Book contents
- Frontmatter
- Contents
- Preface
- Acknowledgements
- Chapter 1 Introduction to Microelectronics
- Chapter 2 From Algorithms to Architectures
- Chapter 3 Functional Verification
- Chapter 4 Modelling Hardware with VHDL
- Chapter 5 The Case for Synchronous Design
- Chapter 6 Clocking of Synchronous Circuits
- Chapter 7 Acquisition of Asynchronous Data
- Chapter 8 Gate- and Transistor-Level Design
- Chapter 9 Energy Efficiency and Heat Removal
- Chapter 10 Signal Integrity
- Chapter 11 Physical Design
- Chapter 12 Design Verification
- Chapter 13 VLSI Economics and Project Management
- Chapter 14 A Primer on CMOS Technology
- Chapter 15 Outlook
- Appendix A Elementary Digital Electronics
- Appendix B Finite State Machines
- Appendix C VLSI Designer's Checklist
- Appendix D Symbols and constants
- References
- Index
- Plate section
Chapter 11 - Physical Design
- Frontmatter
- Contents
- Preface
- Acknowledgements
- Chapter 1 Introduction to Microelectronics
- Chapter 2 From Algorithms to Architectures
- Chapter 3 Functional Verification
- Chapter 4 Modelling Hardware with VHDL
- Chapter 5 The Case for Synchronous Design
- Chapter 6 Clocking of Synchronous Circuits
- Chapter 7 Acquisition of Asynchronous Data
- Chapter 8 Gate- and Transistor-Level Design
- Chapter 9 Energy Efficiency and Heat Removal
- Chapter 10 Signal Integrity
- Chapter 11 Physical Design
- Chapter 12 Design Verification
- Chapter 13 VLSI Economics and Project Management
- Chapter 14 A Primer on CMOS Technology
- Chapter 15 Outlook
- Appendix A Elementary Digital Electronics
- Appendix B Finite State Machines
- Appendix C VLSI Designer's Checklist
- Appendix D Symbols and constants
- References
- Index
- Plate section
Summary
Agenda
Physical design is concerned with turning circuit netlists into layout drawings that
Are amenable to fabrication with some given target process,
Logically function as expected in spite of numerous parasitic effects,
Meet ambitious performance goals in spite of layout parasitics, and
Keep fabrication costs down by minimizing die size and by maximizing yield.
The degree to which physical issues are placed under control of IC designers is highly dependent upon fabrication depth and design level. While global interconnect must be planned for in every design project — even when opting for field-programmable logic — few digital designers continue to work with layout at the detail level today. This chapter is organized accordingly. Sections 11.2 through 11.4 cover issues that are relevant in any IC design, such as floorplanning and packaging, while the material on detailed layout is postponed to section 11.5. Section 11.6, finally, collects discussions of various destructive phenomena that must be contained.
Conducting layers and their characteristics
The layers made available by VLSI processes greatly differ in their geometric and electrical characteristics. Let us begin by studying those properties and differences.
Geometric properties and layout rules
The transfer of layout patterns to the various layers of material on a semiconductor die is obtained from photolithographic methods followed by selective removal of unwanted material.
- Type
- Chapter
- Information
- Digital Integrated Circuit DesignFrom VLSI Architectures to CMOS Fabrication, pp. 523 - 580Publisher: Cambridge University PressPrint publication year: 2008