Bibliography

[1]: J.-R. Riba. The Role of AC Resistance of Bare Stranded Conductors for Developing Dynamic Line Rating Approaches. Applied Sciences 14 (2024).
[2]: V. T. Morgan. The Current Distribution, Resistance and Internal Inductance of Linear Power System Conductors—A Review of Explicit Equations. IEEE Transactions on Power Delivery 28, 1252–1262 (2013).
[3]: Y. Yang, S. Fortin, J. Ma and F. P. Dawalibi. GMR of Stranded Multizone Conductors. In: The 4th IASTED Asian Conference on Power and Energy Systems (AsiaPES) (2008). Link.
[4]: B. Gustavsen. Panel session on data for modeling system transients insulated cables. In: 2001 IEEE Power Engineering Society Winter Meeting. Conference Proceedings (Cat. No.01CH37194), Vol. 2 (2001); p. 718-723 vol.2.
[5]: U. S. Gudmundsdottir, B. Gustavsen, C. L. Bak and W. Wiechowski. Field Test and Simulation of a 400-kV Cross-Bonded Cable System. IEEE Transactions on Power Delivery 26, 1403–1410 (2011).
[6]: A. Ametani. A General Formulation of Impedance and Admittance of Cables. IEEE Transactions on Power Apparatus and Systems PAS-99, 902–910 (1980).
[7]: T. A. Papadopoulos, D. A. Tsiamitros and G. K. Papagiannis. Impedances and Admittances of Underground Cables for the Homogeneous Earth Case. IEEE Transactions on Power Delivery 25, 961–969 (2010).
[8]: CIGRE Working Group B1.30. Cable Systems Electrical Characteristics. Technical Brochure 531 (CIGRE, Apr 2013). Link.
[9]: IEC technical committee 20: Electric cables. IEC 60287 - Electric cables – Calculation of the current rating (International Electrotechnical Commission, 2023). Link.
[10]: T. C. 20. Distribution cables with extruded insulation for rated voltages from 3.6/6 (7.2) kV up to and including 20.8/36 (42) kV (European Committee for Electrotechnical Standardization, 2023); pp. 1–150. Link.
[11]: T. C. VDE. Distribution cables with extruded insulation for rated voltages from 3.6/6 (7.2) kV up to and including 20.8/36 (42) kV (VDE, 2024); pp. 1–120. Link.
[12]: T. C. 7. Conductors for Overhead Lines—Round Wire Concentric Lay Stranded Conductors (European Committee for Electrotechnical Standardization, 2001); pp. 1–73. Link.
[13]: B. Gustavsen, J. Martinez and D. Durbak. Parameter determination for modeling system transients-Part II: Insulated cables. IEEE Transactions on Power Delivery 20, 2045–2050 (2005).
[14]: F. Grover and I. S. America. Inductance Calculations: Working Formulas and Tables. Dover books on engineering and engineering physics (Instrument Society of America, 1981).
[15]: CIGRE Working Group B2.12. Alternating Current (AC) Resistance of Helically Stranded Conductors. Technical Brochure 345 (CIGRE, Apr 2008). Link.
[16]: T. Karmokar and M. Popov. Enhanced Modelling and Parameter Determination of HVDC Cables Using Practice-Oriented Methodology. CIGRE Science and Engineering 2025-February (2025).
[17]: N. Oussalah, Y. Zebboudj and S. A. Boggs. Partial Discharge Pulse Propagation in Shielded Power Cable and Implications for Detection Sensitivity. IEEE Electrical Insulation Magazine 23, 5–10 (2007).
[18]: E. B. Rosa. The self and mutual-inductances of linear conductors. Vol. 4 no. 2 (National Bureau of Standards, 1908).