Searching possible accident black spot locations with accident analysis and GIS software based on GPS coordinates

Hegyi, Pál; Borsos, Attila; Koren, Csaba

doi:10.1556/606.2017.12.3.12

Cited by 17 publications

(12 citation statements)

References 9 publications

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“…Meanwhile, DBSCAN only creates the shape of the clusters and does not mention the density of the clusters. The density differences among clusters are not highlighted (Hegyi, Borsos, and Koren 2017). Also, DBSCAN cannot group well events with changed densities is the biggest drawback of this method (Qiu, Xu, and Bao 2016).…”

Section: Introductionmentioning

confidence: 98%

Determining the road traffic accident hotspots using GIS-based temporal-spatial statistical analytic techniques in Hanoi, Vietnam

Liu

Lin

2019

Geo-spatial Information Science

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This study applied GIS-based statistical analytic techniques to investigate the influence of accident Severity Index (SI) on temporal-spatial patterns of accident hotspots related to the specific time intervals of day and seasons. Road Traffic Accident (RTA) data in 3 years (2015 − 2017) in Hanoi, Vietnam were used to analyze and test this approach. Firstly, the RTA data were divided into four seasons in accordance with Hanoi's weather conditions and the time intervals such as the daytime, nighttime, or peak hours. Then, the Kernel Density Estimation (KDE) method was applied to analyze hotspots according to the time intervals and seasons. Finally, the results were presented by using the comap technique. This study considered both analyses with and without SI. The accident SI measures the seriousness of an accident. The approach method is to give higher weights to the more serious accidents, but not with the extremely high values calculated on a direct rate to the accident expenditures. The results showed that both analyses determined the relatively similar hotspots, but the rankings of some hotspots were quite different due to the integration of SI. It is better to take into account SI in determining RTA hotspots because the gained results are more precise and the rankings of hotspots are more accurate. From there, the traffic authorities can easily understand the causes behind each accident and provide reasonable solutions to solve the most dangerous hotspots in case of limited budget and resources appropriately. This is also the first study about this issue in Vietnam, so the contribution of the article will help the traffic authorities easily solve this problem not only in Hanoi but also in other cities. ARTICLE HISTORY

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Section: Introductionmentioning

confidence: 98%

Determining the road traffic accident hotspots using GIS-based temporal-spatial statistical analytic techniques in Hanoi, Vietnam

Liu

Lin

2019

Geo-spatial Information Science

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“…There are some general attributes of accident black spots to overcome the conceptual confusion. These are usually well-defined sections or intersections of the public road network, where road accidents are historically concentrated (Elvik, 2008;Delorme and Lassarre, 2014;Murray et al, 2012;Montella et al, 2013;Hegyi et al, 2017). Nowadays, road accidents are monitored by the governments and all data about accidents are stored in large, reliable and partially public databases (without any personal information about the participants).…”

Section: Background Black Spot Identificationmentioning

confidence: 99%

Peer Review #1 of "Analysis of historical road accident data supporting autonomous vehicle control strategies (v0.2)"

2021

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It is expected that most accidents occurring due to human mistakes will be eliminated by autonomous vehicles. Their control is based on real-time data obtained from the various sensors, processed by sophisticated algorithms and the operation of actuators. However, it is worth noting that this process flow cannot handle unexpected accident situations like a child running out in front of the vehicle or an unexpectedly slippery road surface. A comprehensive analysis of historical accident data can help to forecast these situations. For example, it is possible to localize areas of the public road network, where the number of accidents related to careless pedestrians or bad road surface conditions is significantly higher than expected. This information can help the control of the autonomous vehicle to prepare for dangerous situations long before the real-time sensors provide any related information. This manuscript presents a data-mining method working on the already existing road accident database records to find the black spots of the road network. As a next step, a further statistical approach is used to find the significant risk factors of these zones, which result can be built into the controlling strategy of self-driven cars to prepare them for these situations to decrease the probability of the potential further incidents. The evaluation part of this paper shows that the robustness of the proposed method is similar to the already existing black spot searching algorithms. However, it provides additional information about the main accident patterns.

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“…Many studies have been conducted around the world using various approaches and methodologies to solve problems related to the occurrence of road tra c crashes, their causes, consequences, and emergency response in order to achieve the SDG, such as Huang & Pan, 2007;Anderson 2009;Durduran, 2010;Lloyd 2010;Polat & Durduran 2011;Plug, Xia, and Caul eld. 2011;Shekhar et al 2011;Han, Pei, and Kamber, 2011;Plug, Xia, and Caul eld, 2011;Han, Pei, and Kamber, 2011;Han, Pei, and Kamber, 2011;Han, Pei, and Kamber, 2011;Han, Pei, Dai, 2012;MOT, 2012;Ponnaluri, 2012;Dai, 2012;Mirbagheri, 2013;ela, Shiode, and Lipovac 2013;Yang, Lu, & Wu, 2013;Xie and Yan 2013;Mohaymany, Shahri, and Mirbagheri 2013;Timmermans et al, 2015;Xuan 2015;Choudhary, Ohri, and Kumar 2015;Qiu, Xu, and Bao 2016;Harirforoush and Bellalite 2016;Satria & Castro, 2016;Sandhu et al 2016;Corazza et al, 2017;Harirforoush 2017;Aghajani et al, 2017;Shafabakhsh, Famili & Bahadori 2017;Hegyi, Borsos, and Koren 2017;Amorim, Ferreira & Couto, 2017;Vemulapalli et al 2017;Phong, 2018;Iyanda, 2019;Chung, 2019;…”

Section: Introductionmentioning

confidence: 99%

Geospatial Analysis of Road Traffic Crashes and Emergency Response Optimization in Kano Metropolis, Nigeria

Yunus

Abdulkarim

2022

Preprint

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Increased occurrence of road traffic crashes in Kano metropolis has resulted in a steady loss of lives, injuries, and increased people's risk exposure. This study looked into the emergency response to road traffic crashes in Kano, with a view to improving efficiency by developing linkages and synergy between Emergency Healthcare Facilities (EHCF), ambulances, and crash hotspots. The geographical location and attributes of the major EHCF, crash hotspots along highway intersections, and the two existent ambulances at the Kano State Fire Service (KSFS) and Federal Road Safety Corp head offices (FRSC) were obtained using GPS surveying. Road traffic network data (vector format) was digitized from satellite image, from which two major road classes (highways and minor roads) were identified, as well as their respective speed limits. The length and speed constraints were used to calculate time distances. Nearest Neighbor and Network (closest facility, shortest route, and location-allocation) analyses were carried out. The results demonstrated that EHCF, ambulances, and crash places have different distribution patterns with almost no linkages. Closest ambulance facility analysis revealed the FRSC ambulance takes 9.41 minutes to arrive to crash spot 18 (Maiduguri Road, following NNPC) and 7.52 minutes to arrive at AKTH, the nearest EHCF. Comparatively, getting to Court road incident scene (spot 16) and IRPH as the closest EHCF takes about 3 times the time it takes to get to spot 18 and 4 times the time it takes to get to AKTH. This means that practically almost all victims in the city suffocate before reaching to the hospital. This signifies that, in cases of demand for CPR at the incident scene, there are higher likelihood of dying as it is expected to be provided within the first four minutes after the crash. Based on a maximum of 4 minutes impedance cutoff from all directions towards the occurrences areas, location-allocation analysis found eight new locations to maximize coverage and improve efficiency. It is concluded that current road traffic crash emergency response system has been determined to be ineffective. As a result, more ambulances should be strategically placed to improve emergency response times.

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Searching possible accident black spot locations with accident analysis and GIS software based on GPS coordinates

Cited by 17 publications

References 9 publications

Determining the road traffic accident hotspots using GIS-based temporal-spatial statistical analytic techniques in Hanoi, Vietnam

Determining the road traffic accident hotspots using GIS-based temporal-spatial statistical analytic techniques in Hanoi, Vietnam

Peer Review #1 of "Analysis of historical road accident data supporting autonomous vehicle control strategies (v0.2)"

Geospatial Analysis of Road Traffic Crashes and Emergency Response Optimization in Kano Metropolis, Nigeria

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