NOISETTE relevant publications

General description of NOISETTE functionality

• I. Abalakin, P. Bakhvalov, V. Bobkov, A. Duben, A. Gorobets, T. Kozubskaya, P. Rodionov, N. Zhdanova. NOISEtte CFD&CAA Supercomputer Code for Research and Applications // Supercomput. Frontiers and Innovations, 11(2), 78-101. (2024) PDF

• P. Bakhvalov, T. Kozubskaya, P. Rodionov. EBR schemes with curvilinear reconstructions for hybrid meshes // Computers and Fluids, 2022, 239, 105352. https://doi.org/10.1016/j.compfluid.2022.105352
• P. Bakhvalov, M.Surnachev, Method of averaged element splittings for diffusion terms discretization in vertex-centered framework // Journal of Computational Physics, Vol. 450, 2022, 110819. http://doi.org/10.1016/j.jcp.2021.110819

• A. Gorobets, P. Bakhvalov. Heterogeneous CPU+GPU parallelization for high-accuracy scale-resolving simulations of compressible turbulent flows on hybrid supercomputers // Computer Physics Communications 2021. 108231. https://doi.org/10.1016/j.cpc.2021.10823
• A. Gorobets. Parallel Algorithm of the NOISEtte Code for CFD and CAA Simulations. Lobachevskii Journal of Mathematics. 2018, Vol. 39, No. 4, pp. 524–532. https://doi.org/10.1134/S1995080218040078

• A. V. Gorobets, S. A. Soukov,A. R. Magomedov. Heterogeneous Parallel Implementation of a Multigrid Method with Full Approximation in the NOISEtte Code // Mathematical Models and Computer Simulations, 2024, 16 (4), 609–619. https://doi.org/10.1134/S2070048224700261
• A. V. Gorobets. An Approach to the Implementation of the Multigrid Method with Full Approximation for CFD Problems // Computational Mathematics and Mathematical Physics, 2023, 63 (11), 2150–2161. https://doi.org/10.1134/S0965542523110106

Problem-oriented solutions

Helicopters and rotors

• I.V. Abalakin, V.G. Bobkov, T.K. Kozubskaya, A.V. Lipatov. Modelling and Supercomputer Simulation of Hinged Rotor // Supercomputing Frontiers and Innovations, 2025, 12(1), pp. 73–93 PDF
• I.V. Abalakin, P.A. Bakhvalov, V.G. Bobkov, A.V. Gorobets. Parallel Algorithm for Flow Simulation in Rotor–Stator Systems Based on Edge-Based Schemes // Math. Models Comput. Simul., 2021, 13(1), 172–180. http://dx.doi.org/10.1134/S2070048221010026

Turbomachinery applications

• A. P. Duben, R.A.Zagitov, N. V. Shuvaev. Nonlinear Harmonics Method for Supercomputer Simulations of Fluid Dynamics in Turbomachines with Higher Accuracy on Unstructured Meshes // Lobachevskii Journal of Mathematics, 2024, Vol. 45, No. 7, pp. 3017–3026. PDF
• Alexey Duben, Andrey Gorobets, Sergey Soukov, Olga Marakueva, Nikolay Shuvaev, Renat Zagitov. Supercomputer Simulations of Turbomachinery Problems with Higher Accuracy on Unstructured Meshes // LNCS 13708, pp. 356–367, 2022. PDF
• More turbomachinery publications

Other references

• A. Gorobets, A. Duben, V. Sapozhnikov. GPU Implementation of Turbulence Modeling Features for High-Fidelity Supercomputer Simulations // RuSCDays 2025, LNCS 16196, pp. 1-15, 2026.
• A. Gorobets, N. Zhdanova, V. Bobkov. Towards Industrial Applicability of CFD Methodology for Massively-Parallel Hybrid Systems // Mathematical Models and Computer Simulations, 2025 (in press)
• Alexey P. Duben, Andrey V. Gorobets. Application-Specific Parallel Linear Solver for Nonlinear Harmonics Method with Implicit Time Integration // Supercomputing Frontiers and Innovations, 12(1), 60–72, 2025 PDF
• A. Gorobets, P. Bakhvalov, A. Duben, P. Rodionov. Acceleration of NOISEtte Code for Scale-resolving Supercomputer Simulations of Turbulent Flows. Lobachevskii Journal of Mathematics. Vol 41, No 8, pp. 1463–1474, 2020. https://doi.org/10.1134/S1995080220080077
• A. Gorobets, P. Bakhvalov. Improving Reliability of Supercomputer CFD Codes on Unstructured Meshes. Supercomputing Frontiers and Innovations. 2019. Vol. 6, No. 4, pp. 44-56. http://dx.doi.org/10.14529/jsfi190403
• A. V. Gorobets, M. I. Neiman-Zade, S. K. Okunev, A. A. Kalyakin, S. A. Soukov. Performance of Elbrus-8C Processor in Supercomputer CFD Simulations. Mathematical Models and Computer Simulations. 2019. vol. 11. pp. 914–923. https://doi.org/10.1134/S2070048219060073
• Bakhvalov Pavel, Kozubskaya Tatiana. EBR-WENO scheme for solving gas dynamics problems with discontinuities on unstructured meshes. Computers and Fluids. 2017. Vol. 157, p. 312-324. https://doi.org/10.1016/j.compfluid.2017.09.004
• Bakhvalov Pavel, Abalakin Ilya, Kozubskaya Tatiana. Edge-based reconstruction schemes for unstructured tetrahedral meshes. International Journal for Numerical Methods in Fluids. 2016. Vol.81(6). P. 331–356. https://doi.org/10.1002/fld.4187
• Gorobets Andrey. Parallel technology for numerical modeling of fluid dynamics problems by high-accuracy algorithms. Computational Mathematics and Mathematical Physics. 2015. Vol. 55(4). P. 638-649. https://doi.org/10.1134/S0965542515040065
• Абалакин И.В., Бахвалов П.А., Горобец А.В., Дубень А.П., Козубская Т.К., Параллельный программный комплекс NOISETTE для крупномасштабных расчетов задач аэродинамики и аэроакустики, Вычислительные методы и программирование. т.13 (2012), стр. 110-125. (PDF)
  

Applications:

• Alexey P. Duben, Viacheslav A. Sapozhnikov, Methodology for Scale-Resolving Simulation of Unsteady Effects in Turbomachines // Supercomputing Frontiers and Innovations, 12(1), 94–111, 2025 PDF
• Alexey Duben, Andrey Gorobets Scale-resolving simulation of a low-pressure turbine on hybrid supercomputers // Computers & Fluids, Vol. 265, 2023, 105984 PDF
• O.V. Marakueva, A.P. Duben. Accuracy of flow simulation in a low-pressure turbine using a laminar-turbulent transition model // St. Petersburg Polytechnic University Journal. Physics and Mathematics. 2023. Vol. 16. No. 1.1 PDF
• S.M. Bosniakov, A.V. Wolkov, A.P. Duben, V.I. Zapryagarev, T.K. Kozubskaya, S.V. Mikhaylov, A.I. Troshin, V.O. Tsvetkova. Comparison of two higher accuracy unstructured scale-resolving approaches applied to dual-stream nozzle jet simulation. Math. Mod. and Comp. Simul.(2020) 12, 368–377. http://doi.org/10.1134/S2070048220030102
• I.V. Abalakin , V.G. Bobkov, T.K. Kozubskaya, V.A. Vershkov, B.S. Kritsky, R.M. Mirgazov, Numerical Simulation of Flow around Rigid Rotor in Forward Flight. Fluid Dynamics, 2020, Vol. 55, No. 4, pp. 534–544. http://doi.org/10.1134/s0015462820040011
• S.M. Bosnyakov, A.P. Duben, A.A. Zheltovodov, T.K. Kozubskaya, S.V. Matyash, S.V. Mikhailov. Numerical simulation of supersonic separated flow over inclined backward-facing step using RANS and LES methods. Math. Mod. and Comp. Simul. 2020. 12. 453-463. https://doi.org/10.1134/S2070048220040043
• Дубень А.П., Жданова Н.С., Козубская Т.К. Численное исследование влияния дефлектора на аэродинамические и акустические характеристики турбулентного течения в каверне. Известия Российской академии наук. Механика жидкости и газа. 2017, № 4, C. 1–12. DOI:10.7868/S0568528117040107
• Duben Alexey, Kozubskaya Tatiana. Jet Noise Simulation Using Quasi-1D Schemes on Unstructured Meshes. AIAA AVIATION Forum 5-9 June 2017, Denver, Colorado 23rd AIAA/CEAS Aeroacoustics Conference. DOI:10.2514/6.2017-3856
• Абалакин И.В., Аникин В.А., Бахвалов П.А., Бобков В.Г., Козубская Т.К. Численное исследование аэродинамических и акустических свойств винта в кольце. Известия Российской академии наук. Механика жидкости и газа. 2016. №3. С. 130-145.
  Abalakin Ilya, Anikin Viktor, Bakhvalov Pavel, Bobkov Vladimir, Kozubskaya Tatiana. Numerical Investigation of the Aerodynamic and Acoustical Properties of a Shrouded Rotor. Fluid Dynamics. 2016. Vol. 51(3). P. 419-433. DOI:10.1134/S0015462816030145
• Даньков Б.Н., Дубень А.П., Козубская Т.К. Численное моделирование возникновения автоколебательного процесса возле трехмерного обратного уступа при трансзвуковом режиме обтекания. Известия Российской академии наук. Механика жидкости и газа. 2016. N 4. С. 108-119.
  Dankov Boris, Duben Alexey, Kozubskaya Tatiana. Numerical modeling of the self-oscillation onset near a three-dimensional backward-facing step in a transonic flow. Fluid Dynamics. July 2016, Vol. 51(4), pp 534–543. DOI: 10.1134/S001546281604013X
• Dankov Boris, Duben Alexey, Kozubskaya Tatiana. Numerical simulation of the transonic turbulent flow around a wedge-shaped body with a backward-facing step. Mathematical Models and Computer Simulations. 2016 Vol.8(3), pp. 274–284. doi:10.1134/S2070048216030054.