DETERMINATION OF THE FASTEST ROUTE FOR FIRE TRUCKS IN CIREBON CITY BASED ON DISTANCE, TIME, CONGESTION AND LAND USE

Authors

  • Mira Lestira Hariani Universitas Swadaya Gunung Djati, Cirebon, Indonesia., Indonesia
  • Yackob Astor Politeknik Negeri Bandung, Jawa Barat, Indonesia., Indonesia

DOI:

https://doi.org/10.33603/jgst.v5i1.4905

Abstract

Fire fighter performance can be represented by the speed of handling the fire case, where greatly influenced by the travel speed of the fire trucks to the fire location. This study aims to determine the fastest route for fire trucks in Cirebon City based on the travel distance, time, congestion and land use. The method used in this study is by applying the Geographic Information System (GIS) model in identifying several variables that affect the travel speed of fire trucks. In this study, several alternative routes were determined from the fire station (Harjamukti fire station and Bima fire station) to the location of fire (Harjamukti Market) and then calculated the travel time on each alternative route by considering travel distance, time, congestion and land use. The results showed that the fastest travel time for fire trucks in Cirebon City was largely influenced by the travel distance. However, in conditions of high traffic flow, a route with a longer distance but does not cross a congested road segment can produce a faster travel time when compared to a shorter route but crosses congested roads. The fastest route from the Bima fire station to  Harjamukti market is route 1 (2,854 m) in the morning, route 3 (3,019 m) in the afternoon and evening. Meanwhile, the fastest route from the Harjamukti fire station to Harjamukti Market is Route 1 (2,069 m) in the morning, afternoon and evening because it has the shortest distance.

References

Abousaeini, M.,Rosmadi, F., Rusnah, M., 2015. “Geographic Information System (GIS) Modeling Approach to Determine The Fastest Delivery Routes”. King Saud University: Saudi Journal of Biological Science. http://dx.doi.org/10.1016/j.sjbs.2015.06.004.

Bhambulkar, A., 2011. “Municipal solid waste collection routes optimized with arc GIS network analyst”. Int. J. Adv. Eng. Sci. Technol. 11 (1), 6.

C¸ela, L., Shiode, S., Lipovac, K., 2013. “Integrating GIS and spatial analytical techniques in an analysis of road traffic accidents in Serbia”. Int. J. Traffic Transport Eng. 3 (1), 1–15.

Diez-Gutierrez, M., Sahar, B., 2020. “Explanatory variables underlying the route choice decisions of tourists: The case of Geiranger Fjord in Norway”. Transportation Research Part A Volume 141, pages 398 - 409. https://doi.org/10.1016/j.tra.2020.09.023.

Gohari, A., 2010. “Route Planning System based on Geographic Information System”. University Technology Malaysia (UTM), University Technology Malaysia.

Nggufron, N., Rochmad., Mashuri., 2019. “Pencarian Rute Terbaik Pemadam Kebakaran Kota Semarang Menggunakan Algoritma Dijkstra Dengan Logika Fuzzy Sebagai Penentu Bobot Pada Graf”. UNNES Journal of Mathematics Vol. 8 No.1. hal 40 – 49.

Peraturan Menteri Pekerjaan Umum Nomor 20/PRT/M/2009 tentang pedoman teknis manajemen proteksi kebakaran di perkotaan

Sadeghi-Niaraki, A., Varshosaz, M., Kim, K., Jung, J.J., 2011. “Real world representation of a road network for route planning in GIS”. Expert Syst. Appl. 38 (10), 11999–12008. http://dx.doi.org/10.1016/ j.eswa.2010.12.123.

Sharifi, M., Hadidi, M., Vessali, E., Mosstafakhani, P., Taheri, K., Shahoie, S., Khodamoradpour, M., 2009. “Integrating multi-criteria decision analysis for a GIS-based hazardous waste landfill sitting in Kurdistan Province, western Iran”. Waste Manage. 29 (10), 2740– 2758. http://dx.doi.org/10.1016/j.wasman.2009.04.010.

Sofia, A.S.S.D., Nithyaa, R., Arulraj, G.P., 2013. “Minimizing the traffic congestion using GIS”. Int. J. Res. Eng. Adv. Technol. 1 (1), 1–6.

S. Ahmed., R.F. Ibrahim., H.A. Hefny., 2017. “GIS-Based Network Analysis for the Roads Network of the Greater Cairo Area”. International Conference on Applied Research in Computer Science and Engineering, Beirut, Lebanon, July 2017.

Standar Nasional Indonesia (SNI) 09-7053-2004 tentang Kendaraan dan Peralatan Pemadam Kebakaran – Pompa.

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Published

2021-03-12

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