Funada, Masaya; Imamura, Taro High-order immersed boundary method for inviscid flows applied to flux reconstruction method on a hierarchical Cartesian grid. (English) Zbl 1521.76804 Comput. Fluids 265, Article ID 105986, 12 p. (2023). MSC: 76Q05 65M25 PDFBibTeX XMLCite \textit{M. Funada} and \textit{T. Imamura}, Comput. Fluids 265, Article ID 105986, 12 p. (2023; Zbl 1521.76804) Full Text: DOI
Llorente, Victor J.; Kou, Jiaqing; Valero, Eusebio; Ferrer, Esteban A modified equation analysis for immersed boundary methods based on volume penalization: applications to linear advection-diffusion equations and high-order discontinuous Galerkin schemes. (English) Zbl 1521.76348 Comput. Fluids 257, Article ID 105869, 16 p. (2023). MSC: 76M10 65M60 PDFBibTeX XMLCite \textit{V. J. Llorente} et al., Comput. Fluids 257, Article ID 105869, 16 p. (2023; Zbl 1521.76348) Full Text: DOI arXiv
Husson, Julien; Terracol, M.; Deck, S.; Le Garrec, T. Critical assessment of wall model numerical implementation in LBM. (English) Zbl 1521.76666 Comput. Fluids 257, Article ID 105857, 21 p. (2023). MSC: 76M28 PDFBibTeX XMLCite \textit{J. Husson} et al., Comput. Fluids 257, Article ID 105857, 21 p. (2023; Zbl 1521.76666) Full Text: DOI
Qin, Zhipeng; Riaz, Amir; Balaras, Elias A locally second order symmetric method for discontinuous solution of Poisson’s equation on uniform Cartesian grids. (English) Zbl 1519.76345 Comput. Fluids 198, Article ID 104397, 14 p. (2020). MSC: 76T99 65N06 PDFBibTeX XMLCite \textit{Z. Qin} et al., Comput. Fluids 198, Article ID 104397, 14 p. (2020; Zbl 1519.76345) Full Text: DOI
Bharadwaj S., Anand; Ghosh, Santanu Data reconstruction at surface in immersed-boundary methods. (English) Zbl 1519.76201 Comput. Fluids 196, Article ID 104236, 17 p. (2020). MSC: 76M20 76M15 PDFBibTeX XMLCite \textit{A. Bharadwaj S.} and \textit{S. Ghosh}, Comput. Fluids 196, Article ID 104236, 17 p. (2020; Zbl 1519.76201) Full Text: DOI
So, R. M. C.; Leung, R. C. K.; Kam, E. W. S.; Fu, S. C. Progress in the development of a new lattice Boltzmann method. (English) Zbl 1496.76104 Comput. Fluids 190, 440-469 (2019). MSC: 76M28 76P05 PDFBibTeX XMLCite \textit{R. M. C. So} et al., Comput. Fluids 190, 440--469 (2019; Zbl 1496.76104) Full Text: DOI
Xu, Songzhe; Xu, Fei; Kommajosula, Aditya; Hsu, Ming-Chen; Ganapathysubramanian, Baskar Immersogeometric analysis of moving objects in incompressible flows. (English) Zbl 1519.76161 Comput. Fluids 189, 24-33 (2019). MSC: 76M10 65M60 74F10 76D05 PDFBibTeX XMLCite \textit{S. Xu} et al., Comput. Fluids 189, 24--33 (2019; Zbl 1519.76161) Full Text: DOI Link
Chen, Xiaohong; Li, Zhilin; Ruiz Álvarez, Juan A direct IIM approach for two-phase Stokes equations with discontinuous viscosity on staggered grids. (English) Zbl 1410.76281 Comput. Fluids 172, 549-563 (2018). MSC: 76M20 65N06 35Q35 35R05 65N22 76D07 PDFBibTeX XMLCite \textit{X. Chen} et al., Comput. Fluids 172, 549--563 (2018; Zbl 1410.76281) Full Text: DOI
Tschisgale, Silvio; Kempe, Tobias; Fröhlich, Jochen A general implicit direct forcing immersed boundary method for rigid particles. (English) Zbl 1410.76049 Comput. Fluids 170, 285-298 (2018). MSC: 76D05 74F10 76-04 76M12 PDFBibTeX XMLCite \textit{S. Tschisgale} et al., Comput. Fluids 170, 285--298 (2018; Zbl 1410.76049) Full Text: DOI
Kumar, Manish; Roy, Somnath A sharp interface immersed boundary method for moving geometries with mass conservation and smooth pressure variation. (English) Zbl 1390.76585 Comput. Fluids 137, 15-35 (2016). MSC: 76M20 65M06 76D05 PDFBibTeX XMLCite \textit{M. Kumar} and \textit{S. Roy}, Comput. Fluids 137, 15--35 (2016; Zbl 1390.76585) Full Text: DOI
Frisani, Angelo; Hassan, Yassin A. On the immersed boundary method: finite element versus finite volume approach. (English) Zbl 1390.65105 Comput. Fluids 121, 51-67 (2015). MSC: 65M60 65M08 76M10 76M12 PDFBibTeX XMLCite \textit{A. Frisani} and \textit{Y. A. Hassan}, Comput. Fluids 121, 51--67 (2015; Zbl 1390.65105) Full Text: DOI
Nicolaou, L.; Jung, S. Y.; Zaki, T. A. A robust direct-forcing immersed boundary method with enhanced stability for moving body problems in curvilinear coordinates. (English) Zbl 1390.76603 Comput. Fluids 119, 101-114 (2015). MSC: 76M20 65M06 76D05 PDFBibTeX XMLCite \textit{L. Nicolaou} et al., Comput. Fluids 119, 101--114 (2015; Zbl 1390.76603) Full Text: DOI Link
van Nimwegen, A. T.; Schutte, K. C. J.; Portela, L. M. Direct numerical simulation of turbulent flow in pipes with an arbitrary roughness topography using a combined momentum-mass source immersed boundary method. (English) Zbl 1390.76249 Comput. Fluids 108, 92-106 (2015). MSC: 76F65 76M12 PDFBibTeX XMLCite \textit{A. T. van Nimwegen} et al., Comput. Fluids 108, 92--106 (2015; Zbl 1390.76249) Full Text: DOI
Muldoon, Frank Maximization of mass flow in a channel obstructed by an infinitely thin plate using a gradient-based control strategy. (English) Zbl 1365.76040 Comput. Fluids 70, 176-194 (2012). MSC: 76D05 76D55 PDFBibTeX XMLCite \textit{F. Muldoon}, Comput. Fluids 70, 176--194 (2012; Zbl 1365.76040) Full Text: DOI
Maniyeri, Ranjith; Suh, Yong Kweon; Kang, Sangmo; Kim, Min Jun Numerical study on the propulsion of a bacterial flagellum in a viscous fluid using an immersed boundary method. (English) Zbl 1365.76359 Comput. Fluids 62, 13-24 (2012). MSC: 76Z10 92C35 76M12 PDFBibTeX XMLCite \textit{R. Maniyeri} et al., Comput. Fluids 62, 13--24 (2012; Zbl 1365.76359) Full Text: DOI
Li, Zhilin; Lai, Ming-Chih; He, Guowei; Zhao, Hongkai An augmented method for free boundary problems with moving contact lines. (English) Zbl 1242.76047 Comput. Fluids 39, No. 6, 1033-1040 (2010). MSC: 76D27 76D45 76M25 76M20 PDFBibTeX XMLCite \textit{Z. Li} et al., Comput. Fluids 39, No. 6, 1033--1040 (2010; Zbl 1242.76047) Full Text: DOI Link
Sudhakar, Y.; Vengadesan, S. Flight force production by flapping insect wings in inclined stroke plane kinematics. (English) Zbl 1242.76379 Comput. Fluids 39, No. 4, 683-695 (2010). MSC: 76Z10 92C10 PDFBibTeX XMLCite \textit{Y. Sudhakar} and \textit{S. Vengadesan}, Comput. Fluids 39, No. 4, 683--695 (2010; Zbl 1242.76379) Full Text: DOI
Kim, Yongsam; Peskin, Charles S. 3-D parachute simulation by the immersed boundary method. (English) Zbl 1242.76242 Comput. Fluids 38, No. 6, 1080-1090 (2009). MSC: 76M25 76D05 PDFBibTeX XMLCite \textit{Y. Kim} and \textit{C. S. Peskin}, Comput. Fluids 38, No. 6, 1080--1090 (2009; Zbl 1242.76242) Full Text: DOI
Layton, Anita T. Using integral equations and the immersed interface method to solve immersed boundary problems with stiff forces. (English) Zbl 1237.76123 Comput. Fluids 38, No. 2, 266-272 (2009). MSC: 76M25 76D05 PDFBibTeX XMLCite \textit{A. T. Layton}, Comput. Fluids 38, No. 2, 266--272 (2009; Zbl 1237.76123) Full Text: DOI
Su, Shen-Wei; Lai, Ming-Chih; Lin, Chao-An An immersed boundary technique for simulating complex flows with rigid boundary. (English) Zbl 1177.76299 Comput. Fluids 36, No. 2, 313-324 (2007). MSC: 76M25 76D05 PDFBibTeX XMLCite \textit{S.-W. Su} et al., Comput. Fluids 36, No. 2, 313--324 (2007; Zbl 1177.76299) Full Text: DOI
Fauci, Lisa J. Peristaltic pumping of solid particles. (English) Zbl 0825.76603 Comput. Fluids 21, No. 4, 583-598 (1992). MSC: 76M25 76T99 76D05 74F10 PDFBibTeX XMLCite \textit{L. J. Fauci}, Comput. Fluids 21, No. 4, 583--598 (1992; Zbl 0825.76603) Full Text: DOI