CMOS low-noise amplifier with noise reduction and linearity improvement techniques

In this paper, a highly linear CMOS low noise amplifier (LNA) for ultra-wideband applications is presented. The proposed LNA improves both input second- and third-order intercept points (IIP2 and IIP3) by canceling the common-mode part of all intermodulation components from the output current. The proposed LNA structure creates equal common-mode currents with the opposite sign by cascading two differential pairs with a cross-connected output. These currents eliminate each other at the output and improve the linearity. Also, the proposed LNA improves the noise performance by canceling the thermal noise of the input and auxiliary transistors at the output. Detailed analysis is provided to show the effectiveness of the proposed LNA structure. Post-layout circuit level simulation results using a 90 nm RF CMOS process with Spectre-RF reveal 9.5 dB power gain, -3 dB bandwidth (BW_−3dB) of 8 GHz from 2.4 GHz to 10.4 GHz, and mean IIP3 and IIP2 of +13.1 dBm and +42.8 dBm, respectively. The simulated S₁₁ is less than −11 dB in whole frequency range while the LNA consumes 14.8 mW from a single 1.2 V power supply.     

A 10 GHz low phase-noise CMOS voltage-controlled oscillator using dual-transformer technology

A novel low phase-noise differential Colpitts VCO by using transformer feedback technology is presented in this paper. This work demonstrates a simple differential topology with dual-transformer approach to reduce phase-noise at low DC power consumption. A symmetrical circuit layout can be realized easily by transformers and a commonly cross-coupled structure is not adopted herein because cross couple feedback path is also a serious parasitic effect more at 10 GHz operation. Therefore, dual-transformers provide a compact feedback path and DC feed path simultaneously. Consuming a DC power of 8 mW in the VCO core, the circuit exhibits a phase-noise of ?115 dBc/Hz at offset frequency of 1-MHz and the figure of merit value is ?184.1 dBc.