Review of Injected Oscillators

Oscillators are critical components in electrical and electronic engineering and other engineering and sciences. Oscillators are classified as free-running oscillators and injected oscillators. This chapter describes the background necessary for the analysis and design of injected oscillators. When an oscillator is injected by an external periodic signal mentioned as an injection signal, it is called an injected oscillator. Consequently, two phenomena occur in the injected oscillators: (I) pulling phenomena and (II) locking phenomena. For locking phenomena, the oscillation frequency of the injection signal must be near free-running oscillation frequency or its sub-/super-harmonics. Due to these phenomena are nonlinear phenomena, it is tough to achieve the exact equation or closed-form equation of them. Therefore, researchers are scrutinizing them by different analytical and numerical methods for accomplishing an exact inside view of their performances. In this chapter, injected oscillators are investigated in two main subjects: first, analytical methods on locking and pulling phenomena are reviewed, and second, applications of injected oscillators are reviewed such as injection-locked frequency dividers at the latter. Furthermore, methods of enhancing the locking range are introduced

Millimeter-wave Communication and Radar Sensing — Opportunities, Challenges, and Solutions

With the development of communication and radar sensing technology, people are able to seek for a more convenient life and better experiences. The fifth generation (5G) mobile network provides high speed communication and internet services with a data rate up to several gigabit per second (Gbps). In addition, 5G offers great opportunities of emerging applications, for example, manufacture automation with the help of precise wireless sensing. For future communication and sensing systems, increasing capacity and accuracy is desired, which can be realized at millimeter-wave spectrum from 30 GHz to 300 GHz with several tens of GHz available bandwidth. Wavelength reduces at higher frequency, this implies more compact transceivers and antennas, and high sensing accuracy and imaging resolution. Challenges arise with these application opportunities when it comes to realizing prototype or demonstrators in practice. This thesis proposes some of the solutions addressing such challenges in a laboratory environment.High data rate millimeter-wave transmission experiments have been demonstrated with the help of advanced instrumentations. These demonstrations show the potential of transceiver chipsets. On the other hand, the real-time communication demonstrations are limited to either low modulation order signals or low symbol rate transmissions. The reason for that is the lack of commercially available high-speed analog-to-digital converters (ADCs); therefore, conventional digital synchronization methods are difficult to implement in real-time systems at very high data rates. In this thesis, two synchronous baseband receivers are proposed with carrier recovery subsystems which only require low-speed ADCs [A][B].Besides synchronization, high-frequency signal generation is also a challenge in millimeter-wave communications. The frequency divider is a critical component of a millimeter-wave frequency synthesizer. Having both wide locking range and high working frequencies is a challenge. In this thesis, a tunable delay gated ring oscillator topology is proposed for dual-mode operation and bandwidth extension [C]. Millimeter-wave radar offers advantages for high accuracy sensing. Traditional millimeter-wave radar with frequency-modulated continuous-wave (FMCW), or continuous-wave (CW), all have their disadvantages. Typically, the FMCW radar cannot share the spectrum with other FMCW radars.\ua0 With limited bandwidth, the number of FMCW radars that could coexist in the same area is limited. CW radars have a limited ambiguous distance of a wavelength. In this thesis, a phase-modulated radar with micrometer accuracy is presented [D]. It is applicable in a multi-radar scenario without occupying more bandwidth, and its ambiguous distance is also much larger than the CW radar. Orthogonal frequency-division multiplexing (OFDM) radar has similar properties. However, its traditional fast calculation method, fast Fourier transform (FFT), limits its measurement accuracy. In this thesis, an accuracy enhancement technique is introduced to increase the measurement accuracy up to the micrometer level [E]

A Novel Retro-directive Phased Array Antenna Architecture

Mobile wireless communication scenarios can range from a simple indoor WiFi link to a satellite internet connection to an airplane. Virtually in all scenarios, dynamic changes in the propagation environment or the movement of transmitter and receiver are inevitable. Therefore, the wireless link often experiences quality degradation or even interruption. Adaptive antenna arrays offer a promising solution to combat wireless channel impairments as they adaptively reshape their radiation pattern. For two-way communication, an antenna should be retro-directive meaning its transmit and receive beams are aligned. To achieve retro-directivity, techniques based on direction-of-arrival and self-phasing can be used. The former usually calls for a complex calibration routine to estimate the direction of arrival and beamsteering; the latter relies on the received signal to generate the transmit beam, imposing several limitations on its adaptability. In this thesis, a novel retro-directive phased array architecture is proposed that does not require calibration and which generates its transmit wave independently of its receive wave. Moreover, its radiation pattern can be adaptively shaped by a simple beamforming algorithm, while its transmitted and received beams remain aligned. Structurally, it is comprised of independent modules that can be placed in virtually any arrangement without any hardware modification. The architecture uses the LO phase-shifting technique to steer its beams. The LO signals are generated with a novel frequency synthesizer; it creates a pair of LO signals for the transmission and reception paths to achieve retro-directivity. The proposed antenna architecture is demonstrated practically using a 10-element prototype, verifying its ability to steer the transmit and receive beams while keeping them aligned. In addition, two of the key circuit components of the LO synthesizer, a fractional frequency divider and a novel phase-conjugating phase shifter, are designed and successfully implemented on 65nm CMOS technology, paving the path for use in future applications

External Cavity Mode-locked Semiconductor Lasers For The Generation Of Ultra-low Noise Multi-gigahertz Frequency Combs And Applications In Multi-heterodyne Detection Of Arbitrary Optical Waveforms

The construction and characterization of ultra-low noise semiconductor-based mode-locked lasers as frequency comb sources with multi-gigahertz combline-to-combline spacing is studied in this dissertation. Several different systems were built and characterized. The first of these systems includes a novel mode-locking mechanism based on phase modulation and periodic spectral filtering. This mode-locked laser design uses the same intra-cavity elements for both mode-locking and frequency stabilization to an intra-cavity, 1,000 Finesse, Fabry-Pérot Etalon (FPE). On a separate effort, a mode-locked laser based on a Slab-Coupled Optical Waveguide Amplifier (SCOWA) was built. This system generates a pulse-train with residual timing jitter o

Frequency Division Using a Micromechanical Resonance Cascade

Frequency conversion mechanisms are essential elements in frequency synthesizers, which are used in many applications ranging from microwave and RF transceivers to wireless applications to vibration energy harvesters. In particular, the frequency divider, which is an integral part of the phase-locked loop circuit, is essential in modern day instrumentation and wireless communications. In most systems requiring frequency conversion, electronic frequency converters are used; these components require significant power input and introduce noise into the system. In this dissertation, we introduce a mechanism for eliminating these noisy electronic components by using coupled mechanical elements. This novel mechanism for frequency division using parametric resonance in MEMS relies on finite deformation kinematics and nonlinear coupling between isolated modes in a structure to divide an input signal through multiple stages using purely mechanical coupling.We present the theoretical framework for a generic subharmonic resonance cascade. Design considerations for one specific implementation are discussed, and a proof-of-concept for low-noise low-power applications is demonstrated. A single input signal is divided through three modal stages, generating output signals at 1/2, 1/4, and 1/8 of the input signal. Coupling and boundary conditions are explored, as well as the noise characteristics of this mechanical frequency divider. We show that this type of cascading frequency conversion improves phase noise performance of each individual mode

Synthèses de fréquence à bas bruit basées sur des oscillateurs opto-électroniques couplés intégrées en technologie BiCMOS SiGe 130nm

Les hyperfréquences jouent un rôle indispensable dans le domaine des télécommunications, que ce soit pour la téléphonie mobile, les radars automobiles, le Wi-Fi ou encore la transmission satellitaire, sans que cette liste ne soit évidemment exhaustive. Pour l'ensemble de ces applications omniprésentes dans la société actuelle, ce sont ces signaux hyperfréquences qui servent de porteuses pour transmettre l'information sur de plus ou moins longues distances. Les méthodes de génération de signaux hyperfréquences actuelles sont basées sur des boucles à verrouillage de phase (PLL). Elles réalisent une multiplication d'une fréquence de référence basse de quelques dizaines à quelques centaines de mégahertz pour l'amener à quelques gigahertz voire dizaines de gigahertz. Il y a cependant un inconvénient majeur lié à cette méthode : synthétiser une fréquence par multiplication d'une référence basse s'accompagne d'une augmentation théorique du bruit de phase du signal généré, d'autant plus que le rapport de multiplication est élevé. À l'inverse, une synthèse par division de fréquence diminue le bruit de phase théorique. Or on voit apparaître depuis quelques années des références à des fréquences déjà élevées, basées sur des oscillateurs optoélectroniques couplés (COEO), qui peuvent dès lors servir à réaliser des synthèses basées sur de la division de fréquence, et c'est dans ce cadre que se situe le travail de cette thèse. Nous utilisons pour référence de fréquence, des COEO qui génèrent un signal de fréquence élevée à haute pureté spectrale, à 10 et 30 GHz. L'objectif est alors d'être capable de générer des signaux dont la fréquence est inférieure à 30 GHz et aussi basse que 1 GHz. Ces signaux synthétisés doivent conserver autant que possible la pureté spectrale du signal de référence en pénalisant le moins possible le bénéfice théorique apporté par la division. Cette thèse décrit la conception de diviseurs hyperfréquences à très faible bruit de phase résiduel disposant au final de rapports de division fractionnaires et/ou programmables. Dans un premier temps, nous avons conçu des diviseurs de rapports fixes afin d'estimer les performances en bruit de phase atteignables à cette fréquence de travail sur les technologies utilisées. Plusieurs diviseurs ECL par 2 et par 3 ont été conçus, fabriqués et mesurés pour une division jusqu'à 30 GHz. Un diviseur CMOS par 10 ainsi qu'une technique de resynchronisation permettant d'annuler la majeure partie du bruit de phase de la chaîne de division sont également présentés. Plusieurs diviseurs analogiques à rang fixe ont également été conçus, bien que s'étant révélés moins performants au final : un diviseur à verrouillage par injection (ILFD) et un diviseur à renforcement du second harmonique, qui réalisent tous les deux une division par 3 autour de 30 GHz. Pour terminer, nous avons conçu des diviseurs fractionnaires large bande fonctionnant au moins jusqu'à 30 GHz et offrant des performances en bruit de phase compétitives. Si ces modèles s'inspirent du principe régénératif connu de Miller, nous en proposons une déclinaison tout à fait originale. Une première série de diviseurs fractionnaires fixes a ainsi été réalisée pour des rapports fixes de 1,25, 2,5 et 4,5. Pour terminer, un diviseur fractionnaire dont la partie décimale est programmable a été ensuite été réalisé et mesuré. Il s'agit d'un diviseur fractionnaire dont la partie entière du rapport de division est 4 et la partie décimale codée sur 4 bits.Microwave signals are essential in the field of telecommunications whether for mobile telephony, automotive radar, Wi-Fi or even satellite transmission, without this list being exhaustive. For all these ubiquitous applications in our current society, microwave signals are the carriers for the transmission of information from a system to another. Microwave signals synthesis techniques are mostly based on Phase-Locked Loop (PLL). PLL multiply a low frequency reference ranging from a dozen to a few hundred megahertz toward a few gigahertz to a few dozen gigahertz. However, there is one main drawback with this synthesis technique: synthesizing a frequency by multiplying a low frequency reference induces an unavoidable rise of the theoretical phase noise of the synthesized signal, even more if the multiplication factor is high. On the contrary, frequency synthesis by division lowers the theoretical phase noise. Yet, high frequency high spectral purity frequency references called Coupled OptoElectronic Oscillator (COEO) are being developed for a few years. They are perfect candidate to be used as reference for frequency synthesis by division, and this is within this framework that our research takes place. We use as frequency references two COEO generating high spectral purity signals at 10 and 30?GHz. The aim of our work is then to be able to generate different signals whose frequencies are below 30?GHz and as low as 1?GHz. These synthesized signals must preserve as much as possible the spectral purity of the reference while deteriorating as less as possible the theoretical benefit brought by the division. This thesis describes the conception of low residual phase noise microwave frequency dividers operating, for the most evolved ones, fractional and/or programmable division ratios. In a first place, we designed static frequency dividers in order to estimate the phase noise performance that we can conceivably reach with the technology we use. Several ECL dividers by 2 and by 3 are designed, fabricated and measured for a division up to 30?GHz. A CMOS divider by 10 along with a resynchronization technique allowing to cancel most of the phase noise in a cascaded divider are also presented. In a second place, we designed analog dividers, although they have proven to be less competitive than digital dividers: an Injection-Locked Frequency Divider (ILFD) and a regenerative second-harmonic frequency divider, both realising a frequency division by 3 around 30 GHz. Finally, we designed wideband fractional dividers operating at least at 30 GHz with competitive phase noise performance. Even though they are inspired by Miller's regenerative frequency dividers, we introduce here an innovative declination of fractional dividers. A first series of static fractional dividers has been designed with ratios of 1.25, 2.5 and 4.5. Ultimately, a fractional divider with a programmable decimal part has been designed and measured. This divider has an integer part of 4 and a decimal part programmed on 4 bits

Integrated RF oscillators and LO signal generation circuits

This thesis deals with fully integrated LC oscillators and local oscillator (LO) signal generation circuits. In communication systems a good-quality LO signal for up- and down-conversion in transmitters is needed. The LO signal needs to span the required frequency range and have good frequency stability and low phase noise. Furthermore, most modern systems require accurate quadrature (IQ) LO signals. This thesis tackles these challenges by presenting a detailed study of LC oscillators, monolithic elements for good-quality LC resonators, and circuits for IQ-signal generation and for frequency conversion, as well as many experimental circuits. Monolithic coils and variable capacitors are essential, and this thesis deals with good structures of these devices and their proper modeling. As experimental test devices, over forty monolithic inductors and thirty varactors have been implemented, measured and modeled. Actively synthesized reactive elements were studied as replacements for these passive devices. At first glance these circuits show promising characteristics, but closer noise and nonlinearity analysis reveals that these circuits suffer from high noise levels and a small dynamic range. Nine circuit implementations with various actively synthesized variable capacitors were done. Quadrature signal generation can be performed with three different methods, and these are analyzed in the thesis. Frequency conversion circuits are used for alleviating coupling problems or to expand the number of frequency bands covered. The thesis includes an analysis of single-sideband mixing, frequency dividers, and frequency multipliers, which are used to perform the four basic arithmetical operations for the frequency tone. Two design cases are presented. The first one is a single-sideband mixing method for the generation of WiMedia UWB LO-signals, and the second one is a frequency conversion unit for a digital period synthesizer. The last part of the thesis presents five research projects. In the first one a temperature-compensated GaAs MESFET VCO was developed. The second one deals with circuit and device development for an experimental-level BiCMOS process. A cable-modem RF tuner IC using a SiGe process was developed in the third project, and a CMOS flip-chip VCO module in the fourth one. Finally, two frequency synthesizers for UWB radios are presented

Novel Optical Frequency Combs Injection Locking Architectures

Due to their highly stable timing characteristics, optical frequency combs have become instrumental in applications ranging from spectroscopy to ultra-wideband optical interconnects, high-speed signal processing, and exoplanet search. In the past few years, there has been a necessity for frequency combs to become more compact, robust to environmental disturbances, and extremely energy efficient, where photonic integration shows a clear pathway to bring optical frequency combs to satellites, airships, drones, cars, and even smartphones. Therefore, the development of chip-scale optical frequency combs has become a topic of high interest in the optics community. This dissertation reviews the work made in the field of chip-scale optical frequency combs using optically injection locked semiconductor mode-locked lasers. First it shows the efforts in the design, characterization and calibration of several semiconductor mode-locked laser architectures on an InP-based platform. Then two separate efforts to obtain a self-referenced optical frequency comb are described. The first one based on an InP-based MLL-PIC that is enhanced via COEO multi-tone injection locking, and then amplified and broadened to an octave using pulse picking and a combination of bulk and integrated nonlinear optics. The second approach is based on the synchronization of two lasers via regenerative harmonic injection locking, one with a repetition rate in the microwave regime (10s of GHz) and another one in the THz domain (100s of GHz), first utilizing an electro-optic modulated comb and then an integrated SiN microresonator-based Kerr frequency comb. This manuscript envisions future work to achieve an optical to RF link using optical injection locking architectures with long-term stabilization and the outlook of using this technique in conjunction with octave-spanning microresonator-based Kerr combs to achieve a self-referenced chip-scale optical frequency comb

Wireless wire - ultra-low-power and high-data-rate wireless communication systems

With the rapid development of communication technologies, wireless personal-area communication systems gain momentum and become increasingly important. When the market gets gradually saturated and the technology becomes much more mature, new demands on higher throughput push the wireless communication further into the high-frequency and high-data-rate direction. For example, in the IEEE 802.15.3c standard, a 60-GHz physical layer is specified, which occupies the unlicensed 57 to 64 GHz band and supports gigabit links for applications such as wireless downloading and data streaming. Along with the progress, however, both wireless protocols and physical systems and devices start to become very complex. Due to the limited cut-off frequency of the technology and high parasitic and noise levels at high frequency bands, the power consumption of these systems, especially of the RF front-ends, increases significantly. The reason behind this is that RF performance does not scale with technology at the same rate as digital baseband circuits. Based on the challenges encountered, the wireless-wire system is proposed for the millimeter wave high-data-rate communication. In this system, beamsteering directional communication front-ends are used, which confine the RF power within a narrow beam and increase the level of the equivalent isotropic radiation power by a factor equal to the number of antenna elements. Since extra gain is obtained from the antenna beamsteering, less front-end gain is required, which will reduce the power consumption accordingly. Besides, the narrow beam also reduces the interference level to other nodes. In order to minimize the system average power consumption, an ultra-low power asynchronous duty-cycled wake-up receiver is added to listen to the channel and control the communication modes. The main receiver is switched on by the wake-up receiver only when the communication is identified while in other cases it will always be in sleep mode with virtually no power consumed. Before transmitting the payload, the event-triggered transmitter will send a wake-up beacon to the wake-up receiver. As long as the wake-up beacon is longer than one cycle of the wake-up receiver, it can be captured and identified. Furthermore, by adopting a frequency-sweeping injection locking oscillator, the wake-up receiver is able to achieve good sensitivity, low latency and wide bandwidth simultaneously. In this way, high-data-rate communication can be achieved with ultra-low average power consumption. System power optimization is achieved by optimizing the antenna number, data rate, modulation scheme, transceiver architecture, and transceiver circuitries with regards to particular application scenarios. Cross-layer power optimization is performed as well. In order to verify the most critical elements of this new approach, a W-band injection-locked oscillator and the wake-up receiver have been designed and implemented in standard TSMC 65-nm CMOS technology. It can be seen from the measurement results that the wake-up receiver is able to achieve about -60 dBm sensitivity, 10 mW peak power consumption and 8.5 µs worst-case latency simultaneously. When applying a duty-cycling scheme, the average power of the wake-up receiver becomes lower than 10 µW if the event frequency is 1000 times/day, which matches battery-based or energy harvesting-based wireless applications. A 4-path phased-array main receiver is simulated working with 1 Gbps data rate and on-off-keying modulation. The average power consumption is 10 µW with 10 Gb communication data per day