Abstract
Abstract. A new numerical model for the on-demand computation of optimal ship routes based on sea-state forecasts has been developed. The model, named VISIR (discoVerIng Safe and effIcient Routes) is designed to support decision-makers when planning a marine voyage. The first version of the system, VISIR-I, considers medium and small motor vessels with lengths of up to a few tens of metres and a displacement hull. The model is comprised of three components: a route optimization algorithm, a mechanical model of the ship, and a processor of the environmental fields. The optimization algorithm is based on a graph-search method with time-dependent edge weights. The algorithm is also able to compute a voluntary ship speed reduction. The ship model accounts for calm water and added wave resistance by making use of just the principal particulars of the vessel as input parameters. It also checks the optimal route for parametric roll, pure loss of stability, and surfriding/broaching-to hazard conditions. The processor of the environmental fields employs significant wave height, wave spectrum peak period, and wave direction forecast fields as input. The topological issues of coastal navigation (islands, peninsulas, narrow passages) are addressed. Examples of VISIR-I routes in the Mediterranean Sea are provided. The optimal route may be longer in terms of miles sailed and yet it is faster and safer than the geodetic route between the same departure and arrival locations. Time savings up to 2.7 % and route lengthening up to 3.2 % are found for the case studies analysed. However, there is no upper bound for the magnitude of the changes of such route metrics, which especially in case of extreme sea states can be much greater. Route diversions result from the safety constraints and the fact that the algorithm takes into account the full temporal evolution and spatial variability of the environmental fields.
Highlights
The operational availability of high spatial and temporal resolution forecasts, for weather, sea state, and oceanographic variables paves the way to a realm of downstream services, which are increasingly closer to end-user needs (Ryder, 2007)
Following Levadou and Gaillarde (2003) and the wave height criterion reported for L < 100 m in Belenky et al (2011), the parametric roll hazard condition is implemented in VISIR-I as
We have presented the scientific basis of VISIRI, a ship routing system, as well as results of its computation of optimal routes in the Mediterranean Sea
Summary
The operational availability of high spatial and temporal resolution forecasts, for weather, sea state, and oceanographic variables paves the way to a realm of downstream services, which are increasingly closer to end-user needs (Ryder, 2007). Such services may support the decision-making process in critical situations where knowledge of the present and predicted environmental state is key to avoiding casualties or to making savings in terms of time, economic cost, or environmental impact. VISIR [vi’zi:r]1 is a model and an operational system for the on-demand computation of safe and efficient ship routes based on sea-state forecasts.
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