Presentation is loading. Please wait.

Presentation is loading. Please wait.

Mapping distributions of marine organisms using environmental niche modelling - AquaMaps K. Kaschner, J. Ready, S. Kullander, R. Froese and many more….INCOFISH,

Published byHarvey Davidson Modified over 9 years ago

Similar presentations

Presentation on theme: "Mapping distributions of marine organisms using environmental niche modelling - AquaMaps K. Kaschner, J. Ready, S. Kullander, R. Froese and many more….INCOFISH,"— Presentation transcript:

1 Mapping distributions of marine organisms using environmental niche modelling - AquaMaps K. Kaschner, J. Ready, S. Kullander, R. Froese and many more….INCOFISH, FishBase…

2 AquaMaps Basic Concept Environmental envelope type modeling approach Predictor Preferred min Preferred max MinMax P Max Species-specific environmental envelopes Relative probability of occurrence (HSPEN) (HCAF) (HSPEC) INTRODUCTION

3 HCAF table Environmental data per 0.5 degree latitude / longitude square Contents –Bathymetry –Mean annual SST (Sea surface temperature) –Mean annual Salinity –Mean annual Chlorophyll A (now primary production) –Mean annual Sea ice concentration (replacing distance to ice edge) –Mean annual distance to land –Etc.

4 AquaMaps Basic Concept INTRODUCTION P c = P Bathymetry c * P SST c * P Salinity c * P ChloroA c * P IceDist c * P LandDist c

5 AquaMaps Basic Concept INTRODUCTION European flounder (Platichthys flesus)

6 AquaMaps Basic Concept INTRODUCTION European flounder (Platichthys flesus)

7 Environmental Envelopes: Sources of Information Envelopes can be defined based on expert knowledge / published information –E.g. depth ranges for fishes -> FishBase automatically generated based on species records (point data) ENVELOPES

8 Automated Envelope Generation: 1. Step: Selection of Species Records ENVELOPES

9 Automated Envelope Generation: 1. Step: Selection of Species Records Minimum: n = 10 records with reliable species ID & location information ENVELOPES European flounder (Platichthys flesus), n = 65

10 2. Step: Selection of “Good” Records Cross-check with known FAO areas of occurrence (e.g. FishBase) ENVELOPES

11 2. Step: Selection of “Good” Records Cross-check with known FAO areas of occurrence (e.g. FishBase) (N.B. Chilean e.g. dealt with by non-native status exclusion) ENVELOPES

12 2. Step: Selection of “Good” Records Cross-check with known FAO areas of occurrence (e.g. FishBase) ENVELOPES European flounder (Platichthys flesus), n = 33

13 3. Step: Grouping over “Good” Cells Mean annual SST [C] ENVELOPES Mean annual SST [C] Frequency Non-grouped records (n = 33) Records grouped over cells (n = 20) Minimum: n = 10 cells

14 4. Step: Calculate Percentile Ranges ENVELOPES Mean annual SST [C] Max =16.75Min =1.6575% = 15.0925% = 9.06

15 4. Step: Calculate Percentile Ranges ENVELOPES Mean annual SST [C] - 2SD = 4.09Mean = 11.85- SD = 7.97+ SD = 15.73+ 2SD = 19.51

16 4. Step: Calculate Percentile Ranges ENVELOPES Min25%75%Max Depth11150100 SST [C]1.659.0615.0916.75 Salinity [ppu]6.1318.0235.0738.00 ChloroA [?]111.56143.01175.94190 IceDist [km]733181629743443 LandDist [km]1519.25328

17 4. Step: Calculate Percentile Ranges ENVELOPES 25% -75 % Percentile = “Preferred range”

18 4. Step: Calculate Percentile Ranges ENVELOPES 25% -75 % Percentile = “Preferred range”

19 4. Step: Calculate Percentile Ranges ENVELOPES 25% -75 % Percentile = “Preferred range”

20 4. Step: Calculate Percentile Ranges ENVELOPES Mean annual SST [C] Max =16.75Min = 1.6590% = 16.2310% = 7.27

21 4. Step: Calculate Percentile Ranges ENVELOPES Min10%90%Max Depth11150100 SST [C]7.27 16.2316.5 Salinity [ppu]6.096.5337.8838 ChloroA [?]111.56113.60188195 IceDist [km]1574 32333434 LandDist [km]12146328

22 4. Step: Calculate Percentile Ranges ENVELOPES 10% -90 % Percentile = “Preferred range”

23 4. Step: Calculate Percentile Ranges ENVELOPES 10% -90 % Percentile = “Preferred range”

24 5. Step: Broadening of Min-Max Ranges ENVELOPES Mean annual SST [C] Max =1.5 * Interquartile = 24.34 90% = 16.2310% = 7.27 Min =1.5 * Interquartile = - 0.21 Note that if true value is more extreme then this is kept

25 ENVELOPES Min10%90%Max Depth11150100 SST [C]-0.217.2716.2724.35 Salinity [ppu]6.136.5337.8838.00 ChloroA [?]70.74113.60188190 IceDist [km]733157432334852 LandDist [km]12146328 5. Step: Broadening of Min-Max Ranges

26 6. Step: Ensure Minimum Range Width ENVELOPES Mean annual SST [C] ΔMin = 1 °C ΔMin = 2 °C

27 ENVELOPES 6. Step: Ensure Minimum Range Width 1 °C 2 °C 1 ppu 2 ppu 1010 20 2 km 4 km 2 km 4 km Min10%90%Max Depth11150100 SST [C]-0.217.2716.2724.35 Salinity [ppu]6.136.5337.8838.00 ChloroA [?]70.74113.60188190 IceDist [km]733157432334852 LandDist [km]12146328

28 ENVELOPES 7. Step: Store Envelope in HSPEN Min10%90%Max Depth11150100 SST [C]-0.217.2716.2724.35 Salinity [ppu]6.136.5337.8838.00 ChloroA [?]70.74113.60188190 IceDist [km]733157432334852 LandDist [km]12146328

29 Model Algorithm Predictor Preferred min Preferred max MinMax P Max Relative probability of occurrence MODEL ALGORITHM

30 Model Algorithm MODEL ALGORITHM P c = P Bathymetry c * P SST c * P Salinity c * P ChloroA c * P IceDist c * P LandDist c – Multiplicative approach: Each parameter can act as “knock-out” criterion Redundant parameters have no effect on distribution

31 Model Output ALGORITHM

32 Model Output ALGORITHM

33 Effects of Individual Predictors MODEL ALGORITHM Bathymetry

34 Effects of Individual Predictors MODEL ALGORITHM SST

35 Effects of Individual Predictors MODEL ALGORITHM Salinity

36 Effects of Individual Predictors MODEL ALGORITHM Chlorophyll A

37 Effects of Individual Predictors MODEL ALGORITHM Distance to ice edge

38 Effects of Individual Predictors MODEL ALGORITHM Distance to land

39 Additional Rules If Min IceEdgeDist > 1000 km then ignore parameter (Rethinking – data changing to ice concentration) If Max LandDist > 1000 km then Max LandDist = maximum distance (4000 km) MODEL ALGORITHM

40 Preliminary Results EXAMPLES Atlantic herring (Clupea harengus), n = 7500

41 Preliminary Results EXAMPLES Atlantic herring (Clupea harengus), n = 7500

42 Preliminary Results EXAMPLES Atlantic cod (Gadus morhua), n = 215

43 Preliminary Results EXAMPLES Atlantic cod (Gadus morhua), n = 215

44 Preliminary Results EXAMPLES Tropical two-wing flyingfish (Exocoetus volitans), n = 330

45 Preliminary Results EXAMPLES Tropical two-wing flyingfish (Exocoetus volitans), n = 330 Data cleaning needed

46 Preliminary Results EXAMPLES Tope shark (Galeorhinus galeus), n = 110

47 Preliminary Results EXAMPLES Tope shark (Galeorhinus galeus), n = 110

48 Preliminary Results EXAMPLES Orange roughy (Hoplostethus atlanticus), n = 116

49 Preliminary Results EXAMPLES Orange roughy (Hoplostethus atlanticus), n = 116

50 Preliminary Results EXAMPLES Coelacanth (Latimeria chalumnae), n = 10

51 Preliminary Results EXAMPLES Coelacanth (Latimeria chalumnae), n = 10

52 Preliminary Results EXAMPLES Coelacanth (Latimeria chalumnae), n = 10

53 Preliminary Results EXAMPLES Red lionfish (Pterois volitans), n = 65

54 Preliminary Results EXAMPLES Red lionfish (Pterois volitans), n = 65

55 Points for Investigation DISCUSSION Advantages/disadvantages of envelope modeling in comparison to other habitat suitability modeling / mapping approaches (GARP, Maxent, Bioclim etc.) Minimum number of records required? Environmental data –Seasonal data –Historical and predicted future data –Categorical data? E.g. habitat types Multiplicative model (Geometric mean)? Weighting factors (e.g. known forcing factors)? Effects of effort biases? Others?

56 Existing modelling DISCUSSION Other presence only modelling –GARP (Genetic Algorithm for Rule-Set Parsimony) The ‘industry standard’ but a bit of a ‘black box’ –Maxent (Maximum entropy) – latest popular method A machine learning method, iterating algorithm Computationally quite fast (but not as fast as AquaMaps) –Bioclim – early simplistic method Uses similar approach to envelopes Moderately fast computation

57 AquaMaps compared DISCUSSION Advantages –Speed Simple calculations take very little time Can be done on-the fly over the internet (www.fishbase.se Tools/AquaMaps)www.fishbase.se –FAO area use to block out areas of known absence Can be switched off to allow prediction of areas that could be invaded –Batch processing runs the whole database in one go – many species Potential Disadvantages –Accuracy? As yet unknown – testing underway but looks good at this scale –Resolution? 0.5 degree scale difficult to reapply at local scales without remaking HCAF But - Other methods also require the environmental data sets to be provided at the correct scale

58 Acknowledgements FishBase – Provision of data and interface –Occurrence records, depth data, FAO area assignment BADC (British Atmospheric Data Centre) – Provision of data from global climate models –Future and past environmental data (just beginning) –Plan to predict the effects of climate change of fish distributions using: Historical data - 100yrs ago and 50yrs ago Future modelled data - 20yrs time, 50yrs time, 100yrs time INCOFISH partners

Download ppt "Mapping distributions of marine organisms using environmental niche modelling - AquaMaps K. Kaschner, J. Ready, S. Kullander, R. Froese and many more….INCOFISH,"

Similar presentations

Ch2 Data Preprocessing part3 Dr. Bernard Chen Ph.D. University of Central Arkansas Fall 2009.

Ch2 Data Preprocessing part3 Dr. Bernard Chen Ph.D. University of Central Arkansas Fall 2009.
WP3 Biomapping results to date WP3: NRM, CDF, CEFAS, DINARA, WCS Additional input: WP1, AquaMaps workgroup.

WP3 Biomapping results to date WP3: NRM, CDF, CEFAS, DINARA, WCS Additional input: WP1, AquaMaps workgroup.
Biodiversity of Fishes Length-Weight Relationships Rainer Froese (27.11.2014)

Biodiversity of Fishes Length-Weight Relationships Rainer Froese ( )
Best Model Dylan Loudon. Linear Regression Results Erin Alvey.

Best Model Dylan Loudon. Linear Regression Results Erin Alvey.
HEMI 2 Hyper-Envelope Modeling Interface 2 Uses Bezier curves to minimize over- fitting Allows automatic fitting with manual adjustment Provides interactive.

HEMI 2 Hyper-Envelope Modeling Interface 2 Uses Bezier curves to minimize over- fitting Allows automatic fitting with manual adjustment Provides interactive.
Maxent interface.

Maxent interface.
Climate modeling Current state of climate knowledge – What does the historical data (temperature, CO 2, etc) tell us – What are trends in the current observational.

Climate modeling Current state of climate knowledge – What does the historical data (temperature, CO 2, etc) tell us – What are trends in the current observational.
Climate case study. Outline The challenge The simulator The data Definitions and conventions Elicitation Expert beliefs about climate parameters Expert.

Climate case study. Outline The challenge The simulator The data Definitions and conventions Elicitation Expert beliefs about climate parameters Expert.
BIODIVERSITY OF REEFS: INFERRING FROM SPARSE DATA Daphne G. Fautin Ecology & Evolutionary Biology Natural History Museum University of Kansas Photo by.

BIODIVERSITY OF REEFS: INFERRING FROM SPARSE DATA Daphne G. Fautin Ecology & Evolutionary Biology Natural History Museum University of Kansas Photo by.
Global Warming Continued Some final clarifying thoughts.

Global Warming Continued Some final clarifying thoughts.
Geographic data: sources and considerations. Geographical Concepts: Geographic coordinate system: defines locations on the earth using an angular unit.

Geographic data: sources and considerations. Geographical Concepts: Geographic coordinate system: defines locations on the earth using an angular unit.
Testing an individual module

Testing an individual module
Mapping Life on Earth: Recent Progress with AquaMaps Rainer Froese IFM-GEOMAR, Kiel, Germany Teldap Conference, Taipei 2 March 2009.

Mapping Life on Earth: Recent Progress with AquaMaps Rainer Froese IFM-GEOMAR, Kiel, Germany Teldap Conference, Taipei 2 March 2009.
Principle of Functional Verification Chapter 1~3 Presenter : Fu-Ching Yang.

Principle of Functional Verification Chapter 1~3 Presenter : Fu-Ching Yang.
Recent Advances with the Ocean Biogeographic Information System (OBIS) Rainer Froese Institute of Marine Research, Kiel

Recent Advances with the Ocean Biogeographic Information System (OBIS) Rainer Froese Institute of Marine Research, Kiel
Ocean Home Swimming Fish Activity created by Jason Turnure and Jason Werrell Do Now: Discuss at your table what you understood from yesterday’s activity.

Ocean Home Swimming Fish Activity created by Jason Turnure and Jason Werrell Do Now: Discuss at your table what you understood from yesterday’s activity.
A PREDICTION APPROACH TO AGRICULTURAL LAND USE ESTIMATION Ambrosio L., Marín C., Iglesias L., Montañés J., Rubio L.A. Universidad Politécnica Madrid. Spain.

A PREDICTION APPROACH TO AGRICULTURAL LAND USE ESTIMATION Ambrosio L., Marín C., Iglesias L., Montañés J., Rubio L.A. Universidad Politécnica Madrid. Spain.
State of the Marine Environment Rainer Froese Leibniz Institute of Marine Sciences, Kiel IfM-GEOMAR

State of the Marine Environment Rainer Froese Leibniz Institute of Marine Sciences, Kiel IfM-GEOMAR
Ocean Biogeographic Information System. ‘Mission’ OBIS publishes primary data on marine species locations online through www.iobis.org www.iobis.org –It.

Ocean Biogeographic Information System. ‘Mission’ OBIS publishes primary data on marine species locations online through –It.
Winners and Losers in the Future Ocean Insights from Millions of Samples Rainer Froese IFM-GEOMAR, Kiel, Germany EDIT Symposium 18th January 2011 1.

Winners and Losers in the Future Ocean Insights from Millions of Samples Rainer Froese IFM-GEOMAR, Kiel, Germany EDIT Symposium 18th January

Similar presentations

Ads by Google