Abstract
Multiple projects within the rail industry across different regions have been initiated to address the issue of over-population. These expansion plans and upgrade of technologies increases the number of intersections, junctions, and level crossings. A level crossing is where a railway line is crossed by a road or right of way on the level without the use of a tunnel or bridge. Level crossings still pose a significant risk to the public, which often leads to serious accidents between rail, road, and footpath users and the risk is dependent on their unpredictable behavior. For Great Britain, there were three fatalities and 385 near misses at level crossings in 2015–2016. Furthermore, in its annual safety report, the Rail Safety and Standards Board (RSSB) highlighted the risk of incidents at level crossings during 2016/17 with a further six fatalities at level crossings including four pedestrians and two road vehicles. The relevant authorities have suggested an upgrade of the existing sensing system and the integration of new novel technology at level crossings. The present work addresses this key issue and discusses the current sensing systems along with the relevant algorithms used for post-processing the information. The given information is adequate for a manual operator to make a decision or start an automated operational cycle. Traditional sensors have certain limitations and are often installed as a “single sensor”. The single sensor does not provide sufficient information; hence another sensor is required. The algorithms integrated with these sensing systems rely on the traditional approach, where background pixels are compared with new pixels. Such an approach is not effective in a dynamic and complex environment. The proposed model integrates deep learning technology with the current Vision system (e.g., CCTV to detect and localize an object at a level crossing). The proposed sensing system should be able to detect and localize particular objects (e.g., pedestrians, bicycles, and vehicles at level crossing areas.) The radar system is also discussed for a “two out of two” logic interlocking system in case of fail-mechanism. Different techniques to train a deep learning model are discussed along with their respective results. The model achieved an accuracy of about 88% from the MobileNet model for classification and a loss metric of 0.092 for object detection. Some related future work is also discussed.
Highlights
Different projects that directly address the issue of over-population and ever-increasing demand for train services, which our current system is unable to cope with, have been initialized within Great Britain
The algorithms integrated with these sensing systems rely on the traditional approach, where background pixels are compared with new pixels
The present work addresses the alarming threats associated with level crossings because of the on-going projects, expansion plans, and increasing number of level crossings throughout Great Britain and Europe
Summary
Different projects that directly address the issue of over-population and ever-increasing demand for train services, which our current system is unable to cope with, have been initialized within Great Britain. Some of these major project plans for Control Period 6 (CP6) are mentioned by the Network Rail [1]. There are currently 7500–8000 operational level crossings within Great Britain [5] and about 7000 are actively used on Network Rail managed infrastructure Out of these 7000 level crossings, around 1500 are on public vehicular roads and others on a public footpath or private road. The risk associated with level crossings is significantly high, where heavy machinery cross with high speeds, and road users such as vehicles and pedestrians misuse level crossings during its operational cycle
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