|
|
|
|
References
|
|
| |
| 1. |
Carey G. G., Cheung Y. K., Lau S. L., “Mixed operator problems using least squares finite element collocation”, Comput. Methods Appl. Mech. Eng., 22 (1980), 121–130    |
| 2. |
Mizusawa T., Kajita T., “Application of point least squares method with B-splines in solid
mechanics problems”, Int. J. Numer. Methods Eng., 18:6 (1982), 897–907 |
| 3. |
Burgess G., Mahajerin E., “Rotational fluid flow using a least squares collocation technique”, Comput. Fluids, 12 (1984), 311–317  |
| 4. |
Dong S. B., Lopez A. E., “Natural vibrations of a clamped circular plate with rectilinear
orthotropy by least-squares collocation”, Int. J. Solids Struct., 21 (1985), 515–526 |
| 5. |
Jiang B.-N., Carey G. F., “Adaptive refinement for least-squares finite elements with
element-by-element conjugate gradient solution”, Int. J. Numer. Meth. Engineering, 24 (1987), 569–580 |
| 6. |
Bentley L. R., Pinder G. F., Herrera I., “Solution of the advective-dispersive transport equation using a least
squares collocation, Eulerian–Lagrangian method”, Numer. Methods Partial Differ. Equations, 5:3 (1989), 227–240 |
| 7. |
Semin L. G., Sleptsov A. G., Shapeev V. P., “Metod kollokatsii – naimenshikh kvadratov dlya uravnenii Stoksa”, Vychisl. tekhnologii, 1:2 (1996), 90–98 |
| 8. |
Karamyshev V., Kovenya V., Sleptsov A., “Adaptive methods for Navier–Stokes equations”, Proc. of the Third ECCOMAS conference on computational fluid
dynamics, Vol. 1, John Wiley & Sons, Paris, 1996, 301–307 |
| 9. |
Semin L. G., Shapeev V. P., “Kollokatsionno-setochnyi metod resheniya kraevykh zadach dlya uravnenii
Nave–Stoksa”, Matematicheskie problemy mekhaniki sploshnykh sred, Tez. dokl. sib. shkoly-seminara, Novosibirsk, 1997, 125–126 |
| 10. |
Semin L. G., Shapeev V. P., “Metod kollokatsii i naimenshikh kvadratov dlya uravnenii Nave–Stoksa”, Vychisl. tekhnologii, 3:3 (1998), 72–84 |
| 11. |
Bochev P., Cai Z., Manteuffel T. A., McCormick S. F., “Analysis of velocity-flux first-order system least-squares principles
for the Navier–Stokes equations. Part I”, SIAM J. Numer. Anal., 35:3 (1998), 990–1009 |
| 12. |
Semin L. G., Shapeev V. P., “Collocation-grid method for solving boundary problems for
Navier–Stokes equations”, Proc. of the international conference on the methods of aerophysical
research., Part 2, Novosibirsk, 1998, 186–191 |
| 13. |
Belyaev V. V., Shapeev V. P., “Metod kollokatsii i naimenshikh kvadratov na adaptivnykh setkakh v oblasti
s krivolineinoi granitsei”, Vychisl. tekhnologii, 5:4 (2000), 12–21 |
| 14. |
Shapeev V. P., Semin L. G., Belyaev V. V., “The collocation and least squares method for numerical solution of
Navier–Stokes equations”, Proc. of the Steklov Inst. of Math., Suppl. 2, 2003, S115–S137 |
| 15. |
Semin L. G., “Collocation and least squares method for 2D heat conductivity equation”, Vychisl. tekhnologii, 11:1 (2006), 18–25 |
| 16. |
Isaev V. I., Shapeev V. P., Eremin S. A., “Issledovanie svoistv metoda kollokatsii i naimenshikh kvadratov
resheniya kraevykh zadach dlya uravneniya Puassona i uravnenii Nave–Stoksa”, Vychisl. tekhnologii, 12:3 (2007), 53–70 |
| 17. |
Issaev V. I., Shapeev V. P., “Investigation of the collocation and least squares method for solving
boundary value problems for Navier–Stokes equations”, Proc. of the international conference on the methods of aerophysical
research (ICMAR2007), Part 3, Novosibirsk, 2007, 147–152 |
| 18. |
Russell R. D., Shampine L. F., “A collocation method for boundary value problems”, Numer. Math., 19 (1972), 1–28 |
| 19. |
Boor C. de, Swartz B., “Collocation at Gaussian points”, SIAM J. Numer. Anal., 10:4 (1973), 582–606 |
| 20. |
Ascher U., Christiansen J., Russel R. D., “A collocation solver for mixed order systems of boundary value problems”, Math. Comp., 33 (1979), 659–679 |
| 21. |
Sleptsov A. G., Letova E. Yu., Salomatov K. G., Shmykov I. V., “Pereopredelennye sistemy konechno-raznostnykh uravnenii dlya zadach tipa
diffuzii-konvektsii”, Vychisl. tekhnologii, 2:5 (1993), 192–201 |
| 22. |
Shapeev A. V., “O dvukh algoritmakh chislennykh metodov lineinoi algebry”, Student i nauchno-tekhnicheskii progress, Tez. dokl. mezhdunar. nauch. stud. konf., Novosibirsk, 2000, 16 |
| 23. |
Moffat H. K., “Viscous and resistive eddies near a sharp corner”, J. Fluid Mech., 18 (1964), 1–18 |
| 24. |
Barragy E., Carey G. F., “Stream function-vorticity driven cavity solution using $p$ finite
elements”, Computers & Fluids, 26:5 (1997), 453–468 |
| 25. |
Garanzha V. A., Konshin V. N., “Chislennye algoritmy dlya techenii vyazkoi zhidkosti, osnovannye na
konservativnykh kompaktnykh skhemakh vysokogo poryadka approksimatsii”, Zhurn. vychisl. matematiki i mat. fiziki, 39:8 (1999), 1378–1392  |
| 26. |
Beklemishev D. V., Dopolnitelnye glavy lineinoi algebry, Nauka, M., 1983 |
| 27. |
Temam R., Uravneniya Nave–Stoksa. Teoriya i chislennyi analiz, Mir, M., 1981 |
| 28. |
Ladyzhenskaya O. A., Matematicheskie voprosy dinamiki vyazkoi neszhimaemoi zhidkosti, Nauka, M., 1970 |
| 29. |
Saad Y., “Krylov subspace methods for solving large unsymmetric linear systems”, Mathematics of Computation, 37:155 (1981), 105–126 |
| 30. |
Sleptsov A. G., “Ob uskorenii skhodimosti lineinykh iteratsii”, Modelirovanie v mekhanike, 3(20), no. 3, Novosibirsk, 1989, 132–147 |
| 31. |
Sleptsov A. G., “Ob uskorenii skhodimosti lineinykh iteratsii 2”, Modelirovanie v mekhanike, 3(20), no. 5, Novosibirsk, 1989, 132–147 |
| 32. |
Fedorenko R. P., Vvedenie v vychislitelnuyu fiziku, MFTI, M., 1994 |
| 33. |
Karamyshev V. B., Kovenya V. M., Sleptsov A. G., Cherny S. G., “Variational method of accelerating linear iterations and its
applications”, Computers & Fluids, 25:5 (1996), 467–484 |
| 34. |
Olshanskii M. A., Ravnomernye po parametru mnogosetochnye i iteratsionnye metody, Dis. $\dots$ dokt. fiz.-mat. nauk, M., 2006 |
| 35. |
Shapeev A. V., “Raznostnaya skhema chetvertogo poryadka dlya uravnenii Nave–Stoksa na
pyatitochechnom shablone”, Dinamika sploshnoi sredy, 116, Novosibirsk, 2000, 119–122 |
| 36. |
Ghia U., Ghia K. N., Shin C. T., “High-Re solutions for incompressible flow using the Navier–Stokes
equations and a multigrid method”, J. Comput. Phys., 48 (1982), 387–411 |
| 37. |
Chen C. J., Chen H. J., “Finite analytic numerical method for unsteady two-dimensional
Navier–Stokes equations”, J. Comput. Physics, 53:2 (1984), 209–226 |
| 38. |
Bruneau C. H., Jouron C., “An efficient scheme for solving steady incompressible Navier–Stokes
equations”, J. Comput. Physics, 89:2 (1990), 389–413 |
| 39. |
Deng G. B., Piquet J., Queutey P., Visonneau M., “A new fully coupled solution of the Navier–Stokes equations”, Int. J. for Numer. Methods in Fluids, 19:7 (1994), 605–639 |
| 40. |
Botella O., Peyret R., “Benchmark spectral results on the lid-driven cavity flow”, Computers & Fluids, 27:4 (1998), 421–433 |
| 41. |
Shankar P. N., Deshpande M. D., “Fluid mechanics in the driven cavity”, Annu. Rev. Fluid Mech., 32 (2000), 93–136 |
| 42. |
Sahin M., Owens R. G., “A novel fully implicit finite volume method applied to the lid-driven
cavity problem. Part I: High Reynolds number flow calculations”, Int. J. Numer. Meth. Fluids, 42 (2003), 57–77 |
| 43. |
Wu Y., Liao S., “Solving high Reynolds-number viscous flows by the general BEM and
domain decomposition method”, Int. J. Numer. Meth. Fluids, 47 (2005), 185–199 |
| 44. |
Erturk E., Corke T. C., Gokcol C., “Numerical solutions of 2-D steady incompressible driven cavity
flow at high Reynolds numbers”, Int. J. Numer. Meth. Fluids, 48:7 (2005), 747–774 |
| 45. |
Cheng M., Hung K. C., “Vortex structure of steady flow in a rectangular cavity”, Computers & Fluids, 35 (2006), 1046–1062 |
| 46. |
Chetverushkin B. N., Introductory word and plenary talk, V International Congress on Mathematical Modelling. Dubna, 2002 |
| 47. |
Tolstykh A. I., Kompaktnye raznostnye skhemy i ikh primenenie v zadachakh aerogidrodinamiki, Nauka, M., 1990 |
