Assessment of a critical area for a give-way ship in a collision encounter

Authors

  • Przemysław Krata Gdynia Maritime University, Faculty of Navigation, Department of Ship Operation, Gdynia, Poland; Waterborne Transport Innovation, Poland Author
  • Jakub Montewka Aalto University, Department of Applied Mechanics, Research Group on Maritime Risk and Safety, Espoo, Finland Author

DOI:

https://doi.org/10.5604/08669546.1169212

Keywords:

maritime traffic safety, collision risk, anticollision, ship's motion model, ship domain

Abstract

Evasive action in ship-ship encounter has to be carried out on time and in line with the international convention on collision regulation – COLREG. The convention not only includes a set of rules defining types of relations between encountering ships but also indicates appropriate action to be taken in a given encounter. One of such encounters is crossing, where, in case of a collision situation, a give-way ship has to take an appropriate action in due time. However, a stand-on vessel is also given an opportunity to manoeuver, if it is made clear to her that the other ship is not fulfilling her obligations. However, it is difficult to specify, at which point in time in the course of an encounter, the stand-on ship has to take an action in order to avoid collision. It is understandable, as this parameter depends on numerous factors, both endogenous (e.g. ship characteristics, her maneuverability), and exogenous (e.g. type of encounter, weather conditions). Therefore in this paper we make an attempt towards the definition of the critical area for a maneuver of a stand-on ship, in the situation where the give-way vessel does not take an action. This is determined with the use of a hydrodynamic model of ship motion, and series of simulations conducted for several types of encountering ships under various conditions. Once determined, the critical area demarcates the no-go area around the own ship, where any other ships on collision courses must not enter. Otherwise a collision cannot be avoided by an action of one ship alone.

References

ARTYSZUK, J., 2000. Ship Motion Mathematical Model Analysis in Aspect of Benefits for Integrated Navigation System Algorithms, Maritime University of Szczecin.

“Baltic Ace Death Toll - Maritime Bulletin.” 2012. Available: http://www.odin.tc/news/ read.asp?articleID=1605.

BRIX, J., 1993. Manoeuvring technical manual. Hamburg, Germany: Seehafen Verlag.

BUKHARI, A.C., TUSSEYEVA, I., LEE, B. and KIM, Y., 2013. An intelligent real-time multi-vessel collision risk assessment system from VTS view point based on fuzzy inference system. Expert Systems with Applications, 40(4), pp. 1220-1230.

CHAUVIN, C., CLOSTERMANN, J. and HOC, J., 2009. Impact of training programs on decision-making and situation awareness of trainee watch officers. Safety Science, 47(9), pp. 1222-1231.

COLDWELL, T., 1983. Marine traffic behaviour in restricted waters. Journal of Navigation, 36(03), pp. 430-444.

COLLEY, B., CURTIS, R. and STOCKEL, C., 1983. Manoeuvring times, domains and arenas. Journal of Navigation, 36(02), pp. 324-328.

CURTIS, R.G., 1986. A Ship Collision Model for Overtaking. The Journal of the Operational Research Society, 37(4), pp. 397-406.

DROST, E.A., 2011. Validity and reliability in social science research. Education Research and Perspectives, 38(1), pp. 105-123.

FUJII, Y. and TANAKA, K., 1971. Traffic capacity. Journal of Navigation, 24(04), pp. 543-552.

GOODWIN, E., 1973. A statistical study of ship domains. Journal of Navigation, 26(01), pp. 130-130.

HÄNNINEN, M., MAZAHERI, A., KUJALA, P., MONTEWKA, J., LAAKSONEN, P., SALMIOVIRTA, M. and KLANG, M., 2013. Expert elicitation of a navigation service implementation effects on ship groundings and collisions in the Gulf of Finland. Proceedings of the Institution of Mechanical Engineers, Part O: Journal of Risk and Reliability, 228(1).

HANSEN, M.G., JENSEN, T.K., LEHN-SCHIØLER, T., MELCHILD, K., RASMUSSEN, F.M. and ENNEMARK, F., 2013. Empirical ship domain based on AIS data. Journal of Navigation, 66(06), pp. 931-940.

IMO, 2003. COLREG: Convention on the International Regulations for Preventing Collisions at Sea, 1972. International Maritime Organization.

KAO, S., LEE, K., CHANG, K. and KO, M., 2007. A fuzzy logic method for collision avoidance in vessel traffic service. Journal of Navigation, 60(01), pp. 17-31.

ŁUKASZEWICZ, A., 2007. Określanie Odległości Krytycznej Podjęcia Manewru Ostatniej Chwili Zgodnie Z Przepisami Konwencji COLREG, Transport XXI wieku: międzynarodowa konferencja naukowa, Stare Jabłonki, 18-21 września 2007, Instytut Technologii Eksploatacji.

MATUSIAK, J. E., 2007. On certain types of ship responses disclosed by the two-stage approach to ship dynamics. Archives of Civil and Mechanical Engineering, 7(4), pp. 151-166.

MATUSIAK, J.E., 2011. On the non-linearities of ship’s restoring and the Froude-Krylov wave load part. International Journal of Naval Architecture and Ocean Engineering, 3(1), pp. 111-115.

MOLLAND, A.F. and TURNOCK, S.R., 2007. Marine rudders and control surfaces: principles, data, design and applications. Oxford: Butterworth-Heinemann Ltd.

MONTEWKA, J., GOERLANDT, F. and KUJALA, P., 2012. Determination of collision criteria and causation factors appropriate to a model for estimating the probability of maritime accidents. Ocean Engineering, 40, pp. 50-61.

MONTEWKA, J., HINZ, T., KUJALA, P. and MATUSIAK, J., 2010. Probability modelling of vessel collisions. Reliability Engineering & System Safety, 95(5), pp. 573-589.

PATRAIKO, D., WAKE, P. and WEINTRIT, A., 2010. e-Navigation and the Human Element. TransNav - The International Journal on Marine Navigation and Safety of Sea Transportation, 4(1), pp. 11-16.

PIETRZYKOWSKI, Z. and URIASZ, J., 2009. The ship domain-a criterion of navigational safety assessment in an open sea area. Journal of Navigation, 62(1), pp. 93-108.

WANG, N., 2010. An intelligent spatial collision risk based on the quaternion ship domain. Journal of Navigation, 63(04), pp. 733-749.

WANG, N., MENG, X., XU, Q. and WANG, Z., 2009. A unified analytical framework for ship domains. Journal of Navigation, 62(04), pp. 643-655.

ZHANG, J., YAN, X., CHEN, X., SANG, L. and ZHANG, D., 2012. A novel approach for assistance with anti-collision decision making based on the International Regulations for Preventing Collisions at Sea. Proceedings of the Institution of Mechanical Engineers, Part M: Journal of Engineering for the Maritime Environment, 226(3), pp. 250-259.

Downloads

Published

2015-06-30

Issue

Section

Original articles

How to Cite

Krata, P., & Montewka, J. (2015). Assessment of a critical area for a give-way ship in a collision encounter. Archives of Transport, 34(2), 51-60. https://doi.org/10.5604/08669546.1169212

Share

Similar Articles

41-50 of 368

You may also start an advanced similarity search for this article.

No Related Submission Found