A multi-objective optimization framework for reducing the impact of ship noise on marine mammals

The underwater radiated noise (URN) emanating from ships presents a significant threat to marine mammals, given their heavy reliance on hearing for essential life activities. The intensity of URN from ships is directly correlated to the speed, making speed reduction a crucial operational mitigation strategy. This paper presents a new multi-objective optimization framework to optimize the ship speed for effective URN mitigation without compromising fuel consumption. The proposed framework addresses a fixed-path voyage scheduling problem, incorporating two objective functions namely (i) noise intensity levels and (ii) fuel consumption. The optimization is performed using the state-of-the-art non-dominated sorting genetic algorithm under voyage constraints. A 2D ocean acoustic environment, comprising randomly scattered marine mammals of diverse audiogram groups and realistic conditions, including sound speed profiles and bathymetry, is simulated. To estimate the objective functions, we consider empirical relations for fuel consumption and near-field noise modeling together with a ray-tracing approach for far-field noise propagation. The optimization problem is solved using the genetic algorithm to determine the Pareto solutions and subsequently the trade-off solution. The effectiveness of the optimization framework is demonstrated via both simplified tests and practical case studies involving a large container ship. A comparative analysis illustrates the adaptability of the optimization framework across different oceanic environments, affirming its potential as a robust tool for reducing the URN from shipping.