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010   $a9786611054724
010   $a0-08-053962-9
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035   $a(OCoLC)182856810
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100   $a20030508d2003      uy         0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aPrinciples of induction logging /$fA.A. Kaufman and Yu. A. Dashevsky
205   $a1st ed.
210   $aAmsterdam ;$aBoston $cElsevier$d2003
215   $a1 online resource (657 p.)
225 1 $aMethods in geochemistry and geophysics ;$v38
300   $aDescription based upon print version of record.
311   $a0-444-50983-6 
320   $aIncludes bibliographical references (p. 639-640) and index.
327   $aCover; Contents; Acknowledgments; List of Symbols; Introduction; Chapter 1. Basic electromagnetic laws and Maxwell's equations; 1.1. Coulomb's law; 1.2. Biot-Savart law; 1.3. The postulate of conservation of charge and the distribution of charges in conducting media; 1.4. Faraday's law and the first Maxwell equation; 1.5. Electromagnetic field equations; 1.6. Relationships between various responses of the electromagnetic field; Chapter 2. Electromagnetic field of the magnetic dipole in a uniform conducting medium; Chapter 3. Methods for the solution of direct problems of induction logging
327   $a3.1. The method of separation of variables3.2. The method of shells; 3.3. The method of integral equations; 3.4. Approximate methods of field calculation in induction logging; Chapter 4. Electromagnetic field of a vertical magnetic dipole on the axis of a borehole; 4.1. Formulation of the boundary problem; 4.2. Derivation of the formula for the vertical component of the magnetic field; 4.3. The quadrature component of the magnetic field at the range of very small model parameters; 4.4. Radial characteristics of a two-coil induction probe at the range of small parameters
327   $a4.5. Influence of the skin effect in the formation on the radial characteristics of a two-coil induction probe4.6. Asymptotic behavior of the magnetic field in the borehole in the range of small parameters; 4.7. Behavior of the field on the borehole axis in the near and far zones; 4.8. Frequency responses of the magnetic field of the vertical magnetic dipole on the borehole axis; 4.9. Influence of finite dimensions of induction probe coils; 4.10. Electrical field of a current ring in a medium with cylindrical interfaces
327   $a4.11. Radial responses of two-coil induction probes displaced with respect to the borehole axis4.12. The influence of magnetic permeability and dielectric constant in induction logging; Chapter 5. Quasistationary magnetic field of a vertical magnetic dipole in a formation with a finite thickness; 5.1. Derivation of formulae for the vertical component of the magnetic field of a vertical magnetic dipole; 5.2. The vertical responses of the two-coil induction probe in the range of small parameters; 5.3. The theory of the two-coil induction probe in beds with a finite thickness
327   $a5.4. Curves of profiling with a two-coil induction probe in a medium with two horizontal interfacesChapter 6. The two-coil induction probe on the borehole axis, when the bed has a finite thickness; 6.1. Doll's theory of the two-coil induction probe located on the borehole axis when a formation has a finite thickness; 6.2. The theory of a two-coil induction probe, taking into account the skin effect in an external medium; 6.3. Influence of the finite thickness of the formation on the magnetic field behavior; Chapter 7. Multi-coil differential induction probes
327   $a7.1. Methods of determination of probe parameters
330   $aThe monograph introduces the reader to the world of inductive well logging - an established method for surveying the electrical conductivity of rocks surrounding a borehole. The emphasis is on developing a theory of inductive logging and on understanding logging tools basic physics, since this theory and understanding furnish valuable insights for inventing practical induction logging techniques.  The first chapter of the book presents the basic laws of electromagnetism from a point of view that will facilitate the application of the theory to problems in electromagnetic logging. Man
410  0$aMethods in geochemistry and geophysics ;$v38.
606   $aInduction logging
606   $aElectromagnetic fields$xMathematical models
615  0$aInduction logging.
615  0$aElectromagnetic fields$xMathematical models.
676   $a622/.154
700   $aKaufman$b Alexander A.$f1931-$01822355
701   $aDashevsky$b Yu. A$01822356
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9911004763703321
996   $aPrinciples of induction logging$94388521
997   $aUNINA