[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12989/sss.2019.23.3.295

Investigation of the SHM-oriented model and dynamic characteristics of a super-tall building

Xiong, Hai-Bei (Department of Disaster Mitigation for Structures, Tongji University)
Cao, Ji-Xing (Department of Disaster Mitigation for Structures, Tongji University)
Zhang, Feng-Liang (School of Civil and Environmental Engineering, Harbin Institute of Technology (HIT))
Ou, Xiang (East China Region of Tahoe (Group) Co. Ltd.)
Chen, Chen-Jie (Shanghai Architectural Design & Research (Co., Ltd.))

Publication Information

Smart Structures and Systems / v.23, no.3, 2019 , pp. 295-306 More about this Journal

Abstract

Shanghai Tower is a 632-meter super high-rise building located in an area with wind and active earthquake. A sophisticated structural health monitoring (SHM) system consisting of more than 400 sensors has been built to carry out a long-term monitoring for its operational safety. In this paper, a reduced-order model including 31 elements was generated from a full model of this super tall building. An iterative regularized matrix method was proposed to tune the system parameters, making the dynamic characteristic of the reduced-order model be consistent with those in the full model. The updating reduced-order model can be regarded as a benchmark model for further analysis. A long-term monitoring for structural dynamic characteristics of Shanghai Tower under different construction stages was also investigated. The identified results, including natural frequency and damping ratio, were discussed. Based on the data collected from the SHM system, the dynamic characteristics of the whole structure was investigated. Compared with the result of the finite element model, a good agreement can be observed. The result provides a valuable reference for examining the evolution of future dynamic characteristics of this super tall building.

Keywords

super high-rise building; reduced-order model; regularization matrix method; dynamic characteristics; modal identification;

Citations & Related Records

Times Cited By KSCI : 1 (Citation Analysis)

Reference
Cited By KSCI

1	Craig, R.R., and Kurdila, A.J. (2006), Fundamentals of structural dynamics, John Wiley & Sons.
2	Davenport, A.G. (1986), "Damping in tall buildings: Its variability and treatment in design", Building Motion in Wind, 42-57.
3	Downs, B. (1980), "Accurate reduction of stiffness and mass matrices for vibration analysis and a rationale for selecting master degrees of freedom", Mech. Des-T Asme, 102(2), 412-416. DOI
4	Flanigan, C.C. (1991), "Development of the Irs component dynamic reduction method for substructure analysis", Proceedings of the 32nd Structures, Structural Dynamics, and Materials Conference.
5	Rezghi, M. and Hosseini, S.M. (2009), "A new variant of L-curve for Tikhonov regularization", Comput. Appl. Math., 231(2), 914-924. DOI
6	Rutzmoser, J.B., Rixen, D.J., Tiso, P. and Jain, S. (2017), "Generalization of quadratic manifolds for reduced order modeling of nonlinear structural dynamics", Comput. Struct., 192, 196-209. DOI
7	Satake, N., Suda, K., Arakawa, T., Sasaki, A. and Tamura, Y. (2003), "Damping Evaluation Using Full-Scale Data of Buildings in Japan", J. Struct. Eng., 129(4), 470-477. DOI
8	Smith, R.J. and Willford, M.R. (2007), "The damped outrigger concept for tall buildings", Struct. Des. Tall Spec., 16(4), 501-517. DOI
9	Su, J.Z., Xia, Y. and Chen, L. (2013), "Long-term structural performance monitoring system for the Shanghai Tower", J. Civil Struct. Health. Monit., 3(1), 49-61. DOI
10	Spence, S.M.J., Bernardini, E., Guo, Y., Kareem, A. and Gioffre, M. (2014a), "Natural frequency coalescing and amplitude dependent damping in the wind-excited response of tall buildings", Probabilist. Eng. Mech., 35(6), 108-117. DOI
11	Spence, S.M.J. and Kareem, A. (2014b), "Tall buildings and damping: a concept-based data-driven model", J. Struct. Eng., 140(5),
12	Wang, J. and Yang, Q.S. (2012), "Modified tikhonov regularization in model updating for damage identification", Struct. Eng. Mech., 44(5), 585-600. DOI
13	GB50011-2010. (2010), Code for Seismic Design of Building, Ministry of Construction of the People's Republic of China, Beijing, China.
14	Friswell, M.I., Mottershead, J.E. and Ahmadian, H. (2001), "Finite-element model updating using experimental test data: parametrization and regularization", Philos. T. Roy. Soc. A, 359(1778), 169-186. DOI
15	Huang, M.J. (2006), "Utilization of strong-motion records for post-earthquake damage assessment of buildings", Proceedings of the international workshop on structural health monitoring and damage assessment.
16	Hansen, P.H. (2001), "The L-curve and its use in the numerical treatment of inverse problems", invited chapter, in: P. Johnston (Ed.), Computational Inverse Problems in Electrocardiology, WIT Press, Southampton.
17	Guo, Y.L., Kareem, A., Ni, Y.Q. and Liao, W.Y. (2012), "Performance evaluation of Canton Tower under winds based on full-scale data", J. Wind Eng. Ind. Aerod., 104, 116-128. DOI
18	Jain, S., Tiso, P., Rutzmoser, J.B. and Rixen, D.J. (2017), "A quadratic manifold for model order reduction of nonlinear structural dynamics", Comput. Struct., 188, 80-94. DOI
19	Yin, T., Jiang, Q.H. and Yuen, K.V. (2017), "Vibration-based damage detection for structural connections using incomplete modal data by Bayesian approach and model reduction technique", Eng. Struct., 132, 260-277. DOI
20	Xiong, H.B., Cao, J.X. and Zhang, F.L. (2018), "Inclinometerbased method to monitor displacement of high-rise buildings", Struct. Monit. Maint., 5(1), 111-127. DOI
21	Zhang, F.L., Xiong, H.B., Shi, W.X. and Ou, X. (2016b), "Structural health monitoring of Shanghai Tower during different stages using a Bayesian approach", Struct. Control Health., 23(11), 1366-1384. DOI
22	Yi, J., Zhang, J.W. and Li, Q.S. (2013), "Dynamic characteristics and wind-induced responses of a super-tall building during typhoons", J. Wind Eng. Ind. Aerod., 121, 116-130. DOI
23	Yi, T.H., Li, H.N. and Gu, M. (2013), "Recent research and applications of GPS-based monitoring technology for high-rise structures", Struct. Control Health., 20(5), 649-670. DOI
24	Zhang, F.L., Ni, Y.Q., Ni, Y.C. and Wang, Y.W. (2016a), "Operational modal analysis of Canton Tower by a fast frequency domain Bayesian method", Smart Struct. Syst., 17(2), 209-230. DOI
25	Zhang, F.L., Ni, Y.C. and Lam, H.F. (2017). "Bayesian structural model updating using ambient vibration data collected by multiple setups", Struct. Control Health., 24(12), e2023. DOI
26	Zhang, F.L., Ventura, C.E., Xiong, H.B., Lu, W.S., Pan, Y.X. and Cao, J.X. (2018), "Evaluation of the dynamic characteristics of a super tall building using data from ambient vibration and shake table tests by a Bayesian approach", Struct. Control Health., 25(2), e2121. DOI
27	Lagomarsino, S. (1993), "Forecast models for damping and vibration periods of buildings", J. Wind Eng. Ind. Aerod., 48(2-3), 221-239. DOI
28	Jeary, A.P. (1986), "Damping in tall buildings-a mechanism and a predictor", Earthq. Eng. Struct., 14(5), 733-750. DOI
29	Kerschen, G., Golinval, J.C., Vakakis, A.F. and Bergman, L.A. (2005), "The method of proper orthogonal decomposition for dynamical characterization and order reduction of mechanical systems: An overview", Nonlinear Dynam., 41(1-3), 147-169. DOI
30	Kijewski-Correa, T.L. and Kareem, A. (2003), "The Chicago monitoring project: a fusion of information technologies and advanced sensing for civil infrastructure". Struct. Health. Monit. Intell. Infrastr., 1(2), 1003-1010.
31	Li, B. and Kiureghian, A.D. (2017), "Operational modal identification using variational Bayes", Mech. Syst. Signal Pr., 88, 377-398. DOI
32	Ng, C.T. and Au, S.K. (2018), "Mode shape scaling and implications in modal identification with known input", Eng. Struct., 156, 411-416. DOI
33	Ni, Y.C., Lu, X.L. and Lu, W.S. (2017), "Operational modal analysis of a high-rise multi-function building with dampers by a Bayesian approach", Mech. Syst. Signal Pr., 86, 286-307. DOI
34	Ni, Y.C., Zhang, Q.W. and Liu, J.F. (2019), "Dynamic property evaluation of a long-span cable-stayed bridge (Sutong Bridge) by a Bayesian method", Int. J. Struct. Stability Dynam., 19(1), 1940010. DOI
35	Ni, Y.C. and Zhang, F.L. (2016), "Bayesian operational modal analysis of a pedestrian bridge using a field test with multiple setups", Int. J. Struct. Stability Dynam., 16(8), 1550052. DOI
36	Ni, Y.C. and Zhang, F.L.(2018), "Fast Bayesian approach for modal identification using forced vibration data considering the ambient effect", Mech. Syst. Signal Pr., 105, 113-128. DOI
37	Au, S.K. (2017), Operational Modal Analysis Modeling, Bayesian Inference, Uncertainty Laws. Springer.
38	Abdelrazaq, A., Amp, H. and Camp, S. (2012), "Validating the structural behavior and response of Burj Khalifa: Full scale structural health monitoring programs", Build. Struct., 44(5), 87-97.
39	Amabili, M., Sarkar, A. and Paidoussis, M.P. (2003), "Reducedorder models for nonlinear vibrations of cylindrical shells via the proper orthogonal decomposition method", Fluid. Struct., 18(2), 227-250. DOI
40	Aquino, R. E. and Tamura, Y. (2011), "Damping based on EPP spring models of stick-slip surfaces", Proceedings of the International Conference on Wind Engineering.
41	Au, S.K. and Zhang, F.L. (2016), "Fundamental two-stage formulation for Bayesian system identification, Part I: general theory", Mech. Syst. Signal Pr., 66-67, 31-42. DOI
42	Au, S.K., Zhang, F.L. and To, P. (2012), "Field observations on modal properties of two tall buildings under strong wind". J. Wind Eng. Ind. Aerod., 101(101), 12-23. DOI
43	Clough, R.W. and Penzien, J. (1995), Dynamics of Structures, Computers & Structures Inc.
44	Brincker, R., Zhang, L. and Andersen, P. (2001), "Modal identification of output-only systems using frequency domaindecomposition", Smart Mater. Struct., 10(3), 44
45	Cao, L. and Li, C. (2019), "Tuned tandem mass dampers-inerters with broadband high effectiveness for structures under white noise base excitations", Struct. Control Health Monit., e2319. https://doi.org/ 10.1002/stc.2319 DOI
46	Chen, W.H., Lu, Z.R., Lin, W., Chen, S.H., Ni, Y.Q., Xia, Y. and Liao, W.Y. (2011), "Theoretical and experimental modal analysis of the Guangzhou New TV Tower", Eng Struct., 33(12), 3628-3646. DOI
47	Ni, Y.Q., Xia, Y., Lin, W., Chen, W.H. and Ko, J.M. (2012), "SHM benchmark for high-rise structures: a reduced-order finite element model and field measurement data", Smart Struct. Syst., 10(4-5), 411-426. DOI
48	Ni, Y.C. and Zhang, F.L.(2019), "Fast Bayesian approach for modal identification from seismic response data", Comput. Struct., 212, 225-235. DOI
49	Ni, Y.C., Zhang, F.L., Lam, H.F. and Au, S.K. (2016), "Fast Bayesian approach for modal identification using free vibration data, Part II-Posterior uncertainty and application", Mech. Syst. Signal Pr., 70, 221-244. DOI
50	Ni, Y.Q., Xia, Y., Liao, W.Y. and Ko, J.M. (2009), "Technology innovation in developing the structural health monitoring system for Guangzhou New TV Tower", Struct. Control Health, 16(1), 73-98. DOI
51	Osmancikli, G., Ucak, S., Turan, F.N., Turker, T. and Bayraktar, A. (2012), "Investigation of restoration effects on the dynamic characteristics of the Hagia Sophia bell-tower by ambient vibration test", Constr. Build. Mater., 29, 564-572. DOI
52	Peeters, B. and Roeck, G.D. (1999), "Reference-based stochastic subspace identifitcation for output-only modal analysis", Mech. Syst. Signal Pr., 13(6), 855-878. DOI
53	Papagiannopoulos, G.A. and Hatzigeorgiou, G.D. (2011), "On the use of the half-power bandwidth method to estimate damping in building structures", Soil Dyn. Earthq. Eng., 31(7), 1075-1079. DOI
54	Pastor, M., Binda, M. and Harcarik, T. (2012), "Modal assurance criterion", Modell. Mech. Mechatron. Syst., 48, 543-548.
55	Rahmani, M. and Todorovska, M.I. (2015), "Structural health monitoring of a 54-story steel-frame Building using a wave method and earthquake records", Earthq. Spectra., 31(1), 501-525. DOI