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Multichip Module Technologies and Alternatives: The Basics

  • Editors
  • Daryl Ann Doane
  • Paul D. Franzon

Table of contents

  1. Front Matter
    Pages i-xxxii
  2. The Framework

    1. Front Matter
      Pages 1-2
    2. Daryl Ann Doane
      Pages 3-36
    3. Allison Casey Dixon, Edward G. Myszka
      Pages 37-86
    4. Lee Hong Ng
      Pages 133-164
  3. The Basics

    1. Front Matter
      Pages 165-167
    2. Leo M. Higgins III
      Pages 169-213
    3. Claudius Feger, Christine Feger
      Pages 311-348
    4. Robert E. Rackerby, Erik N. Larson, Dean R. Haagenson, Steve J. Bezuk, Rajendra D. Pendse, Chee C. Wong et al.
      Pages 349-486
    5. Paul D. Franzon
      Pages 525-568
    6. Thomas C. Russell, Yenting Wen
      Pages 615-660
  4. Case Studies

    1. Front Matter
      Pages 661-663
    2. John A. Nelson, Randy D. Rhodes
      Pages 665-694
    3. Robert L. Bone, Dennis F. Elwell, James J. Licari, Robert S. Miles, Kevin P. Shambrook, Stanley M. Stuhlbarg et al.
      Pages 695-735
    4. R. Wayne Johnson
      Pages 737-768
    5. Salma Y. Abbasi, Arun Malhotra, John D. Marshall, Douglas N. Modlin, Ralph Platz, Hongbee Teoh et al.
      Pages 769-814
  5. Closing the Loop

    1. Front Matter
      Pages 815-816
    2. Ronald W. Gedney, Donald P. Seraphim
      Pages 817-842
  6. Back Matter
    Pages 843-875

About this book

Introduction

Far from being the passive containers for semiconductor devices of the past, the packages in today's high performance computers pose numerous challenges in interconnecting, powering, cooling and protecting devices. While semiconductor circuit performance measured in picoseconds continues to improve, computer performance is expected to be in nanoseconds for the rest of this century -a factor of 1000 difference between on-chip and off-chip performance which is attributable to losses associated with the package. Thus the package, which interconnects all the chips to form a particular function such as a central processor, is likely to set the limits on how far computers can evolve. Multichip packaging, which can relax these limits and also improve the reliability and cost at the systems level, is expected to be the basis of all advanced computers in the future. In addition, since this technology allows chips to be spaced more closely, in less space and with less weight, it has the added advantage of being useful in portable consumer electronics as well as in medical, aerospace, automotive and telecommunications products. The multichip technologies with which these applications can be addressed are many. They range from ceramics to polymer-metal thin films to printed wiring boards for interconnections; flip chip, TAB or wire bond for chip-to-substrate connections; and air or water cooling for the removal of heat.

Keywords

computer electronics manufacturing performance processor reliability telecommunications

Bibliographic information

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