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Quantization-Noise Cancellation Technique and Phase-Locked Loop IC Design in a Fractional¡VN Frequency SynthesizerLi, Shiang-wei 16 August 2007 (has links)
For the fractional-N frequency synthesizers using delta-sigma modulation (DSM) techniques, higher PLL bandwidth is highly desirable in order to achieve faster settling time. As the PLL bandwidth is increased, more quantization noises pass through the PLL so that the output phase noise performance is degraded. There is a tradeoff between phase-noise performance and PLL bandwidth. To improve the problem, the thesis studies the quantization noise cancellation technique. With this technique, the PLL bandwidth can be increased without the cost of degrading phase-noise performance. With the help of Agilent EEsof¡¦s ADS, the phase-noise performance of the studied fractional-N frequency synthesizers can be predicted. For demonstration, this research implements a 2.6 GHz fractional-N frequency synthesizer hybrid module, and compares the measured phase noises with and without the technique under considering various combinations of MASH DSM orders and PLL bandwidth. Another demonstration of this thesis is to design a PLL IC using TSMC 0.18 £gm CMOS process, and make a discussion on the testing performance of the PLL IC.
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Wideband GFSK-Modulated Frequency Synthesizer Using Two-Point Delta-Sigma ModulationPeng, Kang-Chun 03 May 2005 (has links)
This dissertation presents a 2.4 GHz wideband GFSK-modulated frequency synthesizer using two-point delta-sigma modulation (TPDSM). The two bottlenecks in this design have been rigorously investigated. One bottleneck is the nonlinear performance of the phase-locked loop (PLL). The other one is the inherent gain and delay mismatch between the two modulation points. Both nonlinear and mismatch factors dominate the modulation accuracy in the closed PLL. The proposed formulation can successfully predict the dependencies of the modulation accuracy on both factors. The comparison of the averaged frequency deviation and frequency-shift -keying (FSK) error between theory and measurement shows excellent agreement. The modulated frequency synthesizer implemented in this study can achieve a 2.5 Mbps data rate as well as a 15 £gs PLL stable time with only 2.2 % FSK error under good design and operating conditions.
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Design of Fractional-N Frequency Synthesizer Using Single-Loop Delta-Sigma ModulatorHe, Wen-Hau 27 July 2005 (has links)
This thesis establishes a quantization noise model of a delta-sigma modulator (DSM), which is utilized to estimate the phase noise performance of a fractional-N frequency synthesizer. In delta-sigma modulator structures, we choose multi-stage noise shaping (MASH) and single-loop structure for investigating the advantages and disadvantages.
We have implemented a 3rd order single-loop and a 3rd order MASH DSM by using Verilog codes and a Xilinx field-programmable gate-array (FPGA). With a reference frequency of 12MHz, the fractional-N frequency synthesizer has an output frequency band of 2400~2500MHz, and a frequency resolution of 183 Hz. The measured phase noise is lower than -54 dBc/Hz at 10 kHz offset frequency. The PLL settling time is less than 29us with a 48 MHz frequency hopping.
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The Fractional-N Nonlinearity Study and Mixed-Signal IC Implementation of Frequency SynthesizersLou, Zheng-Bin 15 July 2006 (has links)
Abstract¡G
For the fractional-N frequency synthesizers using delta-sigma modulation techniques, the noise source dominant to degrade the spectral purity comes from phase intermodulation of quantization noise due to the PLL nonlinearity. To study and improve the PLL nonlinearity effect, this thesis applies the theory of white quantization noise and nonlinear analysis method to simulate the frequency responses of quantization noises in delta-sigma modulators (DSM) with different order and in various architecture. With the help of Agilent EEsof¡¦s ADS tool, the phase noise performance of the studied fractional-N frequency synthesizers can be well predicted. For demonstration, this thesis work implements a 2.4 GHz fractional-N frequency synthesizer hybrid module, and measures the phase noise under considering various combinations of DSM order and architecture, PLL bandwidth and reference frequency. Another demonstration of this thesis is to implement a PLL IC using 0.18 £gm CMOS process. The implemented PLL IC operates in the frequency range from 2120 to 2380 MHz with a supply voltage of 1.8 V and a current consumption of 27 mA. Under the test condition of reference frequency and PLL bandwidth equal to 20 MHz and 50 kHz, respectively, the measured phase noise is 90 dBc/Hz at an offset frequency of 100 kHz and the measured stable time is about 40 £gs for a frequency jump of 80MHz.
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Investigation of Mechanisms for Spur Generation in Fractional-N Frequency SynthesizersImran Saeed, Sohail January 2012 (has links)
With the advances in wireless communication technology over last two decades, the use of fractional-N frequency synthesizers has increased widely in modern wireless communication applications due to their high frequency resolution and fast settling time. The performance of a fractional-N frequency synthesizer is degraded due to the presence of unwanted spurious tones (spurs) in the output spectrum. The Digital Delta-Sigma Modulator can be directly responsible for the generation of spur because of its inherent nonlinearity and periodicity. Many deterministic and stochastic techniques associated with the architecture of the DDSM have been developed to remove the principal causes responsible for production of spurs. The nonlinearities in a frequency synthesizer are another source for the generation of spurs. In this thesis we have predicted that specific nonlinearities in a fractional-N frequency synthesizer produce spurs at well-defined frequencies even if the output of the DDSM is spur-free. Different spur free DDSM architectures have been investigated for the analysis of spurious tones in the output spectrum of fractional-N frequencysynthesizers. The thesis presents simulation and experimental investigation of mechanisms for spur generation in a fractional-N frequency synthesizer. Simulations are carried out using the CppSim system simulator, MATLAB and Simulink while the experiments are performed on an Analog Devices ADF7021, a high performance narrow-band transceiver IC.
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A Fully Integrated Fractional-N Frequency Synthesizer for Wireless CommunicationsSon, Han-Woong 12 April 2004 (has links)
A fully integrated, fast-locking fractional-N frequency synthesizer is proposed and demonstrated in this work. In this design, to eliminate the need for large, inaccurate capacitors and resistors in a loop filter, an analog continuous-time loop filter whose performance is sensitive to process and temperature variations and aging has been replaced with a programmable digital Finite Impulse Response (FIR) filter. In addition, using the adaptive loop gain control proportional to the frequency difference, the frequency-locking time has been reduced. Also, the phase noise and spurs have been reduced by a Multi-stAge noise SHaping (MASH) controlled Fractional Frequency Detector (FFD) that generates a digital output corresponding directly to the frequency difference. The proposed frequency synthesizer provides many benefits in terms of high integration ability, technological robustness, fast locking time, low noise level, and multimode flexibility.
To prove performance of the proposed frequency synthesizer, the frequency synthesizers analysis, design, and simulation have been carried out at both the system and the circuit levels. Then, the performance was also verified after fabrication and packaging.
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