000 | a | ||
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999 |
_c30793 _d30793 |
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008 | 220728b xxu||||| |||| 00| 0 eng d | ||
020 | _a9789811240515 | ||
082 |
_a620.1064 _bINA |
||
100 | _aInamuro, Takaji | ||
245 | _aIntroduction to the lattice boltzmann method : a numerical method for complex boundary and moving boundary flows | ||
260 |
_bWorld Scientific, _c2022 _aSingapore : |
||
300 |
_axi, 153 p. ; _bill., _c24 cm |
||
365 |
_b58.00 _cUSD _d82.00 |
||
504 | _aIncludes bibliographical references and index. | ||
520 | _aThe book introduces the fundamentals and applications of the lattice Boltzmann method (LBM) for incompressible viscous flows. It is written clearly and easy to understand for graduate students and researchers. The book is organized as follows. In Chapter 1, the SRT- and MRT-LBM schemes are derived from the discrete Boltzmann equation for lattice gases and the relation between the LBM and the Navier-Stokes equation is explained by using the asymptotic expansion (not the Chapman-Enskog expansion). Chapter 2 presents the lattice kinetic scheme (LKS) which is an extension method of the LBM and can save memory because of needlessness for storing the velocity distribution functions. In addition, an improved LKS which can stably simulate high Reynolds number flows is presented. In Chapter 3, the LBM combined with the immersed boundary method (IB-LBM) is presented. The IB-LBM is well suitable for moving boundary flows. In Chapter 4, the two-phase LBM is explained from the point of view of the difficulty in computing two-phase flows with large density ratio. Then, a two-phase LBM for large density ratios is presented. In Appendix, sample codes (available for download) are given for users. | ||
650 | _aViscous flow | ||
650 | _aMathematical models | ||
650 | _aBoundary layer | ||
650 | _aMultiphase flow | ||
650 | _aLattice Boltzmann methods | ||
650 | _aAcoutic time scale | ||
650 | _a Computational algorithm | ||
650 | _aDiffusive time scale | ||
650 | _a Froude number | ||
650 | _aFractional-step method | ||
650 | _aImmersed boundary method | ||
650 | _a Kinematic viscosity coefficient | ||
650 | _aLattice gas model | ||
650 | _aMulti- block grid method | ||
650 | _aPseudo-potential model | ||
650 | _a S-expansion | ||
650 | _aTaylor-Green vortex | ||
650 | _a Wing-tip vortex | ||
700 | _aYoshino, Masato | ||
700 | _aSuzuki, Kosuke | ||
942 |
_2ddc _cBK |