Study on Optimum Multi-Parameter Growth Functions of Deformation Prediction for Loess Tunnel Initial Structure

Fang Biao Liu; Shun Chuan Wu; Jian Li; Jie Hu

doi:10.4028/www.scientific.net/AMM.170-173.1769

Paper Titles

Simulation Method of Tunnel Excavation under Plane Strain Condition
p.1753

Study on Stabilization of Tunnel Foundations Built on Collapsible Loess
p.1757

Study on the System of Multi-Directioncal Inclined Modular Anchorage in the Tunnel Surrounding Rock of Horizontal Bedded
p.1761

Influence of Overlying Soil on Dynamic Response of Underground Structure
p.1765

Study on Optimum Multi-Parameter Growth Functions of Deformation Prediction for Loess Tunnel Initial Structure
p.1769

Simulation and Parameter Inversion on Dalian Metro
p.1773

Design and Application of Secondary High-Capacity Support to Large-Section Tunnel Excavated in High-Stress Condition with Fractured Surrounding Rock
p.1777

Field Monitoring of Segments Deformation during Metro-Station Construction Based on Shield Tunneling
p.1785

Correlation between Underground Space Intensity and Land-Use Transport Interaction
p.1790

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 170-173Study on Optimum Multi-Parameter Growth Functions...

Study on Optimum Multi-Parameter Growth Functions of Deformation Prediction for Loess Tunnel Initial Structure

Abstract:

Initial structure deformation prediction based on the regression analysis is an important means to evaluate the stability of tunnel, but the commonly used regression functions, such as exponential, logarithmic and hyperbolic function, have disadvantages of low accuracy. Aiming at the drawbacks, 3 kinds of multi-parameter growth functions (Weibull growth function, Richard function and Gompertz growth function) and 3 kinds of commonly used functions (exponential, logarithmic and hyperbolic function) are used to conduct the regression analysis for a loess tunnel’s initial structure in north-west China. Comparison results show that, (1) regressions based on multi-parameter growth functions are far more precise than the commonly used functions, reflecting its superiority in initial structure deformation prediction of the loess tunnel, (2) the more coefficients the function have, the higher the regression correlation is, and (3) the similarity of iterative and error analysis algorithm in different multi-parameter growth functions lays foundations for computer programming realization of regression analysis and model selection automation.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volumes 170-173)

Pages:

1769-1772

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.170-173.1769

Citation:

Cite this paper

Online since:

May 2012

Authors:

Fang Biao Liu, Shun Chuan Wu, Jian Li, Jie Hu

Keywords:

Deformation Prediction, Initial Structure, Loess tunnel, Multi-Parameter Growth Function, Regression Analysis

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] Villy A Kontogianni and Stathis C Stiros: Engineering Geology Vol. 63 (2002), p.333.

Google Scholar

[2] Shinichi Akutagawa, Jaeho Lee, Naki Doba, Takashi Kitagawa, Atsumi Isogai and Takeshi Matsunaga: Tunnelling and Underground Space Technology Vol. 21 (2006), p.387.

DOI: 10.1016/j.tust.2005.12.198

Google Scholar

[3] Karmen Fifer Bizjak and Borut Petkovsek: Engineering Geology Vol. 75 (2004), p.89.

Google Scholar

[4] Zhenchang Guan, Yujing Jiang and Yoshihiko Tanabashi: Tunnelling and Underground Space Technology Vol. 24 (2009), p.250.

Google Scholar

[5] Yunhua Zhu, Xinrong Liu and Minghao Huang: Rock and Soil Mechanics Vol. 30 (2009), p.805 (in Chinese).

Google Scholar

[6] Guangzhi Yin, Shun Yue and Tao Zhong: Rock and Soil Mechanics Vol. 30(2009), p.2727 (in Chinese).

Google Scholar

[7] Guowei Li, Tao Yang and Jiangbo Song: Journal of highway and transportation research and development Vol. 20(2003) (in Chinese).

Google Scholar

[8] Shoubin Luo: Journal of Guizhou University(Natural Science Edition) Vol. 2(2010), p.127 (in Chinese).

Google Scholar

[9] Xiuli Wang: Water Resources and Power Vol. 6(2011), p.124 (in Chinese).

Google Scholar