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High Accuracy Non-oscillatory Scheme with the Mean Value Theorem : 평균값 정리를 이용한 고정확도 보간기법
| DC Field | Value | Language |
|---|---|---|
| dc.contributor.advisor | 정인석 | - |
| dc.contributor.author | 성근민 | - |
| dc.date.accessioned | 2017-07-13T06:27:25Z | - |
| dc.date.available | 2017-07-13T06:27:25Z | - |
| dc.date.issued | 2016-08 | - |
| dc.identifier.other | 000000137427 | - |
| dc.identifier.uri | https://hdl.handle.net/10371/118567 | - |
| dc.description | 학위논문 (박사)-- 서울대학교 대학원 : 기계항공공학부, 2016. 8. 정인석. | - |
| dc.description.abstract | High order non-oscillatory interpolation is required for accurate computation. TVD property was introduced to limit the slope near the discontinuity and successfully suppress spurious oscillation | - |
| dc.description.abstract | it also limits slope near smooth extrema and introduces unphysical clipping. ENO scheme selects the smoothest stencil in order to exclude the spurious oscillation, easily would be extended to very high order | - |
| dc.description.abstract | selection of stencil would be affected by the very small error in continuous region. WENO scheme uses convex weighted sum of candidate stencils, could improve the accuracy. Weighted sum would introduce very fine oscillation in continuous region and such small error smears fine flow structures.
Suggested scheme obtained fourth order accuracy interpolation at each cell interfaces. Spurious oscillation of each polynomial was tested by mean value theorem of average or derivative of average. The smallest error stencil without oscillation was selected for each cell interface. High order spatial derivatives was obtained from selected polynomials. High accuracy numerical flux was computed from Lax-Wendroff procedure. The position of discontinuity was deduced from the continuity information of each stencil. The speed of discontinuity was obtained from material derivative of discontinuity. High accuracy numerical flux at the discontinuity was computed from tracing of discontinuity. Suggested scheme showed the fourth order accuracy form the numerical test and more accurate result than WENO scheme, because the suggested scheme use central fourth order interpolation at the smooth region and also it traces the discontinuity with fourth order accuracy. | - |
| dc.description.tableofcontents | Chapter 1 Introduction 1
Chapter 2 Brief about High Order Schemes 5 2.1 Hyperbolic Conservation Laws 5 2.2 Spurious Oscillation near a Discontinuity 6 2.3 Total Variation Diminishing (TVD) Property 8 2.4 Essentially non-Oscillatory Scheme (ENO) 9 2.5 Weighed Essentially non-Oscillatory Scheme (WENO) 10 2.6 Subcell Resolution 10 2.7 Runge-Kutta Time Integration 11 Chapter 3 Non-oscillatory Interpolation with Mean Value Theorem: MENO 13 3.1 Fourth Order Accuracy Interpolation 13 3.2 Compatibility with Matching Derivative 19 3.2.1 Matching of Cell Average (E0 Condition) 19 3.2.2 Matching of First Derivative (E1 Condition) 20 3.2.3 Matching of Second Derivative (E2 Condition) 21 3.3 Compatibility with Mean Value Theorem (MVT) 23 3.3.1 MVT on the Cell Average (M0 Condition) 23 3.3.2 MVT on the First Difference (M1 Condition) 25 3.3.3 MVT on the Second Difference (M2 Condition) 25 3.4 Criterion of the MVT Condition 26 3.4.1 Error of Reconstruction 26 3.4.2 Criterion of M0 Condition 29 3.4.3 Criterion of M1 Condition 29 3.4.4 Criterion of M2 Condition 30 3.5 Procedures for Determining Continuity 31 3.6 Selecting Stencil at Cell Interface 33 3.7 Sub-stencil for Low Order Polynomial 33 3.8 Reconstruction near a Discontinuity 34 3.9 Low Order Interpolation 35 3.10 Stability of Suggested Reconstruction 36 3.11 Procedure of Suggested Reconstruction 36 Chapter 4 High Accuracy Solution on Discontinuity 38 4.1 High Accuracy Flux Evaluation 38 4.1.1 Lax-Wendroff Procedure 38 4.1.2 Arbitrary High Order Godunov Approach (ADER) 40 4.2 Flux Evaluation near the Discontinuity 41 4.3 Exact Riemann Solver and Generalized Riemann Problem (GRP) 42 4.4 High Accuracy GRP for Scalar Conservation Law 43 4.4.1 Type of Discontinuity 43 4.4.2 High Accuracy Tracing of Shock Wave 44 4.4.3 High Accuracy Tracing of Expansion Wave 47 4.5 High Order GRP for the Euler Equation 48 4.5.1 The One Dimensional Euler Equation 48 4.5.2 Exact Riemann Solver for the Euler Equation 50 4.5.3 High Accuracy Tracing of Shock Wave 51 4.5.4 High Accuracy Tracing of Expansion Wave 53 Chapter 5 Numerical Test 54 5.1 Linear Equation: Sine Wave 54 5.2 Linear Equation: Half Sine Wave 61 5.3 Linear Equation: Square Wave 66 5.4 Linear Equation: Triangle Wave 72 5.5 Burgers Equation: Sine Wave 78 5.6 Euler Equation: Sods Shock Tube Problem 87 Chapter 6 Conclusion 90 Bibliography 92 초록 96 | - |
| dc.format | application/pdf | - |
| dc.format.extent | 5621281 bytes | - |
| dc.format.medium | application/pdf | - |
| dc.language.iso | en | - |
| dc.publisher | 서울대학교 대학원 | - |
| dc.subject | MENO | - |
| dc.subject | Mean Value Theorem | - |
| dc.subject | WENO | - |
| dc.subject | Discontinuity | - |
| dc.subject | Interpolation | - |
| dc.subject.ddc | 621 | - |
| dc.title | High Accuracy Non-oscillatory Scheme with the Mean Value Theorem | - |
| dc.title.alternative | 평균값 정리를 이용한 고정확도 보간기법 | - |
| dc.type | Thesis | - |
| dc.contributor.AlternativeAuthor | Kunmin Sung | - |
| dc.description.degree | Doctor | - |
| dc.citation.pages | viii, 96 | - |
| dc.contributor.affiliation | 공과대학 기계항공공학부 | - |
| dc.date.awarded | 2016-08 | - |
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