Hoboken, : Wiley, 2013

1 online resource (382 p.)

Wiley Series in Systems Engineering and Management

JiangJui-Chin

TuMao-Hsiung

745.20285

Industrial design -- Data processing

Product design

Technology

Electronic books.

Inglese

Description based upon print version of record.

Cover; Title page; Copyright page; Dedication; Contents; Foreword; Preface; 1: Introduction to Quality by Design; 1.1 What is Quality?; 1.2 Why Quality by Design?; 1.3 How to Design for Quality; 1.4 New Product Development and QFD; 1.4.1 Reflections on the Development of QFD; 1.4.2 Reflections on the Evolution of NPD Philosophy; 1.5 Technology Development and Functionality Design; 1.6 Outline of This Book; PART I: Optimizing Design for Function; 2: Quality Function Deployment; 2.1 Historical Development and Definition of QFD; 2.2 The Nature of QFD; 2.3 Benefits of QFD

2.4 Two Dominant Approaches to QFD2.4.1 Akao's Matrix of Matrices Model; 2.4.2 The Four-Matrix Model; 2.5 Shortcomings of QFD; 2.6 Review Comments on QFD; 2.6.1 Comments on QFD's Development Trends and Evolutions; 2.6.2 Comments on QFD's Shortcomings; 2.6.3 Comments on QFD's Applications; 2.7 Concluding Remarks; 3: Expanded System of QFD; 3.1 Overview of EQFD System and Its Implementation Process; 3.2 Thirty-Six Steps of the EQFD Implementation Process; I. Business and Product Planning; II. Technology Development Planning; III. Request for Quotation (RFQ); IV. Prototype Design

V. Engineering Verification Test (EVT)VI. Design Verification Test (DVT);

VII. Production Verification Test (PVT); VIII. Shop Floor Real-Time Management and Abnormality Management; 3.3 Reinforcement of EQFD for the Original QFD; 3.4 EQFD Application; 3.4.1 Quality Deployment; 3.4.2 Technology Deployment; 3.4.3 Cost Deployment; 3.4.4 Reliability Deployment; 3.4.5 Shop Floor Management; 3.4.6 Summary; PART II: Optimizing Design for Functionality; 4: R&D Paradigm; 4.1 R&D Strategy as Prediction and Prevention; 4.2 Conventional Approach to R&D; 4.3 R&D Paradigm Shift; 5: Functionality Evaluation

5.1 Energy Transformation and Technology Development5.2 Evaluation of Technology; 5.3 Signal-to-Noise Ratio; 5.3.1 Dynamic SN Ratio; 5.3.2 Static SN Ratio; 5.4 Comparative Assessment of Functionality; 5.4.1 Conventional Evaluation Indicators; 5.4.2 Using the SN Ratio; 5.5 Examples; 5.5.1 Two Measurement Systems; 5.5.2 Two Designs; 6: Functionality Design; 6.1 R&D and Robust Engineering; 6.2 Parameter Design for Robustness; 6.2.1 Key Concepts; 6.2.2 Key Tools; 6.2.3 Process Steps; 6.3 Common Problems of RE Application in Practice; 6.4 Robust Technology Development; 6.5 Case Studies

6.5.1 Optimization of a Current-Voltage Conversion Circuit6.5.2 Robust Engineering of a Voltage Adjustment Component; 6.5.3 Accuracy Engineering of a Measurement System; 6.5.4 Stability Engineering of a Cutting Machine; 6.5.5 Summary; 7: Managing for Paradigm Shift; 7.1 Winning Quality-Based Technology Leadership; 7.2 Key Success Factors; 7.2.1 Technical Aspect; 7.2.2 Managerial Aspect; 7.3 Benefit to the Organization; 7.4 Slogan or Strategy?; PART III: Integration Strategy; 8: Structure for Design Activity Integration; 8.1 Universal Roadmap and Nine Tools for Design Engineering

8.2 Integration of QFD and Other Breakthrough Strategies

Provides a clear, useful framework and methods for R&D, including robust technology development, product planning, and product design and development management  Quality Strategy for Research and Development integrates the Japanese and Western perspectives on Quality Function Deployment (QFD), updates the strategy of Robust Engineering (RE), and relates their unique frameworks to current, widely adopted philosophies of quality assurance. Featuring real-world case studies, more than thirty tables, and over seventy figures, this essential guide identifies key issues and p

Roma, : L'Erma di Bretschneider, 1953 201 p. ; 23 cm

B

Italiano

Hoboken, New Jersey : , : Wiley, , c2009

[Piscataqay, New Jersey] : , : IEEE Xplore, , 2008

1-282-68268-7

9786612682681

0-470-38590-1

0-470-38589-8

1 online resource (729 p.)

Wiley series in microwave and optical engineering ; ; 19

621.381/32

621.38132

Microwave circuits - Mathematical models

Oscillators, Microwave - Automatic control

Oscillators, Microwave - Design and construction

System analysis

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

Preface -- 1. Oscillator Dynamics -- 1.1. Introduction -- 1.2. Operational Principle of Free-Running Oscillators -- 1.3. Impedance-Admittance Analysis of an Oscillator -- 1.4. Frequency-Domain Formulation of an Oscillator Circuit -- 1.5. Oscillator Dynamics -- 1.6. Phase Noise -- 2. Phase Noise -- 2.1. Introduction -- 2.2. Random Variable and random Processes -- 2.3. Noise Sources in Electronic Circuits -- 2.4. Derivation of the Oscillator Noise Spectrum Using Time-Domain Analysis -- 2.5. Frequency-Domain Analysis of a Noisy Oscillator -- 3. Bifurcation Analysis -- 3.1. Introduction -- 3.2. Representation of Solutions -- 3.3. Bifurcations -- 4. Injected Oscillators and Frequency Dividers -- 4.1. Introduction -- 4.2. Injection-Locked Oscillators -- 4.3. Frequency Dividers -- 4.4. Subharmonically and Ultrasubharmonically Injection-Locked Oscillators -- 4.5. Self-Oscillating Mixers -- 5. Nonlinear Circuit Simulation -- 5.1. Introduction -- 5.2. Time-Domain Integration -- 5.3. Fast Time-Domain Techniques -- 5.4. Harmonic Balance -- 5.5. Harmonic Balance Analysis of Autonomous and Synchronized Circuit -- 5.6. Envelope Transient -- 5.7. Conversion Matrix Approach -- 6. Stability Analysis Using Harmonic Balance -- 6.1. Introduction -- 6.2. Local Stability Analysis -- 6.3. Stability Analysis of Free-Running Oscillators -- 6.4. Solution Curves Versus a Circuit Parameter -- 6.5.Global Stability Analysis -- 6.6. Bifurcation Synthesis and Control -- 7. Noise Analysis Using Harmonic Balance -- 7.1. Introduction -- 7.2. Noise in Semiconductor Devices -- 7.3. Decoupled Analysis of Phase and Amplitude Perturbations in a Harmonic Balance System -- 7.4. Coupled Phase and Amplitude Noise Calculation -- 7.5. Carrier Modulation Approach -- 7.6. Conversion Matrix Approach -- 7.7. Noise in Synchronized Oscillators -- 8. Harmonic Balance Techniques for Oscillator Design -- 8.1. Introduction -- 8.2. Oscillator Synthesis -- 8.3. Design of Voltage-Controlled Oscillators

8.4. Maximization of Oscillator Efficiency -- 8.5. Control of Oscillator Transients -- 8.6. Phase Noise Reduction -- 9. Stabilization Techniques for Phase Noise Reduction -- 9.1. Introduction -- 9.2. Self-Injection Topology -- 9.3. Use of High-Q Resonators -- 9.4. Stabilization Loop -- 9.5. Transistor-Based Oscillators -- 10. Coupled-Oscillator Systems -- 10.1. Introduction -- 10.2. Oscillator Systems with Global Coupling -- 10.3. Coupled-Oscillator Systems for Beam Steering -- 11. Simulation Techniques for Frequency-Divider Design -- 11.1. Introduction -- 11.2. Types of frequency dividers -- 11.3. Design of Transistor-Based Regenerative Frequency Dividers -- 11.4. Design of Harmonic Injection Dividers -- 11.5. Extension of the Techniques to Subharmonic Injection Oscillators -- 12. Circuit Stabilization -- 12.1. Introduction -- 12.2. Unstable Class AB Amplifier Using Power Combiners -- 12.3. Unstable Class E/F Amplifier -- 12.4. Unstable Class E Amplifier -- 12.5. Stabilization of Oscillator Circuits -- 12.6. Stabilization of Multifunction MMIC Chips -- Index

Presents simulation techniques that substantially increase designers' control over the oscillationin autonomous circuits This book facilitates a sound understanding of the free-running oscillation mechanism, the start-up from the noise level, and the establishment of the steady-state oscillation. It deals with the operation principles and main characteristics of free-running and injection-locked oscillators, coupled oscillators, and parametric frequency dividers. Analysis and Design of Autonomous Microwave Circuits provides: . An exploration of the main nonlinear-analysis methods, with emphasis on harmonic balance and envelope transient methods. Techniques for the efficient simulation of the most common autonomous regimes. A presentation and comparison of the main stability-analysis methods in the

frequency domain. A detailed examination of the instabilization mechanisms that delimit the operation bands of autonomous circuits. Coverage of techniques used to eliminate common types of undesired behavior, such as spurious oscillations, hysteresis, and chaos. A thorough presentation of the oscillator phase noise. A comparison of the main methodologies of phase-noise analysis. Techniques for autonomous circuit optimization, based on harmonic balance. A consideration of different design objectives: presetting the oscillation frequency and output power, increasing efficiency, modifying the transient duration, and imposing operation bands Analysis and Design of Autonomous Microwave Circuits is a valuable resource for microwave designers, oscillator designers, and graduate students in RF microwave design