Opportunities and challenges for monitoring terrestrial biodiversity in the robotics age

Stephen Pringle; Martin Dallimer; Mark Goddard; Léni Le Goff; Emma Hart; Simon Langdale; Jessica Fisher; Sara-Adela Abad; Marc Ancrenaz; Fabio Angeoletto; Fernando Auat Cheein; Gail Austen; Joseph Bailey; Katherine Baldock; Lindsay Banin; Cristina Banks-Leite; Aliyu Barau; Reshu Bashyal; Adam Bates; Jake Bicknell; Jon Bielby; Petra Bosilj; Emma Bush; Simon Butler; Dan Carpenter; Christopher Clements; Antoine Cully; Kendi Davies; Nicolas Deere; Michael Dodd; Rosie Drinkwater; Don Driscoll; Guillaume Dutilleux; Mads Dyrmann; David Edwards; Mohammad Farhadinia; Aisyah Faruk; Richard Field; Robert Fletcher; Chris Foster; Richard Fox; Richard Francksen; Aldina Franco; Alison Gainsbury; Charlie Gardner; Ioanna Giorgi; Richard Griffiths; Salua Hamaza; Marc Hanheide; Matt Hayward; Marcus Hedblom; Thorunn Helgason; Sui Heon; Kevin Hughes; Edmund Hunt; Daniel Ingram; George Jackson-Mills; Kelly Jowett; Timothy Keitt; Laura Kloepper; Stephanie Kramer-Schadt; Jim Labisko; Frédéric Labrosse; Jenna Lawson; Nicolas Lecomte; Ricardo de Lima; Nick Littlewood; Harry Marshall; Giovanni Masala; Lindsay Maskell; Eleni Matechou; Barbara Mazzolai; Alistair McConnell; Brett Melbourne; Aslan Miriyev; Eric Djomo Nana; Alessandro Ossola; Sarah Papworth; Catherine Parr; Ana Payo-Payo; Gad Perry; Nathalie Pettorelli; Rajeev Pillay; Simon Potts; Miranda Prendergast-Miller; Lan Qie; Persie Rolley-Parnell; Stephen Rossiter; Marcus Rowcliffe; Heather Rumble; Jon Sadler; Christopher Sandom; Asiem Sanyal; Franziska Schrodt; Sarab Sethi; Adi Shabrani; Robert Siddall; Simón Smith; Robbert Snep; Carl Soulsbury; Margaret Stanley; Philip Stephens; P.J. Stephenson; Matthew Struebig; Matthew Studley; Martin Svátek; Gilbert Tang; Nicholas Taylor; Kate Umbers; Robert Ward; Patrick White; Mark Whittingham; Serge Wich; Christopher Williams; Ibrahim Yakubu; Natalie Yoh; Syed Zaidi; Anna Zmarz; Joeri Zwerts; Zoe Davies

doi:10.1038/s41559-025-02704-9

Opportunities and challenges for monitoring terrestrial biodiversity in the robotics age

Stephen Pringle
, Martin Dallimer
, Mark Goddard
, Léni Le Goff
, Emma Hart
, Simon Langdale
, Jessica Fisher
, Sara-Adela Abad
, Marc Ancrenaz
, Fabio Angeoletto
, Fernando Auat Cheein
, Gail Austen
, Joseph Bailey
, Katherine Baldock
, Lindsay Banin
, Cristina Banks-Leite
, Aliyu Barau
, Reshu Bashyal
, Adam Bates
, Jake Bicknell

Jon Bielby, Petra Bosilj, Emma Bush, Simon Butler, Dan Carpenter, Christopher Clements, Antoine Cully, Kendi Davies, Nicolas Deere, Michael Dodd, Rosie Drinkwater, Don Driscoll, Guillaume Dutilleux, Mads Dyrmann, David Edwards, Mohammad Farhadinia, Aisyah Faruk, Richard Field, Robert Fletcher, Chris Foster, Richard Fox, Richard Francksen, Aldina Franco, Alison Gainsbury, Charlie Gardner, Ioanna Giorgi, Richard Griffiths, Salua Hamaza, Marc Hanheide, Matt Hayward, Marcus Hedblom, Thorunn Helgason, Sui Heon, Kevin Hughes, Edmund Hunt, Daniel Ingram, George Jackson-Mills, Kelly Jowett, Timothy Keitt, Laura Kloepper, Stephanie Kramer-Schadt, Jim Labisko, Frédéric Labrosse, Jenna Lawson, Nicolas Lecomte, Ricardo de Lima, Nick Littlewood, Harry Marshall, Giovanni Masala, Lindsay Maskell, Eleni Matechou, Barbara Mazzolai, Alistair McConnell, Brett Melbourne, Aslan Miriyev, Eric Djomo Nana, Alessandro Ossola, Sarah Papworth, Catherine Parr, Ana Payo-Payo, Gad Perry, Nathalie Pettorelli, Rajeev Pillay, Simon Potts, Miranda Prendergast-Miller, Lan Qie, Persie Rolley-Parnell, Stephen Rossiter, Marcus Rowcliffe, Heather Rumble, Jon Sadler, Christopher Sandom, Asiem Sanyal, Franziska Schrodt, Sarab Sethi, Adi Shabrani, Robert Siddall, Simón Smith, Robbert Snep, Carl Soulsbury, Margaret Stanley, Philip Stephens, P.J. Stephenson, Matthew Struebig, Matthew Studley, Martin Svátek, Gilbert Tang, Nicholas Taylor, Kate Umbers, Robert Ward, Patrick White, Mark Whittingham, Serge Wich, Christopher Williams, Ibrahim Yakubu, Natalie Yoh, Syed Zaidi, Anna Zmarz, Joeri Zwerts, Zoe Davies

University of Cumbria

Research output: Contribution to journal › Journal Article › peer-review

Abstract

With biodiversity loss escalating globally, a step change is needed in our capacity to accurately monitor species populations across ecosystems. Robotic and autonomous systems (RAS) offer technological solutions that may substantially advance terrestrial biodiversity monitoring, but this potential is yet to be considered systematically. We used a modified Delphi technique to synthesize knowledge from 98 biodiversity experts and 31 RAS experts, who identified the major methodological barriers that currently hinder monitoring, and explored the opportunities and challenges that RAS offer in overcoming these barriers. Biodiversity experts identified four barrier categories: site access, species and individual identification, data handling and storage, and power and network availability. Robotics experts highlighted technologies that could overcome these barriers and identified the developments needed to facilitate RAS-based autonomous biodiversity monitoring. Some existing RAS could be optimized relatively easily to survey species but would require development to be suitable for monitoring of more 'difficult' taxa and robust enough to work under uncontrolled conditions within ecosystems. Other nascent technologies (for instance, new sensors and biodegradable robots) need accelerated research. Overall, it was felt that RAS could lead to major progress in monitoring of terrestrial biodiversity by supplementing rather than supplanting existing methods. Transdisciplinarity needs to be fostered between biodiversity and RAS experts so that future ideas and technologies can be codeveloped effectively.

Original language	English
Pages (from-to)	1031-1042
Number of pages	21
Journal	Nature Ecology & Evolution
Volume	9
Issue number	6
Early online date	22 May 2025
DOIs	https://doi.org/10.1038/s41559-025-02704-9
Publication status	Published - 1 Jun 2025

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Pringle, S., Dallimer, M., Goddard, M., Le Goff, L., Hart, E., Langdale, S., Fisher, J., Abad, S.-A., Ancrenaz, M., Angeoletto, F., Auat Cheein, F., Austen, G., Bailey, J., Baldock, K., Banin, L., Banks-Leite, C., Barau, A., Bashyal, R., Bates, A., ... Davies, Z. (2025). Opportunities and challenges for monitoring terrestrial biodiversity in the robotics age. Nature Ecology & Evolution, 9(6), 1031-1042. https://doi.org/10.1038/s41559-025-02704-9

@article{120f0738e302487e918cafb4b9d452f3,

title = "Opportunities and challenges for monitoring terrestrial biodiversity in the robotics age",

abstract = "With biodiversity loss escalating globally, a step change is needed in our capacity to accurately monitor species populations across ecosystems. Robotic and autonomous systems (RAS) offer technological solutions that may substantially advance terrestrial biodiversity monitoring, but this potential is yet to be considered systematically. We used a modified Delphi technique to synthesize knowledge from 98 biodiversity experts and 31 RAS experts, who identified the major methodological barriers that currently hinder monitoring, and explored the opportunities and challenges that RAS offer in overcoming these barriers. Biodiversity experts identified four barrier categories: site access, species and individual identification, data handling and storage, and power and network availability. Robotics experts highlighted technologies that could overcome these barriers and identified the developments needed to facilitate RAS-based autonomous biodiversity monitoring. Some existing RAS could be optimized relatively easily to survey species but would require development to be suitable for monitoring of more 'difficult' taxa and robust enough to work under uncontrolled conditions within ecosystems. Other nascent technologies (for instance, new sensors and biodegradable robots) need accelerated research. Overall, it was felt that RAS could lead to major progress in monitoring of terrestrial biodiversity by supplementing rather than supplanting existing methods. Transdisciplinarity needs to be fostered between biodiversity and RAS experts so that future ideas and technologies can be codeveloped effectively.",

author = "Stephen Pringle and Martin Dallimer and Mark Goddard and \{Le Goff\}, L{\'e}ni and Emma Hart and Simon Langdale and Jessica Fisher and Sara-Adela Abad and Marc Ancrenaz and Fabio Angeoletto and \{Auat Cheein\}, Fernando and Gail Austen and Joseph Bailey and Katherine Baldock and Lindsay Banin and Cristina Banks-Leite and Aliyu Barau and Reshu Bashyal and Adam Bates and Jake Bicknell and Jon Bielby and Petra Bosilj and Emma Bush and Simon Butler and Dan Carpenter and Christopher Clements and Antoine Cully and Kendi Davies and Nicolas Deere and Michael Dodd and Rosie Drinkwater and Don Driscoll and Guillaume Dutilleux and Mads Dyrmann and David Edwards and Mohammad Farhadinia and Aisyah Faruk and Richard Field and Robert Fletcher and Chris Foster and Richard Fox and Richard Francksen and Aldina Franco and Alison Gainsbury and Charlie Gardner and Ioanna Giorgi and Richard Griffiths and Salua Hamaza and Marc Hanheide and Matt Hayward and Marcus Hedblom and Thorunn Helgason and Sui Heon and Kevin Hughes and Edmund Hunt and Daniel Ingram and George Jackson-Mills and Kelly Jowett and Timothy Keitt and Laura Kloepper and Stephanie Kramer-Schadt and Jim Labisko and Fr{\'e}d{\'e}ric Labrosse and Jenna Lawson and Nicolas Lecomte and \{de Lima\}, Ricardo and Nick Littlewood and Harry Marshall and Giovanni Masala and Lindsay Maskell and Eleni Matechou and Barbara Mazzolai and Alistair McConnell and Brett Melbourne and Aslan Miriyev and Nana, \{Eric Djomo\} and Alessandro Ossola and Sarah Papworth and Catherine Parr and Ana Payo-Payo and Gad Perry and Nathalie Pettorelli and Rajeev Pillay and Simon Potts and Miranda Prendergast-Miller and Lan Qie and Persie Rolley-Parnell and Stephen Rossiter and Marcus Rowcliffe and Heather Rumble and Jon Sadler and Christopher Sandom and Asiem Sanyal and Franziska Schrodt and Sarab Sethi and Adi Shabrani and Robert Siddall and Sim{\'o}n Smith and Robbert Snep and Carl Soulsbury and Margaret Stanley and Philip Stephens and P.J. Stephenson and Matthew Struebig and Matthew Studley and Martin Sv{\'a}tek and Gilbert Tang and Nicholas Taylor and Kate Umbers and Robert Ward and Patrick White and Mark Whittingham and Serge Wich and Christopher Williams and Ibrahim Yakubu and Natalie Yoh and Syed Zaidi and Anna Zmarz and Joeri Zwerts and Zoe Davies",

note = "Richard M. Francksen, Senior Lecturer and Programme Leader for BSc. (Hons.) Zoology, University of Cumbria, UK. This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made.",

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Pringle, S, Dallimer, M, Goddard, M, Le Goff, L, Hart, E, Langdale, S, Fisher, J, Abad, S-A, Ancrenaz, M, Angeoletto, F, Auat Cheein, F, Austen, G, Bailey, J, Baldock, K, Banin, L, Banks-Leite, C, Barau, A, Bashyal, R, Bates, A, Bicknell, J, Bielby, J, Bosilj, P, Bush, E, Butler, S, Carpenter, D, Clements, C, Cully, A, Davies, K, Deere, N, Dodd, M, Drinkwater, R, Driscoll, D, Dutilleux, G, Dyrmann, M, Edwards, D, Farhadinia, M, Faruk, A, Field, R, Fletcher, R, Foster, C, Fox, R, Francksen, R, Franco, A, Gainsbury, A, Gardner, C, Giorgi, I, Griffiths, R, Hamaza, S, Hanheide, M, Hayward, M, Hedblom, M, Helgason, T, Heon, S, Hughes, K, Hunt, E, Ingram, D, Jackson-Mills, G, Jowett, K, Keitt, T, Kloepper, L, Kramer-Schadt, S, Labisko, J, Labrosse, F, Lawson, J, Lecomte, N, de Lima, R, Littlewood, N, Marshall, H, Masala, G, Maskell, L, Matechou, E, Mazzolai, B, McConnell, A, Melbourne, B, Miriyev, A, Nana, ED, Ossola, A, Papworth, S, Parr, C, Payo-Payo, A, Perry, G, Pettorelli, N, Pillay, R, Potts, S, Prendergast-Miller, M, Qie, L, Rolley-Parnell, P, Rossiter, S, Rowcliffe, M, Rumble, H, Sadler, J, Sandom, C, Sanyal, A, Schrodt, F, Sethi, S, Shabrani, A, Siddall, R, Smith, S, Snep, R, Soulsbury, C, Stanley, M, Stephens, P, Stephenson, PJ, Struebig, M, Studley, M, Svátek, M, Tang, G, Taylor, N, Umbers, K, Ward, R, White, P, Whittingham, M, Wich, S, Williams, C, Yakubu, I, Yoh, N, Zaidi, S, Zmarz, A, Zwerts, J & Davies, Z 2025, 'Opportunities and challenges for monitoring terrestrial biodiversity in the robotics age', Nature Ecology & Evolution, vol. 9, no. 6, pp. 1031-1042. https://doi.org/10.1038/s41559-025-02704-9

TY - JOUR

T1 - Opportunities and challenges for monitoring terrestrial biodiversity in the robotics age

AU - Pringle, Stephen

AU - Dallimer, Martin

AU - Goddard, Mark

AU - Le Goff, Léni

AU - Hart, Emma

AU - Langdale, Simon

AU - Fisher, Jessica

AU - Abad, Sara-Adela

AU - Ancrenaz, Marc

AU - Angeoletto, Fabio

AU - Auat Cheein, Fernando

AU - Austen, Gail

AU - Bailey, Joseph

AU - Baldock, Katherine

AU - Banin, Lindsay

AU - Banks-Leite, Cristina

AU - Barau, Aliyu

AU - Bashyal, Reshu

AU - Bates, Adam

AU - Bicknell, Jake

AU - Bielby, Jon

AU - Bosilj, Petra

AU - Bush, Emma

AU - Butler, Simon

AU - Carpenter, Dan

AU - Clements, Christopher

AU - Cully, Antoine

AU - Davies, Kendi

AU - Deere, Nicolas

AU - Dodd, Michael

AU - Drinkwater, Rosie

AU - Driscoll, Don

AU - Dutilleux, Guillaume

AU - Dyrmann, Mads

AU - Edwards, David

AU - Farhadinia, Mohammad

AU - Faruk, Aisyah

AU - Field, Richard

AU - Fletcher, Robert

AU - Foster, Chris

AU - Fox, Richard

AU - Francksen, Richard

AU - Franco, Aldina

AU - Gainsbury, Alison

AU - Gardner, Charlie

AU - Giorgi, Ioanna

AU - Griffiths, Richard

AU - Hamaza, Salua

AU - Hanheide, Marc

AU - Hayward, Matt

AU - Hedblom, Marcus

AU - Helgason, Thorunn

AU - Heon, Sui

AU - Hughes, Kevin

AU - Hunt, Edmund

AU - Ingram, Daniel

AU - Jackson-Mills, George

AU - Jowett, Kelly

AU - Keitt, Timothy

AU - Kloepper, Laura

AU - Kramer-Schadt, Stephanie

AU - Labisko, Jim

AU - Labrosse, Frédéric

AU - Lawson, Jenna

AU - Lecomte, Nicolas

AU - de Lima, Ricardo

AU - Littlewood, Nick

AU - Marshall, Harry

AU - Masala, Giovanni

AU - Maskell, Lindsay

AU - Matechou, Eleni

AU - Mazzolai, Barbara

AU - McConnell, Alistair

AU - Melbourne, Brett

AU - Miriyev, Aslan

AU - Nana, Eric Djomo

AU - Ossola, Alessandro

AU - Papworth, Sarah

AU - Parr, Catherine

AU - Payo-Payo, Ana

AU - Perry, Gad

AU - Pettorelli, Nathalie

AU - Pillay, Rajeev

AU - Potts, Simon

AU - Prendergast-Miller, Miranda

AU - Qie, Lan

AU - Rolley-Parnell, Persie

AU - Rossiter, Stephen

AU - Rowcliffe, Marcus

AU - Rumble, Heather

AU - Sadler, Jon

AU - Sandom, Christopher

AU - Sanyal, Asiem

AU - Schrodt, Franziska

AU - Sethi, Sarab

AU - Shabrani, Adi

AU - Siddall, Robert

AU - Smith, Simón

AU - Snep, Robbert

AU - Soulsbury, Carl

AU - Stanley, Margaret

AU - Stephens, Philip

AU - Stephenson, P.J.

AU - Struebig, Matthew

AU - Studley, Matthew

AU - Svátek, Martin

AU - Tang, Gilbert

AU - Taylor, Nicholas

AU - Umbers, Kate

AU - Ward, Robert

AU - White, Patrick

AU - Whittingham, Mark

AU - Wich, Serge

AU - Williams, Christopher

AU - Yakubu, Ibrahim

AU - Yoh, Natalie

AU - Zaidi, Syed

AU - Zmarz, Anna

AU - Zwerts, Joeri

AU - Davies, Zoe

N1 - Richard M. Francksen, Senior Lecturer and Programme Leader for BSc. (Hons.) Zoology, University of Cumbria, UK. This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made.

PY - 2025/6/1

Y1 - 2025/6/1

N2 - With biodiversity loss escalating globally, a step change is needed in our capacity to accurately monitor species populations across ecosystems. Robotic and autonomous systems (RAS) offer technological solutions that may substantially advance terrestrial biodiversity monitoring, but this potential is yet to be considered systematically. We used a modified Delphi technique to synthesize knowledge from 98 biodiversity experts and 31 RAS experts, who identified the major methodological barriers that currently hinder monitoring, and explored the opportunities and challenges that RAS offer in overcoming these barriers. Biodiversity experts identified four barrier categories: site access, species and individual identification, data handling and storage, and power and network availability. Robotics experts highlighted technologies that could overcome these barriers and identified the developments needed to facilitate RAS-based autonomous biodiversity monitoring. Some existing RAS could be optimized relatively easily to survey species but would require development to be suitable for monitoring of more 'difficult' taxa and robust enough to work under uncontrolled conditions within ecosystems. Other nascent technologies (for instance, new sensors and biodegradable robots) need accelerated research. Overall, it was felt that RAS could lead to major progress in monitoring of terrestrial biodiversity by supplementing rather than supplanting existing methods. Transdisciplinarity needs to be fostered between biodiversity and RAS experts so that future ideas and technologies can be codeveloped effectively.

AB - With biodiversity loss escalating globally, a step change is needed in our capacity to accurately monitor species populations across ecosystems. Robotic and autonomous systems (RAS) offer technological solutions that may substantially advance terrestrial biodiversity monitoring, but this potential is yet to be considered systematically. We used a modified Delphi technique to synthesize knowledge from 98 biodiversity experts and 31 RAS experts, who identified the major methodological barriers that currently hinder monitoring, and explored the opportunities and challenges that RAS offer in overcoming these barriers. Biodiversity experts identified four barrier categories: site access, species and individual identification, data handling and storage, and power and network availability. Robotics experts highlighted technologies that could overcome these barriers and identified the developments needed to facilitate RAS-based autonomous biodiversity monitoring. Some existing RAS could be optimized relatively easily to survey species but would require development to be suitable for monitoring of more 'difficult' taxa and robust enough to work under uncontrolled conditions within ecosystems. Other nascent technologies (for instance, new sensors and biodegradable robots) need accelerated research. Overall, it was felt that RAS could lead to major progress in monitoring of terrestrial biodiversity by supplementing rather than supplanting existing methods. Transdisciplinarity needs to be fostered between biodiversity and RAS experts so that future ideas and technologies can be codeveloped effectively.

U2 - 10.1038/s41559-025-02704-9

DO - 10.1038/s41559-025-02704-9

M3 - Journal Article

SN - 2397-334X

VL - 9

SP - 1031

EP - 1042

JO - Nature Ecology & Evolution

JF - Nature Ecology & Evolution

IS - 6

ER -

Opportunities and challenges for monitoring terrestrial biodiversity in the robotics age

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