NDT and Structural Health Monitoring

 

[1] Ciampa, F. and Meo, M., 2011. Acoustic emission source localization in anisotropic structures with diffuse field conditions using a time reversal approach. Proceedings of SPIE - The International Society for Optical Engineering, 7984, 798416.

[2] De Angelis, G., Meo, M., Almond, D. P., Pickering, S. G. and Angioni, S. L., 2012. A new technique to detect defect size and depth in composite structures using digital shearography and unconstrained optimization. NDT & E International, 45 (1), pp. 91-96.

[3] Ciampa, F. and Meo, M., 2012. Impact detection in anisotropic materials using a time reversal approach. Structural Health Monitoring - An International Journal, 11 (1), pp. 43-49.

[4] Amerini, F. and Meo, M., 2011. Structural health monitoring of bolted joints using linear and nonlinear acoustic/ultrasound methods. Structural Health Monitoring, 10 (6), pp. 659-672.

[5] Amura, M., Meo, M. and Amerini, F., 2011. Baseline-free estimation of residual fatigue life using a third order acoustic nonlinear parameter. Journal of the Acoustical Society of America, 130 (4), pp. 1829-1837.

[6] Ciampa, F. and Meo, M., 2011. Acoustic emission localization in complex dissipative anisotropic structures using a one-channel reciprocal time reversal method. Journal of the Acoustical Society of America, 130 (1), pp. 168-175.

[7] Barbieri, E. and Meo, M., 2010. Time reversal DORT method applied to nonlinear elastic wave scattering. Wave Motion, 47 (7), pp. 452-467.

[8] Polimeno, U., Meo, M., Almond, D. and Angioni, S., 2010. Detecting low velocity impact damage in composite plate using nonlinear acoustic methods. Applied Composite Materials, 17 (5), pp. 481-488.

[9] Barbieri, E. and Meo, M., 2010. Discriminating linear from nonlinear elastic damage using a nonlinear time reversal DORT method. International Journal of Solids and Structures, 47 (20), pp. 2639-2652.

[10] Amerini, F., Barbieri, E., Meo, M. and Polimeno, U., 2010. Detecting loosening/tightening of clamped structures using nonlinear vibration techniques.Smart Materials and Structures, 19 (8), 085013.

[11] Ciampa, F. and Meo, M., 2010. A new algorithm for acoustic emission localization and flexural group velocity determination in anisotropic structures. Composites Part A Applied Science and Manufacturing, 41 (12), pp. 1777-1786.

[12] Ciampa, F. and Meo, M., 2010. Acoustic emission source localization and velocity determination of the fundamental mode A0 using wavelet analysis and a Newton-based optimization technique. Smart Materials and Structures, 19 (4), 045027.

[13] Polimeno, U. and Meo, M., 2009. Detecting barely visible impact damage detection on aircraft composites structures. Composite Structures, 91 (4), pp. 398-402.

[14] Polimeno, U., Meo, M. and Almond, D., 2008. Smart Nonlinear Acoustic Based Structural Health Monitoring System. Advances in Science and Technology, 56, pp. 426-434.

[15] Meo, M. and Zumpano, G., 2008. Damage assessment on plate-like structures using a global-local optimization approach. Optimization and Engineering, 9 (2), pp. 161-177.

[16] Meo, M., Polimeno, U. and Zumpano, G., 2008. Detecting Damage in Composite Material Using Nonlinear Elastic Wave Spectroscopy Methods. Applied Composite Materials, 15 (3), pp. 115-126.

[17] Zumpano, G. and Meo, M., 2008. Damage localization using transient non-linear elastic wave spectroscopy on composite structures. International Journal of Non-Linear Mechanics, 43 (3), pp. 217-230.

[18] Polimeno, U. and Meo, M., 2008. Understanding the effect of boundary conditions on damage identification process when using non-linear elastic wave spectroscopy methods. International Journal of Non-Linear Mechanics, 43 (3), pp. 187-193.

[19] Zumpano, G. and Meo, M., 2008. Damage detection in an aircraft foam sandwich panel using nonlinear elastic wave spectroscopy. Computers and Structures, 86 (3-5), pp. 483-490.

[20] Meo, M. and Zumpano, G., 2007. A new nonlinear elastic time reversal acoustic method for the identification and localisation of stress corrosion cracking in welded plate-like structures - A simulation study. International Journal of Solids and Structures, 44, p. 3666.

[21] Meo, M., Zumpano, G. and Polimeno, U., 2007. Corrosion identification on an aluminium plate-like structure by monitoring the wave propagation phenomena.Corrosion Reviews, 25, pp. 213-232.

[22] Polimeno, U. and Meo, M., 2007. Detecting barely visible impact damage detection on aircraft composites structures. Composite Structures, 91 (4), pp. 398-402.

[23] Meo, M., Zumpano, G., Meng, X., Cosser, E., Roberts, G. and Dodson, A., 2006.Measurements of dynamic properties of a medium span suspension bridge by using the wavelet transforms. Mechanical Systems and Signal Processing, 20, pp. 1112-1133.

[24] Zumpano, G. and Meo, M., 2006. A new damage detection technique based on wave propagation for rails. International Journal of Solids and Structures, 43, pp. 1023-1046.

[25] Meo, M., Zumpano, G., Piggott, M. and Marengo, G., 2005. Impact identification on a sandwich plate from wave propagation responses. Composite Structures, 71, pp. 302-306.

[26] Meo, M. and Zumpano, G., 2005. Nonlinear elastic wave spectroscopy identification of impact damage on a sandwich plate. Composite Structures, 71, pp. 469-474.

[27] Meo, M. and Zumpano, G., 2005. On the optimal sensor placement techniques for a bridge structure. Engineering Structures, 27, pp. 1488-1497.

[28] Meo, M. and Zumpano, G., 2004. Optimal sensor placement on a large-scale civil structure. Proceedings of SPIE - The International Society for Optical Engineering, 5394 (108).

 

Dr. Michele Meo

Material Research Centre, Dept of Mechanical Engineering

 

 

 

 

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