[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12989/was.2016.23.4.367

Mathematical explanation on the POD applications for wind pressure fields with or without mean value components

Zhang, Jun-Feng (School of Civil Engineering, Zhengzhou University)
Ge, Yao-Jun (State Key Laboratory for Disaster Reduction in Civil Engineering, Tongji University)
Zhao, Lin (State Key Laboratory for Disaster Reduction in Civil Engineering, Tongji University)
Chen, Huai (School of Civil Engineering, Zhengzhou University)

Publication Information

Wind and Structures / v.23, no.4, 2016 , pp. 367-383 More about this Journal

Abstract

The influence mechanism of mean value components, noted as $P_0$ , on POD applications for complete random fields $P_C(t)$ and fluctuating random fields $P_F(t)$ are illustrated mathematically. The critical philosophy of the illustration is introduction of a new matrix, defined as the correlation function matrix of $P_0$ , which connect the correlation function matrix of $P_C(t)$ and $P_F(t)$ , and their POD results. Then, POD analyses for several different wind pressure fields were presented comparatively as validation. It's inevitable mathematically that the first eigenmode of $P_C(t)$ resembles the distribution of $P_0$ and the first eigenvalue of $P_C(t)$ is close to the energy of $P_0$ , due to similarity of the correlation function matrixs of $P_C(t)$ and $P_0$ . However, the viewpoint is not rigorous mathematically that the first mode represents the mean pressure and the following modes represent the fluctuating pressure when $P_C(t)$ are employed in POD application. When $P_C(t)$ are employed, POD results of all modes would be distorted by the mean value components, and it's impossible to identify $P_0$ and $P_F(t)$ separately. Consequently, characteristics of the fluctuating component, which is always the primary concern in wind pressure field analysis, can only be precisely identified with $P_0$ excluded in POD.

Keywords

POD; influence mechanism; mean value components; complete fields; fluctuating fields; eigenmodes; eigenvalues;

Citations & Related Records

Times Cited By KSCI : 5 (Citation Analysis)

Reference
Cited By KSCI

1	Cheng, L., Lam, K.M. and Wong, S.Y. (2015), "POD analysis of crosswind forces on a tall building with square and H-shaped cross sections", Wind Struct., 21(1), 63-84. DOI
2	Davenport, A.G. (1995), "How can we simplify and generalize wind loads?", J. Wind Eng. Ind. Aerod., 54-55, 657-669. DOI
3	Fiore, A. and Monaco, P. (2009), "POD-based representation of the alongwind equivalent static force for long-span bridges", Wind Struct., 12(3), 239-257. DOI
4	Hoa, L.T. (2009), "Proper orthogonal decomposition and recent advanced topics in wind engineering", VNU J. Science, Mathematics - Physics, 25(1), 21-38.
5	Holmes, J.D. (1990), "Analysis and synthesis of pressure fluctuations on bluff bodies using eigenvectors", J. Wind Eng. Ind. Aerod., 33(1-2), 219-230. DOI
6	Holmes, J.D., Sankaran, R., Kwok, K.C.S. and Syme, M.J. (1997), "Eigenvector modes of fluctuating pressures on low-rise building models", J. Wind Eng. Ind. Aerod., 69-71, 697-707. DOI
7	Jeong, S.H., Bienkiewicz B. and Ham, H.J. (2000), "Proper orthogonal decomposition of building wind pressure specified at non-uniformly distributed pressure taps", J. Wind Eng. Ind. Aerod., 87(1), 1-14. DOI
8	Kareem, A. and Cermak, J.E. (1984), "Pressure fluctuations on a square building model in boundary-layer flows", J. Wind Eng. Ind. Aerod., 16(1), 1753-1763.
9	Kikuchi, H., Tamura, Y., Ueda, H. and Hibi, K. (1997), "Dynamic wind pressures acting on a tall building model - proper orthogonal decomposition", J. Wind Eng. Ind. Aerod., 69-71, 631-646. DOI
10	Letchford, C.W. and Mehta, K.C. (1993), "The distribution and correlation of fluctuating pressures on the Texas Tech Building", J. Wind Eng. Ind. Aerod., 50(1-3), 225-234. DOI
11	Tubino, F. and Solari, G. (2007), "Gust buffeting of long span bridges: Double Modal Transformation and effective turbulence", Eng. Struct., 29(8), 1689-1707.
12	Uematsu, Y., Kuribara, O., Yamada, M., Sasaki, A. and Hongo, T. (2001), "Wind-induced dynamic behavior and its load estimation of a single-layer latticed dome with a long span", J. Wind Eng. Ind. Aerod., 89(14-15), 1671-1687. DOI
13	Wang, L., Wang, Y., Li, Z.Q. and Zhang, Y. (2010), "Estimation of the vortex shedding frequency of a 2-D building using correlation and the POD methods", J. Wind Eng. Ind. Aerod., 98(12), 895-902. DOI
14	Baker, C.J. (2000), "Aspects of the use of proper orthogonal decomposition of surface pressure fields", Wind Struct., 3(2), 97-115. DOI
15	Bienkiewicz, B., Ham, H.J. and Sun, Y. (1993), "Proper orthogonal decomposition of roof pressure", J. Wind Eng. Ind. Aerod., 50(1-3), 193-202. DOI
16	Bienkiewicz, B., Tamura, Y., Ham, H.J., Ueda, H. and Hibi, K. (1995), "Proper orthogonal decomposition and reconstruction of multi-channel roof pressure", J. Wind Eng. Ind. Aerod., 54-55, 369-381. DOI
17	Carassale, L., Solari, G. and Tubino, F. (2007), "Proper orthogonal decomposition in wind engineering. Part 2: Theoretical aspects and some applications", Wind Struct., 10(2), 177-208. DOI
18	Chatterjee, A. (2000), "An introduction to proper orthogonal decomposition", Current Sci., 78(7), 808-817.
19	Chen, M.Y., Zhang, J.S. and Zhou, G.G. (2011), "Application of proper orthogonal decomposition technique in wind engineering of structures", Adv. Mater. Res., 250-253, 2678-2681. DOI
20	Chen, Y., Kopp, G.A. and Surry, D. (2004), "Spatial extrapolation of pressure time series on low buildings using proper orthogonal decomposition", Wind Struct., 7(6), 373-392. DOI
21	Lumley, J.L. (1970), Stochastic Tools in Turbulence, New York, Academic Press.
22	Li, F.H., Gu, M., Ni, Z.H. and Shen S.Z. (2012), "Wind pressures on structures by proper orthogonal decomposition", J. Civil Eng. Architecture, 6(2), 238-243.
23	Liang, Y.C., Lee, H.P., Lim, S.P., Lin, W.Z., Lee, K.H. and Wu, C.G. (2002), "Proper orthogonal decomposition and its applications-Part I: Theory", J. Sound Vib., 252(3), 527-544. DOI
24	Loeve, M. (1978), Probability Theory II (4th Edn.), New York, Springer-Verlag.
25	Ricciardelli, F., de Grenet, E.T. and Solari G. (2002), "Analysis of the wind loading of a bridge deck box section using proper orthogonal decomposition", Int. J. Fluid Mech. Res., 29(3-4), 312-322.
26	Solari, G. and Tubino, F. (2002), "A turbulence model based on principal components", Probabilist. Eng. Mech., 17(4), 327-335. DOI
27	Solari, G., Carassale, L. and Tubino, F. (2007), "Proper orthogonal decomposition in wind engineering. Part 1: A state-of-the-art and some prospects", Wind Struct., 10(2), 153-176. DOI
28	Tamura, Y., Suganuma, S., Kikuchi, H. and Hibi, K. (1999), "Proper orthogonal decomposition of random wind pressure field", J. Fluid. Struct., 13(7-8), 1069-1095. DOI
29	Tamura, Y., Ueda, H., Kikuchi, H., Hibi, K., Suganuma, S. and Bienkiewicz, B. (1997), "Proper orthogonal decomposition study of approach wind-building pressure correlation", J. Wind Eng. Industrial Aerodynamics, 72(1-3): 421-431. DOI
30	Taylor, J.A. and Glauser, M.N. (2004), "Towards practical flow sensing and control via POD and LSE based low-dimensional tools", J. Fluids Eng. T. - ASME, 126(3), 337-345. DOI

7	(2020) Physics of fluids Statistical and modal analysis of surface pressure fluctuations in tornado-like vortices / 32 (7) , 075109
3	(2016) Wind & structures Effect of aerodynamic modifications on the surface pressure patterns of buildings using proper orthogonal decomposition / 32 (3) , 227