Foreword xi
Richard Templeton

Foreword xiii
Hans Stork

Preface xv

Acknowledgments xvii

CHAPTER 1 THE BIG PICTURE 1

1. What is a chip? 1

2. What are the requirements of a successful chip design? 3

3. What are the challenges in today s very deep submicron (VDSM), multimillion gate designs? 4

4. What major process technologies are used in today s design environment? 5

5. What are the goals of new chip design? 8

6. What are the major approaches of today s very large scale integration (VLSI) circuit design practices? 9

7. What is standard cell–based, application–specific integrated circuit (ASIC) design methodology? 11

8. What is the system–on–chip (SoC) approach? 12

9. What are the driving forces behind the SoC trend? 15

10. What are the major tasks in developing a SoC chip from concept to silicon? 15

11. What are the major costs of developing a chip? 16

CHAPTER 2 THE BASICS OF THE CMOS PROCESS AND DEVICES 17

12. What are the major process steps in building MOSFET transistors? 17

13. What are the two types of MOSFET transistors? 19

14. What are base layers and metal layers? 20

15. What are wafers and dies? 24

16. What is semiconductor lithography? 28

17. What is a package? 33

CHAPTER 3 THE CHALLENGES IN VLSI CIRCUIT DESIGN 41

18. What is the role of functional verification in the IC design process? 41

19. What are some of the design integrity issues? 44

20. What is design for testability? 46

21. Why is reducing the chip s power consumption so important? 48

22. What are some of the challenges in chip packaging? 49

23. What are the advantages of design reuse? 50

24. What is hardware/software co–design? 51

25. Why is the clock so important? 54

26. What is the leakage current problem? 57

27. What is design for manufacturability? 60

28. What is chip reliability? 62

29. What is analog integration in the digital environment? 65

30. What is the role of EDA tools in IC design? 67

31. What is the role of the embedded processor in the SoC environment? 69

CHAPTER 4 CELL–BASED ASIC DESIGN METHODOLOGY 73

32. What are the major tasks and personnel required in a chip design project? 73

33. What are the major steps in ASIC chip construction? 74

34. What is the ASIC design flow? 75

35. What are the two major aspects of ASIC design flow? 77

36. What are the characteristics of good design flow? 80

37. What is the role of market research in an ASIC project? 81

38. What is the optimal solution of an ASIC project? 82

39. What is system–level study of a project? 84

40. What are the approaches for verifying design at the system level? 85

41. What is register–transfer–level (RTL) system–level description? 86

42. What are methods of verifying design at the register–transfer–level? 87

43. What is a test bench? 88

44. What is code coverage? 89

45. What is functional coverage? 89

46. What is bug rate convergence? 90

47. What is design planning? 91

48. What are hard macro and soft macro? 92

49. What is hardware description language (HDL)? 92

50. What is register–transfer–level (RTL) description of hardware? 93

51. What is standard cell? What are the differences among standard cell, gate–array, and sea–of–gate approaches? 94

52. What is an ASIC library? 103

53. What is logic synthesis? 105

54. What are the optimization targets of logic synthesis? 106

55. What is schematic or netlist? 107

56. What is the gate count of a design? 111

57. What is the purpose of test insertion during logic synthesis? 111

58. What is the most commonly used model in VLSI circuit testing? 112

59. What are controllability and observability in a digital circuit? 114

60. What is a testable circuit? 115

61. What is the aim of scan insertion? 116

62. What is fault coverage? What is defect part per million (DPPM)? 117

63. Why is design for testability important for a product s financial success? 119

64. What is chip power usage analysis? 120

65. What are the major components of CMOS power consumption? 121

66. What is power optimization? 123

67. What is VLSI physical design? 123

68. What are the problems that make VLSI physical design so challenging? 124

69. What is floorplanning? 128

70. What is the placement process? 131

71. What is the routing process? 133

72. What is a power network? 135

73. What is clock distribution? 139

74. What are the key requirements for constructing a clock tree? 143

75. What is the difference between time skew and length skew in a clock tree? 145

76. What is scan chain? 149

77. What is scan chain reordering? 151

78. What is parasitic extraction? 152

79. What is delay calculation? 155

80. What is back annotation? 156

81. What kind of signal integrity problems do place and route tools handle? 156

82. What is cross–talk delay? 157

83. What is cross–talk noise? 158

84. What is IR drop? 159

85. What are the major netlist formats for design representation? 162

86. What is gate–level logic verification before tapeout? 162

87. What is equivalence check? 163

88. What is timing verification? 164

89. What is design constraint? 165

90. What is static timing analysis (STA)? 165

91. What is simulation approach on timing verification? 169

92. What is the logical–effort–based timing closure approach? 173

93. What is physical verification? 178

94. What are design rule check (DRC), design verification (DV), and geometry verification (GV)? 179

95. What is schematic verification (SV) or layout versus schematic (LVS)? 181

96. What is automatic test pattern generation (ATPG)? 182

97. What is tapeout? 184

98. What is yield? 184

99. What are the qualities of a good IC implementation designer? 187

Conclusion 189

Acronyms 191

Bibliography 195

Index 199

Liming Xiu is a Design Engineer and a Senior Member of Technical Staff (SMTS) at Texas Instruments, Inc. His interests include digital and mixed–signal integrated circuit design and VLSI physical design. He has worked on various mixed–signal devices, including video decoders, 3–D graphics controllers, and HDTV decoders, as physical design lead. He is also a Phase Lock Loop (PLL) expert. He is the inventor of "Flying–Adder" frequency and phase synthesis architecture, which has been used in many commercial products. He has eleven granted or pending U.S. patents. He is a Senior Member of the IEEE and the general chair of the IEEE Circuit and Systems Society, Dallas Chapter.

An accessible, intuitive resource to common and not–so–common questions and answers about very large–scale integrated (VLSI) circuit design

The widespread acceptance of sophisticated electronic devices and the growing challenges of a more technically oriented future have created an unprecedented demand for very large–scale integrated (VLSI) circuits. Meeting this crucial need requires advances in material science and processing equipment along with the ability to use the computer more effectively to aid in the design process. More importantly, it also requires a significant number of qualified professionals to work in this exciting field. Unfortunately, due to its complexity and dynamic nature, the topic of VLSI circuit design methodology is not widely taught in universities nor is it well understood by many engineers. Now, VLSI Circuit Design Methodology Demystified takes the guesswork out of this important topic by presenting readers with a succinct and accessible treatment of how a complex chip is developed, from concept to silicon.

Uniquely organized in a question–and–answer format, the book builds on information in the order of chip development: market research/product definition, system design, logic design, logic verification, logic synthesis, Place & Route, and physical verification. A wealth of important questions are addressed, including:

• What are the requirements of a successful chip design?

• What are the major approaches of today′s VLSI circuit design practices?

• What are the major process steps in building MOSFET transistors?

• What is the role of functional verification in the IC design process?

• What are the two major aspects of ASIC design flow?

• What is Hardware Description Language (HDL)?

• What is the most commonly used model in VLSI circuit testing?

• What are the qualities of a good IC implementation designer?

The answers to these questions and many more provide the framework for understanding the key concepts involved in the VLSI chip development process, giving readers a solid foundation for further advancement in the field. Written by an industry expert, the book uses up–to–date, real–world design examples to demonstrate to readers how to become better engineers through a practical approach of diagnosing and attacking problems. Ideal as a resource for electrical engineers specializing in integrated circuit design in the semiconductor industry, this book is also suitable as a supplementary text for students enrolled in advanced VLSI courses.