Kendali Lampu Lalu Lintas dengan Deteksi Kendaraan Menggunakan Metode Blob Detection
Abstract
Traffic jam is a major traffic problem often found in big cities of Indonesia. It is because the number of vehicles increases annually. Therefore, a simulation to detect the number of vehicles in every lane of traffic is needed to monitor the traffic. Traffic control is also required in order to reduce traffic jam. This paper develops a vehicle detection and counting system using image processing. Detection is carried out using image segmentation which is processed by object filtering and blob extraction. Morphological operators are employed for blob extraction. Testing is conducted using a video obtained from the ATCS Bandung. The video is taken at the Laswi - A. Yani intersection Bandung. Software prototypes are created in C++, using Windows Forms Application as a programming library for Windows and Open CV for image processing module. The result shows that blob detection method can give good results if there is no intersection between blobs of each car. The performance is poor when this method is used for heavy traffic conditions, where the cars are close to each other. The performance level of sensitivity is 91.67%, precision is 61.11%, specificity is 80.55%, f-Measure is 73.33%, and accuracy is 83.33%. The accuracy for vehicles detection on sunny condition is 82.11% and reduced by 76.50% on rainy condition. This method works better in quiet condition, with accuracy of 83.07%, and is reduced by 67.70% in crowded condition. The average processing time is 0.042 seconds when using video, and 0.033 seconds using real camera.
References
Suryatini Fitria, "Perancangan dan Implementasi Pengendali Lampu Lalu Lintas Berdasarkan Kepadatan Kendaraan Menggunakan Logika Fuzzy", Tesis, ITB, Bandung, 2015.
Ahmed Bilal, "An Intelligent Traffic Controller Based on Fuzzy Logic", International Journal of Innovation in the Digital Economy (IJIDE), 5 (1), pages 31-40, 2014.
D. Beymer, P. McLauchlan, B. Coifman, and J. Malik, "A real-time computer vision system for measuring traffic parameters," Proc. IEEE Conf. Computer Vision and Pattern Recognition, Puerto Rico, June 1997, pp. 496–501.
K. P. Karmann and A. von Brandt, "Moving object recognition using an adaptive background memory", Proc. Time-Varying Image Processing and Moving Object Recognition, vol. 2, V. Capellini, Ed., 1990
Rensso V. H. Mora Colque, and Guillermo, "Robust Model for Vehicle Type Identification in Video Traffic Surveillance", SIBGRAPI-Conference Graphics, Patterns and Images, Peru, 2013
Gonzales, Rafael, C., Digital Image Processing, Addison-wesley publishing, 2, 760 – 783, 1992.
Willey, John. Sons, Digital Image Processing, A Wiley-Interscience Publication, 3, 401 – 566, 2001.
Willow Garage, Open Computer Vision, [Online]. Available: http:// http://docs.opencv.org/ OpenCV 2.4.11.0 documentation »
Solomon, Chris. Toby, Breckon., Fundamentals of Digital Image Processing, Wileyblackwell Press, 1, 197-200, 2011.
Intel, Open Source Computer Vision Library. U.S.A: Intel Corporation, 1999-2001.
Ritter G.X, Wilson J. N, Hanbook of Computer Vision Algorithms in Image Algebra, CRC Press,Washington D.C, 2001
Kaspers, Anne., "Blob Detection Biomedical Image Sciences", Image Sciences Institute, UMC Utrecht, 2011.
Atkociounas, et al., "Image Processing in Road Traffic Analysis", Nonlinear Analysis: Modelling and Control, Vol. 10, No. 4, 315–332,2005.
Sakamoto,Yoshihiro. Koichiro, Kajitani. Takeshi, Naito., "Development of The Image Processing Vehicle Detector For Intersection", Proceedings of the 13th its world congreaa, London. 2006
Silva. R, Aires.K., Automatic Motorcycle Detection on Public Roads, CLEI Electronic Journal, 16 (3), Paper 04, 2013.
© Jurnal Nasional Teknik Elektro dan Teknologi Informasi, under the terms of the Creative Commons Attribution-ShareAlike 4.0 International License.
1.png)
