Manila Bay Sands| Sustaining Our Planet for Future Generations
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Sustaining Our Planet for Future Generations
Messages in Bottles
Summary
One of the biggest threats to the world's oceans is plastic waste associated with human activity in coastal areas. Plastic waste destroys biodiversity and persists in the ecosystem for centuries, making it toxic to aquatic life and people. While this is a significant issue, related data is often scattered and difficult to understand for non-specialists, which leads to the issue being downplayed. Recent breakthroughs in tracking coastal plastic waste through remote sensing have been made, but it is not effectively communicated to the public. Our solution aims to bridge that with an online platform that visualizes satellite data and research on plastic waste in coastal waters.
How We Addressed This Challenge
Messages in Bottles (MiBs) is an online platform containing interactive visualizations and information on coastal plastic waste using remote sensing data from ESA’s earth observation platform Sentinel-2. Inspired by the work of Dr. Biermann, Dr. Clewley, Dr. Martinez-Vicente, and Dr. Topouzelis entitled “Finding Plastic Patches in Coastal Waters using Optical Satellite Data”, our solution bridges the gap between their research and the general public in the interest of providing a full picture on the severity of this problem to everyone.
The platform contains an interactive world map highlighting some coastal communities capable of being sources of plastic waste. Users can click on these areas and will be shown summarized information on the region’s coastal plastic waste. Given the time constraints, regions of interest were selected based on the findings of the aforementioned study since the presence of plastic waste has been verified and atmospheric conditions all accounted for. We expanded this method to other new regions of interest as well that we suspect to contain coastal plastic waste.
The remote sensing data was collected from Sentinel-2 through the Copernicus Open Access Hub, searching for regions of interest during timeframes with atmospheric conditions conducive to identifying coastal plastic waste. This project focuses on visualization instead of time-series prediction; though the latter is an area for future improvement. The following are the steps taken to prepare the data for visualization:
- Sentinel-2 L1C data was collected.
- The data was observed and processed with Sentinel Toolboxes in the Sentinel Application Platform (SNAP).
- Atmospheric correction was applied using ACOLITE Dark Spectrum Fitting Algorithm and Python.
- Land-Sea Masking within SNAP was applied to isolate bodies of water.
- The Normalized Difference Vegetation Index (NDVI) and Floating Debris Index (FDI) were calculated to isolate suspected floating plastic waste by their reflectance.
- The FDI is a novel index developed by Dr. Biermann, Dr. Clewley, Dr. Martinez-Vicente, and Dr. Topouzelis specifically for detecting suspected coastal plastic waste.
- Suspected plastics were then masked and saved as a TXT file (SNAP output)
- The post process text file output was translated to JSON and used along with the coordinates that were processed with Pandas for use in the web app.
How We Developed This Project
One difficulty common to all areas of scientific research is communicating information to the general public. This is particularly troublesome in the field of marine environmental science where educating the public is crucial to sparking action that could lead to cleaner seas. While the information age has opened up countless opportunities for research in academe, the data is not necessarily accessible and comprehensible to non-specialists. Our project aims to be the framework for which marine environmental science research can be packaged into easily understandable visual and text information to communicate the dire state of our oceans to the general public. In the interest of arousing a passion for working towards cleaner seas, this project is a crucial step. Our approach was inspired by the work of Dr. Biermann, Dr. Clewley, Dr. Martinez-Vicente, and Dr. Topouzelis who used remote sensing data and their novel Floating Debris Index to detect suspected plastic waste patches in coastal waters, and then a Naive Bayes classifier to confirm the presence of plastic waste. We believe this proof of concept can be applied into a framework for the visualization of other marine environmental science research. Once the public is sufficiently informed, a grassroots movement can head towards international collaboration for making the oceans clean once again.
How We Used Space Agency Data in This Project
Using Sentinel-2 Level 1C data publicly available on the Copernicus Science Hub page, we decided to try the methods used in the paper of Biermann et al. We decided to try to observe the ocean for patches using Sentinel-3 data, but after experimentation as well as consultation with the authors of the paper, Sentinel-3 data could not effectively identify floating patches at its rated resolution. This caused us to focus more on coastal areas. Future progress on this project will be made by developing more discriminatory data processing algorithms for other satellite platforms to be able to distinguish floating plastic waste, like Sentinel-3. Sentinel-3 has the advantage of providing data in the open ocean to track the Great Pacific Garbage Patch, while Sentinel-2 is restricted to coastal waters and landmasses.
Datasets obtained through satellite remote sensing have several advantages over traditional plane or research boat based chartered surveys. Plane flights and expeditions need to be scheduled in advance and require the foresight to plan around specific dates, but satellites have constant uptime during their whole service period. Plane and boat surveys have the advantage of higher resolution, but Biermann et al. proved that remote sensing using the Sentinel-2 platform is able to distinguish floating debris on the ocean surface. Moreover, it can distinguish plastics from floating algae, pumice or other materials.
Project Demo
Project Code
Data & Resources
Tools
- https://sentinel.esa.int/web/sentinel/toolboxes/sentinel-2
- https://odnature.naturalsciences.be/remsem/software-and-data/acolite
- https://scihub.copernicus.eu/
- https://docs.google.com/
- https://drive.google.com/
- https://earth.google.com/
Datasets
- Sentinel-2, European Space Agency
Literature
- Biermann, L., Clewley, D., Martinez-Vicente, V., & Topouzelis, K. (2020, April 23). Finding Plastic Patches in Coastal Waters using Optical Satellite Data. Retrieved October 03, 2020, from https://www.nature.com/articles/s41598-020-62298-z
- Hu, C. (2009). A novel ocean color index to detect floating algae in the global oceans. Remote Sensing of Environment, 113(10), 2118-2129. doi:10.1016/j.rse.2009.05.012
- Topouzelis, K., Papageorgiou, D., Karagaitanakis, A., Papakonstantinou, A., & Ballesteros, M. (2020, June 23). Remote Sensing of Sea Surface Artificial Floating Plastic Targets with Sentinel-2 and Unmanned Aerial Systems (Plastic Litter Project 2019). Retrieved October 04, 2020, from https://www.mdpi.com/2072-4292/12/12/2013/htm
- Shirah, G., & Mitchell, H. (2015, August 10). SVS: Garbage Patch Visualization Experiment. Retrieved October 04, 2020, from https://svs.gsfc.nasa.gov/cgi-bin/details.cgi?aid=4174
- The Ocean Cleanup. (2013). Retrieved from https://theoceancleanup.com/