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Article ? AI-assigned paper type based on the abstract. Classification may not be perfect — flag errors using the feedback button. Tier 2 ? Original research — experimental, observational, or case-control study. Direct primary evidence. Environmental Sources Marine & Wildlife Policy & Risk Sign in to save

Advancing Floating Macroplastic Detection from Space Using Experimental Hyperspectral Imagery

Remote Sensing 2021 77 citations ? Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count. Score: 45 ? 0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.
Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Paolo Tasseron Paolo Tasseron Paolo Tasseron Paolo Tasseron Paolo Tasseron Paolo Tasseron Paolo Tasseron Lauren Biermann, Lauren Biermann, Louise Schreyers, Louise Schreyers, Louise Schreyers, Louise Schreyers, Louise Schreyers, Louise Schreyers, Louise Schreyers, Louise Schreyers, Louise Schreyers, Louise Schreyers, Louise Schreyers, Louise Schreyers, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Louise Schreyers, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Louise Schreyers, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Paolo Tasseron Louise Schreyers, Paolo Tasseron Tim van Emmerik, Tim van Emmerik, Louise Schreyers, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Louise Schreyers, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Louise Schreyers, Joseph Peller, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Louise Schreyers, Louise Schreyers, Louise Schreyers, Louise Schreyers, Lauren Biermann, Joseph Peller, Joseph Peller, Lauren Biermann, Lauren Biermann, Paolo Tasseron Tim van Emmerik, Tim van Emmerik, Lauren Biermann, Tim van Emmerik, Tim van Emmerik, Louise Schreyers, Lauren Biermann, Tim van Emmerik, Lauren Biermann, Lauren Biermann, Louise Schreyers, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Louise Schreyers, Lauren Biermann, Lauren Biermann, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Paolo Tasseron Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Lauren Biermann, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Lauren Biermann, Lauren Biermann, Louise Schreyers, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Tim van Emmerik, Louise Schreyers, Paolo Tasseron

Summary

Researchers tested experimental hyperspectral airborne imagery to detect floating macroplastics in rivers and the ocean, demonstrating that combining spectral and spatial features improves detection accuracy over single-band approaches.

Airborne and spaceborne remote sensing (RS) collecting hyperspectral imagery provides unprecedented opportunities for the detection and monitoring of floating riverine and marine plastic debris. However, a major challenge in the application of RS techniques is the lack of a fundamental understanding of spectral signatures of water-borne plastic debris. Recent work has emphasised the case for open-access hyperspectral reflectance reference libraries of commonly used polymer items. In this paper, we present and analyse a high-resolution hyperspectral image database of a unique mix of 40 virgin macroplastic items and vegetation. Our double camera setup covered the visible to shortwave infrared (VIS-SWIR) range from 400 to 1700 nm in a darkroom experiment with controlled illumination. The cameras scanned the samples floating in water and captured high-resolution images in 336 spectral bands. Using the resulting reflectance spectra of 1.89 million pixels in linear discriminant analyses (LDA), we determined the importance of each spectral band for discriminating between water and mixed floating debris, and vegetation and plastics. The absorption peaks of plastics (1215 nm, 1410 nm) and vegetation (710 nm, 1450 nm) are associated with high LDA weights. We then compared Sentinel-2 and Worldview-3 satellite bands with these outcomes and identified 12 satellite bands to overlap with important wavelengths for discrimination between the classes. Lastly, the Normalised Vegetation Difference Index (NDVI) and Floating Debris Index (FDI) were calculated to determine why they work, and how they could potentially be improved. These findings could be used to enhance existing efforts in monitoring macroplastic pollution, as well as form a baseline for the design of future multispectral RS systems.

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