TY  - BOOK
AU  - Shina,Sammy G.
TI  - Six Sigma for electronics design and manufacturing
T2  - McGraw-Hill professional engineering
SN  - 0071395113
AV  - TK7836 .S4824 2002
U1  - 621.381 21
PY  - 2002///]
CY  - New York
PB  - McGraw-Hill
KW  - Electronic apparatus and appliances
KW  - Design and construction
KW  - Quality control
KW  - Standards
KW  - Six sigma (Quality control standard)
N1  - Includes bibliographical references and index; Ch. 1; The Nature of Six Sigma and Its Connectivity to Other Quality Tools; 1.1; Historical Perspective; 1.2; Why Six Sigma?; 1.3; Defending Six Sigma; 1.4; The Definitions of Six Sigma; 1.5; Increasing the Cp Level to Reach Six Sigma; 1.6; Definitions of Major Quality Tools and How They Effect Six Sigma; 1.7; Mandatory Quality Tools; 1.8; Quality Function Deployment (QFD); 1.9; Design of Manufacture (DFM); 1.10; Design of Experiments (DoE); 1.11; Other Quality Tools; 1.12; Gauge Repeatability and Reproducibility (GR&R) --; Ch. 2; The Elements of Six Sigma and Their Determination; 2.1; The Quality Measurement Techniques: SQC, Six Sigma, Cp and Cpk; 2.2; The Cpk Approach Versus Six Sigma; 2.3; Calculating Defects Using Normal Distribution; 2.4; Are Manufacturing Processes and Supply Parts Always Normally Distributed? --; Ch. 3; Six Sigma and the Manufacturing Control Systems; 3.1; Manufacturing Variability Measurement and Control; 3.2; The Control of Variable Processes and Its Relationship with Six Sigma; 3.3; Attribute charts and their Relationship with Six Sigma; 3.4; Using TQM Techniques to Maintain Six Sigma Quality in Manufacturing --; Ch. 4; The Use of Six Sigma in Determining the Manufacturing Yield and Test Strategy; 4.1; Determining Units of Defects; 4.2; Determining Manufacturing Yield on a Single Operation or a Part with Multiple Similar Operations; 4.3; Determining Design or Manufacturing Yield on Multiple Parts with Multiple Manufacturing Operations or Design Specifications; 4.4; Determining Overall Product Testing Strategy --; Ch. 5; The Use of Six Sigma With High- and Low-Volume Products and Processes; 5.1; Process Average and Standard Deviation Calculations for Samples and Populations; 5.2; Determining Process Capability; 5.3; Determining Gauge Capability; 5.4; Determining Short- and Long-Term Process Capability --; Ch. 6; Six Sigma Quality and Manufacturing Costs of Electronics Products; 6.1; The Overall Electronic Product Life Cycle Cost Model; 6.2; The Quality and Cost Relationship; 6.3; Electronic Products Cost Estimating Systems; 6.4; PCB Assembly Cost Estimating Systems --; Ch. 7; Six Sigma and Design of Experiments (DoE); 7.1; DoE Definitions and Expectations; 7.2; Design of Experiments (DoE) Techniques; 7.3; The DoE Analysis Tool Set; 7.4; Variability Reduction Using DoE; 7.5; Using DoE Methods in Six Sigma Design and Manufacturing Projects --; Ch. 8; Six Sigma and Its Use in the Analysis of Design and Manufacturing for Current and New Products and Processes; 8.1; Current Product Six Sigma Strategy; 8.2; Transitioning New Product Development to Six Sigma; 8.3; Determining Six Sigma Quality in Different Design Disciplines; 8.4; Applying Six Sigma Quality for New Product Introduction --; Ch. 9; Six Sigma and the New Product Life Cycle; 9.1; Background: Concurrent Engineering Successes and New Trends; 9.2; Supply Chain Development; 9.3; Product Life Cycle and the Six Sigma Design Quality Issues --; Ch. 10; New Product and Systems Project Management Using Six Sigma Quality; 10.1; The Quality System Review and Quality-Based Project Management Methodologies; 10.2; Technical Design Information Flow and Six Sigma System Design --; Ch. 11; Implementing Six Sigma in Electronics Design and Manufacturing; 11.1; Six Sigma Design Project Management Models; 11.2; Cultural Issues with the Six Sigma Based System Design Process; 11.3; Key Processes to Enhance the Concurrent Product Creation Process; 11.4; Tools to Support Suggested Processes
N2  - Annotation; HERE'S THE NUTS, BOLTS, AND STATISTICS OF IMPLEMENTING SIX SIGMA IN NEW PRODUCT DESIGN AND MANUFACTURING Fewer defects, optimal design, lower production costs, higher quality products, and increased customer satisfaction - with benefits like those, is it any wonder that premier firms such as GE have adopted the Six Sigma approach to design and manufacturing and thousands of other companies are following suit? This powerful engineering resource provides the detailed methodologies, illustrations, and calculations needed for the implementation and improved utilization of Six Sigma in the electronics, mechanical, aerospace, and medical industries. Written by an acknowledged Six Sigma quality expert with a flair for clear, succinct writing - and priceless hands-on new product development and manufacturing experience -- "Six Sigma for Electronics Design and Manufacturing includes eye-opening real-world electronics and high-technology industry case studies and covers essential issues such as: *Six Sigma connectivity with world-class quality tools * Achieving Six Sigma using the manufacturing control systems * Six Sigma methodology in the design of new systems and products * Using Six Sigma for product cost estimation and test strategy * How to use Six Sigma in high- and low-volume products and lifecycles * Six Sigma in project management, including the supply chain * Using Design of Experiments (DoE) to achieve Six Sigma goals * Successful Six Sigma roadmaps * And much more For electrical and mechanical engineers, technicians, and managers who need "the numbers" to make Six Sigma work in the complex electronics and high-technology arena, here is a trulyindispensable reference
UR  - http://www.loc.gov/catdir/bios/mh041/2002021283.html
ER  -