Design Techniques of Energy Efficient PLL for Enhanced Noise and Lock Performance

Phase locked loops(PLLs)are vital building blocks of communication sys-tems whose performance dictates the quality of communication.The design of PLL to o_er superior performance is the prime objective of this research.It is desirable for the PLL to have fast locking,low noise,low reference spur,wide lock range,low power consumption consuming less silicon area.To achieve these performance parameters simultaneously in a PLL being a challenging task is taken up as a scope of the present work.A comprehensive study of the performance linked PLL components along with their design challenges is made in this report.The phase noise which is directly related to the dead zone of the PLL is minimized using an e_cient phase frequency detector(PFD)in this thesis.Here a voltage variable delay element is inserted in the reset path of the PFD to reduce the dead zone.An adaptive PFD architecture is also proposed to have a low noise and fast PLL simultaneously.In this work,before locking a fast PFD and in the locked state a low noise PFD operates to dictate the phase di_erence of the reference and feedback signals.To reduce the reference spur,a novel charge pump architecture is proposed which eventually reduces the lock time up to a great extent.In this charge pump a single current source is employed to reduce the output current mis-match and transmission gates are used to reduce the non ideal e_ects.Besides this,the fabrication process variations have a predominant e_ect on the PLL performance,which is directly linked to the locking capability.This necessitates a manufacturing process variation tolerant design of the PLL.In this work an e_cient multi-objective optimization method is also applied to at-tain multiple optimal performance objectives.The major performances under consideration are lock time,phase noise,lock range and power consumption

Design of CMOS integrated phase-locked loops for multi-gigabits serial data links

High-speed serial data links are quickly gaining in popularity and replacing the conventional parallel data links in recent years when the data rate of communication exceeds one gigabits per second. Compared with parallel data links, serial data links are able to achieve higher data rate and longer transfer distance. This dissertation is focused on the design of CMOS integrated phase-locked loops (PLLs) and relevant building blocks used in multi-gigabits serial data link transceivers. Firstly, binary phase-locked loops (BPLLs, i.e., PLLs based on binary phase detectors) are modeled and analyzed. The steady-state behavior of BPLLs is derived with combined discrete-time and continuous-time analysis. The jitter performance characteristics of BPLLs are analyzed. Secondly, a 10 Gbps clock and data recovery (CDR) chip for SONET OC- 192, the mainstream standard for optical serial data links, is presented. The CDR is based on a novel referenceless dual-loop half-rate architecture. It includes a binary phase-locked loop based on a quad-level phase detector and a linear frequency-locked loop based on a linear frequency detector. The proposed architecture enables the CDR to achieve large locking range and small jitter generation at the same time. The prototype is implemented in 0.18 üm CMOS technology and consumes 250 mW under 1.8 V supply. The jitter generation is 0.5 ps-rms and 4.8 ps-pp. The jitter peaking and jitter tolerance performance exceeds the specifications defined by SONET OC-192 standard. Thirdly, a fully-differential divide-by-eight injection-locked frequency divider with low power dissipation is presented. The frequency divider consists of a four-stage ring of CML (current mode logic) latches. It has a maximum operating frequency of 18 GHz. The ratio of locking range over center frequency is up to 50%. The prototype chip is implemented in 0.18 üm CMOS technology and consumes 3.6 mW under 1.8 V supply. Lastly, the design and optimization techniques of fully differential charge pumps are discussed. Techniques are proposed to minimize the nonidealities associated with a fully differential charge pump, including differential mismatch, output current variation, low-speed glitches and high-speed glitches. The performance improvement brought by the techniques is verified with simulations of schematics designed in 0.35 üm CMOS technology