Humans and robots are joining forces to restore coral reefs on a massive scale. But here's where it gets controversial: it's not just about the technology, it's about the collaboration between humans and machines. And this is the part most people miss: it's not just about the robots, it's about the human element too.
The Deployment Guidance System (DGS) is a groundbreaking collaboration between marine robotics and artificial intelligence. It aims to place young corals, housed in purpose-built devices, across the Great Barrier Reef in locations where they are likely to grow to adulthood. This ambitious project is designed to be near impossible or incredibly costly to achieve with manual labor and human decision-making alone.
"The system is not so much one technology as many, brought together in a workflow that improves the yield for our coral seeding efforts," explains Dr. Ben Moshirian, the project engineer behind the DGS. "The aim is to ensure coral seeding devices are accurately and safely deployed in pre-specified locations."
The devices, small ceramic objects housing tiles to which juvenile corals attach, are designed for the specific needs of large-scale reef restoration. Once dropped to the seafloor, they help protect the young corals, giving them a better chance of reaching adulthood.
Setting engines to warp seed
The coral seeding devices need to be dropped in prime locations across a vast area. The DGS will help achieve this in several ways. First, the system selects promising sites using a computer model based on knowledge provided by reef ecologists. Then, once on the water at a suitable location, the system uses cameras and real-time AI analysis to guide the deployment of reef seeding devices. The DGS releases the devices from the vessel at the optimum moment, with this decision-making informed by years of oceanographic and ecological observations by scientists.
Autonomy is an important goal here. The system has been developed to provide autonomous vessel guidance, a bit like autopilot, and to automatically deploy the coral devices in suitable locations. However, if you prefer to come back to the site later to deploy the corals yourself, the DGS has inbuilt geo-tagging to record the location of deployment sites. This feature also allows scientists to easily return to and monitor sites as the young corals grow in years to come.
Brace for scientific impact
The data models underpinning the system are based on knowledge gained throughout the last five years by RRAP's Modelling and Decision Support, EcoRRAP, and Coral Aquaculture and Deployment teams, and the AI systems developed by T2D through collaboration between Queensland University of Technology (QUT) and AIMS. As coral seeding deployments roll out, and our understanding evolves, so will the modeling of the DGS.
"This technology is not about machines replacing humans. It is about humans working with machines, to give our science impact at a scale which was difficult to achieve previously," Dr. Moshirian said. Ideally, the system would be able to operate from many different vessels. This would create opportunities for collaboration with a range of maritime operators, from Traditional Owners to tourism companies, who don’t operate specialist research vessels.
Trials on the water are underway on five-meter vessels in inshore waters, and on much smaller tenders which are typically used on the outer reef. These test the real-world capabilities of the AI and automation, but also answer more fundamental questions such as: how much space is needed onboard to accommodate all the DGS kit?
While testing is currently limited to crewed vessels, in the future, it is hoped the system will also run from autonomous surface vessels (ASVs) to increase the scale of coral seeding even further. But for Dr. Moshirian, this robotics venture will always have a human heart. "That’s the magic in the project. To be able to bring people together across so many domains to work as one."
The Deployment Guidance System is one of several innovations developed as part of the Reef Restoration and Adaptation Program (RRAP). RRAP is funded by the partnership between the Australian Government’s Reef Trust and the Great Barrier Reef Foundation and is a consortium of the Australian Institute of Marine Science, the Great Barrier Reef Foundation, CSIRO, Queensland University of Technology, James Cook University, the University of Queensland, and Southern Cross University.
The DGS will be trialed and developed under the Pilot Deployments Program, the operational testing component of the RRAP.
