Pada penelitian ini akan dilakukan simulasi teknik pendeteksian lokasi sumber noise berupa partial discharge (PD) pada peralatan tegangan tinggi, dengan menggunakan susunan antena yang terdiri dari empat buah antena monopole sebagai sensor untuk mendeteksi gelombang elektromagnetik (EM) yang dipancarkan dari partial discharge (PD). Algoritma yang digunakan mengacu kepada time difference of arrival (TDOA) dari sinyal yang diterima antar antena (dengan menjadikan salah satu antena sebagai antena referensi). Metode yang digunakan untuk menentukan TDOA adalah metode Akaike Information Criterion, metode Energy Criterion, metode Gabor Centroid, metode threshold detection, metode peak detection, dan metode cross-correlation. Sistem pendeteksian lokasi sumber noise ini menggunakan konfigurasi susunan antena membentuk Y. Jarak antar antena diatur sejauh 2 meter dan 4 meter. Berdasarkan hasil pengamatan dan analisis, konfigurasi susunan antena membentuk Y memiliki tingkat akurasi 97.67%. Metode yang paling akurat untuk menentukan TDOA adalah metode cross-correlation.

Kata kunci: PD, TDOA, susunan antena.

This paper presents a simulation of locating noise source (Partial Discharge) on high-voltage apparatuses, by using antenna array that consisted of four monopole antennas as sensor to record the electromagnetic waves (EM) emitted from Partial Discharge (PD). The detection algorithm is based on the time difference of arrival (TDOA) of the signals received between antennas (by using one of four antennas as reference antenna). The methods to determine TDOAs are Akaike Information Criterion method, Energy Criterion method, Gabor Centroid method, threshold detection method, peak detection method, and/or cross-correlation method. These system use Y-shaped array configuration. The adjusted distance between antennas are 2 meter and 4 meter. From the observation and analysis results, Y-shaped array antenna configuration has accuracy 97.76%. The best method to get TDOA is the cross-correlation method.

Keywords: PD, TDOA, antenna array.

Kreuger, F. H. (1964). Discharge Detection in High Voltage Equipment. London: Temple Press.

Steiner, J. P., Reynolds, P. H., and Weeks, W. L. (1992). Estimating the location of partial discharges in cables: IEEE Trans. Electr. Insul., vol. 27, no. 1, pp. 44–59.

Quak, B., Gulski, E., Wester, F. J., and Seitz, P. N. (2003). Advanced PD site location in distribution power cables: Proc. 7th Int. Conf. Properties and Applications of Dielectric Materials, vol. 1, pp. 183–186.

Mashikian, M. S. (2002). Preventive maintenance testing of shielded power cable systems: IEEE Trans. Ind. Appl., vol. 38, no. 3, pp. 736–743.

Knapp, C. H., and Carter, G. C. (1976). The generalized correlation method for estimation of time delay: IEEE Trans. on Acoustic, Speech, Signal Processing, Vol. 24, No. 4, 320–327.

Challa, R. N., and Shamsunder, S. (1998). Passive near-ï¬eld localization of multiple non-Gaussian sources in 3-D using cumulates: Signal Proc., Vol. 65, 39–53.

Tungkanawanich, A., Kawasaki, Z., and Matsuura, K. (2001). Analysis of VHF-wideband impulsive electromagnetic noises on power distribution lines: Trans. IEE Japan, Vol. 120-B, No. 11, 1538–1544.

Cavallini, A., et al. (2003). A new approach to the diagnosis of solid insulation systems based on PD signal inference: IEEE Electr. Insul. Mag., vol. 19, no. 2, pp. 23–30.

Oussalah, N., Zebboudj, Y., and Boggs, S. A. (2007). Partial Discharge Pulse Propagation in Shielded Power Cable and Implications for Detection Sensitivity: IEEE Trans. Electr. Insul., vol. 23, no.6, pp. 5–10.

Wagenaars, P., Wouters, P.A.A.F., Wielen, P.J.C.M van der, and Steennis, E.F. (2008). Algorithms for Arrival Time Estimation of Partial Discharge Pulses in Cable Systems. Vancouver: ISEI.

Mardiana R., and Kawasaki, Z. (2000). Broadband Radio Interferometer Utilizing a Sequential Triggering Technique for Locating Fast-Moving Electromagnetic Sources Emitted from Lightning: IEEE Transactions on Instrumentation and Measurement, vol. 49, No.2.

Ibrahim, Nur. (2014). 3D Localization Technique for Broad Band Impulsive Noise Source. Bandung: IC3INA.