Numerical Methods for Fluid Dynamics IV - Rilegato

Contenuti

• Invited Papers
• 1: K.W. Morton: Node-cell mappings for the cell vertex method
• 2: D. Catherall: Solution adaptivity with structured grids
• 3: Bernadette Palmerio: Mesh adaption for compressible flows
• 4: C.L. Farmer: Grid generation as a discrete optimisation problem
• 5: Eitan Tadmor: Super-viscosity and spectral approximations of nonlinear conservation laws
• 6: P.L. Roe: Waves in discrete fluids
• 7: S. Hickmott, A.G. Hutton, M. Rabbitt and R.M. Smith: Practical flow simulation employing high order accuracy, implicit, finite element based algorithms
• 8: Bengt Fornberg: Computing stready incompressible flows past blunt bodies - A historical overview
• 9: H.C. Yee, P.K. Sweby, and A. Lafon: Basins of attraction and the time-dependent approach to obtaining steady-state numerical solutions
• 10: Maurizio Pandolfi: Physical and numerical aspects of non-equilibrium flows
• 11: Randall J. LeVeque: Simplified multi-dimensional flux limiter methods
• 12: Bertil Gustafsson and Per Lötstedt: Convergence acceleration for first order systems
• 13: Barry Koren, Marie-Hélène Lallemand: Iterative defect correction and multigrid accelerated explicit time stepping for the steady Euler equations
• 14: J. Peraire, M. Vahdati and J. Peiró and K. Morgan: The construction and behaviour of some
• Contributed Papers
• 15: Th. Sonar, V. Hannemann, O. Friedrich: Adaptive concepts for the resolution of compressible flow by upwind finite volume methods
• 16: U. Göhner, G. Warnecke, W. Wendland: Adaptive finite elements for transonic flows
• 17: Alain Dervieux, Lopula Fézoui, Marie-Pierre Leclercq and Bruno Stoufflet: A general upwind formulation for compressible flows on multi-element meshes
• 18: Michael G. Edwards: A dynamically adaptiove Godunov scheme for reservoir simulation on large aspect ratio grids
• 19: Ron Trompert: Local uniform mesh refinement and brine transport in porous media
• 20: A. Lerat and Z.N. Wu: A subdomain matching condition for implicit Euler solvers
• 21: R. Arina and S. Tarditi: Orthogonal block structured surface grids
• 22: Masahiro Suzuki: Surface grid generation with a linkage to geometric generation
• 23: Bonita V. Saunders: Boundary fitted grid generation using tensor product B-splines 309
• 24: Gary P. Warren, W. Kyle Anderson, James L. Thomas, Sherrie L. Krist: Grid convergence for adaptive methods
• 25: A.E.P. Veldman and E.F.F. Botta: Grid quality: an interplay of grid and solver
• 26: S.A.E.G. Falle and J.R. Giddings: Body capturing using adaptive cartesian grids
• 27: Bassi F., Rebay S. and Savini M.: A high resolution discontinuous Galerkin method for hyperbolic problems on unstructured grids
• 28: R. Richter and P. Leyland: Shock capturing using auto-adaptive finite elements
• 29: G. Lacombe and A. Lerat: On the steady-state accuracy of an implicit Navier-Stokes solver of Lax-Wendroff type
• 30: E.F. Toro: Riemann solvers: linearizations and adaption
• 31: James J. Quirk: A cartesian grid scheme for gas dynamic flows that involve complex geometries
• 32: Andrew Priestley: Recent developments of the Lagrange-Calerkin method
• 33: Alison Ramage and Andrew J. Wathen: Iterative solution technique for the Lagrange-Galerkin method 401
• 34: E. Süli and A. Ware: The spectral Lagrange-Galerkin method for the Navier-Stokes equations
• 35: I.J. Sobey and T. Mullin: Calculation of multiple solutions for the two-dimensional Navier-Stokes equations
• 36: Florian De Vuyst: A new implicit second order scheme based on a kinetic interpretation for solving the Euler Equations
• 37: Mark H. Mawson: A solution method for the shallow water Quasi-equilibrium equations on the sphere
• 38: Steven R. Allmaras: Contamination of laminar boundary layers by artificial dissipation in Navier-Stokes solutions
• 39: J. Blazek, N. Kroll, C.C. Rossow: A comparison of several implicit smoothing methods
• 40: P. Tattersall and J. McGuirk: Numerical diffusion estimates as input for grid adaption
• 41: David W. Zingg and Harvard Lomax: On the eigensystems associated with numerical boundary schemes for hyperbolic equations
• 42: K. Engel, M. Faden, S. Pokorny: Implementation of non-reflecting boundary conditions in an unsteady flow simulation system
• 43: Rosemary A. Renaut: Absorbing boundary conditions for acoustic and elastic waves
• 44: P.N. Childs and J.A. Shaw: Generation and analysis of hybrid structured/unstructured grids
• 45: C. Mensink, H. Deconinck: A 2D multiblock method for viscous and inviscid flow computations
• 46: J.A. Mackenzie, D.F. Mayers and A.J. Mayfield: Error estimates for adaptive cell vertex finite volume algorithms
• 47: Gabriele C. Hegerl, Albert Sachs: Energy-reduced boundary conditions for the simulation of compressible viscous flows in domains with moving boundaries
• 48: Erik Dick and Kris Riemslagh: Multi-stage Jacobi relaxation as smoother in a multigrid method for steady Euler equations
• 49: S.H. Onslow and C.M. Albone: Multigrid convergence acceleration of an upwind Euler algorithm on multiply-embedded meshes
• 50: Lixia Wing and David A. Caughey: Implicit multigrid algorithm for Euler equations on block-structured grids with discontinuous interfaces
• 51: Michael Rudgyard: A comparison of multidimensional upwinding for cell vertex schemes on triangular meshes
• 52: P.K. Jimack: A new approach to finite element error control for time-dependent problems
• 53: Jaakko Hoffren and Timo Siikonen: Time-accurate calculations with an implicit Euler-Navier-Stokes solver
• 54: N. Qin, X. Xu and B.E. Richards: SFDN-*a-GMRES and SQN-*a-GMRES methods for fast high resolution N-S simulations
• 55: A.J. Peace: Towards a cell-vertex multi-grid Navier-Stokes algorithm for three-dimensional structured/unstructured meshes