Collision risk assessment for complex navigable waters based on ship dynamic cluster
Article Text (Baidu Translation)
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摘要: 针对复杂通航水域船舶碰撞风险感知时空精细度不足、动态实时性不强等问题,提出了基于船舶动态群组的碰撞风险评估框架;在船舶轨迹数据预处理的基础上,构建了复杂通航水域船舶交通拓扑网络模型,表征区域内船舶碰撞风险的相互作用关系;考虑船舶动态时空变化特性,引入了谱聚类算法进行交通划分,界定船舶动态群组,并通过Davies-Bouldin指数进一步优化船舶动态群组划分策略;基于图论知识,引入船间干扰复杂度量化指标,建立了船舶动态群组风险评估方法,辨识复杂通航水域内船舶碰撞高风险区域;选取典型复杂通航水域——宁波-舟山港核心港区开展研究,采集该水域1个月的船舶交通流数据,评估了多船会遇场景下船舶碰撞风险状态。研究结果表明:通过自适应确定船舶动态群组划分方法,将水域内船舶划分为若干群组,简化船舶碰撞风险关系,同时保留全局范围内最主要的碰撞风险;所提船舶碰撞风险评估方法可保留全局84.98%的风险,与传统基于距离的聚类算法、K-means、层次聚类、带噪声的基于密度的空间聚类(DBSCAN)算法等经典聚类算法相比,本文方法的保留风险值更大,并可以减少不必要的风险关系,在精度、群组紧凑性、尺度均衡性上综合效果最优,可有效降低虚警率、离散区域整体风险;进一步利用所提风险评估方法对8 640个的多船会遇场景的风险状态进行叠加计算,识别出的港区高风险区域与实际调研情况相符。Abstract: To address the challenges of insufficient spatial-temporal granularity and limited real-time dynamics in perceiving collision risk within complex navigable waters, a collision risk assessment framework based on ship dynamic clusters was developed. After preprocessing of ship trajectory data, a ship traffic topology network model for complex navigable waters was constructed to depict the interplay of ship collision risk within the region. By taking into account the dynamic spatial-temporal characteristics of ships, the spectral clustering algorithm was introduced for traffic segmentation, defining ship dynamic clusters. Further optimization of the ship dynamic cluster partitioning strategy was performed through the Davies-Bouldin index. Based on the graph theory, measures for ship interference complexity were introduced to establish a ship dynamic cluster risk assessment method, discerning high-risk collision areas within the complex navigable waters. A study was conducted on a representative complex navigable waters, the core port area of Ningbo-Zhoushan Port, where one-month ship traffic flow data was collected to assess ship collision risk under multi-ship encounter scenarios. Research results show that the proposed adaptive method for ship dynamic cluster partitioning effectively divides ships within navigable waters into several clusters. This approach simplifies ship-to-ship collision risk relationship, while retaining the most critical collision risk across the entire spatial scope. The proposed ship collision risk assesment method preserves 84.98% of the global risk. Compared to traditional distance-based clustering algorithm and other classical clustering algorithms such as K-means, hierarchical clustering, and density-based spatial clustering of applications with noise (DBSCAN), the proposed method has a larger retained risk value and can reduce unnecessary risk relationships. It achieves optimal comprehensive performance in terms of accuracy, cluster compactness, and scale balance, effectively reducing false positive rates and discretizing the overall regional risk. By further utilizing the proposed risk assessment model, the risk states of 8 640 multi-ship encounter scenarios are computed through superimposition, identifying high-risk areas within the port area and align with actual survey results.
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图 13 基于距离度量的群组划分结果
Figure 13. Partitioning result of clusters based on distance measurement
表 1 各聚类算法性能对比
Table 1. Performance comparison of various clustering algorithms
划分方法 划分群组数/个 连边数/条 保留风险值/% 本文方法 15 292 84.98 传统基于距离的聚类算法 15 272 70.36 K-means算法 8 241 79.62 DBSCAN算法 12 399 89.37 层次聚类算法 14 208 62.53 
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表 2 部分船舶动态群组特征
Table 2. Characteristics of partial ship dynamic clusters
群组编号 U X Q J H 群组风险值 7 4 0.80 0.91 1.00 1.50 0.91 6 6 0.74 0.74 1.00 0.50 0.82 8 8 0.37 0.87 1.00 1.00 0.75 4 8 0.24 0.75 0.89 3.56 0.63 1 5 0.16 0.84 0.29 1.77 0.43
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