Cross-programmatic grants from the foundation's science and environmental conservation teams are supporting an international collaboration to create an innovative biodiversity monitoring technology, using new sensor developments and increased power in processing modules at the scale of the Amazon rainforest. The distributed wireless sensor network will allow researchers to study biodiversity under the Amazon canopy.
To learn more, read the full announcement below:
An international team of scientists from Brazil, Australia, and Spain have joined forces to develop the most sophisticated remote monitoring system ever used to track the diminishing biodiversity of South America's Amazon Jungle.
The high tech project will revolutionize the way biodiversity is monitored by creating a distributed, wireless sensor network throughout the jungle with autonomous nodes that continuously monitor wildlife under the canopy of the Amazon Forest.
The international team has been granted nearly US$ 1.5 million by the Gordon and Betty Moore Foundation, a philanthropic funding body established by Gordon Moore — the founder of Intel — to carry out the first stage of this biodiversity monitoring project.
The four research partners involved in the project, dubbed Providence, are meeting in Australia this week to commence phase one.
Dr. Emiliano Esterci Ramalho, researcher and monitoring coordinator at the Mamirauá Institute in Brazil and Project Providence leader, said that one of the major concerns for scientists worldwide is loss of biodiversity and the extinction of species, and that an accurate biodiversity assessment of an area such as the Amazon is essential to help combat the potential loss of wildlife.
“Remote sensing satellites and science aircraft provide a wealth of data about broad changes in forest cover, deforestation and land use, but these methods reveal almost nothing about the true story of biodiversity beneath the forest canopy,” Dr. Ramalho said.
“Biodiversity assessments are difficult to carry out in rugged and remote areas using traditional survey methods. Researchers need to trek into the jungle to count the species they see and hear, and this returns very low detection of most species of interest.” Said Dr. Ramalho.
Alberto Elfes, research scientist at CSIRO’s Data61 and leader of the Australian arm of Providence, said species are being extinguished at a faster rate than we can catalogue them, but accurate biodiversity assessments are difficult to obtain.
“Our technological innovation to monitor biodiversity in the Amazon is on a scale that hasn’t been seen before, and will use multiple technologies including acoustics, visual and thermal imaging. This work will also benefit forest biodiversity research in Australia and other countries worldwide,” Dr. Elfes said.
Tropical forests are rapidly disappearing from our planet due to deforestation from activities such as logging, mining, expanding agriculture and urbanization. Combined with global warming, the result is a dramatic increase in the rate of species extinction and loss of biodiversity.
The Amazon River Basin itself is home to the largest rainforest on Earth. The basin — roughly the size of the United States — covers some 40 percent of the South American continent. This new technology will have a major impact on measuring and preserving the Amazon’s ecosystem, allowing researchers, governments and the public to understand and monitor the impact of changes in forest cover and biodiversity.
“We’ll be collecting data from acoustic sensors (for underwater creatures, as well as terrestrial animals such as birds, frogs and monkeys), visual images, environmental data (wind, temperature, humidity, air pressure), and even thermal images. The animals of key interest in the trial stages are a range of species including jaguars, monkeys, bats, birds, reptiles, river dolphins and fish,” he said.
Phase one of Providence will field test 10 prototype monitoring devices in the Amazon, to create a wireless network of sensor nodes. Phase two will scale up to around 100 nodes in the Amazon basin and phase three will see up to 1000 nodes installed.
Professor Michel André, founder and president of The Sense of Silence Foundation and director of the Laboratory of Applied Bioacoustics of the Technical University of Catalonia, BarcelonaTech, said monitoring wildlife with underwater passive acoustics will be a key technology in this project.
“New sensor developments and increased power in processing modules, originally developed for complex underwater ocean ecosystems, will be applied to the conservation of terrestrial and aquatic creatures for the first time in a large scale environment like the Amazon,” Professor André said.
“One of our biggest challenges is handling a live stream of data containing sounds and images from a tremendous number of known animals, and probably several unknown species, from the smallest bugs to jaguars. This unique biodiversity of sounds will be streamed online so the scientific community and the general public can follow our progress in real-time from the comfort of their lounge room,” he said.
Professor Reginaldo Carvalho, from the Federal University of Amazonas in Brazil, said Providence is a ground-breaking project providing a unique opportunity to apply state-of-the-art technologies that will conserve the Amazon and benefit the whole planet for future generations.
CEO of CSIRO’s Data61, Mr. Adrian Turner, said Project Providence brings together and extends state-of-the-art wildlife monitoring techniques in species identification, data compression and transmission, and energy management.
“The integration of technologies involved in the Providence project will revolutionise the way we monitor biodiversity in tropical forests around the world,” Mr. Turner said.
“Providence will enable, for the first time, the establishment of an accurate recording and assessment system of the biodiversity status of this region in the Amazon, and provide a warning system alerting us to any change that could threaten the amazing wildlife resident there.
“This is the first large scale project where sensor nodes have been designed to incorporate multiple sensors to collect such a wealth of information at one time. By combining multiple sensor modalities, the system will be able to detect a much larger array of species than previous methods,” Mr. Turner said.