hello

1 collaborator

Clarke Chen (Author)

WHAT IS IT?

This model explores the stability of predator-prey ecosystems. Such a system is called unstable if it tends to result in extinction for one or more species involved. In contrast, a system is stable if it tends to maintain itself over time, despite fluctuations in population sizes.

HOW IT WORKS

There are two main variations to this model.

In the first variation, wolves and sheep wander randomly around the landscape, while the wolves look for sheep to prey on. Each step costs the wolves energy, and they must eat sheep in order to replenish their energy - when they run out of energy they die. To allow the population to continue, each wolf or sheep has a fixed probability of reproducing at each time step. This variation produces interesting population dynamics, but is ultimately unstable.

The second variation includes grass (green) in addition to wolves and sheep. The behavior of the wolves is identical to the first variation, however this time the sheep must eat grass in order to maintain their energy - when they run out of energy they die. Once grass is eaten it will only regrow after a fixed amount of time. This variation is more complex than the first, but it is generally stable.

The construction of this model is described in two papers by Wilensky & Reisman referenced below.

HOW TO USE IT

Set the GRASS? switch to TRUE to include grass in the model, or to FALSE to only include wolves (red) and sheep (white).
Adjust the slider parameters (see below), or use the default settings.
Press the SETUP button.
Press the GO button to begin the simulation.
Look at the monitors to see the current population sizes
Look at the POPULATIONS plot to watch the populations fluctuate over time

Parameters: INITIAL-NUMBER-SHEEP: The initial size of sheep population INITIAL-NUMBER-WOLVES: The initial size of wolf population SHEEP-GAIN-FROM-FOOD: The amount of energy sheep get for every grass patch eaten WOLF-GAIN-FROM-FOOD: The amount of energy wolves get for every sheep eaten SHEEP-REPRODUCE: The probability of a sheep reproducing at each time step WOLF-REPRODUCE: The probability of a wolf reproducing at each time step GRASS?: Whether or not to include grass in the model GRASS-REGROWTH-TIME: How long it takes for grass to regrow once it is eaten SHOW-ENERGY?: Whether or not to show the energy of each animal as a number

Notes:

one unit of energy is deducted for every step a wolf takes
when grass is included, one unit of energy is deducted for every step a sheep takes

THINGS TO NOTICE

When grass is not included, watch as the sheep and wolf populations fluctuate. Notice that increases and decreases in the sizes of each population are related. In what way are they related? What eventually happens?

Once grass is added, notice the green line added to the population plot representing fluctuations in the amount of grass. How do the sizes of the three populations appear to relate now? What is the explanation for this?

Why do you suppose that some variations of the model might be stable while others are not?

THINGS TO TRY

Try adjusting the parameters under various settings. How sensitive is the stability of the model to the particular parameters?

Can you find any parameters that generate a stable ecosystem that includes only wolves and sheep?

Try setting GRASS? to TRUE, but setting INITIAL-NUMBER-WOLVES to 0. This gives a stable ecosystem with only sheep and grass. Why might this be stable while the variation with only sheep and wolves is not?

Notice that under stable settings, the populations tend to fluctuate at a predictable pace. Can you find any parameters that will speed this up or slow it down?

Try changing the reproduction rules -- for example, what would happen if reproduction depended on energy rather than being determined by a fixed probability?

EXTENDING THE MODEL

There are a number ways to alter the model so that it will be stable with only wolves and sheep (no grass). Some will require new elements to be coded in or existing behaviors to be changed. Can you develop such a version?

Can you modify the model so the sheep will flock?

Can you modify the model so that wolf actively chase sheep?

NETLOGO FEATURES

Note the use of breeds to model two different kinds of "turtles": wolves and sheep. Note the use of patches to model grass.

Note use of the ONE-OF agentset reporter to select a random sheep to be eaten by a wolf.

RELATED MODELS

Look at Rabbits Grass Weeds for another model of interacting populations with different rules.

CREDITS AND REFERENCES

Wilensky, U. & Reisman, K. (1999). Connected Science: Learning Biology through Constructing and Testing Computational Theories -- an Embodied Modeling Approach. International Journal of Complex Systems, M. 234, pp. 1 - 12. (This model is a slightly extended version of the model described in the paper.)

Wilensky, U. & Reisman, K. (2006). Thinking like a Wolf, a Sheep or a Firefly: Learning Biology through Constructing and Testing Computational Theories -- an Embodied Modeling Approach. Cognition & Instruction, 24(2), pp. 171-209. http://ccl.northwestern.edu/papers/wolfsheep.pdf

HOW TO CITE

If you mention this model or the NetLogo software in a publication, we ask that you include the citations below.

For the model itself:

Wilensky, U. (1997). NetLogo Wolf Sheep Predation model. http://ccl.northwestern.edu/netlogo/models/WolfSheepPredation. Center for Connected Learning and Computer-Based Modeling, Northwestern University, Evanston, IL.

Please cite the NetLogo software as:

Wilensky, U. (1999). NetLogo. http://ccl.northwestern.edu/netlogo/. Center for Connected Learning and Computer-Based Modeling, Northwestern University, Evanston, IL.

COPYRIGHT AND LICENSE

CC BY-NC-SA 3.0

This work is licensed under the Creative Commons Attribution-NonCommercial-ShareAlike 3.0 License. To view a copy of this license, visit https://creativecommons.org/licenses/by-nc-sa/3.0/ or send a letter to Creative Commons, 559 Nathan Abbott Way, Stanford, California 94305, USA.

Commercial licenses are also available. To inquire about commercial licenses, please contact Uri Wilensky at uri@northwestern.edu.

This model was created as part of the project: CONNECTED MATHEMATICS: MAKING SENSE OF COMPLEX PHENOMENA THROUGH BUILDING OBJECT-BASED PARALLEL MODELS (OBPML). The project gratefully acknowledges the support of the National Science Foundation (Applications of Advanced Technologies Program) -- grant numbers RED #9552950 and REC #9632612.

This model was converted to NetLogo as part of the projects: PARTICIPATORY SIMULATIONS: NETWORK-BASED DESIGN FOR SYSTEMS LEARNING IN CLASSROOMS and/or INTEGRATED SIMULATION AND MODELING ENVIRONMENT. The project gratefully acknowledges the support of the National Science Foundation (REPP & ROLE programs) -- grant numbers REC #9814682 and REC-0126227. Converted from StarLogoT to NetLogo, 2000.

Comments and Questions

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Click to Run Model

globals [grass]

breed [sheep a-sheep]
breed [wolves wolf]
breed [Anglers Angler]
turtles-own [energy]
patches-own [countdown]

to setup
  clear-all
  ask patches [ set pcolor sky ]

  if plankton? [
    ask patches [
      set pcolor one-of [sky blue]
      if-else pcolor = sky
        [ set countdown Plankton-repopulation-rate ]
        [ set countdown random Plankton-repopulation-rate ]
    ]
  ]
  set-default-shape sheep "fish"
  create-sheep initial-number-salmon
  [
    set color red
        set size 1.0
    set label-color blue - 2
    set energy random (2 * salmon-gain-from-food)
    setxy random-xcor random-ycor
  ]
  set-default-shape wolves "fish"
  create-wolves initial-number-sharks
  [
    set color grey
    set size 2
    set energy random (2 * shark-gain-from-food)
    setxy random-xcor random-ycor
  ]
  set-default-shape Anglers "person"
  create-anglers initial-number-humans
  [
    set color brown
    set size 3
    set energy 10000
    setxy random-xcor random-ycor
  ]
  display-labels
  set grass count patches with [pcolor = sky]
  reset-ticks
end 

to go
  if not any? turtles [ stop ]
  ask sheep [
    move
    if plankton? [
      set energy energy - 1
      eat-grass
    ]
    death
    reproduce-sheep
  ]
  ask wolves [
    move
    set energy energy - 1
    catch-sheep
    death
    reproduce-wolves
  ]
  ask anglers [
    move
    set energy energy - 1000
    catch-sheep
    eat-grass
    catch-wolf
  ]
  if plankton? [ ask patches [ grow-grass ] ]
  set grass count patches with [pcolor = sky]
  tick
  display-labels
end 

to move
  rt random 50
  lt random 50
  fd 1
end 

to eat-grass
  if pcolor = sky [
    set pcolor blue
    set energy energy + salmon-gain-from-food
  ]
end 

to reproduce-sheep
  if random-float 100 < salmon-reproduce [
    set energy (energy / 2)
    hatch 3 [ rt random-float 360 fd 1 ]
  ]
end 

to reproduce-wolves
  if random-float 100 < shark-reproduce [
    set energy (energy / 2)
    hatch 1 [ rt random-float 360 fd 1 ]
  ]
end 

to catch-sheep
  let prey one-of sheep-here
  if prey != nobody
    [ ask prey [ die ]
      set energy energy + shark-gain-from-food ]
end 

to catch-wolf
 if random-float 100 < catch-chance [
  let prey one-of wolves
  if prey != nobody
  [ask prey[die attack]
    set energy 10000]
 ]
end 

to death
  if energy < 0 [ die ]
end 

to grow-grass
  if pcolor = blue [
    ifelse countdown <= 0
      [ set pcolor sky
        set countdown Plankton-repopulation-rate ]
      [ set countdown countdown - 1 ]
  ]
end 

to display-labels
  ask turtles [ set label "" ]
  if show-energy? [
    ask wolves [ set label round energy ]
    if plankton? [ ask sheep [ set label round energy ] ]
  ]
end 

to attack
  let prey one-of anglers
  if prey != nobody
  [ask prey [die attack]
  ]
end

There is only one version of this model, created over 7 years ago by Clarke Chen.

Attached files

File	Type	Description	Last updated
hello.png	preview	Preview for 'hello'	over 7 years ago, by Clarke Chen	Download

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