References
- [1] Hamia, R., Cordier, C., Dolabdjian, C. (2014). Eddycurrent non-destructive testing system for the determination of crack orientation. NDT & E International, 61, 24-28.
- [2] Tian, G.Y., Sophian, A. (2005). Defect classification using a new feature for pulsed eddy current sensors. NDT & E International, 38 (1), 77-82.
- [3] Heidari, T., Seidfaraji, H., Sadeghi, S.H.H., et al. (2013). A fast analysis technique for electromagnetic interaction of high-frequency AC current-carrying wires with arbitrary-shape cracks in ferrous metals. IEEE Transactions on Magnetics, 49 (3), 1101-1107.
- [4] Zhang, J., Drinkwater, B.W., Wilcox, P.D., et al. (2010). Defect detection using ultrasonic arrays: The multi-mode total focusing method. NDT & E International, 43 (2), 123-133.
- [5] Merah, N. (2003). Detecting and measuring flaws using electric potential techniques. Journal of Quality in Maintenance Engineering, 9 (2), 160-175.
- [6] Bowler, N., Huang, Y. (2005). Model-based characterization of homogeneous metal plates by fourpoint alternating current potential drop measurements. IEEE Transactions on Magnetics, 41 (6), 2102-2110.
- [7] Lu, Z.J., Nicholas, P.J., Evans, W.J. (1995). Calibration of an ACPD monitoring system for small crack growth in corner crack specimens. Engineering Fracture Mechanics, 50 (4), 443-456.
- [8] Saguy, H., Rittel, D. (2005). Bridging thin and thick skin solutions for alternating currents in cracked conductors. Applied Physics Letters, 87 (8), 084103.
- [9] Venkatsubramanian, T.V., Unvala, B.A. (1984). An AC potential drop system for monitoring crack length. Journal of Physics E: Scientific Instruments, 17 (9), 765.
- [10] Bowler, N. (2011). Four-point potential drop measurements for materials characterization. Measurement Science and Technology, 22 (1), 012001.
- [11] Wheeler, H.A. (1942) Formulas for the skin effect. Proceedings of the IRE, 30 (9), 412-424.
- [12] Sposito, G., Cawley, P., Nagy, P.B. (2010). An approximate model for three-dimensional alternating current potential drop analyses using a commercial finite element code. NDT & E International, 43 (2), 134-140.
- [13] Raja, M.K., Mahadevan, S., Rao, B.P.C, et al. (2010). Influence of crack length on crack depth measurement by an alternating current potential drop technique. Measurement Science and Technology, 21 (10), 105702.
- [14] Lewis, A.M., Michael, D.H., Lugg, M.C., et al. (1988). Thin skin electromagnetic fields around surface breaking cracks in metals. Journal of Applied Physics, 64 (8), 3777-3784.
- [15] Sposito, G., Cawley, P., Nagy, P.B. (2010). Potential drop mapping for the monitoring of corrosion or erosion. NDT & E International, 43 (5), 394-402.
- [16] Kawakam, Y., Kanaji, H., Oku, K. (2011). Study on application of field signature method (FSM) to fatigue crack monitoring on steel bridges. Procedia Engineering, 14, 1059-1064.
- [17] Kim, Y.C., Asa, Y., Oku, K. (2007). Monitoring of initiation and propagation of fatigue cracks in steel plate deck by FSM. Quarterly Journal of the Japan Welding Society, 25 (4), 542-547.
- [18] Hwang, I.S. (1992). A multi-frequency AC potential drop technique for the detection of small cracks. Measurement Science and Technology, 3 (1), 62.
- [19] Saguy, H., Rittel, D. (2006). Alternating current flow in internally flawed conductors: A tomographic analysis. Applied Physics Letters, 89 (9), 094102.
- [20] Saguy, H., Rittel, D. (2007). Application of ac tomography to crack identification. Applied Physics Letters, 91 (8), 084104.
- [21] Pryor, R.W. (2011). Multiphysics Modeling Using COMSOL: A First Principles Approach. Ontario, Canada: Jones & Bartlett Publishers.