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Methods and tools for simulation and quality control of design and production of microwave devices / edited by Sergey V. Savel'kaev and Sergey B. Danilevich.
- Format:
- Book
- Language:
- English
- Subjects (All):
- Microwave amplifiers--Design and construction.
- Microwave amplifiers.
- Genre:
- Libros electrónicos.
- Physical Description:
- 1 online resource (286 pages)
- Edition:
- 1st ed.
- Place of Publication:
- Newcastle upon Tyne, England : Cambridge Scholars Publishing, [2020]
- Summary:
- The book deals with the design and quality control of microwave devices using simulation and measurement methods. It describes principles for designing simulators of microwave amplifiers and oscillators that provide simulation modeling of these devices in accordance with the technical specifications for their design. In addition, it shows how simulators can be used for accurate and adequate measurements of the parameters of the simulated devices required for their subsequent design. The book also addresses the development of effective methods for controlling the quality of complex technical products (including microwave amplifiers and oscillators). The simulation method and control modeling algorithms proposed here can be used to analyze existing and plan new effective methods of measuring control that minimize the costs associated with control.The text will be useful for developers of measuring systems and methods, as well as quality experts involved in the design and manufacture of technical products. In addition, it will appeal to researchers, teachers, and both undergraduate and graduate students.
- Contents:
- Intro
- Contents
- List of Abbreviations
- Introduction
- Part I: Theoretical basis for designing analyzers/simulators for microwave devices
- 1: Microwave Network Analyzers
- 1.1 Principle of operation and advantages
- 1.2 Generalized equation of physical conversion in the space of D-matrices
- 1.3 Classification of network analyzers into types with the choice of the basic structure
- 2: Theoretical Basis for Designing Simulators/Analyzers for Microwave Amplifiers and Oscillators
- 2. 1 Block diagram and design of simulators/analyzers
- 2.2. Operating principle of simulators/analyzers
- 2.3 Mathematical model of simulators/analyzers
- 2.3.1 Homodyne mode
- 2.3.2 Two-signal mode
- 2.4 Method of stability analysis
- 2.5 Methods for measuring the S-parameters of two-ports
- 2.6 Calibration of the simulator/analyzer
- 2.6.1 Calibration of directional bridges in the homodyne mode
- 2.6.2 Calibration of directional bridges in the two-signal mode
- 2.6.3 Calibration of detectors
- 2.7 Normalization of measurement results with respect to microstrip lines
- 2.8 Mathematical model of tunable matching transformers
- 2.9 Calibration of tunable matching transformers
- 2.10 Autonomous synthesis of matching networks of simulated amplifiers and oscillators
- 3: Methods for Increasing the Measurement Accuracy of Simulators/Analyzers
- 3.1 Amplitude and phase adjustment of simulators/analyzers and their metrological characteristics
- 3.2 Variational method for estimating the limiting total measurement error of simulators/analyzers
- 4: Library of Mathematical Models of Microwave Amplifiers and Oscillators and Their Components in the Space of S-Parameters
- 4.1 Three-section drift-diffusion mathematical model of a Schottky-barrier field-effect transistor
- 4.1.1 Calculation of current-voltage characteristics.
- 4.1.2 Calculation of the immittance g , R, C τ and L -parameters of the equivalent circuit
- 4.1.3 Calculation of S-parameters
- 4.2 Mathematical modeling of amplifiers with required output power
- 4.3 Mathematical modeling of unstabilized oscillators
- 4.4 Method for calculating the resonant frequency of a multilayer dielectric structure based on network theory
- 4.4.1 Calculation method
- 4.4.2 Practical application of the method
- 5: Technical Implementation of Simulators/Analyzers and Simulated Microwave Amplifiers and Oscillators
- 5.1 Technical implementation of simulators/analyzers
- 5.2 Technical implementation of amplifiers
- 5. 3 Technical implementation of an unstabilizedoscillator
- 5. 4 Technical implementation of an oscillator stabilized by a multilayer dielectric structure
- Conclusions
- Part II: Effective methods of quality control of technical products
- 6: Performance Assurance of Quality Control Methods for Technical Products
- 6.1 Development of measuring test methods
- 6.2 Indicators of reliability of test results
- 7: Multivariate Continuous Quality Control Model
- 7.1 Development of a simulation model for continuousquality control
- 7.2 Modeling of test parameters of products
- 7.3 Modeling of a quality control procedure
- 8: Planning of Multivariate Sampling Quality Control
- 8.1 Sampling quality control model
- 8.2 Development of sampling quality control procedures
- 9: Optimization of Sampling Inspection
- 9.1 Problems in optimizing sampling quality control
- 9.2 Efficiency of sampling quality control of limited batchesof products
- Conclusion
- References.
- Notes:
- Description based on print version record.
- Description based on publisher supplied metadata and other sources.
- ISBN:
- 1-5275-4489-3
- OCLC:
- 1183030477
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