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Computational Geomechanics. Manuel Pastor

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Computational Geomechanics - Manuel Pastor

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d upper Omega equals 0"/>

Neglecting source term and integrating by part the first part of the first term

minus integral Underscript normal upper Gamma Subscript w Baseline Endscripts upper N Subscript upper K Superscript p Baseline n Subscript i Baseline k Subscript italic i j Baseline p Subscript w comma j Baseline d upper Gamma plus integral Underscript normal upper Omega Endscripts left-bracket upper N Subscript upper K comma i Superscript p Baseline k Subscript italic i j Baseline p Subscript w comma j Baseline plus upper N Subscript upper K Superscript p Baseline left-parenthesis k Subscript italic i j Baseline upper S Subscript w Baseline rho Subscript f Baseline b Subscript j Baseline right-parenthesis Subscript comma i Baseline plus upper N Subscript upper K Superscript p Baseline alpha ModifyingAbove u With ampersand c period dotab semicolon Subscript i comma i Baseline plus upper N Subscript upper K Superscript p Baseline StartFraction ModifyingAbove p With ampersand c period dotab semicolon Subscript w Baseline Over upper Q Superscript asterisk Baseline EndFraction right-bracket d upper Omega equals 0

Inserting the shape functions

(3.28b)

(3.29b) upper Q overTilde Subscript italic upper K i upper L Baseline equals integral Underscript normal upper Omega Endscripts upper N Subscript upper K comma i Superscript u Baseline alpha upper N Subscript upper L Superscript p Baseline d upper Omega

(3.30b) upper H Subscript italic upper K upper L Baseline equals integral Underscript normal upper Omega Endscripts upper N Subscript upper K comma i Superscript p Baseline k Subscript italic i j Baseline upper N Subscript upper L comma j Superscript p Baseline d upper Omega

(3.31b) upper S Subscript italic upper K upper L Baseline equals integral Underscript normal upper Omega Endscripts upper N Subscript upper K Superscript upper P Baseline StartFraction 1 Over upper Q asterisk EndFraction upper N Subscript upper L Superscript p Baseline d upper Omega

(3.32b)

Equation (3.33) is scalar.

3.4 Conclusions

In this chapter, the governing equations introduced in Chapter 2 are discretized in space and time using various implicit and explicit algorithms. They are now ready for implementation into computer codes. In Chapter 5, we shall address some special modeling aspects and in Chapters 6–8, we shall show some applications for static, quasi‐static, and dynamic examples to illustrate the practical applications of the method and to validate and verify the schemes and constitutive models used.

References

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7 Clough, R. W. and Penzien, J. (1975). Dynamics of Structures, McGraw‐Hill, New York.

8 Clough, R. W. and Penzien, J. (1993). Dynamics of Structures (2nd edn), McGraw‐Hill, Inc., New York.

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10 Dewoolkar, M. M. (1996). A study of seismic effects on centiliver‐retaining walls with saturated backfill. Ph.D Thesis. Dept of Civil Engineering, University of Colorado. Boulder, USA.

11 Katona, M. G. (1985). A general family of single‐step methods for numerical time integration of structural dynamic equations, NUMETA 85, 1, 213–225.

12 Katona,

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