12???14.5 GHZ DIGITALLY CONTROLLED OSCILLATOR USING A HIGH-RESOLUTION DELTA-SIGMA DIGITAL-TO-ANALOG CONVERTER

Department of Electrical EngineeringThis thesis focuses on the design of digitally-controlled oscillators (DCO) for ultra-low-jitter digital phase-locked-loops (PLL), which requires very fine frequency resolution and low phase noise performance. Before going details of the design, fundamentals of the digital-to-analog converter (DAC), delta-sigma modulator (DSM), LC voltage-controlled oscillator (VCO) are discussed in Chapters 2, 3, and 4 respectively. Detailly, Chapter 2 begins with the basic operations of the digital-toanalog converters. Plus, several types of DACs and their properties are discussed. For instance, resistorbased DAC or current source-based DAC. In Chapter 3, the backgrounds of DSMs are presented. The reason why DSMs are indispensable components in fractional number generation is presented. The meaning of the randomization and noise shaping in DSMs is discussed then high-order noise shaping DSMs are explained as well. Chapter 4, starts with the LC tanks. Integrated passive components are introduced such as spiral inductors, metal-insulator-metal (MIM) capacitors, and metal-oxide-metal (MOM) capacitors. The start-up of the oscillators also explained by using two approaches, the Barkhausen criterion and the negative resistance theory. Then the pros and cons of the CMOS and NMOS type topologies are stated. Finally, the phase noise in oscillators is analyzed by using the Leeson???s equation and the impulse-sensitivity function theory. In chapter 5, the detailed designs of the prototype DCO are presented. The designed DCO consists of 2nd order DSM, string resistor-based DAC, and CMOS-type LC VCO. The frequency resolutions of the proportional and integral path are different but the structures are identical. For the high-performance oscillator, iterative design is required. In the measurements, the designed DCO achieved 17 and 18 bit of frequency resolution in the proportional and integral path respectively, 12-14.5GHz of the frequency tuning range, 50 and 500MHz/V of KVCO for the main and auxiliary loop respectively, and -184.5 dB of figure of merit (FOM). The power consumption is 5.5mW and the prototype was fabricated in TSMC 65nm CMOS process.clos

LOW PHASE NOISE CMOS PLL FREQUENCY SYNTHESIZER DESIGN AND ANALYSIS

The phase-locked loop (PLL) frequency synthesizer is a critical device of wireless transceivers. It works as a local oscillator (LO) for frequency translation and channel selection in the transceivers but suffers phase noise including reference spurs. In this dissertation for lowing phase noise and power consumption, efforts are placed on the new design of PLL components: VCOs, charge pumps and sigma delta modulators. Based on the analysis of the VCO phase noise generation mechanism and improving on the literature results, a design-oriented phase noise model for a complementary cross-coupled LC VCO is provided. The model reveals the relationship between the phase noise performance and circuit design parameters. Using this phase noise model, an optimized 2GHz low phase noise CMOS LC VCO is designed, simulated and fabricated. The theoretical analysis results are confirmed by the simulation and experimental results. With this VCO phase noise model, we also design a low phase noise, low gain wideband VCO with the typical VCO gain around 100MHz/V. Improving upon literature results, a complete quantitative analysis of reference spur is given in this dissertation. This leads to a design of a charge pump by using a negative feedback circuit and replica bias to reduce the current mismatch which causes the reference spur. In addition, low-impedance charge/discharge paths are provided to overcome the charge pump current glitches which also cause PLL spurs. With a large bit-width high order sigma delta modulator, the fractional-N PLL has fine frequency resolution and fast locking time. Based on an analysis of sigma delta modulator models introduced in this dissertation, a 3rd-order MASH 1-1-1 digital sigma delta modulator is designed. Pipelining techniques and true single phase clock (TSPC) techniques are used for saving power and area. Included is the design of a fully integrated 2.4GHz §¢ fractional-N CMOS PLL frequency synthesizer. It takes advantage of a sigma delta modulator to get a very fine frequency resolution and a relatively large loop bandwidth. This frequency synthesizer is a 4th-order charge pump PLL with 26MHz reference frequency. The loop bandwidth is about 150KHz, while the whole PLL phase noise is about -120dBc/Hz at 1MHz frequency offset