Abstract
In Lagrangian dynamics, the detection of coherent clusters can help understand the organization of transport by identifying regions with coherent trajectory patterns. Many clustering algorithms, however, rely on user-input parameters, requiring a priori knowledge about the flow and making the outcome subjective. Building on the conventional spectral clustering method of Hadjighasem et al. (2016), a new optimized-parameter spectral clustering approach is developed that automatically identifies optimal parameters within pre-defined ranges. A noise-based metric for quantifying the coherence of the resulting coherent clusters is also introduced. The optimized-parameter spectral clustering is applied to two benchmark analytical flows, the Bickley Jet and the asymmetric Duffing oscillator, and to a realistic, numerically generated oceanic coastal flow. In the latter case, the identified model-based clusters are tested using observed trajectories of real drifters. In all examples, our approach succeeded in performing the partition of the domain into coherent clusters with minimal inter-cluster similarity and maximum intra-cluster similarity. For the coastal flow, the resulting coherent clusters are qualitatively similar over the same phase of the tide on different days and even different years, whereas coherent clusters for the opposite tidal phase are qualitatively different.
Highlights
In geophysical fluid flows, the Lagrangian approach, where one follows fluid parcels as they move through time and space, provides a natural perspective to study the dynamics of motion and the patterns of transport [1,2,3,4,5]
A reliable method for identifying coherent clusters in oceanic flows is important for a variety of applications – from understanding of mixing and exchanges of biogeophysical tracers, to hazard mitigation and search-and-rescue operations
In studies of exchange processes, coherent clusters can help visualizing tracers that stay coherent over time
Summary
The Lagrangian approach, where one follows fluid parcels as they move through time and space, provides a natural perspective to study the dynamics of motion and the patterns of transport [1,2,3,4,5]. The Lagrangian structures that organize transport and govern coherent trajectory patterns are referred to as Lagrangian Coherent Structures (LCS), a term introduced by Haller and Yuan [8]. These structures act as the hidden skeleton of a flow [9,10] that can be uncovered using techniques from the dynamical systems theory [8,11,12]. Recent review papers of LCS detection methods include [13,14,15,16]
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