IISPH-FLIP for incompressible fluids

We propose to use Implicit Incompressible Smoothed Particle Hydrodynamics (IISPH) for pressure projection and boundary handling in Fluid‐Implicit‐Particle (FLIP) solvers for the simulation of incompressible fluids. This novel combination addresses two issues of existing SPH and FLIP solvers, namely...

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Published in	Computer graphics forum Vol. 33; no. 2; pp. 255 - 262
Main Authors	Cornelis, Jens, Ihmsen, Markus, Peer, Andreas, Teschner, Matthias
Format	Journal Article
Language	English
Published	Oxford Blackwell Publishing Ltd 01.05.2014
Subjects	Analysis Categories and Subject Descriptors (according to ACM CCS) Computational fluid dynamics Computer graphics Computer simulation Density Deviation Fluid flow Fluid mechanics I.3.7 [Computer Graphics]: Three-Dimensional Graphics and Realism-Animation Incompressible fluids Preservation Simulation Solvers Studies
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ISSN	0167-7055 1467-8659
DOI	10.1111/cgf.12324

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Abstract	We propose to use Implicit Incompressible Smoothed Particle Hydrodynamics (IISPH) for pressure projection and boundary handling in Fluid‐Implicit‐Particle (FLIP) solvers for the simulation of incompressible fluids. This novel combination addresses two issues of existing SPH and FLIP solvers, namely mass preservation in FLIP and efficiency and memory consumption in SPH. First, the SPH component enables the simulation of incompressible fluids with perfect mass preservation. Second, the FLIP component efficiently enriches the SPH component with detail that is comparable to a standard SPH simulation with the same number of particles, while improving the performance by a factor of 7 and significantly reducing the memory consumption. We demonstrate that the proposed IISPH‐FLIP solver can simulate incompressible fluids with a quantifiable, imperceptible density deviation below 0.1%. We show large‐scale scenarios with up to 160 million particles that have been processed on a single desktop PC using only 15GB of memory. One‐ and two‐way coupled solids are illustrated.
AbstractList	We propose to use Implicit Incompressible Smoothed Particle Hydrodynamics (IISPH) for pressure projection and boundary handling in Fluid‐Implicit‐Particle (FLIP) solvers for the simulation of incompressible fluids. This novel combination addresses two issues of existing SPH and FLIP solvers, namely mass preservation in FLIP and efficiency and memory consumption in SPH. First, the SPH component enables the simulation of incompressible fluids with perfect mass preservation. Second, the FLIP component efficiently enriches the SPH component with detail that is comparable to a standard SPH simulation with the same number of particles, while improving the performance by a factor of 7 and significantly reducing the memory consumption. We demonstrate that the proposed IISPH‐FLIP solver can simulate incompressible fluids with a quantifiable, imperceptible density deviation below 0.1%. We show large‐scale scenarios with up to 160 million particles that have been processed on a single desktop PC using only 15GB of memory. One‐ and two‐way coupled solids are illustrated. We propose to use Implicit Incompressible Smoothed Particle Hydrodynamics (IISPH) for pressure projection and boundary handling in Fluid-Implicit-Particle (FLIP) solvers for the simulation of incompressible fluids. This novel combination addresses two issues of existing SPH and FLIP solvers, namely mass preservation in FLIP and efficiency and memory consumption in SPH. First, the SPH component enables the simulation of incompressible fluids with perfect mass preservation. Second, the FLIP component efficiently enriches the SPH component with detail that is comparable to a standard SPH simulation with the same number of particles, while improving the performance by a factor of 7 and significantly reducing the memory consumption. We demonstrate that the proposed IISPH-FLIP solver can simulate incompressible fluids with a quantifiable, imperceptible density deviation below 0.1%. We show large-scale scenarios with up to 160 million particles that have been processed on a single desktop PC using only 15GB of memory. One- and two-way coupled solids are illustrated. [PUBLICATION ABSTRACT]
Author	Cornelis, Jens Ihmsen, Markus Teschner, Matthias Peer, Andreas
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Cites_doi	10.1145/2159516.2159522 10.1090/S0025-5718-1968-0242392-2 10.1007/s00371-009-0339-z 10.1088/0034-4885/68/8/R01 10.1111/j.1467-8659.2010.01832.x 10.1145/2019406.2019411 10.1109/TVCG.2012.87 10.1111/j.1467-8659.2012.03074.x 10.1201/b10635 10.1111/j.1467-8659.2009.01562.x 10.1145/1276377.1276502 10.1145/2185520.2185558 10.1145/1778765.1778851 10.1016/0010-4655(88)90020-3 10.1145/2461912.2461999 10.1145/2508363.2508430 10.1145/2010324.1964976 10.1109/TVCG.2011.29 10.1145/1073204.1073298 10.1111/j.1467-8659.2010.01809.x 10.1109/TVCG.2008.37 10.1145/2461912.2461982 10.1016/j.jcp.2004.12.007 10.1145/1531326.1531346 10.1016/0021-9991(86)90211-1 10.1146/annurev.aa.30.090192.002551 10.1002/cav.1499
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Copyright	2014 The Author(s) Computer Graphics Forum © 2014 The Eurographics Association and John Wiley & Sons Ltd. Published by John Wiley & Sons Ltd. 2014 The Eurographics Association and John Wiley & Sons Ltd.
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References_xml	– reference: [ZYF10] Zhu B., Yang X., Fan Y.: Creating and preserving vortical details in SPH fluid. Computer Graphics Forum 29, 7 (2010), 2207-2214. 2. – reference: [BR86] Brackbill J., Ruppel H.: FLIP: A method for adaptively zoned, particle-in-cell calculations for fluid flows in two dimensions. Journal of Computational Physics 65 (1986), 314-343. 1, 2, 3. – reference: [Cho68] Chorin A.J.: Numerical solution of the Navier-Stokes equations. Mathematics of Computation 22, 104 (1968), 745-762. 3. – reference: [APKG07] Adams B., Pauly M., Keiser R., Guibas L.: Adaptively sampled particle fluids. In ACM Transactions on Graphics (Proceedings SIGGRAPH) (2007), vol. 26, pp. 48:1-48:7. 2. – reference: [SP09] Solenthaler B., Pajarola R.: Predictive-corrective incompressible SPH. ACM Trans. on Graphics (Proceedings of the ACM SIGGRAPH) 28 (2009), 40:1-40:6. 2. – reference: [HLWW12] He X., Liu N., Wang H., Wang G.: Local Poisson SPH for viscous incompressible fluids. Computer Graphics Forum 31 (2012), 1948-1958. 2. – reference: [BKR88] Brackbill J., Kothe D., Ruppel H.: FLIP: A low-dissipation, particle-in-cell method for fluid flow. Computer Physics Communications 48 (1988), 25-38. 1, 3. – reference: [SG11] Solenthaler B., Gross M.: Two-scale particle simulation. ACM Transactions on Graphics (Proceedings SIGGRAPH) 30, 4 (2011), 81:1-81:8. 2. – reference: [ZLC] Zhu B., Lu W., Cong M., Kim B., Fedkiw R.: A new grid structure for domain extension. ACM Trans. Graph. 32, 4 (2013), 63:1-63:12. 2. – reference: [GB13] Gerszewski D., Bargteil A.W.: Physics-based animation of large-scale splashing liquids. ACM Trans. on Graphics (Proceedings of the ACM SIGGRAPH Asia) 32, 6 (2013), 1-6. 2, 3. – reference: [LTKF08] Losasso F., Talton J., Kwatra N., Fedkiw R.: Two-way coupled SPH and particle level set fluid simulation. IEEE Transactions on Visualization and Computer Graphics 14, 4 (2008), 797-804. 2. – reference: [ATT12] Ando R., Thuerey N., Tsuruno R.: Preserving fluid sheets with adaptively sampled anisotropic particles. IEEE Transactions on Visualization and Computer Graphics 18, 8 (2012), 1202-1214. 1, 2, 3. – reference: [BBB07] Batty C., Bertails F., Bridson R.: A fast variational framework for accurate solid-fluid coupling. ACM Trans. Graph. 26, 3 (2007). 1, 2, 3, 4. – reference: [LHK09] Lee H.-Y., Hong J.-M., Kim C.-H.: Interchangeable SPH and level set method in multiphase fluids. The Visual Computer 25, 5-7 (2009), 713-718. 2. – reference: [LZF10] Lentine M., Zheng W., Fedkiw R.: A novel algorithm for incompressible flow using only a coarse grid projection. ACM Trans. Graph. 29, 4 (2010), 114:1-114:9. 2. – reference: [Mon05] Monaghan J.: Smoothed particle hydrodynamics. Reports on Progress in Physics 68, 8 (2005), 1703-1759. 2, 4. – reference: [ICS13] Ihmsen M., Cornelis J., Solenthaler B., Horvath C., Teschner M.: Implicit incompressible SPH. IEEE Transactions on Visualization and Computer Graphics 19 (2013). 2, 3. – reference: [IABT11] Ihmsen M., Akinci N., Becker M., Teschner M.: A parallel SPH implementation on multi-core CPUs. Computer Graphics Forum 30, 1 (2011), 99-112. 4. – reference: [ACAT13] Akinci N., Cornelis J., Akinci G., Teschner M.: Coupling elastic solids with smoothed particle hydrodynamics fluids. Computer Animation and Virtual Worlds 24 (2013), 195-203. 3. – reference: [ZB05] Zhu Y., Bridson R.: Animating sand as a fluid. ACM Transactions on Graphics (Proceedings of the ACM SIGGRAPH) 24, 3 (2005), 965-972. 1, 2, 3, 4. – reference: [AIA12] Akinci N., Ihmsen M., Akinci G., Solenthaler B., Teschner M.: Versatile rigid-fluid coupling for incompressible SPH. ACM Transactions on Graphics (Proceedings of the ACM SIGGRAPH) 31, 4 (2012), 62:1-62:8. 3, 4. – reference: [BLS12] Bodin K., Lacoursière C., Servin M.: Constraint fluids. IEEE Transactions on Visualization and Computer Graphics 18, 3 (2012), 516-526. 2. – reference: [GLHB09] Gao Y., Li C.-F., Hu S.-M., Barsky B.A.: Simulating gaseous fluids with low and high speeds. Computer Graphics Forum 28, 28 (2009), 1845-1852. 2. – reference: [Bri08] Bridson R.: Fluid Simulation for Computer Graphics. A K Peters/CRC Press, 2008. 1, 3, 4. – reference: [KFV05] Kleefsman K. M. T., Fekken G., Veldman A. E. P., Iwanowski B., Buchner B.: A volume-of-fluid based simulation method for wave impact problems. Journal of Computational Physics 206, 1 (2005), 363-393. 4. – reference: [BB12] Boyd L., Bridson R.: MultiFLIP for energetic two-phase fluid simulation. 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Snippet	We propose to use Implicit Incompressible Smoothed Particle Hydrodynamics (IISPH) for pressure projection and boundary handling in Fluid‐Implicit‐Particle... We propose to use Implicit Incompressible Smoothed Particle Hydrodynamics (IISPH) for pressure projection and boundary handling in Fluid-Implicit-Particle...
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SubjectTerms	Analysis Categories and Subject Descriptors (according to ACM CCS) Computational fluid dynamics Computer graphics Computer simulation Density Deviation Fluid flow Fluid mechanics I.3.7 [Computer Graphics]: Three-Dimensional Graphics and Realism-Animation Incompressible fluids Preservation Simulation Solvers Studies
Title	IISPH-FLIP for incompressible fluids
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