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A MICROWAVE DIGITAL FREQUENCY SYNTHESIZER USED FOR S-BAND TELEMETRY RECEIVERShubo, Jin, Yanshan, Zhao 10 1900 (has links)
International Telemetering Conference Proceedings / October 27-30, 1997 / Riviera Hotel and Convention Center, Las Vegas, Nevada / This paper describes a kind of Microwave Digital Frequency Synthesizer used for S-band telemetry receivers. As well known many modern electronic systems employ a Frequency Synthesizer whose spectral purity is critical. The characteristics of a PLL (Phase-Locked Loop) Frequency Synthesizer, such as frequency resolution, phase noise, spurious suppression and switch time, should be compromised in our design. A heterodyne Frequency Synthesis is often considered as a good approach to solve the problem. But it is complicated in structure and circuit. A variable-reference-driven PLL Frequency Synthesizer was introduced which can give an improved trade-off among frequency resolution, phase noise, spurious suppression. In this paper the phase noise and spurious suppression characteristic of variable-reference-driven PLL Frequency Synthesizer is analyzed theoretically and compared with that of the heterodyne Frequency Synthesizer. For engineering application, a practical Microwave Digital Frequency Synthesizer used for telemetry receiver has been designed, which is characterized by simply structure, low phase noise and low spurious output. The output spectrum of experimental measurements is given.
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Direct Digital Frequency Synthesis in Field-Programmable Gate Arrays / Digital Frekvenssyntes för FPGAerKällström, Petter January 2010 (has links)
<p>This thesis is about creation of a Matlab program that suggests and automatically generates a Phase to Sine Amplitude Converter (PSAC) in the hardware language VHDL, suitable for Direct Digital Frequency Synthesis (DDFS). Main hardware target is Field Programmable Gate Arrays (FPGAs).</p><p>Focus in this report is how an FPGA works, different methods for sine amplitude generation and their signal qualities vs the hardware resources they use.</p> / <p>Detta exjobb handlar om att skapa ett Matlab-program som föreslår och implementerar en sinusgenerator i hårdvaruspråket VHDL, avsedd för digital frekvenssyntes (DDFS). Ämnad hårdvara för implementeringen är en fältprogrammerbar grindmatris (FPGA).</p><p>Fokus i denna rapport ligger på hur en FPGA är uppbyggd, olika metoder för sinusgenerering och vilka kvaliteter på sinusvågen de ger och vilka resurser i hårdvaran de använder.</p>
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Direct Digital Frequency Synthesis in Field-Programmable Gate Arrays / Digital Frekvenssyntes för FPGAerKällström, Petter January 2010 (has links)
This thesis is about creation of a Matlab program that suggests and automatically generates a Phase to Sine Amplitude Converter (PSAC) in the hardware language VHDL, suitable for Direct Digital Frequency Synthesis (DDFS). Main hardware target is Field Programmable Gate Arrays (FPGAs). Focus in this report is how an FPGA works, different methods for sine amplitude generation and their signal qualities vs the hardware resources they use. / Detta exjobb handlar om att skapa ett Matlab-program som föreslår och implementerar en sinusgenerator i hårdvaruspråket VHDL, avsedd för digital frekvenssyntes (DDFS). Ämnad hårdvara för implementeringen är en fältprogrammerbar grindmatris (FPGA). Fokus i denna rapport ligger på hur en FPGA är uppbyggd, olika metoder för sinusgenerering och vilka kvaliteter på sinusvågen de ger och vilka resurser i hårdvaran de använder.
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Circuit techniques for the rejection of LO harmonics within CMOS MixersForbes, Travis Michael, 1986- 13 August 2012 (has links)
The availability of low-cost wireless devices has enabled wide-scale connectivity over recent years. Today’s wireless devices provide services including voice communication, GPS location, and internet connectivity. With a larger number of supported wireless standards within a single device, new wireless radio techniques are required in order to implement flexible and programmable broadband receivers to replace the standard specific receivers often seen today.
The continual growth in the use of the wireless spectrum has led to an increasingly hostile interference environment for such receivers. While interferers may be located out of the signal band of interest, they may still reside within the large band of operation of the broadband receiver, making removal of the interference by filtering difficult. The requirement for small form-factor
and cost minimization has made an increased level of integration highly desirable to minimize the number of external filter components required to reject interferers.
A key consideration in the design of broadband receivers is the spurious response of the downconversion mixers, where local oscillator (LO) harmonics can lead to downconversion of unfiltered interferers to baseband, along with
the desired signal, thus degrading the signal-to-noise ratio. Recent broadband receivers utilize a harmonic rejection mixer to reject LO harmonics within the downconversion mixer and prevent interferers from being downconverted to baseband.
This report details the cause of harmonic mixing within CMOS mixers and provides a survey of published circuit techniques robust to device mismatch to remove LO harmonic response. A description of frequency translation and the effect of harmonic mixing on the translation is presented. The theoretical background of the operation of harmonic rejection mixers is described, including the effect of gain and phase errors on the achievable level of harmonic rejection. An overview of published harmonic rejection mixer techniques including the first harmonic rejection mixer and techniques to limit the effects of phase and gain mismatch on harmonic rejection is discussed.
The report concludes with the introduction of a novel method for effective synthesis of multiple downconversion local oscillator frequencies within a harmonic rejection mixer. The proposed method reduces the tuning range
required of the downconversion oscillator in broadband applications. Based on Monte Carlo simulations, while considering device mismatches over a 3σ spread, harmonic rejection better than 63 dB is observed for all selectable LO frequencies. / text
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Digital Δ-Σ Modulation:variable modulus and tonal behaviour in a fixed-point digital environmentBorkowski, M. (Maciej) 28 October 2008 (has links)
Abstract
Digital delta-sigma modulators are used in a broad range of modern electronic sub-systems, including oversampled digital-to-analogue converters, class-D amplifiers and fractional-N frequency synthesizers.
This work addresses a well known problem of unwanted spurious tones in the modulator’s output spectrum. When a delta-sigma modulator works with a constant input, the output signal can be periodic, where short periods lead to strong deterministic tones. In this work we propose means for guaranteeing that the output period will never be shorter than a prescribed minimum value for all constant inputs. This allows a relationship to be formulated between the modulator’s bus width and the spurious-free range, thereby making it possible to trade output spectrum quality for hardware consumption.
The second problem addressed in this thesis is related to the finite accuracy of frequencies generated in delta-sigma fractional-N frequency synthesis. The synthesized frequencies are usually approximated with an accuracy that is dependent on the modulator’s bus width. We propose a solution which allows frequencies to be generated exactly and removes the problem of a constant phase drift. This solution, which is applicable to a broad range of digital delta-sigma modulator architectures, replaces the traditionally used truncation quantizer with a variable modulus quantizer. The modulus, provided by a separate input, defines the denominator of the rational output mean.
The thesis concludes with a practical example of a delta-sigma modulator used in a fractional-N frequency synthesizer designed to meet the strict accuracy requirements of a GSM base station transceiver. Here we optimize and compare a traditional modulator and a variable modulus design in order to minimize hardware consumption. The example illustrates the use made of the relationship between the spurious-free range and the modulator’s bus width, and the practical use of the variable modulus functionality.
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Návrh fázového závěsu / Phase locked loop designKonečný, Tomáš January 2009 (has links)
Thesis deals with design of phase locked loop, which will be used as frequency multiplier. Full integrated phase locked loop with current pump is presented.
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Monitorovací přijímač pro VKV letecké pásmo / VHF Air-Band Monitoring ReceiverSobotka, Martin January 2011 (has links)
The aim of this work is to propose the involvement of a monitoring receiver for air band and its practical realization. The receiver is controlled from a PC via USB, after which it is transmitted simultaneously digitized audio signal. The receiver can be controlled from a PC, or some basic function by buttons.
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Přímý číslicový syntezátor pro mikrovlnné aplikace / Direct digital synthesizerfor microwave applicationDluhý, Vojtěch January 2015 (has links)
The aim of this thesis is introduce readers to the basics of digital frequency synthesis and design of direct digital synthesizer with circuit AD9951 by Analog Devices. The device will be controlled from a PC via RS232. The device will work with internal oscillator, with the ability to connect an external frequency standard.
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Millimeter-wave and terahertz frequency synthesis on advanced silicon technology / Synthèse de fréquence millimétrique et térahertz en technologie silicium avancéeGuillaume, Raphael 18 December 2018 (has links)
Ces dernières années les bandes de fréquence millimétriques et térahertz (THz) on tmontrées un fort potentiel pour de nombreuses applications telles que l’imagerie médicale et ,biologique, le contrôle de qualité ou les communications à très haut débit. Les principales raisons de cet intérêt sont les nombreuses propriétés intéressantes des ondes THz et millimétriques, telles que leur capacité traverser la matière et ceci de manière inoffensive ou le large spectre disponible à ces fréquences. Les applications visées nécessitent des sources de signaux énergétiquement efficaces, à forte puissance de sortie et, pour certaines applications, à faible bruit de phase. De plus, la demande croissante pour des applications dans ces bandes de fréquence imposent l’utilisation de technologie de hautes performances à coût métrisé et permettant une intégration à très grande échelle, telle que la technologie28nm CMOS FD-SOI. Dans ce contexte, cette thèse propose une solution innovante pour la génération de fréquence millimétrique et THz en technologie CMOS : l’oscillateur distribué verrouillé par injection. Les travaux présentés dans ce manuscrit englobent l’analyse détaillé de l’état de l’art et de ses limites, l’étude théorique approfondie de la solution proposée pour une intégration en ondes millimétriques, le développement d’une méthodologie de conception spécifique en technologie CMOS ainsi que la conception de démonstrateurs technologique. Les différents oscillateurs intégrés en technologie 28nm FDSOI et opérant à des fréquences respectivement de 134 GHz et 200 GHz ont permis de démontrer la faisabilité de sources de signaux millimétrique et THz, à forte efficacité énergétique, forte puissance de sortie et faible bruit de phase en technologie CMOS à très grande échelle d’intégration. Enfin, la capacité de verrouillage par injection de tels oscillateurs distribués a été démontrée expérimentalement ouvrant la voie à de futurs systèmes THz totalement intégrés sur silicium. Les solutions intégrées démontrées dans cette thèse ont, à l’heure actuelle, la plus grande fréquence d’oscillation dans un noeud Silicium 28nm CMOS. / In recent years, millimeter-wave (mm-wave) and terahertz (THz) frequency bands haverevealed a great potential for many applications such as medical and biological imaging,quality control, and very-high-speed communications. The main reasons for this interestare the many interesting properties of THz and millimeter waves, such as their ability toharmlessly penetrate through matter or the broad spectrum available at these frequencies.Targeted applications require energy efficient signal sources with high power outputand, for some applications, low phase noise. In addition, the increasing demand in mmwave/THz applications requires the use of a cost-optimized, high-performance, and verylarge scale integration (VLSI) technologies, such as the 28nm CMOS FD-SOI technology.In this context, this thesis proposes an innovative solution for mm-wave and THz frequencygeneration in CMOS technology: the injection locked distributed oscillator (ILDO). Thework presented in this manuscript includes the detailed analysis of the state-of-the-artand its limitations, the detailed theoretical study of the proposed millimeter-waves bandsolution, the development of a specific design methodology in CMOS technology as well asthe design of technological demonstrators. The several 28nm FDSOI integrated distributedoscillators at 134 GHz and respectively 200 GHz have demonstrated the feasibility ofmm-wave and THz signal sources with high-energy efficiency, high output power, and lowphase noise in a VLSI CMOS technology. Finally, the injection locking capability of suchdistributed oscillators has been demonstrated experimentally paving the way for a futuresilicon-based fully integrated THz systems. The proposed circuits are as of today thehighest oscillation frequency solutions demonstrated in a 28nm CMOS Silicon technology.
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Frequency synthesis for cognitive multi-radioValenta, Václav 12 November 2010 (has links) (PDF)
This doctoral thesis deals with design aspects of a reconfigurable frequency synthesizer for flexible radio transceivers in future cognitive multi-radios. The frequency bandwidth to be covered by this multi-radio synthesizer corresponds to the frequency bands of the most diffused wireless communication standards in the frequency band 800 MHz to 6 GHz. Since multi-standard operation is required, the synthesizer must fulfil the most stringent and sometimes conflicting requirements. Given these requirements, a novel approach for multi-mode frequency synthesis has been conceived. A hybrid phase locked loop based frequency synthesizer has been proposed and a novel switching protocol has been presented and validated on an experimental evaluation board. This approach combines fractional-N and integer-N modes of operation with switched loop filter topology. Compared to standard PLL techniques, the hybrid configuration provides a great flexibility in terms of reconfiguration and moreover, it offers relatively low circuit complexity and low power consumption. This architecture provides reconfiguration of the loop bandwidth, frequency resolution, phase noise and settling time performance and hence, it can adapt itself to diverse requirements given by the concerned wireless communication standards. Corresponding analyses, simulations and measurements have been carried out in order to verify the performance and functionality of the proposed solution. A part from the design of the multiband frequency synthesizer, a set of regional measurements of the radio spectrum utilization has been carried out in the framework of this dissertation research. These measurements are based on the energy detection principle and provide a close look at the degree of radio spectrum utilization in different regions, namely in the city of Brno in the Czech Republic and in the city of Paris and one of its suburbs in France. The goal of the experimental measurement campaign has been to estimate the degree of radio spectrum usage in a particular environment and to point out the fact that a new approach for radio spectrum management is inevitable
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