Authors: Kasthurirangan Gopalakrishnan, Marshall R. Thompson, Anshu Manik

Abstract:

This paper describes the use of artificial neural networks (ANN) for predicting non-linear layer moduli of flexible airfield pavements subjected to new generation aircraft (NGA) loading, based on the deflection profiles obtained from Heavy Weight Deflectometer (HWD) test data. The HWD test is one of the most widely used tests for routinely assessing the structural integrity of airport pavements in a non-destructive manner. The elastic moduli of the individual pavement layers backcalculated from the HWD deflection profiles are effective indicators of layer condition and are used for estimating the pavement remaining life. HWD tests were periodically conducted at the Federal Aviation Administration-s (FAA-s) National Airport Pavement Test Facility (NAPTF) to monitor the effect of Boeing 777 (B777) and Beoing 747 (B747) test gear trafficking on the structural condition of flexible pavement sections. In this study, a multi-layer, feed-forward network which uses an error-backpropagation algorithm was trained to approximate the HWD backcalculation function. The synthetic database generated using an advanced non-linear pavement finite-element program was used to train the ANN to overcome the limitations associated with conventional pavement moduli backcalculation. The changes in ANN-based backcalculated pavement moduli with trafficking were used to compare the relative severity effects of the aircraft landing gears on the NAPTF test pavements.

Keywords: Airfield pavements, ANN, backcalculation, newgeneration aircraft

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1084592

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References:

[1] R. G. Hicks, "Factors influencing the resilient properties of granular materials," Ph.D. dissertation, Univ. of California, Berkeley, 1970.
[2] M. R. Thompson and Q. L. Robnett, "Resilient properties of subgrade soils," ASCE Transportation Engineering Journal, vol. 105, no. TE1, 1979.
[3] L. Raad and J. L. Figueroa, "Load response of transportation support systems," ASCE Transportation Engineering Journal, vol 16, no. TE1, 1980.
[4] H. Ceylan, "Analysis and design of concrete pavement systems using artificial neural networks," Ph.D. dissertation, Univ. of Illinois at Urbana-Champaign, December, 2002.
[5] R. W. Meir and G. J. Rix, "Backcalculation of flexible pavement moduli from dynamic deflection basins using artificial neural networks," Transportation Research Record no. 1473, TRB, 1995, pp. 72-81.
[6] N. Gucunski and V. Krstic, "Backcalculation of pavement profiles from spectral analysis of surface waves test by neural networks using individual receiver spacing approach," Transportation Research Record no. 1526, TRB, 1996, pp. 6-13.
[7] L. Khazanovich and J. Roesler, "DIPLOBACK: neural-network based backcalculation program for composite pavements," Transportation Research Record no. 1570, TRB, 1997, pp. 143-150.
[8] Y. Kim and R. Y. Kim, "Prediction of layer moduli from falling weight deflectometer and surface wave measurements using artificial neural network," Transportation Research Record no. 1570, 1997, pp. 143-150.
[9] R. W. Meier and G. J. Rix, "Backcalculation of flexible pavement moduli using artificial neural networks," in Proc. 73rd Annual Meeting of the Transportation Research Board, Washington, D.C., 1993
[10] H. Ceylan, A. Guclu, E. Tutumluer, and M. R. Thompson, "Backcalculation of full-depth asphalt pavement layer moduli considering nonlinear stress-dependent subgrade behavior," International Journal of Pavement Engineering, vol. 6, no. 3, 2005, pp. 171-182.
[11] Gopalakrishnan, K., "Performance analysis of airport flexible pavement subjected to new generation aircraft," Ph.D. Dissertation, University of Illinois at Urbana-Champaign, December, 2004.
[12] G. Rada and M. W. Witczak, "Comprehensive evaluation of laboratory resilient moduli results for granular material," Transportation Research Record no. 810, TRB, 1970.
[13] M. R. Thompson and R. P. Elliot, "ILLI-PAVE based response algorithms for design of conventional flexible pavements," Transportation Research Record no. 1043, TRB, 1985.
[14] D. E. Rumelhart, G. E. Hinton, and R. J. Williams, "Learning internal representation by error propogation," in Rumelhart, D.E. eds, Parallel Distributed Processing, MIT Press, Cambridge, MA, 1986, pp. 318-362.
[15] H. Adeli and S. L. Hung, Machine learning: neural networks, genetic algorithms, and fuzzy systems. Wiley, New York, 1995.
[16] S. Haykin. Neural networks: A comprehensive foundation.Prentice-Hall Inc., NJ, USA, 1999.
[17] H. Adeli, "Neural Networks in civil engineering: 1989-2000," Computer-Aided Civil and Infrastructure Engineering, vol. 16, 2001, pp. 126-142.
[18] S. M. Hossain and J. P. Zaniewski, "Characterization of falling weight deflectometer deflection basin," Transportation Research Record no. 1293, TRB, 1991, pp. 1-11.
[19] B. Xu, S. R. Ranjithan, and Y. R. Kim, "Development of relationships between FWD deflections and asphalt pavement layer condition indicators," in Proc., 81st Annual Meeting of the Transportation Research Board, Washington, D.C., 2001.
[20] E. L. Gervais, G. F. Hayhoe, and N. Garg, "Towards a permanent ACN solution for 6-wheel landing gear aircraft," in Proc., 2003 ASCE Airfield Pavement Specialty Conference, Las Vegas, NV, 2003.
[21] G. H. Hayhoe, "LEAF - A new layered elastic computational program for FAA pavement design and evaluation procedures," in Proc., 2002 Federal Aviation Administration Technology Transfer Conference, Chicago, IL, 2002.
[22] R. D. McQueen, W. Marsey, and J. M. Arze, "Analysis of nondestructive data on flexible pavement acquired at the national airport pavement test facility," in Proc., 2001 Airfield Pavement Specialty Conference, ASCE, Chicago, IL, 2001.