This engineering reference covers new techniques in electronic packaging - flip chip, BGA, and MEMs. It includes high density packaging and cleaning options.
*Covers design, packaging, construction, assembly, and application of all three approaches to Area Array Packaging: Ball Grid Array (BGA), Chip Scale Package (CSP), and Flip Chip (FC) *Details the pros and cons of each technology with varying applications *Examines packaging ramifications of high density interconnects (HDI)
Microelectronic packaging has been recognized as an important "enabler" for the solid state revolution in electronics which we have witnessed in the last third of the twentieth century. Packaging has provided the necessary external wiring and interconnection capability for transistors and integrated circuits while they have gone through their own spectacular revolution from discrete device to gigascale integration. At IBM we are proud to have created the initial, simple concept of flip chip with solder bump connections at a time when a better way was needed to boost the reliability and improve the manufacturability of semiconductors. The basic design which was chosen for SLT (Solid Logic Technology) in the 1960s was easily extended to integrated circuits in the '70s and VLSI in the '80s and '90s. Three I/O bumps have grown to 3000 with even more anticipated for the future. The package families have evolved from thick-film (SLT) to thin-film (metallized ceramic) to co-fired multi-layer ceramic. A later family or ceramics with matching expansivity to sili con and copper internal wiring was developed as a predecessor of the chip interconnection revolution in copper, multilevel, submicron wiring. Powerful server packages have been de veloped in which the combined chip and package copper wiring exceeds a kilometer. All of this was achieved with the constant objective of minimizing circuit delays through short, efficient interconnects.
This engineering reference covers the most important solders and materials in modern electronic packaging. Written by a team of world-class professionals and researchers, Area Array Packaging Materials includes vital information necessary for the design of cutting-edge electronics products.
An advanced reference documenting, in detail, every step of a real System-in-Package (SiP) design flow Written by an engineer at the leading edge of SiP design and implementation, this book demonstrates how to design SiPs using Mentor EE Flow. Key topics covered include wire bonding, die stacks, cavity, flip chip and RDL (redistribution layer), Embedded Passive, RF design, concurrent design, Xtreme design, 3D real-time DRC (design rule checking), and SiP manufacture. Extensively illustrated throughout, System in Package Design and Simulation covers an array of issues of vital concern for SiP design and fabrication electronics engineers, as well as SiP users, including: Cavity and sacked dies design FlipChip and RDL design Routing and coppering 3D Real-Time DRC check SiP simulation technology Mentor SiP Design and Simulation Platform Designed to function equally well as a reference, tutorial, and self-study, System in Package Design and Simulation is an indispensable working resource for every SiP designer, especially those who use Mentor design tools.
Reviewing the various IC packaging, assembly, and interconnection technologies, this professional reference provides an overview of the materials and the processes, as well as the trends and available options that encompass electronic manufacturing. It covers both the technical issues and touches on some of the reliability concerns with the various technologies applicable to packaging and assembly of the IC. The book discusses the various packaging approaches, assembly options, and essential manufacturing technologies, among other relevant topics.
In semiconductor manufacturing, understanding how various materials behave and interact is critical to making a reliable and robust semiconductor package. Semiconductor Packaging: Materials Interaction and Reliability provides a fundamental understanding of the underlying physical properties of the materials used in a semiconductor package. By tying together the disparate elements essential to a semiconductor package, the authors show how all the parts fit and work together to provide durable protection for the integrated circuit chip within as well as a means for the chip to communicate with the outside world. The text also covers packaging materials for MEMS, solar technology, and LEDs and explores future trends in semiconductor packages.
A comprehensive guide to antenna design, manufacturing processes, antenna integration, and packaging Antenna-in-Package Technology and Applications contains an introduction to the history of AiP technology. It explores antennas and packages, thermal analysis and design, as well as measurement setups and methods for AiP technology. The authors—well-known experts on the topic—explain why microstrip patch antennas are the most popular and describe the myriad constraints of packaging, such as electrical performance, thermo-mechanical reliability, compactness, manufacturability, and cost. The book includes information on how the choice of interconnects is governed by JEDEC for automatic assembly and describes low-temperature co-fired ceramic, high-density interconnects, fan-out wafer level packaging–based AiP, and 3D-printing-based AiP. The book includes a detailed discussion of the surface laminar circuit–based AiP designs for large-scale mm-wave phased arrays for 94-GHz imagers and 28-GHz 5G New Radios. Additionally, the book includes information on 3D AiP for sensor nodes, near-field wireless power transfer, and IoT applications. This important book: • Includes a brief history of antenna-in-package technology • Describes package structures widely used in AiP, such as ball grid array (BGA) and quad flat no-leads (QFN) • Explores the concepts, materials and processes, designs, and verifications with special consideration for excellent electrical, mechanical, and thermal performance Written for students in electrical engineering, professors, researchers, and RF engineers, Antenna-in-Package Technology and Applications offers a guide to material selection for antennas and packages, antenna design with manufacturing processes and packaging constraints, antenna integration, and packaging.
Surveys the electrical and layout perspectives of System-in-Package, the system integration technology that has emerged as a required technology to reduce the system board space and height in addition to the overall time-to-market and design cost of consumer electronics products such as those of cell phones, audio/video players and digital cameras.
This handbook provides the most comprehensive, up-to-date and easy-to-apply information on the physics, mechanics, reliability and packaging of micro- and opto-electronic materials. It details their assemblies, structures and systems, and each chapter contains a summary of the state-of-the-art in a particular field. The book provides practical recommendations on how to apply current knowledge and technology to design and manufacture. It further describes how to operate a viable, reliable and cost-effective electronic component or photonic device, and how to make such a device into a successful commercial product.