1 / 42

Autonomous Monitoring of Vulnerable Habitats

Autonomous Monitoring of Vulnerable Habitats. And other tales. Robin Freeman, CEES, Microsoft Research 13 July 2007. Overview. Introduction Previous Work Analysing Avian Navigation Habitat Monitoring Brief Results Future Work. Introduction. About Me

MartaAdara
Download Presentation

Autonomous Monitoring of Vulnerable Habitats

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Autonomous Monitoring of Vulnerable Habitats And other tales.. Robin Freeman, CEES, Microsoft Research 13 July 2007

  2. Overview • Introduction • Previous Work • Analysing Avian Navigation • Habitat Monitoring • Brief Results • Future Work

  3. Introduction • About Me • BSc CS-AI, MSc Evolutionary and Adaptive Systems, • D.Phil (Engineering and Zoology) • Part of the Life Sciences Interface Doctoral Training Centre, Oxford • Trains physical and computation sciences graduates in biology before starting PhD in life sciences. • Now a Post-Doc at Microsoft Research • Computational Ecology and Biodiversity Science Group • European Science Initiative, External Research Office.

  4. ~9hrs ~15min

  5. Introduction • Analysing Avian Navigation • GPS Tracking of Pigeons, Oxford • GPS Tracking of Manx Shearwaters, Skomer • Habitat Monitoring • Manx Shearwater • Skomer Island, Wales

  6. Introduction • Zoological Interest • Specific questions (Sensory basis of navigation), • Conservation (home range, behavioural anomalies), • Other general questions. • Technical Interest • Novel algorithms/methods • Analysis of positional information • Feedback to bio-robotics, Complex Systems, Artificial Life, etc

  7. Pigeons? - Why Pigeons? • Model Navigational Species • Much easier to study than wild birds, • Birds return to a maintained loft (Wytham). • Allows attachment of GPS device • Large body of research to draw on. • Pigeon navigation has been studied for over 100 years.

  8. How Do They Navigate? • Two hypotheses for the sensory basis of navigation in the familiar area • ‘Map and Compass’ • Compass controlled navigation (as it is at unfamiliar locations). • Series of decision points using compass. • ‘Pilotage’ • Independent of a compass, relying directly on visual cues • Oh look, there’s that house!

  9. Clock Shift • Experiment • Train the birds to ‘recapitulate’ routes to home, • Then ‘clock-shift’ the birds by 90° • Sets up a direct competition between visual landmarks (the recapitulated route) and erroneous compass instructions With D Biro, J Meade, T Guilford & S J Roberts

  10. Nearest Neighbour Analysis • Shows offset and variance between controls and familiar clock-shift.

  11. Delayed Clock shift response (landmark related) Tracks ranked by Mahalonobis distance from recapping distribution

  12. Demonstrates that both mechanisms must be involved. • The birds must be able to home using visual information alone (they recapitulate) • Consistent deviation from recapitulated path • Offset? Zigzag? Biro D, Freeman R, Meade J, S. Roberts, Guilford T. (2007) PNAS. 104(18)

  13. Behavioural Segmentation - Hidden-Markov Models - Positional Entropy

  14. Landscape Analysis • More likely to fly over edge ‘rich’ areas • Flight pattern becomes less predictable over edge rich areas. Lau KK, Roberts S, Biro D, Freeman R, Meade J, Guilford T. (2006) J. Theo. Bio. 239(1) pp71-78

  15. Paired Homing Pigeon Flight Actual pair • GPS data for 48 Pigeons from 4 diff. sites • All possible pairs considered • Any real interaction between the birds should be seen as higher coupling between real pairs • Other pairs may show • High coupling due to same landscape/other unknown variables Bird paired with self Bird & random bird from different site

  16. Birds which flew together show significantly (p < 0.05) higher coupling than other possible pairings. Implies some form of information transfer.

  17. Manx Shearwater (Puffinus puffinus) • Highly pelagic, migratory seabird. • Burrow dwelling, central place forager. • UK summer breeding • Winters in South America • 250, 000 – 300, 000 breeding pairs. • 45% on three Pembrokeshire islands, Skomer, Skokholm and Middleholm; • 36% on Rum.

  18. Motivation • Ecology and Behaviour very similar to other Procellariiformes • Albatrosses, Petrels and Shearwaters. • 19 of 21 Albatross Species now globally threatened; • Devastating impact of long-line fishing • Understanding their behaviour, habitat and ecology may allow us to reduce this decline.

  19. Motivation UK Seabird decline over recent years Source: JNCC, UK Seabirds 2005

  20. Skomer Island • Small Island (~2km long) off coast of Wales • Home to large populations of Guillemots, Razorbills, Kittiwakes, Puffins, Fulmars • Worlds largest population of Manx Shearwaters • Well established research centre and study programmes

  21. Skomer Island

  22. Previous Work • GPS Tracking of Manx Shearwater • Distribution of foraging was largely unknown; • South to Spain; • Interaction • With fisheries? • Environmental variables? • Establishment of Marine protection zones.

  23. Foraging largely confined to Irish Sea; • Birds did not fly far south.. • Even when they had the opportunity to do so. • Climate effect? • Clustered areas; • Rafting. Right: Distribution of individual over trips of 1 to 7 days. Red shows incubating birds, blue chick rearing

  24. Each 2-hourly fix gives a small burst of 1Hz data. • Bursts can be segmented into different behaviours. • Speed Vs Directionality

  25. Sitting & Erratic Movement Directional Movement

  26. Speed has no obvious effect on depth • Time of day appears to (right)

  27. Autonomous Habitat Monitoring • Working closely with Academic Partners • University of Oxford • Prof. Tim Guilford, Animal Behaviour • Prof. Chris Perrins, Edward Grey Ornithology Institute • University of Freie Berlin • Tomasz Naumowicz, PHD, Free University Berlin • Prof Torben Weis, U Duisburg-Essen

  28. Autonomous Habitat Monitoring • Create and deploy a wireless sensor network that can: • Monitor the visitations of individual birds; • Monitor environmental conditions inside and outside the burrow; • Provide a pilot system for eventual integration with GPS tracking; • Do this all night, every night…

  29. Methods • Approx. 10 Burrow monitored • Ringed and RFID tagged pair of birds in each burrow; • Sensors & wireless sensor node to each burrow;

  30. Methods • Network • ScatterWeb platform from Freie Universitat Berlin; • Nodes • 2 x Passive Infrared • 2 x Temp/Humidity • RFID Detector

  31. Initial Results • No observable impact on birds’ behaviour • No evidence of digging, distress or abandonment. • Of 10 monitored burrows • 7 hatched (last week) • Remainder still on eggs

  32. Initial Results • Obvious nocturnal distribution of activity • Bimodal? • Resolution and density of data already significantly higher that achievable using traditional methods. All recorded events

  33. 2007/05/15 12:00 2007/05/15 00:00 2007/05/14 12:00

  34. Initial Results

  35. 00:00 Temperature Variation over 4 days (20-23 June) • Red: Temp Outside • Green: Temp Inside 06:00 18:00 12:00

  36. Future Questions… • Do individuals return at specific times? • How do pairs alternate feeding strategies? • How does activity/environment vary across space and time? • How do the results vary with weather?

  37. Future Directions • Deploy second network • Pilot has allowed us to iron out most problems; • Hope to set up additional network this winter. • Create a toolkit that any ecologist can deploy and use. • Integrate GPS tracking with network • Continual monitoring of foraging behaviour.

  38. ~9hrs ~15min

  39. An Aside (1)

  40. An Aside (2)

More Related