Tag: sensing

Mitigating animal-vehicle collisions with field sensors, artificial intelligence and ecological modelling

A French research team has developed a method for mapping the risk of collisions between animals and vehicles along transport infrastructures.

Collisions between animals and vehicles are a threat to conservation efforts and human safety, and have a massive cost for transport infrastructure managers and users.

Using the opportunities offered by the increasing number of sensors embedded into transport infrastructures and the development of their digital twins, a French research team has developed a method aiming at managing animal-vehicle collisions. The goal is to map the collision risk between trains and ungulates (roe deer and wild boar) by deploying a camera trap network.

Roe deer crossing a railway, photographed by a field sensor and automatically identified with artificial intelligence. Image credit: TerrOïko

Led by Sylvain Moulherat and Léa Pautrel, from OïkoLab and TerrOïko, France, the study is published in the open-access journal Nature Conservation.

Connecting people, connecting landscapes: a new special issue from Nature Conservation

The proposed method starts by simulating the most probable movements of animals within and around an infrastructure using an ecological modelling software. This allows the assessment of where they are most likely to cross.

After identifying these collision hotspots, ecological modelling is used again to assist with the design of photo sensor deployment in the field. Various deployment scenarios are modelled to find the one whose predicted results are most consistent with the initial simulation.

Example of a map showing the estimated relative abundance of a species along a railway section. The higher the abundance, the higher the collision risk. Image credit: TerrOïko

Once sensors are deployed, the data collected (in this case, photos) are processed through artificial intelligence (deep learning) to detect and identify species at the infrastructure’s vicinity.

Finally, the processed data are fed into an abundance model, which is another type of ecological model. It is used to estimate the probable density of animals in every part of a studied area using data collected at only a few points in that area. The result is a map showing the relative abundance of species and, therefore, the collision risk along an infrastructure.

This method was implemented on an actual section of railway in south-western France, but it can be applied to any type of transport infrastructure. It may be implemented not only on existing infrastructures but also during the conception phase of new ones (as part of the environmental impact assessment strategy).

Such a method paves the way for the integration of biodiversity-oriented monitoring systems into transport infrastructures and their digital twins. As sensors collect data continuously, it could be improved in the future to provide real-time driver information and produce dynamic adaptive maps that could be ultimately sent to autonomous vehicles.

Original source

Moulherat S, Pautrel L, Debat G, Etienne M-P, Gendron L, Hautière N, Tarel J-P, Testud G, Gimenez O (2024) Biodiversity monitoring with intelligent sensors: An integrated pipeline for mitigating animal-vehicle collisions. In: Papp C-R, Seiler A, Bhardwaj M, François D, Dostál I (Eds) Connecting people, connecting landscapes. Nature Conservation 57: 103-124. https://doi.org/10.3897/natureconservation.57.108950 

Novel tech for research & protection of marine biodiversity: Pensoft joins EU project ANERIS

Pensoft joins the ANERIS consortium as an expert in science communication with the goal to engage stakeholders and build an active community

Coastal and marine biodiversity has been declining at an alarming rate in recent years due to anthropogenic activity, climate change, ocean acidification and other factors. 

To help protect and preserve these precious ecosystems, the new research project under the name of ANERIS (operAtional seNsing lifE technologies for maRIne ecosystemS) and coordinated by the Institute of Marine Sciences (ICM-CSIC) was launched under the Horizon Europe program.

ANERIS aims to contribute to improving the understanding, monitoring and protection of these ecosystems through technological, scientific and methodological innovation in the fields of marine life-sensing and monitoring.

Pensoft is joining the ANERIS consortium as a leader of WP6 Exploitation, Communication and Networking. The Pensoft team is to develop and implement sustainable communication and dissemination strategies, which will ensure the impactful knowledge exchange between partners and external stakeholders.

In addition, Pensoft is responsible for the development of a long-lasting brand identity of the project, which shall be reached by establishing and maintaining a user-friendly and eye-appealing public website. The overall visual identity of ANERIS will be supported by a set of innovatively-designed promotional materials

The project

ANERIS project’s intro video: Towards a network of Operational Marine Biology

ANERIS launched in January 2023 and will be running until December 2026 with the support of EUR 10 million of funding provided by the European Union’s Horizon Europe program and the work on the project officially kicked off with the project’s first consortium meeting, which took place on the 8th and 9th of March 2023 in Barcelona, Spain. 

The joint mission of the ANERIS partners for the next four years is to build the next generation of marine-sensing instruments and infrastructure for systematic routine measurements and monitoring of oceanic and coastal life, and their rapid interpretation and dissemination to all interested stakeholders.

In total, ANERIS aims to pioneer 11 novel technologies rerelated to marine ecosystem monitoring, data processing and dissemination:

  • NANOMICS – NAnopore sequeNcing for Operational Marine genomICS
  • MARGENODAT – workflows for the MARine GENOmics DAta managemenT
  • SLIM-2.0 – A Virtual Environment for genomic data analysis (ANERIS extended version)
  • EMUAS – Expandable Multi-imaging Underwater Acquisition System
  • AIES-ZOO – Automatic Information Extraction System for ZOOplankton images
  • AIES-PHY – Automatic Information Extraction System for PHYtoplankton images
  • ATIRES – Automatic underwaTer Image REstoration System
  • AIES-MAC – Automatic Information Extraction System for MACroorganisms
  • AMAMER – Advanced Multiplatform App for Marine lifE Reporting
  • AMOVALIH – Advanced Marine Observations VALidation-Identification system based on Hybrid intelligence
  • AWIMAR – Adaptive Web Interfaces for MARine life reporting, sharing and consulting

These technologies will be validated across four ANERIS case studies which aim to bridge the gaps between existing technologies and incorporate them into a functional technological framework:

  • High-temporal resolution marine life monitoring in research infrastructure observatories;
  • Improved spatial and temporal resolution of marine life monitoring based on genomics;
  • Large scale marine participatory actions;
  • Merging imaging and genomic information in different monitoring scenarios.

The final goal of the project through the creation and validation of these novel technologies and involving academia, industry, governments and civil society, is to build up the concept of Operational Marine Biology (OMB) to provide faster, higher quality, reliable, and accessible marine and coastal life data. OMB opens the door for near-real-time marine observations, data interpretation and decision making based on that data.

International Consortium

The interdisciplinary ANERIS consortium consists of 25 partnering organisations from 13 countries around Europe, the Mediterranean basin and Israel, bringing diverse expertise spanning from robotics, biooptics, marine biology and genomics, to programming and sustainability.

Many partners represent acclaimed scientific institutions with rich experience in collaboration in EU projects, specifically in the fields of marine research.

Full list of partners:

Visit the ANERIS website on https://www.aneris.eu/. You can also follow the project on Twitter (@ANERISproject), LinkedIn (/ANERIS Project) and Instagram (@aneris_project).