References
- [1] Underwriters Laboratories 1699 Standard for Arc-Fault Circuit Interrupters (3rd edition), Northbrook, USA: Underwriters Laboratories Incorporated, 2017.
- [2] International Electrical Commission 62606 General Requirements for Arc Fault Detection Devices (1st edition), Geneva, Switzerland: International Electrical Commission, 2013.
- [3] National Fire Protection Associate An Overview of the U.S. Fire Problem, Retrieved March 13, 2017, from National Fire Protection Associate: https://www.usfa.f.
- [4] National Fire Data System Statistics of Cause of Fire, Retrieved January 1, 2018, from National Fire Data System: http://www.nfds.go.kr/frbase 0001.jsf, 2018.
- [5] K. Yang, R. Zhang, J. Yang, C. Liu, S. Chen and F. Zhang, “A Novel Arc Fault Detector for Early Detection of Electrical Fires”, Sensors vol. 16, 2016, pp. 500(1)–500(24).
- [6] H. G. Ji, Y. J. Cho, G. M. Wang, S. C. Hwang and G. S. Kil, “Extraction of Series Arc Signals based on Wavelet Transform an Indoor Wiring System”, Transaction on Electrical and Electronic Materials vol. 18, no. 4, 2017, pp. 221–224.
- [7] D. G. George, W. Kon and D. Robert, “More about Arc-Fault Circuit Interrupter”, IEEE Transactions on Industry Application vol. 40, no.4, 2004, pp. 1006–1011.
- [8] National Fire Protection Association, National Electrical Code (2017 edition). Massachusetts, USA, 2007.
- [9] E. R. Carlos, “Arc Fault Detection and Discrimination Methods”, IEEE Holm Conference on Electrical Contacts pp. 115–122, Pittsburgh, USA, 16-19 September 2007.
- [10] C. J. Wu and Y. W. Liu, “Smart Detection Technology of Serial Arc Fault on Low-Voltage Indoor Power Lines”, International Journal of Electrical Power and Energy Systems vol. 69, 2015, pp. 391–398.
- [11] W. Y. Su and C. J. Wu, “The Assessment of Introduction of the Arc Fault Circuit Interrupters”, Report prepared for Institute of Occupational Safety and Health Taipei, Taiwan, 2010.
- [12] D. G. George and W. S. Gary, “The Arc-Fault Circuit Interrupter: an Emerging Product”, IEEE Transactions on Industry Application vol. 34, no. 5, 1998, pp. 928–933.
- [13] W. S. Moon, J. C. Kim, A. Jo, S. B. Bang and W. S. Koh, “Ignition Characteristics of Residential Series Arc Faults 220-V HIVWires”, IEEE Transactions on Industry Application vol. 51, no. 3, 2015, pp. 2054–2059.
- [14] Y. H. Lin, C. W. M. Liu and C. S. Chen, “A New PMU-based Fault Detection/Location Technique for Transmission Lines with Consideration of Arcing Fault Discrimination-Part I: Theory and Algorithms”, IEEE Transactions on Power Delivery vol. 19, no. 4, 2006, pp. 1587–1593.
- [15] N. Malakondaiah, J. S. Thomas, G. Suresh and G, “Arc Fault Detection Scheme for 42-V Automotive DC Networks using Current Shunt”, IEEE Transactions on Power Electronics vol. 21, no. 3, 2006, pp. 633–639.
- [16] A. Haddad and D. Warne, Advances in High Voltage Engineering (1st ed.), London, United Kingdom: The Institution of Engineering and Technology, 2004.
- [17] A. Glowacz, “Diagnostics of DC and Induction Motors based on the Analysis of Acoustic Signals”, Measurement Science Review vol. 14, no. 5, 2014, pp. 257–262.
- [18] A. Glowacz, “Recognition of Acoustic Signals of Synchronous Motors with the Use of MoFS and selected Classifiers”, Measurement Science Review vol. 15, no. 4, 2015, pp. 167–175.
- [19] H. E. Jo, G. M. Wang, S. J. Kim and G. S. Kil, “Comparison of Partial Discharge Characteristics SF6 Gas under AC and DC”, Transaction on Electrical and Electronic Materials vol. 16, no. 6, 2015, pp. 323-327.
- [20] National Instrument Overview of Lab VIEW Time Frequency Analysis Tools, Retrieved June, 2014, from National Instrument: http://zone.ni.com/reference/en-XX/help/372656C01/lvasptconcepts/tfa_overview , 2016.