Lecture 4 - optimal foraging

Question 1

why does natural selection favour animals that behave most efficiently?

Answer 1

because for example individuals that forage optimally will maximise energy intake while minimising handling time

Question 2

who pioneered optimality modelling and what is it used for?

Answer 2

john maynard-smith

- used to determine how animals can best optimise (best source of action) their behaviour

Question 3

what is optimality logic?

Answer 3

• selection will favour animals that forage most efficiently

Question 4

how can you quantify the rate at which an animal obtains energy?

Answer 4

divide the caloric value by the time to find, process (e.g. open a mussel) and eat something

Question 5

How do Northwestern crows predate whelks ?

Answer 5

• they drip the whelks from 5m onto rocks to crack them open
• small whelks are unprofitable so they only select large ones
• they continue to drop the whelk until it breaks

Question 6

what gives an insight into the strategy of the northwestern crows?

Answer 6

measurements of drop height on the number of drops needed to crack whelks of different sizes

Question 7

what were the 3 predictions of the northwestern crow experiment?

Answer 7

1) large whelks should break more easily at 5m than small whelks
2) whelks dropped at <5m should be less likely to break, whelks dropped at >5m should be more likely to berak
3) the chances of a whelk breaking should be independent of number of times its dropped

Question 8

what were the results of the experiment on northwestern crows whelk strategy?

Answer 8

1) bigger whelks require fewer drops to crack
2) dropping from 5m is almost as good as greater heights
3) there doesnt seem to be any resistant whelks so if a whelk has not cracked after say 5 drops it is probably just lucky so its not appropriate to abandon whelks that do not crack

Question 9

describe mismatch?

Answer 9

When a hypothesis based on cost benefit logic is found to be incorrect this can lead to further insights

Question 10

what are the 4 further insights from mismatch

Answer 10

1) The animal may not have been well ‘designed’ by selection
2) The observations may have been inappropriate
3) An important factor may have been omitted from the model
4) The assumptions may not have been valid

Question 11

predictions can be made about the optimal size of food items that should be taken by an animal however its not always the case - give an example of this

Answer 11

oystercatchers were found to not select the largest mussels (appear to be behaving non-optimally) - optimum size for mussels that can be opened is 50mm- the larger mussels were more difficult to open

Question 12

describe the mismatch foraging of leaf cutter ants?

Answer 12

• the larger ants reduced their daytime foraging to limit attacks from parasitic flies

Question 13

describe the diet of moose

Answer 13

moose need to eat energy rich forest leaves and sodium rich aquatic vegetation

Question 14

moose behave optimally in the bounds of 3 constraints what are they?

Answer 14

1) an energy constraint
2) sodium constraint
3) a rumen constraint
- that means they dont eat the highest/ expected for each food source because they have to have a balance between the 3 constraints

Question 15

what is charnovs marginal value theorem

Answer 15

• foraging environments tend to be patchy
• when foraging animals need to decide when to move from one patch to another - the theorem predicts how animals should forage in a patchy environment

Question 16

what is the idea charnovs marginal value theorem is based on?

Answer 16

the idea that animals should move from one patch to the next (or return to their young with food) when the patch at which they are feeding becomes unprofitable - depends on the quality of the patch and the time taken to travel between patches (or to and form their young)

Question 17

on the marginal theorem graph what does the loading curve show?

Answer 17

the diminishing returns of continuing to feed on a patch

Question 18

what does the tangent to the loading curve show?

Answer 18

indicates the optimal time for an individual to forage in th§e patch

Question 19

what does increasing travel time predict?

Answer 19

that an individual should spend longer in the patch

Question 20

describe Kacelnik (1984) experiment on starlings?

Answer 20

• Starlings get diminishing returns as they forage because it is harder to find food when carrying prey.
• Starlings trained to feed from artificial patches with diminishing returns placed at 8m - 600m from nest
• experiments found that he starlings forage optimally when collecting food for their young

Question 21

the MVT is restrictive, describe 4 assumptions of it

Answer 21

1) travel time between patches is known
2) travel time and patch time have equal energetic costs
3) patch profitability is known
4) no predation or competition etc

Question 22

describe an experiment teting the assumption do travel costs= patch costs?

Answer 22

• great tits (Cowie 1997)
• great tits expend more energy during travelling time than during patch time
• cowie adjusted for this and then observed travel and foraging times that were closer to those predicted by the model

Question 23

describe the experiment testing the assumption ‘patch profitability is known’

Answer 23

Lima (1984) - Downy woodpecker - when faced with patches of unknown profitability they sampled the patches and are thereby able to maximise their energy intake by minimising their search costs

Question 24

why are optimality models good for studying behaviour?

Answer 24

1) they provide testable quantitative predictions that can be used to test whether our theories for why animals are behaving in particular ways are correct
2) they involve explicit assumptions -
3) they illustrate the generality of decision making

Question 25

things to do when the model fails to predict observations?

Answer 25

1) Ignore it (count as acceptable error)
2) Accept animal is sub-optimal
3) Re-build model
when animals dont behave in the way the models predict we can rebuild our models to incorporate constraints or alter assumptions and thereby learn more about the behaviour