Author	Matisoff, Bernard S. author
Title	Handbook Of Electronics Packaging Design and Engineering [electronic resource] / by Bernard S. Matisoff
Imprint	Dordrecht : Springer Netherlands, 1982
Connect to	http://dx.doi.org/10.1007/978-94-011-6979-0
Descript	VIII, 472 p. online resource

The Handbook of Electronics Packaging Design and Engineering has been writยญ ten as a reference source for use in the packaging design of electronics equipยญ ment. It is designed to provide a single convenient source for the solution of reยญ curring design problems. The primary consideration of any design is that the end product meet or exceed the applicable product specifications. The judicious use of uniform design practices will realize the following economies and equipment improvements: โ{128}ข Economics of design. Uniform design practices will result in less engineering and design times and lower costs. They will also reduce the number of changes that may be required due to poor reliability, maintainability, or producibility. โ{128}ข Improved design. Better designs with increased reliability, maintainability, and producibility will result from the use of uniform design practices. โ{128}ข Production economies. Uniform designs employing standard available tools, materials, and parts will result in the cost control of manufacturing. The Handbook is intended primarily for the serious student of electronics packaging and for those engineers and designers actively engaged in this vital and interesting profession. It attempts to present electronics packaging as it is today. It can be used as a training text for instructional purposes and as a reference source for the practicing designer and engineer

1 Electronics Packaging Design and Engineering: Definition and purpose of electronics packaging and the role of the Designer and Engineer. -- 2 Project Planning: Defining the task to be performed, estimating the documentation, labor, costs, and scheduling. -- 3 Human Factors Engineering: Designing the man-machine interface. Achieving success through the integration of the Human into the system. -- 4 Fabrication Processes: The Designer and Engineer must have a good knowledge of the manufacturing processes used in the production of electronics equipment. -- 5 Mechanical Fasteners: Reliability of available mechanical fastening devices and their applications, strength, and protective finishes. -- 6 Heat Transfer and Thermal Control: One of the most critical problems in electronics packaging is the removal of excessive heat. A simplified method of Thermal design. -- 7 Shock and Vibration Design: Shock and vibration become problems long before the equipment is installed. A quick empirical method of evaluating the mechanical stability of the equipment. -- 8 Subassemblies and Assemblies: Experience has shown that the so-called โ{128}{156}scrambledโ{128}{157} parts and wiring are not acceptable for reliable electronics equipment. -- 9 Design Considerations for Space Electronics: Equipment must be protected from the harsh environments of Space. Some of this data is useful in ground installations where severe environments may be encountered. -- 10 Environmental Protection: Methods and materials for the protection of equipment in harsh applications, including rain, dust, heat, salt water atmosphere, etc. -- 11 Radio Frequency and Electromagnetic Shielding: An ideal equipment would not radiate unwanted energy, nor would it be susceptable to unwanted radiations. Designing seals and enclosures for EMI/RFI environments. -- 12 Design and Development of Miniature Electronics Systems: The advantage of the miniaturized, compact equipment is the ease with which it can be ruggedized. In modern electronics space is often limited. -- 13 Wiring and Cabling: Conductors play an important role in reliable electronics equipment. Conductor variation have become as complex as the electronics they serve. -- 14 Materials and Processes: Material availability and the applications they serve. How and what to use in specific designs. -- 15 Safety: The design of every electronics equipment must employ features to protect the operating and maintenance personnel. Protection must also be enforced to prevent inadvertant damage to the machine. -- 16 Printed Circuits: Printed wiring can produce a more reliable and lower cost product. -- 17 Reference Tables and and Figures: Standard data of commercially available and military hardware. Engineering standards and measures. -- 18 Terminology: Terminology used in Engineering design and manufacturing. Communications