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図書
図書
1. Principles of signals and systems : deterministic signals
Bernard Picinbono
出版情報: Norwood, Ma. : Artech House, c1988  xiii, 243 p. ; 24 cm
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Preface
Introduction to Signals and Systems / Chapter 1:
The concept of signals / 1.1:
The concept of a linear system / 1.2:
The concept of linear filters / 1.3:
The concept of signal representation and transform / 1.4:
Problems
Representations of Continuous-time Signals / Chapter 2:
Energy and power; scalar product of signals / 2.1:
Fourier series / 2.2:
Time-limited signals / 2.2.1:
Periodic signals / 2.2.2:
Principal properties of Fourier series of periodic signals / 2.2.3:
Fourier transforms of signals of finite energy / 2.3:
Definitions and notation / 2.3.1:
Examples of Fourier transforms / 2.3.2:
Principal properties of Fourier transforms / 2.3.3:
Examples / 2.3.4:
Fourier representation of signals with infinite energy / 2.4:
The unit impulse function / 2.4.1:
Fourier transforms of periodic signals / 2.4.2:
The Dirac comb signal / 2.4.3:
Fourier transform of the unit step signal / 2.4.4:
Real narrowband signals: instantaneous amplitude and phase, duration and bandwidth / 2.5:
Analytic signal of a real signal / 2.5.1:
Instantaneous amplitude and phase of a signal / 2.5.2:
Application to the case of narrowband signals / 2.5.3:
Laplace representation / 2.6:
Definition and notation / 2.6.1:
Region of convergence / 2.6.2:
Inversion of the Laplace transform / 2.6.3:
Inverse Laplace transform of rational functions / 2.6.4:
Principal properties of the Laplace transform / 2.6.5:
From Continuous Time to Discrete Time by Sampling / Chapter 3:
The principle of sampling: the sampling theorem / 3.1:
The sampling formula and consequences / 3.2:
Sampling and signal representation / 3.2.1:
Sampling and interpolation / 3.2.2:
Sampling and linear spaces / 3.2.3:
Minimum sampling rate / 3.2.4:
Exact position of the sampling time instants / 3.2.5:
Exact position of the frequency band / 3.2.6:
Some practical comments / 3.2.7:
Sampling and filtering / 3.3:
The sampling transformation T / 3.3.1:
Physical structure of the transformation T / 3.3.2:
Interpretation of the sampling theorem / 3.3.3:
Aliasing; undersampling and oversampling / 3.3.4:
Duality between sampling and periodicity / 3.3.5:
Sampling and Fourier representation / 3.4:
Geometrical interpretation of sampling / 3.5:
Discrete Fourier transform of a continuous signal / 3.6:
Principle of the discrete Fourier transform / 3.6.1:
Calculation of the discrete Fourier transform / 3.6.2:
Relation between the Fourier transform and the discrete Fourier transform / 3.6.3:
Representations of Discrete-time Signals / Chapter 4:
Time-limited and periodic signals: the discrete Fourier transform / 4.1:
Fourier transform of discrete-time signals / 4.2:
The z transform / 4.3:
Inversion of the z transform / 4.3.1:
Principal properties of the z transform / 4.3.4:
The z transform of sampled signals / 4.3.5:
Some algebraic properties of discrete-time signals: the fast Fourier transform / 4.4:
The discrete Fourier transform as an eigenvalue problem: circulant matrices / 4.4.1:
The discrete Fourier transform as a linear problem: the fast Fourier algorithm / 4.4.2:
Linear Filtering / Chapter 5:
Definitions and examples / 5.1:
Some basic properties of filters / 5.2:
Causality of linear filters / 5.3:
Causality and impulse response / 5.3.1:
Causality and the transfer function / 5.3.2:
Causality and frequency response / 5.3.3:
Multidimensional filters / 5.4:
Dynamical Filters / Chapter 6:
Definitions and basic properties / 6.1:
Representations of dynamical filters / 6.2:
The continuous-time case / 6.2.1:
The discrete-time case / 6.2.2:
Stability problems / 6.3:
Impulse and unit step responses / 6.3.1:
Internal Representation of Dynamical Filters / 6.4.1:
Introduction / 7.1:
Principles of the internal representation of linear systems / 7.2:
Canonical internal representation of dynamical filters / 7.3:
First continuous-time canonical representation / 7.3.1:
Second continuous-time canonical representation / 7.3.2:
First discrete-time canonical representation / 7.3.3:
Diagonal and quasi-diagonal representations / 7.3.4:
Solution of the state equation in the discrete-time case / 7.4:
Solution of the state equation in the continuous-time case / 7.5:
Free system: transition matrix / 7.5.1:
Driven system / 7.5.2:
Input-output relationship / 7.6:
Modes of a dynamical filter / 7.7:
On the Routh criterion / Appendix A:
Reflection coefficients and stability / Appendix B:
Bibliography
Glossary
Index
Preface
Introduction to Signals and Systems / Chapter 1:
The concept of signals / 1.1:
2.

図書
図書
2. Molecular genetics of bacteria
Jeremy Dale
出版情報: Chichester ; New York : Wiley, c1989  vii, 222 p. ; 23 cm
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Nucleic Acid Structure and Function / 1:
Structure of nucleic acids / 1.1:
DNA / 1.1.1:
Mutation and Variation
Regulation and Gene Expression / 1.1.2:
RNA
Genetics of Bacteriophages / 4:
Hydrophobic interactions / 5:
Plasmids
Gene Transfer / 1.1.4:
Different forms of the double helix
Genomic Plasticity: Movable Genes and Phase Variation / 7:
Supercoiling / 8:
Genetic Modification: Exploiting the Potential of Bacteria
Genetic Methods for Investigating Bacteria / 1.1.6:
Denaturation and hybridization
Gene Mapping to Genomics / 10:
Orientation of nucleic acid strands / Appendix A:
Further Reading
Abbreviations / 1.2:
Replication of DNA
Glossary / Appendix C:
Unwinding and rewinding / Appendix D:
Enzymes
Genes / 1.2.2:
Fidelity of replication: proof-reading
Standard Genetic Code / Appendix F:
Chromosome replication and cell division / Appendix G:
Bacterial Species
Index / 1.4:
DNA repair
Mismatch repair / 1.4.1:
Excision repair / 1.4.2:
Recombination (post-replication) repair / 1.4.3:
SOS repair / 1.4.4:
Gene expression / 1.5:
Transcription / 1.5.1:
Translation / 1.5.2:
Post-translational events / 1.5.3:
Gene organization / 1.6:
Variation and evolution / 2.1:
Fluctuation test / 2.1.1:
Directed mutation in bacteria? / 2.1.2:
Types of mutations / 2.2:
Point mutations / 2.2.1:
Conditional mutants / 2.2.2:
Variation due to larger scale DNA alterations / 2.2.3:
Extrachromosomal agents and horizontal gene transfer / 2.2.4:
Phenotypes / 2.3:
Restoration of phenotype / 2.4:
Reversion and suppression / 2.4.1:
Complementation / 2.4.2:
Recombination / 2.5:
Mechanisms of mutation / 2.6:
Spontaneous mutation / 2.6.1:
Chemical mutagens / 2.6.2:
Ultraviolet irradiation / 2.6.3:
Isolation and identification of mutants / 2.7:
Mutation and selection / 2.7.1:
Replica plating / 2.7.2:
Penicillin enrichment / 2.7.3:
Isolation of other mutants / 2.7.4:
Molecular methods / 2.7.5:
Regulation of Gene Expression
Gene copy number / 3.1:
Transcriptional control / 3.2:
Promoters / 3.2.1:
Terminators, attenuators and anti-terminators / 3.2.2:
Induction and repression: regulatory proteins / 3.2.3:
Attenuation: trp operon / 3.2.4:
Two-component regulatory systems / 3.2.5:
Global regulatory systems / 3.2.6:
Feast or famine and the RpoS regulon / 3.2.7:
Quorum sensing / 3.2.8:
Translational control / 3.3:
Ribosome binding / 3.3.1:
Codon usage / 3.3.2:
Stringent response / 3.3.3:
Regulatory RNA / 3.3.4:
Phase variation / 3.3.5:
Single-stranded DNA bacteriophages / 4.1:
oX174 / 4.1.1:
M13 / 4.1.2:
RNA-containing phages: MS2 / 4.2:
Double-stranded DNA phages / 4.3:
Bacteriophage T4 / 4.3.1:
Bacteriophage lambda / 4.3.2:
Lytic and lysogenic regulation of bacteriophage lambda / 4.3.3:
Restriction and modification / 4.4:
Complementation and recombination / 4.5:
Why are bacteriophages important? / 4.6:
Phage typing / 4.6.1:
Phage therapy / 4.6.2:
Phage display / 4.6.3:
Bacterial virulence and phage conversion / 4.6.4:
Some bacterial characteristics are determined by plasmids / 5.1:
Antibiotic resistance / 5.1.1:
Colicins and bacteriocins / 5.1.2:
Virulence determinants / 5.1.3:
Plasmids in plant-associated bacteria / 5.1.4:
Metabolic activities / 5.1.5:
Molecular properties of plasmids / 5.2:
Plasmid replication and control / 5.2.1:
Plasmid stability / 5.3:
Plasmid integrity / 5.3.1:
Partitioning / 5.3.2:
Differential growth rate / 5.3.3:
Methods for studying plasmids / 5.4:
Associating a plasmid with a phenotype / 5.4.1:
Classification of plasmids / 5.4.2:
Transformation / 6.1:
Conjugation / 6.2:
Mechanism of conjugation / 6.2.1:
The F plasmid / 6.2.2:
Conjugation in other bacteria / 6.2.3:
Transduction / 6.3:
Specialized transduction / 6.3.1:
General (homologous) recombination / 6.4:
Site-specific and non-homologous (illegitimate) recombination / 6.4.2:
Mosaic genes and chromosome plasticity / 6.5:
Insertion sequences / 7.1:
Structure of insertion sequences / 7.1.1:
Occurrence of insertion sequences / 7.1.2:
Transposons / 7.2:
Structure of transposons / 7.2.1:
Integrons / 7.2.2:
Mechanisms of transposition / 7.3:
Replicative transposition / 7.3.1:
Non-replicative (conservative) transposition / 7.3.2:
Regulation of transposition / 7.3.3:
Activation of genes by transposable elements / 7.3.4:
Mu: a transposable bacteriophage / 7.3.5:
Conjugative transposons and other transposable elements / 7.3.6:
Variation mediated by simple DNA inversion / 7.4:
Variation mediated by nested DNA inversion / 7.4.2:
Antigenic variation in the gonococcus / 7.4.3:
Phase variation by slipped strand mispairing / 7.4.4:
Phase variation mediated by differential DNA methylation / 7.4.5:
Strain development / 8.1:
Generation of variation / 8.1.1:
Selection of desired variants / 8.1.2:
Overproduction of primary metabolites / 8.2:
Simple pathways / 8.2.1:
Branched pathways / 8.2.2:
Overproduction of secondary metabolites / 8.3:
Gene cloning / 8.4:
Cutting and joining DNA / 8.4.1:
Plasmid vectors / 8.4.2:
Bacteriophage lambda vectors / 8.4.3:
Cloning larger fragments / 8.4.5:
Bacteriophage M13 vectors / 8.4.6:
Gene libraries / 8.5:
Construction of genomic libraries / 8.5.1:
Screening a gene library / 8.5.2:
Construction of a cDNA library / 8.5.3:
Products from cloned genes / 8.6:
Expression vectors / 8.6.1:
Making new genes / 8.6.2:
Other bacterial hosts / 8.6.3:
Novel vaccines / 8.6.4:
Other uses of gene technology / 8.7:
Metabolic pathways / 9.1:
Cross-feeding / 9.1.1:
Microbial physiology / 9.2:
Reporter genes / 9.2.1:
Lysogeny / 9.2.2:
Cell division / 9.2.3:
Motility and chemotaxis / 9.2.4:
Cell differentiation / 9.2.5:
Bacterial virulence / 9.3:
Wide range mechanisms of bacterial pathogenesis / 9.3.1:
Detection of virulence genes / 9.3.2:
Specific mutagenesis / 9.4:
Gene replacement / 9.4.1:
Antisense RNA / 9.4.2:
Taxonomy, evolution and epidemiology / 9.5:
Molecular taxonomy / 9.5.1:
Diagnostic use of PCR / 9.5.2:
Molecular epidemiology / 9.5.3:
Gene mapping / 10.1:
Conjugational analysis / 10.1.1:
Co-transformation and co-transduction / 10.1.2:
Molecular techniques for gene mapping / 10.1.3:
Gene sequencing / 10.2:
DNA sequence determination / 10.2.1:
Genome sequencing / 10.2.2:
Comparative genomics / 10.2.3:
Bioinformatics / 10.2.4:
Physical and genetic maps / 10.3:
Deletions and insertions / 10.3.1:
Transposon mutagenesis / 10.3.2:
Site-directed mutagenesis / 10.3.3:
Analysis of gene expression / 10.4:
Transcriptional analysis / 10.4.1:
Translational analysis / 10.4.2:
Systematic analysis of gene function / 10.4.3:
Conclusion / 10.5:
Nucleic Acid Structure and Function / 1:
Structure of nucleic acids / 1.1:
DNA / 1.1.1:
3.

図書
図書
3. Nonlinear fiber optics
Govind P. Agrawal
出版情報: Boston ; Tokyo : Academic Press, c1989  xii, 342 p. ; 24 cm
シリーズ名: Quantum electronics : principles and applications
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Preface
Introduction / 1:
Historical Perspective / 1.1:
Fiber Characteristics / 1.2:
Material and Fabrication / 1.2.1:
Fiber Losses / 1.2.2:
Chromatic Dispersion / 1.2.3:
Polarization-Mode Dispersion / 1.2.4:
Fiber Nonlinearities / 1.3:
Nonlinear Refraction / 1.3.1:
Stimulated Inelastic Scattering / 1.3.2:
Importance of Nonlinear Effects / 1.3.3:
Overview / 1.4:
Problems
References
Pulse Propagation in Fibers / 2:
Maxwell's Equations / 2.1:
Fiber Modes / 2.2:
Eigenvalue Equation / 2.2.1:
Single-Mode Condition / 2.2.2:
Characteristics of the Fundamental Mode / 2.2.3:
Pulse-Propagation Equation / 2.3:
Nonlinear Pulse Propagation / 2.3.1:
Higher-Order Nonlinear Effects / 2.3.2:
Numerical Methods / 2.4:
Split-Step Fourier Method / 2.4.1:
Finite-Difference Methods / 2.4.2:
Group-Velocity Dispersion / 3:
Different Propagation Regimes / 3.1:
Dispersion-Induced Pulse Broadening / 3.2:
Gaussian Pulses / 3.2.1:
Chirped Gaussian Pulses / 3.2.2:
Hyperbolic-Secant Pulses / 3.2.3:
Super-Gaussian Pulses / 3.2.4:
Experimental Results / 3.2.5:
Third-Order Dispersion / 3.3:
Changes in Pulse Shape / 3.3.1:
Broadening Factor / 3.3.2:
Arbitrary-Shape Pulses / 3.3.3:
Ultrashort-Pulse Measurements / 3.3.4:
Dispersion Management / 3.4:
GVD-Induced Limitations / 3.4.1:
Dispersion Compensation / 3.4.2:
Compensation of Third-Order Dispersion / 3.4.3:
Self-Phase Modulation / 4:
SPM-Induced Spectral Broadening / 4.1:
Nonlinear Phase Shift / 4.1.1:
Changes in Pulse Spectra / 4.1.2:
Effect of Pulse Shape and Initial Chirp / 4.1.3:
Effect of Partial Coherence / 4.1.4:
Effect of Group-Velocity Dispersion / 4.2:
Pulse Evolution / 4.2.1:
Optical Wave Breaking / 4.2.2:
Effect of Third-Order Dispersion / 4.2.4:
Self-Steepening / 4.3:
Effect of GVD on Optical Shocks / 4.3.2:
Intrapulse Raman Scattering / 4.3.3:
Optical Solitons / 5:
Modulation Instability / 5.1:
Linear Stability Analysis / 5.1.1:
Gain Spectrum / 5.1.2:
Experimental Observation / 5.1.3:
Ultrashort Pulse Generation / 5.1.4:
Impact on Lightwave Systems / 5.1.5:
Fiber Solitons / 5.2:
Inverse Scattering Method / 5.2.1:
Fundamental Soliton / 5.2.2:
Higher-Order Solitons / 5.2.3:
Experimental Confirmation / 5.2.4:
Soliton Stability / 5.2.5:
Other Types of Solitons / 5.3:
Dark Solitons / 5.3.1:
Dispersion-Managed Solitons / 5.3.2:
Bistable Solitons / 5.3.3:
Perturbation of Solitons / 5.4:
Perturbation Methods / 5.4.1:
Soliton Amplification / 5.4.2:
Soliton Interaction / 5.4.4:
Higher-Order Effects / 5.5:
Propagation of Femtosecond Pulses / 5.5.1:
Polarization Effects / 6:
Nonlinear Birefringence / 6.1:
Origin of Nonlinear Birefringence / 6.1.1:
Coupled-Mode Equations / 6.1.2:
Elliptically Birefringent Fibers / 6.1.3:
Nondispersive XPM / 6.2:
Optical Kerr Effect / 6.2.2:
Pulse Shaping / 6.2.3:
Evolution of Polarization State / 6.3:
Analytic Solution / 6.3.1:
Poincare-Sphere Representation / 6.3.2:
Polarization Instability / 6.3.3:
Polarization Chaos / 6.3.4:
Vector Modulation Instability / 6.4:
Low-Birefringence Fibers / 6.4.1:
High-Birefringence Fibers / 6.4.2:
Isotropic Fibers / 6.4.3:
Birefringence and Solitons / 6.4.4:
Soliton-Dragging Logic Gates / 6.5.1:
Vector Solitons / 6.5.4:
Random Birefringence / 6.6:
Polarization State of Solitons / 6.6.1:
Cross-Phase Modulation / 7:
XPM-Induced Nonlinear Coupling / 7.1:
Nonlinear Refractive Index / 7.1.1:
Coupled NLS Equations / 7.1.2:
Propagation in Birefringent Fibers / 7.1.3:
XPM-Induced Modulation Instability / 7.2:
XPM-Paired Solitons / 7.2.1:
Bright-Dark Soliton Pair / 7.3.1:
Bright-Gray Soliton Pair / 7.3.2:
Other Soliton Pairs / 7.3.3:
Spectral and Temporal Effects / 7.4:
Asymmetric Spectral Broadening / 7.4.1:
Asymmetric Temporal Changes / 7.4.2:
Applications of XPM / 7.4.3:
XPM-Induced Pulse Compression / 7.5.1:
XPM-Induced Optical Switching / 7.5.2:
XPM-Induced Nonreciprocity / 7.5.3:
Stimulated Raman Scattering / 8:
Basic Concepts / 8.1:
Raman-Gain Spectrum / 8.1.1:
Raman Threshold / 8.1.2:
Coupled Amplitude Equations / 8.1.3:
Quasi-Continuous SRS / 8.2:
Single-Pass Raman Generation / 8.2.1:
Raman Fiber Lasers / 8.2.2:
Raman Fiber Amplifiers / 8.2.3:
Raman-Induced Crosstalk / 8.2.4:
SRS with Short Pump Pulses / 8.3:
Pulse-Propagation Equations / 8.3.1:
Nondispersive Case / 8.3.2:
Effects of GVD / 8.3.3:
Synchronously Pumped Raman Lasers / 8.3.4:
Soliton Effects / 8.4:
Raman Solitons / 8.4.1:
Raman Soliton Lasers / 8.4.2:
Soliton-Effect Pulse Compression / 8.4.3:
Effect of Four-Wave Mixing / 8.5:
Stimulated Brillouin Scattering / 9:
Physical Process / 9.1:
Brillouin-Gain Spectrum / 9.1.2:
Quasi-CW SBS / 9.2:
Coupled Intensity Equations / 9.2.1:
Brillouin Threshold / 9.2.2:
Gain Saturation / 9.2.3:
Dynamic Aspects / 9.2.4:
Relaxation Oscillations / 9.3.1:
Modulation Instability and Chaos / 9.3.3:
Transient Regime / 9.3.4:
Brillouin Fiber Lasers / 9.4:
CW Operation / 9.4.1:
Pulsed Operation / 9.4.2:
SBS Applications / 9.5:
Brillouin Fiber Amplifiers / 9.5.1:
Fiber Sensors / 9.5.2:
Parametric Processes / 10:
Origin of Four-Wave Mixing / 10.1:
Theory of Four-Wave Mixing / 10.2:
Approximate Solution / 10.2.1:
Effect of Phase Matching / 10.2.3:
Ultrafast FWM / 10.2.4:
Phase-Matching Techniques / 10.3:
Physical Mechanisms / 10.3.1:
Phase Matching in Multimode Fibers / 10.3.2:
Phase Matching in Single-Mode Fibers / 10.3.3:
Phase Matching in Birefringent Fibers / 10.3.4:
Parametric Amplification / 10.4:
Gain and Bandwidth / 10.4.1:
Pump Depletion / 10.4.2:
Parametric Amplifiers / 10.4.3:
Parametric Oscillators / 10.4.4:
FWM Applications / 10.5:
Wavelength Conversion / 10.5.1:
Phase Conjugation / 10.5.2:
Squeezing / 10.5.3:
Supercontinuum Generation / 10.5.4:
Second-Harmonic Generation / 10.6:
Physical Mechanism / 10.6.1:
Simple Theory / 10.6.3:
Quasi-Phase-Matching Technique / 10.6.4:
Decibel Units / Appendix A:
Acronyms / Appendix B:
Index
Preface
Introduction / 1:
Historical Perspective / 1.1:
4.

図書
図書
4. Introduction to electronic warfare
D. Curtis Schleher
出版情報: Dedham, Mass. : Artech House, c1986  xii, 559 p. ; 24 cm
シリーズ名: The Artech House radar library
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Electronic Warfare (EW) Principles and Overview / Chapter 1:
Electronic Warfare Taxonomy / 1.1:
Electronic Warfare Definitions and Areas / 1.1.1:
Electronic Warfare Support Measures (ESM) / 1.1.1.1:
Signals Intelligence (SIGINT) / 1.1.1.2:
Electronic Countermeasures (ECM) / 1.1.1.3:
Electronic Counter Countermeasures (ECCM) / 1.1.1.4:
Electronic Warfare Simulators / 1.1.1.5:
Defense Suppression / 1.1.1.6:
Signal Security (SIGSEC) / 1.1.1.7:
Electronic Warfare Frequency Bands and Channels / 1.1.1.8:
EW Missions and Scenarios / 1.2:
The EW Radar Threat Scenario / 1.2.1:
The EW Communications Threat Scenario / 1.2.2:
Electronic Support Measures (ESM) Receivers / Chapter 2:
Radar Warning Receivers (RWR) / 2.1:
Current ESM Receivers / 2.2:
The Crystal Video Receiver / 2.2.1:
The Superheterodyne Receiver / 2.2.2:
Instantaneous Frequency Measurement (IFM) Receiver / 2.2.3:
Advanced ESM Receivers / 2.3:
The Channelized Receiver / 2.3.1:
The Compressive Receiver / 2.3.2:
The Acousto-Optic Bragg Cell Receiver / 2.3.3:
Passive Direction Finding and Emitter Location / 2.4:
Noise Jamming / Chapter 3:
Noise Jammer Effectiveness / 3.1.1:
Jammer Look-Through / 3.1.2:
Power Management / 3.1.3:
Deception Electronic Countermeasures (DECM) / 3.2:
Range Gate Deception / 3.2.1:
Angle Deception / 3.2.2:
ECM against Conical Scanning Tracking Radars / 3.2.2.1:
ECM against Monopulse Tracking Radars / 3.2.2.2:
Velocity Deception / 3.2.3:
Modern ECM Systems / 3.3:
ECM against Pulse Compression and Low Probability of Intercept (LPI) Radars / 3.3.1:
Expendable Electronic Countermeasures / 3.4:
Chaff / 3.4.1:
Radar and Electronic Counter-Countermeasures (ECCM) / Chapter 4:
Radar Applications in Weapon Systems / 4.1:
Surveillance Radars / 4.2:
Surveillance Radar Design Principles / 4.2.1:
Surveillance Radar Detection Range--Clear and Jamming Environments / 4.2.1.1:
Low Altitude Detection--Radar Clutter / 4.2.1.2:
Surveillance Radar--Data Rate and Accuracy / 4.2.1.3:
Surveillance Radar Frequency Trade-Offs / 4.2.1.4:
Surveillance Radars--ECCM Considerations / 4.2.1.5:
Target Acquisition Radars / 4.3:
Weapon Control Radars / 4.4:
Tracking Radar Design Principles / 4.4.1:
Target Tracking Radar / 4.4.2:
Track-While-Scan Tracking Systems / 4.4.3:
Phased Array Tracking Radars / 4.4.4:
Tracking Radar--ECCM Considerations / 4.4.5:
Aircraft Control Radars / 4.5:
Weapon Location Radars / 4.6:
Missile Guidance Radars / 4.7:
Navigation and Mapping Radars / 4.8:
Radar Types and Characteristics / 4.9:
2-D Search Radars / 4.9.1:
3-D Search Radars / 4.9.2:
Moving Target Indicator (MTI) Radar / 4.9.3:
Pulsed Doppler Radar / 4.9.4:
Special Purpose Radar Types / 4.9.5:
Millimeter-Wave (MMW) Radar / 4.9.5.1:
Low Probability of Intercept (LPI) Radar / 4.9.5.2:
Over-the-Horizon (OTH) Radar / 4.9.5.3:
Bistatic Radar / 4.9.5.4:
Automatic Detection Radar / 4.9.5.5:
Command, Control, and Communications (C[superscript 3]) Systems / Chapter 5:
Strategic C[superscript 3] Systems / 5.1:
Tactical C[superscript 3] Systems / 5.2:
Naval Tactical Data System (NTDS) / 5.2.1:
Tactical Air Control System (TACS) / 5.2.2:
Rapid Deployment Force C[superscript 3]I / 5.2.3:
Tactical Data Links / 5.2.4:
Tactical Communication Radio Nets / 5.2.5:
C[superscript 3] Navigation Systems / 5.2.6:
Command, Control, and Communications Countermeasures (C[superscript 3]CM) / 5.3:
Air Defense Systems / 5.4:
Early Warning Radars / 5.4.1:
Airborne Early Warning Radars / 5.4.2:
Ground Control Intercept Radars / 5.4.3:
Air-to-Air Missile Guidance Systems / 5.4.4:
Surface-to-Air Missile (SAM) Systems / 5.4.5:
Missile Control Laws / 5.4.5.1:
Modern SAM System / 5.4.5.2:
Radar and ECM Performance Analysis / Chapter 6:
Radar Detection Performance / 6.1:
Search Radar Detection Performance / 6.1.1:
Propagation Absorption Loss (L[subscript a]) / 6.1.1.1:
Beam Shape Loss (L[subscript b]) / 6.1.1.2:
Pattern Propagation Factor (F[subscript t],F[subscript r]) / 6.1.1.3:
System Noise Temperature (T[subscript s]) / 6.1.1.4:
Transmission Line Loss (L[subscript t]) / 6.1.1.5:
Receiver Matching Loss (C[subscript B]) / 6.1.1.6:
Collapsing Loss (L[subscript c]) / 6.1.1.7:
MTI Processing Loss / 6.1.1.8:
Signal-to-Noise Power Ratio / 6.1.1.9:
Search Radar Detection Range Calculation / 6.1.1.10:
The Cumulative Probability of Detection / 6.1.2:
ECM Jamming Equations / 6.2:
Repeater Jammer Equations / 6.2.1:
EW Receiver Sensitivity / 6.3:
Scanning Superheterodyne Receiver Sensitivity / 6.3.1:
EW Signal Processing / Chapter 7:
Input Signal Processing / 7.1:
Signal Environment / 7.1.1:
Processing of Multiple-Pulse Emitters / 7.1.1.1:
EM Sensor Subsystems / 7.1.2:
Large Aperture Antennas for ESM / 7.1.2.1:
Low Radar Cross Section (RCS) Antenna Systems / 7.1.2.2:
Sparse Arrays / 7.1.2.3:
The Receiver Subsystem / 7.1.3:
Transform Receivers / 7.1.3.1:
Conventional Channelizers / 7.1.3.2:
Digital Transforms / 7.1.3.3:
Parameter Encoding / 7.1.3.4:
Intrapulse Parameters
The Preprocessor / 7.1.4:
Mapping, Binning, or Histogramming / 7.1.4.1:
Associative Memories / 7.1.4.2:
Window Addressable Memories
Content Addressable Memories
Random Accessible Memories (RAMs)
The Data Servo Loop / 7.1.4.3:
Single-Instruction Multiple Data Arrays / 7.1.4.4:
Agile Parameter Tracking / 7.1.4.5:
High Duty Factor Emitters
Agile Pulse Repetition Interval (PRI) Emitters
Agile RF Emitters
Wideband Intrapulse RF Emitters
Output Signal Processing / 7.2:
The Computer / 7.2.1:
Jamming Logic / 7.2.2:
Advanced Fully Power-Managed Jamming / 7.2.2.1:
Time-Managed Jamming
RF Management
Coherent RF
Digital Exciters
Coherent Repetition
Amplitude Management
Direction Management
Generating Control Signals / 7.2.2.2:
Programmable Techniques Generator / 7.2.2.3:
Time-Ordered File / 7.2.2.4:
EW Technology and Future Trends / Chapter 8:
Antenna Technology / 8.1:
Fixed-Beam EW Antennas / 8.1.1:
Spiral Antennas / 8.1.1.1:
Horn Antennas / 8.1.1.2:
Helical Antennas / 8.1.1.3:
Log-Periodic Dipole Array Antennas / 8.1.1.4:
ECM Phased Array Antennas / 8.1.2:
Lens-Fed Multiple Beam Array / 8.1.3:
ECM Transmitter Power Source Technology / 8.2:
ECM Traveling Wave Tubes (TWTs) / 8.2.1:
Gallium Arsenide (GaAs) FET Amplifiers / 8.2.2:
Voltage Controlled Oscillators / 8.2.3:
Digital Radio Frequency Memories / 8.2.4:
EW Receiver Technology / 8.3:
Low-Noise Receivers / 8.3.1:
Surface Acoustic Wave (SAW) Delay Lines / 8.3.2:
EW at Millimeter Wavelengths / 8.4:
Low Observability EW Technology / 8.5:
Very High Speed Integrated Circuits (VHSIC) / 8.6:
Artificial Intelligence / 8.7:
Index
Electronic Warfare (EW) Principles and Overview / Chapter 1:
Electronic Warfare Taxonomy / 1.1:
Electronic Warfare Definitions and Areas / 1.1.1:
5.

図書
図書
5. Statistical theory of extended radar targets : a translation from the Russian of Statisticheskaya teoriya radiolokatsii protyazhennyz [sic] tselei ((cover))
by R.V. Ostrovityanov & F.A. Basalov ; translated by William F. Barton and David K. Barton
出版情報: Dedham, MA : Artech House, 1985  xviii, 364 p. ; 24 cm
所蔵情報: loading…
目次情報: 続きを見る
Introduction / 1.0:
Purpose
Objective / 1.2:
Orientation / 1.3:
Scope / 1.4:
Sources and Coupling of Em Energy / 2.0:
The Environment / 2.1:
Environment Sources / 2.2:
General Signal Characteristics / 2.2.1:
Pulse Signal / 2.2.2:
Signal Transmission / 2.2.3:
Radiated Energy / 2.3:
The Radiation Field / 2.3.1:
Distinction Between Induction and Radiation Fields / 2.3.2:
Nonlinear Environmental Effects / 2.3.3:
Propagation Effects / 2.3.4:
The GSE Radiated Environments / 2.3.5:
Conducted Energy / 2.4:
Conducted Routes / 2.4.1:
The GSE Conducted Environment / 2.4.2:
Combined Effects / 2.5:
Design Considerations / 3.0:
General Guidelines / 3.1:
Electrical Design / 3.1.1:
Physical Layout of Components / 3.1.2:
Mechanical Factors / 3.1.3:
Safety / 3.2:
The Effects of High RF Fields / 3.2.1:
Safety Procedures and Design Criteria / 3.2.2:
Factors Influencing Gse Emc / 3.3:
EMC Maintenance Considerations / 3.3.1:
Cost Benefit Considerations / 3.3.2:
Microprocessors and Digital Systems / 3.3.3:
Examples of Avionic and Gse Designs / 3.4:
Flight or Hangar Deck Operation / 3.4.1:
Shop Testing / 3.4.2:
Control and Test Planning / 4.0:
General / 4.1:
The Emc Control Plan / 4.2:
The Role of the Control Plan / 4.2.1:
The Contents of the Control Plan / 4.2.2:
Control Plan Checklist / 4.2.3:
The Emc Test Plan / 4.3:
Shielding / 5.0:
General Shield Design Considerations / 5.1:
Solid Shielding Materials / 5.2:
Shielding Analysis / 5.2.1:
Additional Comments on Magnetic Shielding / 5.2.2:
Multiple Solid Shields / 5.2.3:
Coating and Thin-Film Shielding / 5.2.4:
Non-Solid Shielding Materials / 5.3:
Types of Discontinuities / 5.3.1:
Composite Materials / 5.3.2:
Cables and Connectors / 5.4:
Cable Shielding / 5.4.1:
Cable Shield Terminations and Connectors / 5.4.2:
New Connector Technology / 5.4.3:
Fiber Optics / 5.4.4:
Other Design Techniques to Maintain Shielding Effectiveness / 5.5:
Seams Without Gaskets / 5.5.1:
Seams With Gaskets / 5.5.2:
Use of Waveguide Attenuators / 5.5.3:
Panel Openings / 5.5.4:
Required Visual Openings / 5.5.5:
Shielding Tests / 5.6:
Low Impedance Magnetic Field Testing Using Small Loops / 5.6.1:
Low Impedance Magnetic Field Testing Using a Helmholtz Coil / 5.6.3:
High Impedance Electric Field Testing Using Rod Antennas / 5.6.4:
High Impedance Electric Field Testing Using a Parallel Line Radiator / 5.6.5:
Plane Wave Testing Using Antennas / 5.6.6:
Plane Wave Testing Using a Parallel Plate Transmission Line / 5.6.7:
MIL-STD-1377 Testing / 5.6.8:
Summary of Good Shielding Practices / 5.7:
Bonding / 6.0:
Surface Treatment / 6.1:
Corrosion / 6.3:
Bonding Effectiveness Characteristics / 6.4:
Bond Jumper Equivalent Circuit / 6.4.1:
Equipment Effects on Indirect Bonds / 6.4.2:
Bonding Resistance / 6.4.3:
Bonding Tests / 6.5:
DC Resistance Measurement / 6.5.1:
Swept Frequency/Shunt-T Insertion Loss Measurement / 6.5.3:
Single Vs. Multi-Point Bonding / 6.6:
Bonding Design Guidelines / 6.7:
Grounding / 7.0:
Grounding Techniques / 7.1:
Circuit Grounding Considerations / 7.3:
Power Supply Considerations / 7.4:
Prime Power Considerations / 7.5:
Cabling Considerations / 7.6:
Grounding Design Guidelines / 7.7:
Fil Tering / 8.0:
Filter Desing / 8.1:
Low-Pass Filters / 8.2.1:
High Pass Filters / 8.2.2:
Bandpass Filters / 8.2.3:
Band-Rejection Filters / 8.2.4:
Transient Suppression / 8.3:
Inductive Loads / 8.3.1:
Mechanical Switches / 8.3.2:
Transformer Switching / 8.3.3:
Semiconductor Transients / 8.3.4:
Active Power Line Filters / 8.4:
Noise Blanking, Cancelling, And Limiting circuits / 8.5:
Noise Blanking / 8.5.1:
Cancellation / 8.5.2:
Limiting / 8.5.3:
Filter Tests / 8.6:
MIL-STD-220A Insertion Loss Test / 8.6.1:
Filter Admittance Transfer Test / 8.6.3:
Parallel Signal Injection Test / 8.6.4:
Series Signal Injection Test / 8.6.5:
Current Injection Probes / 8.6.6:
Leakage Current Test / 8.6.7:
Filter Installation And Mounting / 8.7:
Specifying Fil Ters / 8.8:
Testing Requirements and Techniques / 9.0:
Shielded Enclosure Requirements / 9.1:
Enclosure Limitations / 9.2.1:
Enclosure Design Considerations / 9.2.2:
Microwave Absorbers / 9.2.3:
Testing Guidelines / 9.3:
Signal Sources / 9.3.1:
Sweep Generators and Oscillators / 9.3.3:
Attenuators / 9.3.4:
Detectors / 9.3.5:
Radiated And Conducted Equipment Testing / 9.4:
Emission Tests / 9.4.1:
Susceptibility Tests / 9.4.3:
Transient Testing / 9.4.4:
Specifications and Standards / 10.0:
Applicable Specifications / 10.1:
Obtaining Specifications / 10.3:
Tables And Nomographs / 11.0:
Order Of Contents / 11.1:
Introduction / 1.0:
Purpose
Objective / 1.2:
6.

図書
図書
6. Analysis and performance of fiber composites
Bhagwan D. Agarwal, Lawrence J. Broutman
出版情報: New York : J. Wiley, c1980  ix, 355 p. ; 24 cm
シリーズ名: SPE monographs
所蔵情報: loading…
目次情報: 続きを見る
Preface
Introduction. / 1:
Definition / 1.1:
Characteristics / 1.2:
Classification / 1.3:
Particulate Composites / 1.4:
Fiber-Reinforced Composites / 1.5:
Applications of Fiber Composites / 1.6:
Exercise Problems
References
Fibers, Matrices, and Fabrication of Composites. / 2:
Advanced Fibers / 2.1:
Glass Fibers / 2.1.1:
Carbon and Graphite Fibers / 2.1.2:
Aramid Fibers / 2.1.3:
Boron Fibers / 2.1.4:
Other Fibers / 2.1.5:
Matrix Materials / 2.2:
Polymers / 2.2.1:
Metals / 2.2.2:
Fabrication of Composites / 2.3:
Fabrication of Thermosetting Resin Matrix Composites / 2.3.1:
Fabrication of Thermoplastic-Resin Matrix Composites (Short-Fiber Composites / 2.3.2:
Fabrication of Metal Matrix Composites / 2.3.3:
Fabrication of Ceramic Matrix Composites / 2.3.4:
Suggested Reading
Behavior of Unidirectional Composites. / 3:
Introduction / 3.1:
Nomenclature / 3.1.1:
Volume and Weight Fractions / 3.1.2:
Longitudinal Behavior of Unidirectional Composites / 3.2:
Initial Stiffness / 3.2.1:
Load Sharing / 3.2.2:
Behavior beyond Initial Deformation / 3.2.3:
Failure Mechanism and Strength / 3.2.4:
Factors Influencing Longitudinal Strength and Stiffness / 3.2.5:
Transverse Stiffness and Strength / 3.3:
Constant-Stress Model / 3.3.1:
Elasticity Methods of Stiffness Prediction / 3.3.2:
Halpin-Tsai Equations for Transverse Modulus / 3.3.3:
Transverse Strength / 3.3.4:
Prediction of Shear Modulus / 3.4:
Prediction of Poisson's Ratio / 3.5:
Failure Modes / 3.6:
Failure under Longitudinal Tensile Loads / 3.6.1:
Failure under Longitudinal Compressive Loads / 3.6.2:
Failure under Transverse Tensile Loads / 3.6.3:
Failure under Transverse Compressive Loads / 3.6.4:
Failure under In-Plane Shear Loads / 3.6.5:
Expansion Coefficients and Transport Properties / 3.7:
Thermal Expansion Coefficients / 3.7.1:
Moisture Expansion Coefficients / 3.7.2:
Transport Properties / 3.7.3:
Mass Diffusion / 3.7.4:
Typical Unidirectional Fiber Composite Properties / 3.8:
Short-Fiber Composites. / 4:
Theories of Stress Transfer / 4.1:
Approximate Analysis of Stress Transfer / 4.2.1:
Stress Distributions from Finite-Element Analysis / 4.2.2:
Average Fiber Stress / 4.2.3:
Modulus and Strength of Short-Fiber Composites / 4.3:
Prediction of Modulus / 4.3.1:
Prediction of Strength / 4.3.2:
Effect of Matrix Ductility / 4.3.3:
Ribbon-Reinforced Composites / 4.4:
Analysis of an Orthotropic Lamina. / 5:
Orthotropic Materials / 5.1:
Stress-Strain Relations and Engineering Constants / 5.2:
Stress-Strain Relations for Specially Orthotropic Lamina / 5.2.1:
Stress-Strain Relations for Generally Orthotropic Lamina / 5.2.2:
Transformation of Engineering Constants / 5.2.3:
Hooke's Law and Stiffness and Compliance Matrices / 5.3:
General Anisotropic Material / 5.3.1:
Specially Orthotropic Material / 5.3.2:
Transversely Isotropic Material / 5.3.3:
Isotropic Material / 5.3.4:
Specially Orthotropic Material under Plane Stress / 5.3.5:
Compliance Tensor and Compliance Matrix / 5.3.6:
Relations between Engineering Constants and Elements of Stiffness and Compliance Matrices / 5.3.7:
Restrictions on Elastic Constants / 5.3.8:
Transformation of Stiffness and Compliance Matrices / 5.3.9:
Invariant Forms of Stiffness and Compliance Matrices / 5.3.10:
Strengths of an Orthotropic Lamina / 5.4:
Maximum-Stress Theory / 5.4.1:
Maximum-Strain Theory / 5.4.2:
Maximum-Work Theory / 5.4.3:
Importance of Sign of Shear Stress on Strength of Composites / 5.4.4:
Analysis of Laminated Composites. / 6:
Laminate Strains / 6.1:
Variation of Stresses in a Laminate / 6.3:
Resultant Forces and Moments: Synthesis of Stiffness Matrix / 6.4:
Laminate Description System / 6.5:
Construction and Properties of Special Laminates / 6.6:
Symmetric Laminates / 6.6.1:
Unidirectional, Cross-Ply, and Angle-Ply Laminates / 6.6.2:
Quasi-isotropic Laminates / 6.6.3:
Determination of Laminae Stresses and Strains / 6.7:
Analysis of Laminates after Initial Failure / 6.8:
Hygrothermal Stresses in Laminates / 6.9:
Concepts of Thermal Stresses / 6.9.1:
Hygrothermal Stress Calculations / 6.9.2:
Laminate Analysis Through Computers / 6.10:
Analysis of Laminated Plates and Beams. / 7:
Governing Equations for Plates / 7.1:
Equilibrium Equations / 7.2.1:
Equilibrium Equations in Terms of Displacements / 7.2.2:
Application of Plate Theory / 7.3:
Bending / 7.3.1:
Buckling / 7.3.2:
Free Vibrations / 7.3.3:
Deformations Due to Transverse Shear / 7.4:
First-Order Shear Deformation Theory / 7.4.1:
Higher-Order Shear Deformation Theory / 7.4.2:
Analysis of Laminated Beams / 7.5:
Governing Equations for Laminated Beams / 7.5.1:
Application of Beam Theory / 7.5.2:
Advanced Topics in Fiber Composites. / 8:
Interlaminar Stresses and Free-Edge Effects / 8.1:
Concepts of Interlaminar Stresses / 8.1.1:
Determination of Interlaminar Stresses / 8.1.2:
Effect of Stacking Sequence on Interlaminar Stresses / 8.1.3:
Approximate Solutions for Interlaminar Stresses / 8.1.4:
Summary / 8.1.5:
Fracture Mechanics of Fiber Composites / 8.2:
Fracture Mechanics Concepts and Measures of Fracture Toughness / 8.2.1:
Fracture Toughness of Composite Laminates / 8.2.3:
Whitney-Nuismer Failure Criteria for Notched Composites / 8.2.4:
Joints for Composite Structures / 8.3:
Adhesively Bonded Joints / 8.3.1:
Mechanically Fastened Joints / 8.3.2:
Bonded-Fastened Joints / 8.3.3:
Performance of Fiber Composites: Fatigue, Impact, and Environmental Effects. / 9:
Fatigue / 9.1:
Fatigue Damage / 9.1.1:
Factors Influencing Fatigue Behavior of Composites / 9.1.3:
Empirical Relations for Fatigue Damage and Fatigue Life / 9.1.4:
Fatigue of High-Modulus Fiber-Reinforced Composites / 9.1.5:
Fatigue of Short-Fiber Composites / 9.1.6:
Impact / 9.2:
Introduction and Fracture Process / 9.2.1:
Energy-Absorbing Mechanisms and Failure Models / 9.2.2:
Effect of Materials and Testing Variables on Impact Properties / 9.2.3:
Hybrid Composites and Their Impact Strength / 9.2.4:
Damage Due to Low-Velocity Impact / 9.2.5:
Environmental-Interaction Effects / 9.3:
Fiber Strength / 9.3.1:
Matrix Effects / 9.3.2:
Experimental Characterization of Composites. / 10:
Measurement of Physical Properties / 10.1:
Density / 10.2.1:
Constituent Weight and Volume Fractions / 10.2.2:
Void Volume Fraction / 10.2.3:
Moisture Absorption and Diffusivity / 10.2.4:
Measurement of Mechanical Properties / 10.2.6:
Properties in Tension / 10.3.1:
Properties in Compression / 10.3.2:
In-Place Shear Properties / 10.3.3:
Flexural Properties / 10.3.4:
Measures of In-Plane Fracture Toughness / 10.3.5:
Interlaminar Shear Strength and Fracture Toughness / 10.3.6:
Impact Properties / 10.3.7:
Damage Identification Using Nondestructive Evaluation Techniques / 10.4:
Ultrasonics / 10.4.1:
Acoustic Emission / 10.4.2:
x-Radiography / 10.4.3:
Thermography / 10.4.4:
Laser Shearography / 10.4.5:
General Remarks on Characterization / 10.5:
Emerging Composite Materials. / 11:
Nanocomposites / 11.1:
Carbon-Carbon Composites / 11.2:
Biocomposites / 11.3:
Biofibers / 11.3.1:
Wood-Plastic Composites (WPCs / 11.3.2:
Biopolymers / 11.3.3:
Composites in ''Smart'' Structures / 11.4:
Matrices and Tensors. / Appendix 1:
Equations of Theory of Elasticity. / Appendix 2:
Laminate Orientation Code. / Appendix 3:
Properties of Fiber Composites. / Appendix 4:
Computer Programs for Laminate Analysis. / Appendix 5:
Index.
Preface
Introduction. / 1:
Definition / 1.1:
7.

図書
図書
7. SO[2], NO, and NO[2] oxidation mechanisms : atmospheric considerations
edited by Jack G. Calvert
出版情報: Boston : Butterworth Publishers, c1984  xiv, 254 p. ; 25 cm
シリーズ名: Acid precipitation series ; v. 3
所蔵情報: loading…
8.

図書
図書
8. Bibliographic guide to technology (1975 - 1989)
G.K. Hall & Company
出版情報: Boston, Mass. : G.K. Hall & Co., 1983-1988  v. ; 29 cm
所蔵情報: loading…
9.

図書
図書
9. Numerical solution of partial differential equations in science and engineering
Leon Lapidus, George F. Pinder
出版情報: New York : Wiley, c1982  677 p. ; 24 cm
所蔵情報: loading…
目次情報: 続きを見る
Fundamental Concepts / Chapter 1.:
Notation / 1.0.:
First-Order Partial Differential Equations / 1.1.:
First-Order Quasilinear Partial Differential Equations / 1.1.1.:
Initial Value or Cauchy Problem / 1.1.2.:
Application of Characteristic Curves / 1.1.3.:
Nonlinear First-Order Partial Differential Equations / 1.1.4.:
Second-Order Partial Differential Equations / 1.2.:
Linear Second-Order Partial Differential Equations / 1.2.1.:
Classification and Canonical Form of Selected Partial Differential Equations / 1.2.2.:
Quasilinear Partial Differential Equations and Other Ideas / 1.2.3.:
Systems of First-Order PDEs / 1.3.:
First-Order and Second-Order PDEs / 1.3.1.:
Characteristic Curves / 1.3.2.:
Applications of Characteristic Curves / 1.3.3.:
Initial and Boundary Conditions / 1.4.:
References
Basic Concepts in the Finite Difference and Finite Element Methods / Chapter 2.:
Introduction / 2.0.:
Finite Difference Approximations / 2.1.:
Taylor Series Expansions / 2.1.1.:
Operator Notation for u(x) / 2.1.3.:
Finite Difference Approximations in Two Dimensions / 2.1.4.:
Additional Concepts / 2.1.5.:
Introduction to Finite Element Approximations / 2.2.:
Method of Weighted Residuals / 2.2.1.:
Application of the Method of Weighted Residuals / 2.2.2.:
The Choice of Basis Functions / 2.2.3.:
Two-Dimensional Basis Functions / 2.2.4.:
Approximating Equations / 2.2.5.:
Relationship between Finite Element and Finite Difference Methods / 2.3.:
Finite Elements on Irregular Subspaces / Chapter 3.:
Triangular Elements / 3.0.:
The Linear Triangular Element / 3.1.1.:
Area Coordinates / 3.1.2.:
The Quadratic Triangular Element / 3.1.3.:
The Cubic Triangular Element / 3.1.4.:
Higher-Order Triangular Elements / 3.1.5.:
Isoparametric Finite Elements / 3.2.:
Transformation Functions / 3.2.1.:
Numerical Integration / 3.2.2.:
Isoparametric Serendipity Hermitian Elements / 3.2.3.:
Isoparametric Hermitian Elements in Normal and Tangential Coordinates / 3.2.4.:
Boundary Conditions / 3.3.:
Three-Dimensional Elements / 3.4.:
Parabolic Partial Differential Equations / Chapter 4.:
Partial Differential Equations / 4.0.:
Well-Posed Partial Differential Equations / 4.1.1.:
Model Difference Approximations / 4.2.:
Well-Posed Difference Forms / 4.2.1.:
Derivation of Finite Difference Approximations / 4.3.:
The Classic Explicit Approximation / 4.3.1.:
The Dufort-Frankel Explicit Approximation / 4.3.2.:
The Richardson Explicit Approximation / 4.3.3.:
The Backwards Implicit Approximation / 4.3.4.:
The Crank-Nicolson Implicit Approximation / 4.3.5.:
The Variable-Weighted Implicit Approximation / 4.3.6.:
Consistency and Convergence / 4.4.:
Stability / 4.5.:
Heuristic Stability / 4.5.1.:
Von Neumann Stability / 4.5.2.:
Matrix Stability / 4.5.3.:
Some Extensions / 4.6.:
Influence of Lower-Order Terms / 4.6.1.:
Higher-Order Forms / 4.6.2.:
Predictor-Corrector Methods / 4.6.3.:
Asymmetric Approximations / 4.6.4.:
Variable Coefficients / 4.6.5.:
Nonlinear Parabolic PDEs / 4.6.6.:
The Box Method / 4.6.7.:
Solution of Finite Difference Approximations / 4.7.:
Solution of Implicit Approximations / 4.7.1.:
Explicit versus Implicit Approximations / 4.7.2.:
Composite Solutions / 4.8.:
Global Extrapolation / 4.8.1.:
Some Numerical Results / 4.8.2.:
Local Combination / 4.8.3.:
Composites of Different Approximations / 4.8.4.:
Finite Difference Approximations in Two Space Dimensions / 4.9.:
Explicit Methods / 4.9.1.:
Irregular Boundaries / 4.9.2.:
Implicit Methods / 4.9.3.:
Alternating Direction Explicit (ADE) Methods / 4.9.4.:
Alternating Direction Implicit (ADI) Methods / 4.9.5.:
LOD and Fractional Splitting Methods / 4.9.6.:
Hopscotch Methods / 4.9.7.:
Mesh Refinement / 4.9.8.:
Three-Dimensional Problems / 4.10.:
ADI Methods / 4.10.1.:
Iterative Solutions / 4.10.2.:
Finite Element Solution of Parabolic Partial Differential Equations / 4.11.:
Galerkin Approximation to the Model Parabolic Partial Differential Equation / 4.11.1.:
Approximation of the Time Derivative / 4.11.2.:
Approximation of the Time Derivative for Weakly Nonlinear Equations / 4.11.3.:
Finite Element Approximations in One Space Dimension / 4.12.:
Formulation of the Galerkin Approximating Equations / 4.12.1.:
Linear Basis Function Approximation / 4.12.2.:
Higher-Degree Polynomial Basis Function Approximation / 4.12.3.:
Formulation Using the Dirac Delta Function / 4.12.4.:
Orthogonal Collocation Formulation / 4.12.5.:
Asymmetric Weighting Functions / 4.12.6.:
Finite Element Approximations in Two Space Dimensions / 4.13.:
Galerkin Approximation in Space and Time / 4.13.1.:
Galerkin Approximation in Space Finite Difference in Time / 4.13.2.:
Asymmetric Weighting Functions in Two Space Dimensions / 4.13.3.:
Lumped and Consistent Time Matrices / 4.13.4.:
Collocation Finite Element Formulation / 4.13.5.:
Treatment of Sources and Sinks / 4.13.6.:
Alternating Direction Formulation / 4.13.7.:
Finite Element Approximations in Three Space Dimensions / 4.14.:
Example Problem / 4.14.1.:
Summary / 4.15.:
Elliptic Partial Differential Equations / Chapter 5.:
Model Elliptic PDEs / 5.0.:
Specific Elliptic PDEs / 5.1.1.:
Further Items / 5.1.2.:
Finite Difference Solutions in Two Space Dimensions / 5.2.:
Five-Point Approximations and Truncation Error / 5.2.1.:
Nine-Point Approximations and Truncation Error / 5.2.2.:
Approximations to the Biharmonic Equation / 5.2.3.:
Boundary Condition Approximations / 5.2.4.:
Matrix Form of Finite Difference Equations / 5.2.5.:
Direct Methods of Solution / 5.2.6.:
Iterative Concepts / 5.2.7.:
Formulation of Point Iterative Methods / 5.2.8.:
Convergence of Point Iterative Methods / 5.2.9.:
Line and Block Iteration Methods / 5.2.10.:
Acceleration and Semi-Iterative Overlays / 5.2.11.:
Finite Difference Solutions in Three Space Dimensions / 5.3.:
Iteration Concepts / 5.3.1.:
Finite Element Methods for Two Space Dimensions / 5.3.3.:
Galerkin Approximation / 5.4.1.:
Collocation Approximation / 5.4.2.:
Mixed Finite Element Approximation / 5.4.4.:
Approximation of the Biharmonic Equation / 5.4.5.:
Boundary Integral Equation Methods / 5.5.:
Fundamental Theory / 5.5.1.:
Boundary Element Formulation / 5.5.2.:
Linear Interpolation Functions / 5.5.3.:
Poisson's Equation / 5.5.5.:
Nonhomogeneous Materials / 5.5.6.:
Combination of Finite Element and Boundary Integral Equation Methods / 5.5.7.:
Three-Dimensional Finite Element Simulation / 5.6.:
Hyperbolic Partial Differential Equations / 5.7.:
Equations of Hyperbolic Type / 6.0.:
Finite Difference Solution of First-Order Scalar Hyperbolic Partial Differential Equations / 6.2.:
Stability, Truncation Error, and Other Features / 6.2.1.:
Other Approximations / 6.2.2.:
Dissipation and Dispersion / 6.2.3.:
Hopscotch Methods and Mesh Refinement / 6.2.4.:
Finite Difference Solution of First-Order Vector Hyperbolic Partial Differential Equations / 6.3.:
Finite Difference Solution of First-Order Vector Conservative Hyperbolic Partial Differential Equations / 6.4.:
Finite Difference Solutions to Two- and Three-Dimensional Hyperbolic Partial Differential Equations / 6.5.:
Finite Difference Schemes / 6.5.1.:
Two-Step, ADI, and Strang-Type Algorithms / 6.5.2.:
Conservative Hyperbolic Partial Differential Equations / 6.5.3.:
Finite Difference Solution of Second-Order Model Hyperbolic Partial Differential Equations / 6.6.:
One-Space-Dimension Hyperbolic Partial Differential Equation / 6.6.1.:
Explicit Algorithms / 6.6.2.:
Implicit Algorithms / 6.6.3.:
Simultaneous First-Order Partial Differential Equations / 6.6.4.:
Mixed Systems / 6.6.5.:
Two- and Three-Space-Dimensional Hyperbolic Partial Differential Equations / 6.6.6.:
Implicit ADI and LOD Methods / 6.6.7.:
Finite Element Solution of First-Order Model Hyperbolic Partial Differential Equations / 6.7.:
Asymmetric Weighting Function Approximation / 6.7.1.:
An H[superscript -1] Galerkin Approximation / 6.7.3.:
Orthogonal Collocation with Asymmetric Bases / 6.7.4.:
Finite Element Solution of Two- and Three-Space-Dimensional First-Order Hyperbolic Partial Differential Equations / 6.7.6.:
Galerkin Finite Element Formulation / 6.8.1.:
Finite Element Solution of First-Order Vector Hyperbolic Partial Differential Equations / 6.8.2.:
Finite Element Solution of Two- and Three-Space-Dimensional First-Order Vector Hyperbolic Partial Differential Equations / 6.9.1.:
Finite Element Solution of One-Space-Dimensional Second-Order Hyperbolic Partial Differential Equations / 6.10.1.:
Time Approximations / 6.11.1.:
Finite Element Solution of Two- and Three-Space-Dimensional Second-Order Hyperbolic Partial Differential Equations / 6.11.3.:
Index / 6.12.1.:
Fundamental Concepts / Chapter 1.:
Notation / 1.0.:
First-Order Partial Differential Equations / 1.1.:
10.

図書
図書
10. Reaction modes and products (pt. 1 ; pt. 2)
Frimer, Aryeh A., 1946-
出版情報: Boca Raton, Fla. : CRC Press, c1985  2 v. ; 26 cm
シリーズ名: Singlet O[2] / editor, Aryeh A. Frimer ; v. 2-v. 3
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