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Design for Manufacturability and Statistical Design: A Constructive Approach PDF

314 Pages·2008·20.564 MB·English
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Design for Manufacturability and Statistical Design A Constructive Approach Series on Integrated Circuits and Systems Series Editor: Anantha Chandrakasan Massachusetts Institute of Technology Cambridge, Massachusetts Design for Manufacturability and Statistical Design: A Constructive Approach Michael Orshansky, Sani R. Nassif, and Duane Boning ISBN 978-0-387-30928-6 Low Power Methodology Manual: For System-on-Chip Design Michael Keating, David Flynn, Rob Aitken, Alan Gibbons, and Kaijian Shi ISBN 978-0-387-71818-7 Modern Circuit Placement: Best Practices and Results Gi-Joon Nam and Jason Cong ISBN 978-0-387-36837-5 CMOS Biotechnology Hakho Lee, Donhee Ham and Robert M. 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Hachtel, and Fabio Somenzi ISBN 978-0-387-28594-2, 2006 A Practical Introduction to PSL Cindy Eisner and Dana Fisman ISBN 978-0-387-35313-5, 2006 Thermal and Power Management of Integrated Systems Arman Vassighi and Manoj Sachdev ISBN 978-0-387-25762-4, 2006 Leakage in Nanometer CMOS Technologies Siva G. Narendra and Anantha Chandrakasan ISBN 978-0-387-25737-2,2005 Continued after index Michael Orshansky Sani R. Nassif • • Duane Boning Design for Manufacturability and Statistical Design A Constructive Approach ABC Michael Orshansky Sani R. Nassif The University of Texas at Austin IBM Research Laboratories Austin, TX Austin, TX USA USA Duane Boning Massachusetts Institute of Technology Cambridge, MA USA Series Editor: Anantha Chandrakasan Department of Electrical Engineering and Computer Science Massachusetts Institute of Technology Cambridge, MA 02139 USA An image by Eugene Timerman used in cover design Library of Congress Control Number: 2007933405 ISBN 978-0-387-30928-6 e-ISBN 978-0-387-69011-7 ©2008 Springer Science+Business Media, LLC All rights reserved. This work may not be translated or copied in whole or in part without the written permission of the publisher (Springer Science+Business Media, LLC, 233 Spring Street, New York, NY 10013, USA), except for brief excerpts in connection with reviews or scholarly analysis. Use in connection with any form of information storage and retrieval, electronic adaptation, computer software, or by similar or dissimilar methodology now known or hereafter developed is forbidden. The use in this publication of trade names, trademarks, service marks, and similar terms, even if they are not identified as such, is not to be taken as an expression of opinion as to whether or not they are subject to proprietary rights. Printed on acid-free paper. 9 8 7 6 5 4 3 2 1 springer.com To Leo, Mariya, Boris, Yana and Zhenya Michael To Cosette, Julie, Victoria and Kamal Sani To my family Duane Preface Progress in microelectronics over the last several decades has been intimately linked to our ability to accurately measure, model, and predict the physical properties of solid-state electronic devices. This ability is currently endan- gered by the manufacturing and fundamental limitations of nanometer scale technology, that result in increasing unpredictability in the physical proper- ties of semiconductor devices. Recent years have seen an explosion of interest in Design for Manufacturability (DFM) and in statistical design techniques. This interest is directly attributed to the difficulties of manufacturing of in- tegrated circuits in nanometer scale CMOS technologies with high functional and parametric yield. The scaling of CMOS technologies brought about the increasing magni- tude of variability of key parameters affecting the performance of integrated circuits. The large variation can be attributed to several factors. The first is the rise of multiple systematic sources of parameter variability caused by the interaction between the manufacturing process and the design attributes. For example, optical proximity effects cause polysilicon feature sizes to vary de- pendingonthelocallayoutsurroundings,whilecopperwirethicknessstrongly depends on the local wire density because of chemical-mechanical polishing. The second is that while technology scaling reduces the nominal values of key process parameters, such as effective channel length, our ability to corre- spondinglyimprovemanufacturingtolerances,suchasmaskfabricationerrors and mask overlay control, is limited. This results in an increase in the rela- tive amount of variations observed. The third, and most profound, reason for thefutureincreaseinparametric variability isthattechnologyisapproaching the regime of fundamental randomness in the behavior of silicon structures. For example, the shrinking volume of silicon that forms the channel of the MOS transistor will soon contain a small countable number of dopant atoms. Because the placement of these dopant atoms is random, the final number of atomsthatendupinthechannelofeachtransistorisarandomvariable.Thus, the threshold voltage of the transistor, which is determined by the number VIII Preface of dopant atoms, will also exhibit significant variation, eventually leading to variation in circuit-level performances, such as delay and power. Thisbookpresentsanoverviewofthemethodsthatneedtobemasteredin understanding state-of-the-art Design for Manufacturability (DFM) and Sta- tisticalDesign(SD)methodologies.Broadly,designformanufacturabilityisa setoftechniquesthatattempttofixthesystematicsourcesofvariability,such as those due to photolithography and CMP. Statistical design, on the other hand, deals with the random sources of variability. Both paradigms must op- erate within a common framework, and their joint understanding is one of the objectives of this book. The areas of design for manufacturability and statistical design are still being actively developed and the established canon of methods and principles does not yet exist. This book attempts to provide a constructive treatment of the causes of variability, the methods for statis- tical data characterization, and the techniques for modeling, analysis, and optimization of integrated circuits to improve yield. The objective of such a constructive approach is to formulate a consistent set of methods and prin- ciples that allow rigorous statistical design and design for manufacturability from device physics to large-scale circuit optimization. Writing about relatively new areas like design for manufacturability and statistical design presents its difficulties. The subjects span a wide area be- tween design and manufacturing making it impossible to do justice to the whole area in this one volume. We also limit our discussion to problems di- rectly related to variability, with the realization that the term DFM may be understood to refer to topics that we do not address in this book. Thus, we do not discuss topics related to catastrophic yield modeling due to random defects and particles, and the accompanying issues of critical area, via dou- bling, wire spreading, and other layout optimization strategies for random yield improvement. These topics have been researched extensively, and there are excellent books on the subject, notably [89] and [204]. Also, with the rapid continuous progress occurring at the time of this writing, it is the authors’ sincere hope that many of the issues and problems outlined in this book will shortly be irrelevant solved problems. We assume that the reader has had a thorough introduction to integrated circuits design and manufacturing, and that the basics of how one creates an IC from the high level system-oriented view down to the behavior of a single MOSFET are well understood. For a refresher, we would recommend [75] and [5]. The book is organized in four major parts. The first part on Sources ofVariability contains the three chapters of the book that deal with three major sources of variability: front-end variability impacting devices (Chapter 2), back-end variability impacting metal interconnect (Chapter 3), and envi- ronmental variability (Chapter 4). The second part on Variability Character- ization and Analysis contains two chapters. Chapter 5 discusses the design of test structures for variability characterization. Chapter 6 deals with the statistically sound analysis of the results of measurements that are needed to create rigorous models of variability. The third part is on Design Techniques Preface IX for Systematic Manufacturability Problems, and deals with techniques of de- sign for manufacturability. Chapter 7 describes the interaction of the design and the lithographic flow, and methods for improving printability. Chapter 8 isdevotedtoadescriptionoftechniquesformetalfillrequiredtoensuregood planarity of multi-level interconnect structures. The final part on Statistical Circuit Design is devoted to statistical design techniques proper: it contains four chapters dealing with the prediction and mitigation of the impact of variabilityoncircuits.Chapter9presentsstrategiesforstatisticalcircuitsim- ulation. Chapter 10 discusses the methods for system-level statistical timing analysis using static timing analysis techniques. In Chapter 11, the impact of variabilityonleakagepowerconsumptionisdiscussed.Thefinalchapterofthe book,Chapter12,isdevotedtostatisticalandrobustoptimizationtechniques for improving parametric yield. This book would not be possible without the generous help and support of a lot of people: our colleagues and graduate students. Several individuals have been kind enough to read through the entire manuscript or its parts, andgivetheauthorsessentialfeedback.Theircommentsandsuggestionshave helpedustomakethisbookbetter.WewouldliketospecificallythankAseem Agarwal,ShayakBanerjee,PuneetGupta,NagibHakim,YeheaIsmail,Murari Mani, Dejan Markovic, Alessandra Nardi, Ashish Singh, Ashish Srivastava, Brian Stine, Wei-Shen Wang, Bin Zhang, and Vladimir Zolotov. We want to particularly thank Wojciech Maly and Lou Scheffer for reading the entire manuscript and giving us invaluable advice. We thank Denis Gudovskiy for his help with typesetting. Carl Harris, our publisher at Springer, has been a source of encouragement throughout the process of writing. And, of course, this book owes an enormous debt to our families. Michael Orshansky, Austin, Texas Sani Nassif, Austin, Texas Duane Boning, Boston, Massachusetts July 2007 Contents 1 INTRODUCTION......................................... 1 1.1 RISE OF LAYOUT CONTEXT DEPENDENCE............ 2 1.2 VARIABILITY AND UNCERTAINTY..................... 3 1.3 CHARACTERIZATION VS. MODELING.................. 5 1.4 MODEL TO HARDWARE MATCHING ................... 6 1.5 DESIGN FOR MANUFACTURABILITY VS. STATISTICAL DESIGN ............................. 6 Part I Sources of Variability 2 FRONT END VARIABILITY ............................. 11 2.1 INTRODUCTION....................................... 11 2.2 VARIABILITY OF GATE LENGTH ...................... 15 2.2.1 Gate Length Variability: Overview................... 15 2.2.2 Contributions of Photolithography .................. 16 2.2.3 Impact of Etch.................................... 20 2.2.4 Line Edge Roughness .............................. 22 2.2.5 Models of L Spatial Correlation.................. 24 gate 2.3 GATE WIDTH VARIABILITY ........................... 26 2.4 THRESHOLD VOLTAGE VARIABILITY.................. 27 2.5 THIN FILM THICKNESS................................ 32 2.6 LATTICE STRESS...................................... 35 2.7 VARIABILITY IN EMERGING DEVICES ................. 37 2.8 PHYSICAL VARIATIONS DUE TO AGING AND WEAROUT ....................................... 39 2.9 SUMMARY ............................................ 41 3 BACK END VARIABILITY .............................. 43 3.1 INTRODUCTION....................................... 43 3.2 COPPER CMP ......................................... 44 3.3 COPPER ELECTROPLATING........................... 48 XII Contents 3.4 MULTILEVEL COPPER INTERCONNECT VARIATION ... 50 3.5 INTERCONNECT LITHOGRAPHY AND ETCH VARIATION ........................................... 52 3.6 DIELECTRIC VARIATION .............................. 54 3.7 BARRIER METAL DEPOSITION ........................ 54 3.8 COPPER AND VIA RESISTIVITY ....................... 55 3.9 COPPER LINE EDGE ROUGHNESS ..................... 56 3.10 CARBON NANOTUBE INTERCONNECTS ............... 57 3.11 SUMMARY ............................................ 57 4 ENVIRONMENTAL VARIABILITY ...................... 59 4.1 INTRODUCTION....................................... 59 4.2 IMPACT OF ENVIRONMENTAL VARIABILITY .......... 60 4.3 ANALYSIS OF VOLTAGE VARIABILITY................. 66 4.3.1 Power Grid Analysis............................... 67 4.3.2 Estimation of Power Variability ..................... 71 4.4 SYSTEMATIC ANALYSIS OF TEMPERATURE VARIABILITY ......................................... 74 4.5 OTHER SOURCES OF VARIABILITY.................... 82 4.6 SUMMARY ............................................ 82 Part II Variability Characterization and Analysis 5 TEST STRUCTURES FOR VARIABILITY............... 85 5.1 TEST STRUCTURES: CLASSIFICATION AND FIGURES OF MERIT............................................. 85 5.2 CHARACTERIZATION USING SHORT LOOP FLOWS .... 87 5.3 TRANSISTOR TEST STRUCTURES ..................... 92 5.4 DIGITAL TEST STRUCTURES .......................... 94 5.5 SUMMARY ............................................ 98 6 STATISTICAL FOUNDATIONS OF DATA ANALYSIS AND MODELING ........................................101 6.1 A BRIEF PROBABILITY PRIMER.......................102 6.2 EMPIRICAL MOMENT ESTIMATION ...................104 6.3 ANALYSIS OF VARIANCE AND ADDITIVE MODELS.....106 6.4 CASE STUDIES: ANOVA FOR GATE LENGTH VARIABILITY .........................................109 6.5 DECOMPOSITION OF VARIANCE INTO SPATIAL SIGNATURES..........................................113 6.6 SPATIAL STATISTICS: DATA ANALYSIS AND MODELING ......................................118 6.6.1 Measurements and Data Analysis....................118 6.6.2 Modeling of Spatial Variability......................119 6.7 SUMMARY ............................................122

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