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181   $ctxt
182   $cc
183   $acr
200 00$aRockfall engineering /$fedited by Stephane Lambert, Francois Nicot
210   $aLondon $cISTE ;$aHoboken, N.J. $cWiley$d2011
215   $a1 online resource (461 p.)
225 1 $aISTE
300   $aDescription based upon print version of record.
311 08$a9781848212565 
311 08$a1848212569 
320   $aIncludes bibliographical references and index.
327   $aCover; Title Page; Copyright Page; Table of Contents; Foreword; Introduction; Chapter 1. Geophysical Detection and Characterization of Discontinuities in Rock Slopes; 1.1. Introduction; 1.2. Geophysical parameters and methods; 1.2.1. Introduction; 1.2.2. Seismic velocity; 1.2.3. Electrical resistivity; 1.2.4. Dielectrical permittivity; 1.2.5. Resonance frequency; 1.3. Applications; 1.3.1. Introduction; 1.3.2. Plateau survey: Ravin de l'Aiguille; 1.3.3. Cliff survey: Gorge de la Bourne; 1.3.4. Column survey: Chamousset; 1.4. Conclusions; 1.5. Acknowledgments; 1.6. Bibliography
327   $aChapter 2. Remote Sensing and Monitoring Techniques for the Characterization of Rock Mass Deformation and Change Detection2.1. Introduction; 2.2. Main issues; 2.3. Investigation and monitoring techniques; 2.3.1. Geotechnical instrumentation: crackmeter, extensometer, tiltmeter; 2.3.2. Distancemeter; 2.3.3. Laser scanning; 2.3.4. High resolution imaging and photogrammetry; 2.3.5. Synthetic aperture radar interferometry (InSAR); 2.3.6. Global navigation satellite system (GNSS); 2.4. Examples of applications; 2.4.1. Detection of rock slope instabilities; 2.4.2. Geometry and structure analysis
327   $a2.4.3. Movement detection and characterization2.4.4. Monitoring and real-time warning; 2.5. Perspectives; 2.6. Conclusions; 2.7. Bibliography; Chapter 3. Mechanical Stability Analyses of Fractured Rock Slopes; 3.1. Introduction; 3.2. Experimental study of rock joint behavior; 3.2.1. Description of natural rock joints; 3.2.2. Compression behavior of natural rock joints; 3.2.3. Shear behavior of natural rock joints; 3.2.4. Behavior of natural rock joints under other loading paths; 3.3. Failure computations of rigid blocks; 3.3.1. Geometrical aspects of block failure
327   $a3.3.2. Mechanical aspects of failure computation3.3.3. Examples of deterministic and probabilistic stability analyses; 3.3.4. Conclusion on failure computations; 3.4. Overview of different stress-strain analyses; 3.4.1. Different stress-strain methods; 3.4.2. Continuous approaches with joints; 3.4.3. Discrete methods; 3.4.4. Distinct element modeling; 3.4.5. NSCD method; 3.4.6. Hybrid methods; 3.5. An advanced stress-strain analysis of failure; 3.5.1. Framework of the analysis; 3.5.2. A new rock joint constitutive relation: the INL2 relation; 3.5.3. Stability analysis of INL2 relation
327   $a3.5.4. A stress-strain analysis of a rock slope3.6. Conclusions; 3.7. Bibliography; Chapter 4. Assessment of Constitutive Behaviors in Jointed Rock Masses from a DEM Perspective; 4.1. Introduction; 4.2. Discrete Element Modeling of rock materials; 4.3. Representation of rock discontinuities; 4.3.1. Smooth joint contact; 4.3.2. Synthetic rock joint; 4.3.3. Shear behavior of rough joints; 4.4. Synthetic Rock Mass modeling methodology; 4.4.1. Rock mass structural representation; 4.4.2. Equivalent rock mass model; 4.4.3. Rock mass constitutive behavior; 4.4.4. Anisotropy in rock mass properties
327   $a4.5. Analysis of specific mechanical behaviors: case studies
330   $aRockfall Engineering is an up-to-date, international picture of the state of the art in rockfall engineering.The three basic stages of rockfalls are considered: the triggering stage, the motion stage, and the interaction with a structure stage; along with contributions including structural characterization of cliffs, remote monitoring, stability analysis, boulder propagation, design of protection structures an risk assessment.Academic contributions are illustrated by practical examples, and completed by engineering contributions where practical purposes are thoroughly considered. This
410  0$aISTE
517 3 $aRock fall engineering
606   $aRockslides$xPrevention
606   $aSoil stabilization
606   $aRock slopes
615  0$aRockslides$xPrevention.
615  0$aSoil stabilization.
615  0$aRock slopes.
676   $a624.1/5132
701   $aLambert$b Stephane$f1969-$01457567
701   $aNicot$b Francois$01839920
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801  1$bMiAaPQ
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906   $aBOOK
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