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200 10$aConverting to DFSMSrmm from CA-1$b[electronic resource] /$f[Mary Lovelace, Norbert Schlumberger, Sue Hamner]
205   $a2nd ed.
210   $a[S.l.] $cIBM, International Technical Support Organization$dc2003
215   $a1 online resource (828 p.) 
225 1 $aIBM redbooks
300   $a"December 2003."
311   $a0-7384-9865-3 
320   $aIncludes bibliographical references and index.
330   $aDFSMSrmm is the IBM tape management system for OS/390 and z/OS platforms. As part of DFSMS, DFSMSrmm is completely integrated into the IBM storage management strategy. This allows an easier installation and maintenance, as well as standard interfaces with other systems components, such as DFSMSdfp and DFSMShsm. DFSMSrmm provides a simple and flexible tape management environment, with support for all tape technologies, including IBM automated tape libraries, manual tapes, and other tape libraries. This IBM Redbooks publication is written for people who are planning to convert from CA-1 to DFSMSrmm. We have designed this book to help you with all aspects of the conversion, from the early planning stage through implementation and customization of DFSMSrmm into your production system. We provide details on the differences between DFSMSrmm and CA-1 and compare the terminology, data, and functions. We explain how to use the IBM-supplied sample conversion programs, validate the converted data, and prepare it for use in a production environment. Working samples that are ready for use both during and after conversion are included.
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606   $aMemory management (Computer science)
606   $aComputer storage devices
606   $aData tapes
615  0$aMemory management (Computer science)
615  0$aComputer storage devices.
615  0$aData tapes.
676   $a005.4/35
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200 10$aNonlinear Ultrasonic Guided Waves
205   $a1st ed.
210  1$aBristol [England] (Temple Circus, Temple Way, Bristol BS1 6HG, UK) :$cIOP Publishing,$d[2024]
215   $a1 online resource (335 pages)
225 1 $aIOP Ebooks Series
300   $a"Version: 20240601"--Title page verso.
311 08$a9780750349093 
311 08$a0750349093 
320   $aIncludes bibliographical references.
327   $aIntro -- Acknowledgments -- Author biography -- Cliff J Lissenden -- Chapter  Introduction -- 1.1 Motivation -- 1.2 Brief perspective on nonlinear ultrasonic guided waves -- 1.3 Approach -- 1.4 Content -- 1.5 Closure -- References -- Chapter  Preliminaries -- 2.1 Notation -- 2.2 Continuum mechanics -- 2.2.1 Kinematics -- Example 2.2. Normal strains -- Example 2.3. Shear strain -- 2.2.2 Balance laws -- 2.2.3 Stress -- 2.2.4 Constitutive relations -- Example 2.4. Stress components decomposed into linear and nonlinear parts -- Example 2.5. Strain energy function for transversely isotropic material -- 2.3 Elastodynamics -- 2.3.1 Wave equation -- 2.3.2 Wave equation for isotropic materials -- 2.3.3 Attenuation -- 2.4 Closure -- References -- Chapter  Nonlinear elastic waves -- 3.1 Bulk longitudinal waves -- Example 3.1. Longitudinal wave nonlinearity -- Example 3.2. Regular perturbation approach to the nonlinear longitudinal wave problem -- Example 3.3. Nonlinear longitudinal wave solution using the method of multiple scales -- Example 3.4. Determine ? in terms of Landau-Lifshitz TOECs for an isotropic material -- 3.2 Bulk shear waves -- Example 3.5. Shear wave third harmonic generation -- 3.3 Attenuation -- 3.4 Measurements of nonlinearity -- 3.4.1 Acoustoelasticity -- 3.4.2 Second harmonic generation -- 3.4.3 Wave mixing -- 3.4.4 Nonlinear resonant ultrasound spectroscopy (NRUS) -- 3.4.5 Vibro-acoustics -- 3.4.6 Dynamic acoustoelastic testing -- 3.5 Closure -- References -- Chapter  Boundary value problem formulation -- 4.1 Linear BVPs -- 4.1.1 Free surfaces -- 4.1.2 Plates -- 4.1.3 Hollow cylinders -- 4.1.4 Arbitrary cross-sections -- 4.2 Nonlinear BVPs -- 4.2.1 Regular perturbation method -- 4.2.2 Wave interactions -- Example 4.1. Third order interactions -- 4.3 Closure -- References -- Chapter  Ultrasonic guided waves-linear features.
327   $a5.1 Physical characteristics of waves -- 5.1.1 Phase velocity -- 5.1.2 Wavestructure -- 5.1.3 Group velocity -- Example 5.1. Group velocity calculation -- 5.1.4 Attenuation -- 5.2 Rayleigh waves -- 5.3 Waves in plates -- 5.3.1 Shear-horizontal (SH) waves -- 5.3.2 Lamb waves -- 5.3.3 Anisotropic plates -- 5.3.4 Finite-width plates -- 5.4 Hollow cylinder waves -- 5.5 Other types of guided waves -- 5.6 Closure -- References -- Chapter  Nonlinear analysis of plates -- 6.1 Reciprocity -- 6.2 Orthogonality -- Example 6.1. Auld's real reciprocity relation -- Example 6.2. Orthogonality of SH waves -- Example 6.3. Orthogonality of Lamb waves -- 6.3 Completeness -- 6.4 Normal mode expansion -- 6.5 Perturbation approach -- 6.6 Internal resonance -- Example 6.4. Second harmonic generation of Lamb waves -- 6.7 Wave mixing -- 6.8 Closure -- References -- Chapter  Internal resonance in plates -- 7.1 Power flow for self-interaction -- 7.1.1 Second order -- 7.1.2 Third order -- 7.2 Power flow for mutual interaction -- 7.2.1 Second order co-directional -- Example 7.1. Parity analysis of mutual interaction between SRL and ASH wavefields -- 7.2.2 Third order co-directional -- 7.3 Effect of directionality -- 7.4 Synchronism -- 7.4.1 Second order self-interaction -- 7.4.2 Third order self-interaction -- 7.5 Group velocity matching -- 7.5.1 Co-directional wave mixing -- 7.5.2 Counter-propagating wave mixing -- 7.5.3 Non-collinear wave mixing -- 7.6 Comments on hollow cylinders -- 7.7 Closure -- References -- Chapter  Selecting primary waves -- 8.1 Self-interaction in plates -- 8.1.1 Seond harmonic generation -- 8.1.2 Third harmonic generation -- 8.1.3 Method of multiple scales -- 8.2 Mutual interaction in plates -- 8.2.1 Co-directional, ?=0° -- 8.2.2 Counter-propagating, ?=180° -- 8.2.3 Non-collinear, ??0° and ??180° -- 8.3 Hollow cylinders -- 8.4 Arbitrary cross-section.
327   $a8.5 Half-space -- 8.6 Closure -- References -- Chapter  Finite amplitude pulse loading -- 9.1 Descriptors of nonlinearity -- 9.2 Experimental results from laser generation -- Example 9.1 Relationship between Rayleigh wave components -- 9.3 Modeling waveform evolution -- 9.4 Closure -- References -- Chapter  Numerical simulations -- 10.1 Methods -- 10.2 Software tools -- 10.3 Sample problems -- 10.3.1 Reported in the literature -- 10.3.2 Lamb wave analyses using commercial software -- 10.4 Closure -- References -- Chapter  Making measurements -- 11.1 Instrumentation -- 11.2 Generation -- 11.2.1 Transmitting transducers -- 11.2.2 Transmitting methods -- 11.3 Reception -- 11.3.1 Receiving transducers -- 11.3.2 Receiving methods -- 11.4 Signal processing -- 11.5 Closure -- References -- Chapter  Highlights of experimental testing -- 12.1 Self-interaction -- 12.2 Mutual interaction -- 12.3 Quasi-Rayleigh waves -- 12.4 Closure -- References -- Chapter  Perspective -- 13.1 Separation of material nonlinearity from measurement system nonlinearity -- 13.2 Link with the structural design that identifies hot spots to be monitored and a plan for inclusion of nonlinear ultrasonic guided waves in the operations management and maintenance planning -- 13.3 Standards for test methods that are broad enough to be applicable to the emerging needs for offline inspection and in-service monitoring -- 13.4 Define specifications needed to build monitoring systems into self-aware smart structures -- 13.5 Solid connection between nonlinear wave propagation characteristics and the material microstructure that dictates its strength and fracture properties -- References.
330   $aThe book sets the stage for nonlinear guided waves by introducing nonlinear wave propagation in 1D and expanding the mathematical treatment to guided waves. It considers self-interaction for harmonic generation and mutual interactions for wave mixing. It demonstrates the characteristics of nonlinear guided waves numerically and experimentally.
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606   $aWave-motion, Theory of
606   $aNonlinear waves
606   $aOptical wave guides
606   $aUltrasonic testing
606   $aElectrical engineering$2bicssc
606   $aTECHNOLOGY & ENGINEERING / Electrical$2bisacsh
615  0$aWave-motion, Theory of.
615  0$aNonlinear waves.
615  0$aOptical wave guides.
615  0$aUltrasonic testing.
615  7$aElectrical engineering.
615  7$aTECHNOLOGY & ENGINEERING / Electrical.
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