A team of experts in artificial intelligence and animal ecology have put forth a new, cross-disciplinary approach intended to enhance research on wildlife species and make more effective use of the vast amounts of data now being collected thanks to new technology.
From:
Ecole Polytechnique Fédérale de Lausanne
February 8, 2022 -- The field of animal
ecology has entered the era of big data and the Internet of Things.
Unprecedented amounts of data are now being collected on wildlife populations,
thanks to sophisticated technology such as satellites, drones and terrestrial
devices like automatic cameras and sensors placed on animals or in their
surroundings. These data have become so easy to acquire and share that they
have shortened distances and time requirements for researchers while minimizing
the disrupting presence of humans in natural habitats. Today, a variety of AI
programs are available to analyze large datasets, but they're often general in
nature and ill-suited to observing the exact behavior and appearance of wild
animals. A team of scientists from EPFL and other universities has outlined a
pioneering approach to resolve that problem and develop more accurate models by
combining advances in computer vision with the expertise of ecologists. Their
findings, which appear today in Nature Communications, open up new
perspectives on the use of AI to help preserve wildlife species.
Building up cross-disciplinary know-how
Wildlife research has gone from local to
global. Modern technology now offers revolutionary new ways to produce more
accurate estimates of wildlife populations, better understand animal behavior,
combat poaching and halt the decline in biodiversity. Ecologists can use AI,
and more specifically computer vision, to extract key features from images,
videos and other visual forms of data in order to quickly classify wildlife
species, count individual animals, and glean certain information, using large
datasets. The generic programs currently used to process such data often work
like black boxes and don't leverage the full scope of existing knowledge about
the animal kingdom. What's more, they're hard to customize, sometimes suffer
from poor quality control, and are potentially subject to ethical issues
related to the use of sensitive data. They also contain several biases,
especially regional ones; for example, if all the data used to train a given
program were collected in Europe, the program might not be suitable for other
world regions.
"We wanted to get more researchers
interested in this topic and pool their efforts so as to move forward in this
emerging field. AI can serve as a key catalyst in wildlife research and
environmental protection more broadly," says Prof. Devis Tuia, the head of
EPFL's Environmental Computational Science and Earth Observation Laboratory and
the study's lead author. If computer scientists want to reduce the margin of
error of an AI program that's been trained to recognize a given species, for
example, they need to be able to draw on the knowledge of animal ecologists.
These experts can specify which characteristics should be factored into the program,
such as whether a species can survive at a given latitude, whether it's crucial
for the survival of another species (such as through a predator-prey
relationship) or whether the species' physiology changes over its lifetime.
"We used this approach to improve a bear-recognition program a few years
ago," says Prof. Mackenzie Mathis, a neuroscientist at EPFL and co-author
of the study. "A researcher studying bear DNA had installed automatic
cameras in bear habitats in order to recognize individual animals. But bears
shed half of their body fat when they hibernate, meaning the generic programs
she used were no longer able to recognize the bears once the season changed. We
therefore added criteria to the program that can not only look at whether an
animal has a given characteristic, but also be tweaked manually to allow for
possible deviations."
Getting the word out about existing
initiatives
The idea of forging stronger ties
between computer vision and ecology came up as Tuia, Mathis and others
discussed their research challenges at various conferences over the past two
years. They saw that such collaboration could be extremely useful in preventing
certain wildlife species from going extinct. A handful of initiatives have
already been rolled out in this direction; some of them are listed in the Nature
Communications article. For instance, Tuia and his team at EPFL have
developed a program that can recognize animal species based on drone images. It
was tested recently on a seal population. Meanwhile, Mathis and her colleagues
have unveiled an open-source software package called DeepLabCut that allows
scientists to estimate and track animal poses with remarkable accuracy. It's
already been downloaded 300,000 times. DeepLabCut was designed for lab animals
but can be used for other species as well. Researchers at other universities
have developed programs too, but it's hard for them to share their discoveries
since no real community has yet been formed in this area. Other scientists
often don't know these programs exist or which one would be best for their
specific research.
That said, initial steps towards such a
community have been taken through various online forums. The Nature
Communications article aims for a broader audience, however,
consisting of researchers from around the world. "A community is steadily
taking shape," says Tuia. "So far we've used word of mouth to build
up an initial network. We first started two years ago with the people who are
now the article's other lead authors: Benjamin Kellenberger, also at EPFL; Sara
Beery at Caltech in the US; and Blair Costelloe at the Max Planck Institute in
Germany."
https://www.sciencedaily.com/releases/2022/02/220208105313.htm
No comments:
Post a Comment