The problem of traffic accidents in Indonesia has a high level of risk. In an effort to minimize losses due to traffic accidents, it is necessary to study the data and characteristics of traffic accidents and identify these events as extreme events. This study was conducted to find out how to estimate the shape and scale parameters using Maximum Likelihood Estimation (MLE), and to explore data on traffic accident losses in Indonesia. The method used to analyze the extreme value of traffic accident losses is the Extreme Value Theory. One approach to identify extreme values is Peaks Over Threshold which follows the Generalized Pareto Distribution (GPD). Traffic accident loss data is divided into three types based on the cause, namely driver negligence, vehicle quality, and other external factors in the period (2008-2017). Estimation of shape and scale parameters is obtained through MLE which is then solved by Newton Raphson because it produces equations that are not closed form. This study resulted in an estimate of the shape and scale of the GPD distribution parameter, as well as a confidence interval (1-α) of 100% with of 5%. In addition, it is concluded that the parameters obtained from the estimation have the same characteristics for each type of risk analyzed, but have different parameter values. Based on parameter estimation, GPD distribution is obtained from each risk which is expected to be useful for related parties in analyzing the number of traffic accident losses in the next period to consider steps that can be taken to reduce losses due to traffic accidents.

Baran, J. and Witzany, J. (2011). A Comparison of EVT and Standard VaR Estimations. SSRN eJournals. Czech: Science Foundation grant no. 402/09/0732

Chavez-Demoulin, V. (1999). Two problems in environmental statistics: Capture-recaptureanalysis and smooth extremal models. Ph.D. thesis. Department of Mathematics, Swiss Federal Institute of Technology, Lausanne.

Chavez-Demoulin, V., Davison, A., and McNeil, A. (2003). A point process approach to value-at-risk estimation. National Centre of Competence in Research Financial Valuation and Risk Management, 134, 1-30.

Davison, A. C. (1984). Modelling Excesses Over High Thresholds, with an Application, in Statistical Extremes and Applications, ed. J.Tiago de Oliveira , Dordrecht : D.Reidel. 461-482.

Efron, B. (1982). The Jacknife, the Bootstrap and Other Resampling Plans. Stanford, California: National Science Foundation, Division of Biostatistics.

Frank, J. and Massey, Jr. (1951). The Kolmogorov-Smirnov Test for Goodness of Fit. Journal of the American Statistical Association. Vol. 46(253), 68-78.

Gourier, E. Abbate, D. and Farkas, W. (2009). Operational Risk Quantivication using Extreme Value Theory and Copulas: from Theory to Practice. The Journal of Operational Risk, Vol. 4(3).

Hubbert, S. (2012). Essential Mathematics for Market Risk Management. Great Britain (UK): John Wiley & Sons Ltd., Publication.

Kang, S. and Song, J. (2017). Parameter and Quantile Estimation for the Generalized Pareto Distribution In Peaks Over Threshold Framework. Journal of the Korean Statistical Society, Vol. 46(4), 487-501.

Matthias, D., Paul, E., and Lambrigger, D. D. (2007). The Quantitative Modeling of Operational Risk : Between G and H and EVT. Astin Bulletin, Vol 37(2), 2007, 265-291.

Mohammed, A., Ambak, K., Mosa, A., and Syamsunur, D. (2019). A Review of the Traffic Accidents and Related Practices Worldwide. The Open Transportation Journal, 13, 65-83.

Smith, R. (1985). Maximum Likelihood Estimation in A Class of Nonregularcases. Journal of Biometrika,72(1), 67–90.

Vinod, H. D. and Lacalle, L. J. (2009). Maximum Entropy Bootstrap for Time Series: The MEBoot R Package. Journal of Statistical Software. 29(5), 1-19.

Yustika, D. W. (2011). Estimating Total Claim Size in the Auto Insurance Industry: a Comparison between Tweedie and Zero-Adjusted Inverse Gaussian Distribution. Journal of Brazilian Administration Review,8(1), 37-47.