Noise is an un-expected signal which exists naturally at any system. In the study of fractal batik coloring, noise as a spot is generated as the basis of batik motive coloring. Even distribution of noise spots will produce art-works which involve elements of culture and technology. The development of batik motives and colors could be harmonized with the development of technology, such as the use of fractal method in order to create the new motives of batik. Fractal is a geometric form which can be separated into pieces, where each part is the repeated small version. The coloring of batik was based on the generating noise using Gaussian method. Noise on fractal batik was spots which were generated randomly on the surface of fractal batik, meanwhile Gaussian method was a noise model which followed normal distribution standard with zero average and standard deviation 1.The generating noise as coloring basis of fractal batik patterns, which was formed in the previous study, showed the distant error of noise between 9.1 pixels and 13.7 pixels. This was because the distribution of noise on the fractal batik patterns was carried out randomly using Gaussian method for every process of fractal rewriting system.

batik fractal; noise; Gaussian; noise model

Y. Efendy.”Seni Kriya Batik Dalam Tradisi Baru Menghadapi Arus Budaya Global.” Jurnal Seni Rupa dan Desain Volume 1,yang diterbitkan oleh Pusat Penelitian dan Pengembangan Masyarakat (P3M) Sekolah Tinggi Seni Rupa dan Desain Indonesia (STISI) Bandung, 1 Agustus 2000.

Y. Hariadi, Fractal Geometry on Batik.Journal of Social Complexity. Bandung Fe Institute, 2008.

W.Constantine and D. Percival, “Insightful Fractal Time Series Modelling And Analysis”, 19 April 2010.

P. Prusinkiewicz, M. Shirmohammadi, and F. Samavati, “Lsystems in Geometric Modeling”, Proceedings of the Twelfth Annual Worskshop on Descriptional Complexity of Formal Systems, pp. 3-12, 2010.

J. Knutzen, “Generating Climbing Plants Using L-Systems”, Master of Science Thesis in the Programme Software Engineering andTechnology Department of Computer Science and Engineering Chalmers University Of Technology University Of Go Thenburg, Göteborg, Sweden, March 2009.

O. Št’ava , B. Beneš , R. Moch , D. G. Aliaga and P. Krištof: Inverse Procedural Modeling by Automatic Generation of Lsystems, 2010.

M. Ghazel, G. H. Freeman, and E. R. Vrscay,”Fractal Image Denoising”, IEEE Transactions On Image Processing, Vol. 12, No. 12, Desember 2003.

M. Bicego, D.Gonzalez-Jimenez, E.Grosso, J. L. A. Castro. “Generalized Gaussian Distribution for Sequential Data Classification”, Proc. IEEE Int. Conf. , 2008.

D. Pastor, A. Amehraye, “Algorithms and Applications for Estimating the Standard Deviation of AWGN when Observations are not Signal-Free”, Journal Of Computers, Vol. 2, No. 7, September 2007.

H. S. Doellah. ”Batik : The Impact of Time and Environment”, Published by Danar Hadi, 2002.

W. Wardiana and A. Heryana,”Studi Komparasi untuk Unjuk Kerja Komputer pada Proses Perhitungan Fractal”, Pusat Penelitian Informatika-LIPI Bandung, Jurnal Teknologi Industri Vol. XII No.1 Januari 2008: 63 – 70.

J. Jauhari, “Pengembangan Perangkat Lunak Pembangkit Geometri Fraktal Berbasis Bilangan Komplek (PLFrakom)”, Fakultas Ilmu Komputer, Universitas Sriwijaya, Jurnal Generic, Januari 2010.