A Low Phase-Noise QVCO With Integrated Back-Gate Coupling and Source Resistive Degeneration Technique

A 0.18 $mu$ m CMOS quadrature voltage-controlled oscillator with an extremely-low phase noise is presented. The excellent phase noise performance is accomplished by integration of the back-gate quadrature phase coupling and source resistive degeneration techniques into a complementary oscillator topology. The measured phase noise is as low as ${-}133$ dBc/Hz at 1 MHz offset from 3.01 GHz. The output phase imbalance is less than 1$^{circ}$ . The output power is $-1.25{pm} 0.5$ dBm and harmonic suppression is greater than 30.8 dBc. The oscillator core consumes 5.38 mA from a 1.5 V power supply. This QVCO achieves the highest figure-of-merit of ${-}193.5$ dBc/Hz.      

A 4.39–5.26 GHz LC-Tank CMOS Voltage-Controlled Oscillator With Small VCO-Gain Variation

A wide band CMOS LC-tank voltage controlled oscillator (VCO) with small VCO gain $(K_{VCO})$ variation was developed. For small $K_{VCO}$ variation, serial capacitor bank was added to the LC-tank with parallel capacitor array. Implemented in a 0.18 $mu{rm m}$ CMOS RF technology, the proposed VCO can be tuned from 4.39 GHz to 5.26 GHz with the VCO gain variation less than 9.56%. While consuming 3.5 mA from a 1.8 V supply, the VCO has $-$ 113.65 dBc/Hz phase noise at 1 MHz offset from the carrier.      

A Biphase Modulator Circuit for Impulse Radio-UWB Applications

This letter presents a circuit to provide binary phase shift keying to ultra-wideband (UWB) impulse transmitters. The circuit is based on a Gilbert-cell multiplier and uses active on-chip balun and unbalanced-to-balanced converters for single-ended to single-ended operation. Detailed measurements of the circuit show a gain ripple of $pm 1~{rm dB}$ at an overall gain of $-2~{rm dB}$, an input reflection below $-12~{rm dB}$, an output reflection below $-18~{rm dB}$, a group delay variation below 6 ps and a $-1~{rm dB}$ input compression point of more than 1 dBm in both switching states over the full 3.1–10.6 GHz UWB frequency range. A time domain measurement verifies the switching operation using an FCC-compliant impulse generator. The circuit is fabricated in a $0.8~mu {rm m}$ Si/SiGe HBT technology, consumes 31.4 mA at a 3.2 V supply and has a size of $510 times 490~mu{rm m}^{2}$ , including pads. It can be used in UWB systems using pulse correlation reception or spectral spreading.      

A Dual-Band Self-Oscillating Mixer for -Band and -Band Applications

A self-oscillating mixer that employs both the fundamental and harmonic signals generated by the oscillator subcircuit in the mixing process is experimentally demonstrated. The resulting circuit is a dual-band down-converting mixer that can operate in $C$ -band from 5.0 to 6.0 GHz, or in $X$-band from 9.8 to 11.8 GHz. The oscillator uses active superharmonic coupling to enforce the quadrature relationship of the fundamental outputs. Either the fundamental outputs of the oscillator or the second harmonic oscillator output signals that exists at the common-mode nodes are connected to the mixer via a set of complementary switches. The mixer achieves a conversion gain between 5–12 dB in both frequency bands. The output 1-dB compression points for both modes of the mixer are approximately $-{hbox{5 dBm}}$ and the output third-order intercept point for $C$ -band and $X$ -band operation are 12 and 13 dBm, respectively. The integrated circuit was fabricated in 0.13-$mu {hbox{m}}$ CMOS technology and measures ${hbox{0.525 mm}}^{2}$ including bonding pads.      

A 9-pJ/Pulse 1.42-Vpp OOK CMOS UWB Pulse Generator for the 3.1–10.6-GHz FCC Band

This paper presents the design of a fully integrated ultra-wideband (UWB) pulse generator for the Federal Communications Commission (FCC) 3.1–10.6-GHz band. This generator is reserved for medium rate applications and achieves pulses for an on–off keying (OOK) modulation, pulse position modulation, or pulse interval modulation. This UWB transmitter is based on the impulse response filter method, which uses an edge combiner in order to excite an integrated bandpass filter. The circuit has been integrated in an ST-Microelectronics CMOS 0.13-$mu{hbox{m}}$ technology with 1.2-V supply voltage and the die size is 0.54 ${hbox{mm}}^{2}$. The pulse generator power consumption is 9 pJ per pulse and achieves a peak to peak magnitude of 1.42 V. The pulse is FCC compliant and the generator can be used with a rate up to 38 ${hbox{Mbs}}^{-1}$ with an OOK modulation. Based on the FCC power spectral density limitation, a sizing method is also presented.      

A 3–10 GHz CMOS UWB Low-Noise Amplifier With ESD Protection Circuits

A low-power fully integrated low-noise amplifier (LNA) with an on-chip electrostatic-static discharge (ESD) protection circuit for ultra-wide band (UWB) applications is presented. With the use of a common-gate scheme with a ${rm g}_{rm m}$ -boosted technique, a simple input matching network, low noise figure (NF), and low power consumption can be achieved. Through the combination of an input matching network, an ESD clamp circuit has been designed for the proposed LNA circuit to enhance system robustness. The measured results show that the fabricated LNA can be operated over the full UWB bandwidth of 3.0 to 10.35 GHz. The input return loss $({rm S}_{11})$ and output return loss $({rm S}_{22})$ are less than ${-}8.3$ dB and ${-}9$ dB, respectively. The measured power gain $({rm S}_{21})$ is $11 pm 1.5$ dB, and the measured minimum NF is 3.3 dB at 4 GHz. The dc power dissipation is 7.2 mW from a 1.2 V supply. The chip area, including testing pads, is 1.05 mm$,times,$ 0.73 mm.      

A 25-MHz Self-Referenced Solid-State Frequency Source Suitable for XO-Replacement

Recent trends in the development of integrated silicon frequency sources are discussed. Within that context, a 25-MHz self-referenced solid-state frequency source is presented and demonstrated where measured performance makes it suitable for replacement of crystal oscillators (XOs) in data interface applications. The frequency source is referenced to a frequency-trimmed and temperature-compensated 800-MHz free-running $LC$ oscillator (LCO) that is implemented in a standard logic CMOS process and with no specialized analog process options. Mechanisms giving rise to frequency drift in integrated LCOs are discussed and supported by analytical expressions. Design objectives and a compensation technique are presented where several implementation challenges are uncovered. Fabricated in a 0.25-$mu$m 1P5M CMOS process, and with no external components, the prototype frequency source dissipates 59.4 mW while maintaining ${pm} 152$ ppm frequency inaccuracy over process, ${pm} 10hbox{%}$ variation in the power supply voltage, and from ${-}$ 10 $^{circ}$ C to 80 $^{circ}$ C. Variation against other environmental factors is also presented. Nominal period jitter and power-on start-up latency are 2.75 ps$_{rm rms}$ and 268 $mu$s, respectively. These performance metrics are compared with an XO at the same frequency.      

Characterization and Modeling of RF-Performance $(f_{T})$ Fluctuation in MOSFETs

The fluctuation of RF performance (particularly for $f_{T}$ : cutoff frequency) in the transistors fabricated by 90-nm CMOS technology has been investigated. The modeling for $f_{T}$ fluctuation is well fitted with the measurement data within approximately 1% error. Low-$V_{t}$ transistors (fabricated by lower doping concentration in the channel) show higher $f_{T}$ fluctuation than normal transistors. Such a higher $f_{T}$ fluctuation results from $C_{rm gg}$ (total gate capacitance) variation rather than $g_{m}$ variation. More detailed analysis shows that $C_{rm gs} + C_{rm gb}$ (charges in the channel and the bulk) are predominant factors over $C_{rm gd}$ (charges in LDD/halo region) to determine $C_{rm gg}$ fluctuation.      

180$^{circ}$ and 90$^{circ}$ Phase Shifting Networks With an Octave Bandwidth and Small Phase Errors

A new phase shifting network for both 180 $^{circ}$ and 90 $^{circ}$ phase shift with small phase errors over an octave bandwidth is presented. The theoretical bandwidth is 67% for the 180$^{circ}$ phase bit and 86% for the 90$^{circ}$ phase bit when phase errors are $pm 2^{circ}$. The proposed topology consists of a bandpass filter (BPF) branch, consisting of a LC resonator and two shunt quarter-wavelength transmission lines (TLs), and a reference TL. A theoretical analysis is provided and scalable parameters are listed for both phase bits. To test the theory, phase shifting networks from 1 GHz to 3 GHz were designed. The measured phase errors of the 180$^{circ}$ and the 90$^{circ}$ phase bit are $pm 3.5^{circ}$ and $pm 2.5^{circ}$ over a bandwidth of 73% and 102% while the return losses are better than 18 dB and 12 dB, respectively.      

Super-Regenerative Architecture for UWB Pulse Detection: From Theory to RF Front-End Design

This paper presents an optimization of the super-regenerative architecture for impulse-based ultrawideband (UWB) technology dedicated to low-data-rate applications. The receiver belongs to the noncoherent category but enables nanosecond resolution for efficient location and tracking applications. Relying on analytical developments, this paper demonstrates how the super-regenerative architecture can suit the UWB context. Such a receiver enables a high RF gain and pulse-matched filter effect with tied power consumption to be achieved, thanks to the suitable control of the inherent unstable behavior. Bit-error-rate simulations based on this architecture are conducted and show a required $Eb/n_{0}$ of 12.5 dB at $10^{-4}$ in the additive white Gaussian noise channel. RF impairment impacts are evaluated and demonstrate good tolerance to the oscillator central frequency accordance and synchronization issue. Specifications of the circuit and controlled signal are drawn up. To validate this concept, the design of the RF front is performed in the CMOS 0.13-${rm mu}hbox{m}$ technology. It includes an LNA, a transconductance stage, and the detector formed by a fully integrated $LC$ -NMOS oscillator. This circuit consumes less than 10 mA for an RF gain above 50 dB and a 1-GHz-wide input signal bandwidth. The measured sensitivity is $-99 hbox{dBm}$ at $10^{-3}$ for a 1-Mb/s pulse rate for binary modulation.      

Pulsed $I_{d}$– $V_{g}$ Methodology and Its Application to Electron-Trapping Characterization and Defect Density Profiling

The pulsed current–voltage ($I$– $V$) measurement technique with pulse times ranging from $sim$17 ns to $sim$ 6 ms was employed to study the effect of fast transient charging on the threshold voltage shift $Delta V_{t}$ of MOSFETs. The extracted $Delta V_{t}$ values are found to be strongly dependent on the band bending of the dielectric stack defined by the high-$kappa$ and interfacial layer dielectric constants and thicknesses, as well as applied voltages. Various hafnium-based gate stacks were found to exhibit a similar trap density profile.      

A 47 GHz Cross-Coupled VCO Employing High- Island-Gate Varactor for Phase Noise Reduction

A 47 GHz $LC$ cross-coupled voltage controlled oscillator (VCO) employing the high-$Q$ island-gate varactor (IGV) based on a 0.13 $mu{rm m}$ RFCMOS technology is reported in this work. To verify the improvement in the phase noise, two otherwise identical VCOs, each with an IGV and a conventional multi-finger varactor, were fabricated and the phase noise performance was compared. With $V_{DD}$ of 1.2 V and core power consumption of 3.86 mW, the VCOs with the IGV and the multi-finger varactor have a phase noise of $-$95.4 dBc/Hz and $-$91.4 dBc/Hz respectively, at 1 MHz offset, verifying the phase noise reduction with the introduction of the high-$Q$ IGV. The VCO with IGV exhibited an output power of around $-$15 dBm, leading to a FoM of $-$182.9 dBc/Hz and a tuning range of 3.35% (45.69 to 47.22 GHz).      

A Low-Complexity, Low-Phase-Noise, Low-Voltage Phase-Aligned Ring Oscillator in 90 nm Digital CMOS

An 8-phase phase-aligned ring oscillator in 90 nm digital CMOS is presented that operates up to 2 GHz. The low-complexity circuit consumes 13 mW at 2 GHz and 1.2 mW at 400 MHz, while a flat in-band phase noise below $-$120 dBc$/$Hz is achieved, in close agreement with the presented theory. The circuit occupies an area of 0.008 mm$^{2}$ .      

A 0.13 $mu$ m CMOS Quad-Band GSM/GPRS/EDGE RF Transceiver Using a Low-Noise Fractional-N Frequency Synthesizer and Direct-Conversion Architecture

This paper presents a single-chip CMOS quad-band (850/900/1800/1900 MHz) RF transceiver for GSM/GPRS/EDGE applications which adopts a direct-conversion receiver, a direct-conversion transmitter and a fractional-N frequency synthesizer with a built-in DCXO. In the GSM mode, the transmitter delivers 4 dBm of output power with 1$^{circ}$ RMS phase error and the measured phase noise is ${-}$164.5 dBc/Hz at 20 MHz offset from a 914.8$~$MHz carrier. In the EDGE mode, the TX RMS EVM is 2.4% with a 0.5 $~$dB gain step for the overall 36 dB dynamic range. The RX NF and IIP3 are 2.7 dB/ ${-}$12 dBm for the low bands (850/900 MHz) and 3 dB/${-}$ 11 dBm for the high bands (1800/1900 MHz). This transceiver is implemented in 0.13 $mu$m CMOS technology and occupies 10.5 mm$^{2}$ . The device consumes 118 mA and 84 mA in TX and RX modes from 2.8 V, respectively and is housed in a 5$,times,$ 5 mm$^{2}$ 40-pin QFN package.      

A 98/196 GHz Low Phase Noise Voltage Controlled Oscillator With a Mode Selector Using a 90 nm CMOS Process

A 98/196 GHz low phase noise voltage controlled oscillator (VCO) with a fundamental/push-push mode selector using a 90 nm CMOS process is presented in this letter. An innovative concept of the VCO with the mode selector is proposed to switch the fundamental or second harmonic to the RF output. The VCO demonstrates a fundamental frequency of up to 98 GHz with an output power of greater than $-8~{rm dBm}$. The phase noise of the VCO is better than $-100.8~{rm dBc}/{rm Hz}$ at 1 MHz offset frequency, and its figure-of-merit is better than $-186~{rm dBc}/{rm Hz}$. Moreover, the output frequency of the work is up to 196 GHz with a fundamental suppression of greater than $-30~{rm dBc}$ as the VCO is operated in push-push mode.      

A $Q$ -Band Four-Element Phased-Array Front-End Receiver With Integrated Wilkinson Power Combiners in 0.18-$mu{{hbox{m}}}$ SiGe BiCMOS Technology

A four-element phased-array front-end receiver based on 4-bit RF phase shifters is demonstrated in a standard 0.18- $mu{{hbox{m}}}$ SiGe BiCMOS technology for $Q$-band (30–50 GHz) satellite communications and radar applications. The phased-array receiver uses a corporate-feed approach with on-chip Wilkinson power combiners, and shows a power gain of 10.4 dB with an ${rm IIP}_{3}$ of $-$13.8 dBm per element at 38.5 GHz and a 3-dB gain bandwidth of 32.8–44 GHz. The rms gain and phase errors are $leq$1.2 dB and $leq {hbox{8.7}}^{circ}$ for all 4-bit phase states at 30–50 GHz. The beamformer also results in $leq$ 0.4 dB of rms gain mismatch and $leq {hbox{2}}^{circ}$ of rms phase mismatch between the four channels. The channel-to-channel isolation is better than $-$35 dB at 30–50 GHz. The chip consumes 118 mA from a 5-V supply voltage and overall chip size is ${hbox{1.4}}times {hbox{1.7}} {{hbox{mm}}}^{2}$ including all pads and CMOS control electronics.      

A V-Band CMOS VCO With an Admittance-Transforming Cross-Coupled Pair

A novel circuit topology suitable for the implementation of CMOS voltage-controlled oscillators (VCOs) at millimeter-wave frequencies is presented in this paper. By employing transmission line segments to transform the admittance of the additional cross-coupled pair, the proposed LC-tank VCO can sustain fundamental oscillation at a frequency close to the $f _{max}$ of the transistors. Using a standard 0.18 $muhbox{m}$ CMOS process, a V-band VCO is realized for demonstration. The fabricated circuit exhibits a frequency tuning range of 670 MHz in the vicinity of 63 GHz. The measured output power and phase noise at 1 MHz offset are $-hbox{15~dBm}$ and $-hbox{89~dBc}/hbox{Hz}$ , respectively. Operated at a 1.8 $~$V supply voltage, the VCO core and the output buffer consume a total DC current of 55 mA.      

A 24 GHz Amplitude Monopulse Comparator in 0.13 $mu$m CMOS

This letter presents the design and implementation of a wideband 24 GHz amplitude monopulse comparator in 0.13 $mu$m CMOS technology. The circuit results in 9.6 dB gain in the sum channel at 24 GHz with a 3-dB bandwidth of 23.0–25.2 GHz, and a sum/difference ratio of $> 25$ dB at 20–26 GHz. The measured input P1 dB is ${-}14.4$ dBm at 24 GHz. The chip is only 0.55$,times,$ 0.50 mm$^{2}$ (without pads) and consumes 44 mA from a 1.5 V supply, including the input active baluns and the differential to single-ended output stages (28 mA without the input and output stages). To our knowledge, this is the first demonstration of a high performance mm-wave CMOS monopulse comparator RFIC.      

A 2.4–2.5 GHz WLAN Direct-Conversion Receiver Front-End With Low-Distortion Baseband Filters

Low-distortion I/Q baseband filters interface with a 2.5 GHz RF receiver front-end configured as a Gm-cell in a direct-conversion architecture targeted towards WLAN 802.11b application. The active I/Q current-mode filters use AC current to carry the large swing of both desired and blocker signals, relaxing the voltage headroom requirement to a 1.2 V supply. An on chip master–slave automatic tuner is used to lock the filter bandwidth to a precision 20 MHz reference crystal oscillator, resulting in a $≪ ,$3% tuning accuracy and $≪, $ 0.5% I/Q bandwidth matching. The receiver achieves a 3.2 dB DSB NF, ${-}$14 dBm out-of-band IIP3, and ${+}$ 27 dBm worst case IIP2, all referred to the LNA input, while drawing 30mA from a 2.7 V supply. The chip is fabricated in a 0.5 $mu$m 46 GHz $f_{T}$ SiGe BiCMOS process. The active area is 2.54 mm$^{2}$ .      

A 30–100 GHz Wideband Sub-Harmonic Active Mixer in 90 nm CMOS Technology

This letter presents a 30–100 GHz wideband and compact fully integrated sub-harmonic Gilbert-cell mixer using 90 nm standard CMOS technology. The sub-harmonic pumped scheme with advantages of high port isolation and low local oscillation frequency operation is selected in millimeter-wave mixer design. A distributed transconductance stage and a high impedance compensation line are introduced to achieve the flatness of conversion gain over broad bandwidth. The CMOS sub-harmonic Gilbert-cell mixer exhibits ${-}{hbox{1.5}} pm {hbox{1.5}}$ dB measured conversion gain from 30 to 100 GHz with a compact chip size of 0.35 mm$^{2}$. The OP$_{1 {rm dB}}$ of the mixer is ${-}$ 10.4 dBm and ${-}$9.6 dBm at 77 and 94 GHz, respectively. To the best of our knowledge, the monolithic microwave integrated circuit is the first CMOS Gilbert-cell mixer operating up to 100 GHz.