USING A GAME THEORETICAL APPROACH FOR

EXPERIMENTAL SIMULATION OF BROOD REDUCTION

Conflict and co-operation, effect on brood size with limited resources

Fredrik Åhman, Lars Hillström

Department of mathematics natural and computer sciences, University of Gävle, 801 76 Gävle, Sweden

Keywords: ESS, agent, brood reduction, fitness, intra-familiar conflicts

Abstract: A number of hypothesis have been presented to explain the complex interactions occurring during brood

reduction, but few simulation models successfully combines hypothesis together necessary to describe

evolutionary stable strategies. In our solution we present a simple experimental simulation for brood

reduction for which each sibling act as an autonomous agent that has the ability to initiate actions for co-

operation and competition against others chicks within the same brood. Agents have a limited set of actions

that can be activated during the onset of some environmental condition. Parameters for food distribution are

determined on a basis of a former known theory for maximizing inclusive fitness. During the experimental

simulations we have studied size and fitness measures with varying degree of asynchrony and prey density

for siblings within the artificial brood. Results from the experimental simulation shows interesting

similarities with brood reduction in a real world setting. Agents within the artificial brood respond with

competitiveness whenever resources are limited. Simulated later hatching also showed a lower rate of

survival because of natural size hierarchy to co-siblings within the simulated brood.

1 INTRODUCTION

A number of hypothesis have been presented to

explain causes of brood reduction but few simulation

models successfully combines important parameters

from each hypothesis together necessary to describe

evolutionary stable strategies. In intra-familiar

conflicts there is always a trade off between degree

of selfishness and altruistic behaviours serving the

benefits to the next sibling in the brood (Krebs,

Davies, 1984). This trade-off is also well known

from the Hamilton equation (1) (Bergstrom ref to

Hamilton, 2000) where relatedness ( r ) and benefits

(b) is compared to cost for co-operation (c).

0>− crb

(1)

Mock et al, 1998 describes an interesting

optimization problem for fitness in which the degree

of selfishness is balanced against the interest of

maximizing inclusive fitness for the whole brood.

Mocks theory describes a simplistic relationship

between total parental investment (M) and portions

of (M) for siblings (m

), (m

). If portions of prey

could do twice as much use for one of the co-

siblings within the same brood its in the dominant

chicks best interest to pass that portion on to the next

sib. Dependent on relatedness between chicks the

portion of the meal passed on can vary in size. Mock

et al, 1998 shows optimisation for full siblings

which means that relatedness is always 0.5.

In a brood with two siblings portions of parental

investment (PI) can be split into p*M for the

dominant chick A and (1-p)*M for the subordinate

chick B. Mock tries to find a value (p) that maximize

fitness for the most dominant chick. The fitness

curve f(m) (2) describes an exponential relationship

between parental investment (m) and fitness f(m).

Increase is very in the beginning of the curve but

will slow down as the amount of investment

approaches maximum amount (M).

min))(1exp(1)( mmkmf −

−

(2)

Mock believe that there is a value of portion (p)

in which the remains (1-p) comes in better use for

the co-sibling B. The equation describes a

relationship between the first partial order derivate

where increase of fitness for the dominant A-chick

should be equivalent to the double increase of fitness

for the B-chick (3).

220

Åhman F. and Hillström L. (2005).

USING A GAME THEORETICAL APPROACH FOR EXPERIMENTAL SIMULATION OF BROOD REDUCTION - Conﬂict and co-operation, effect on

brood size with limited resources.

In Proceedings of the Seventh International Conference on Enterprise Information Systems, pages 220-225

DOI: 10.5220/0002539502200225

 SciTePress

)('2/1)('

mfmf =

(3)

1.1 Conflicting versus co-operative

behaviours

Combining conflicting behaviours with co-operating

behaviours such as portioning foods to co-siblings

seems to be an appealing game theoretical approach.

In order to maximize fitness individual interests are

likely to be balanced to the benefit of the whole

brood. Environmental changes such as variation in

prey density and climate variation demands good

strategies for survival (Temme, Charnov, 1987).

When food abundance is low resources must be

carefully invested to maximize reproductive output

(Ploger, Mock, 1986).

Controlled brood reduction through hatching

asynchrony is often initiated by parents when

environmental conditions are less beneficial

(Vinuela, 2000; Lamey, Mock, 1991). Hatching

asynchrony plays a major role in sibling size

hierarchy where the first hatched chick often has

total control of food resources due to its large size.

Sibling competition will be less frequent because of

the natural dominance of the elder chick (Lamey,

Mock, 1991).

1.2 Theoretical framework for the

experimental simulation

Our aim with this work is to build an experimental

simulation model for brood reduction. The

underlying theory for the game theoretical approach

is based on Mock & Parkers earlier work on intra-

familiar parent-offspring conflict (Mock et al, 1998).

Our experimental model is based on a number of

assumptions that is originally inspired by the food

and egg viability hypothesis that effects hatching

asynchrony (Vinuela, 2000).

We view each sibling is as an agent able to make

its own decisions for competition and food

ingestion. The agent behaviours is controlled by its

characteristics such as aggressiveness and strategy

selection for competitive games.

2 METHODS

We have chosen to evaluate the agents response to

three different variables namely access to prey,

hatching asynchrony and rankings within the sibling

hierarchy. Each agent is activated by starting a new

thread for the corresponding chick. In our game

simulation sibling hierarchy is dependent on the

number of winnings in conflicts. Chicks winning

many conflicts will conquer favourable positions

during feeding. The dominant chick is always

controlling the amount of food distributed similar to

(Mock et al, 1998).

After each feeding data is stored about the chicks

size, fitness, minimum mass for starvation and

ranking. Feeding is repeated iteratively until chick is

ready for fledging or may have deceased due to

starvation. The simulation procedure is repeated ten

times for each parameter setting.

2.1 The simulation platform

We have chosen to implement the brood simulation

platform in Java. The Java language is object

oriented and supports threading which is needed if

we want agents within our simulation environment

to act independently. A maximum number of three

siblings act simultaneously in our nestling

environment. Each sibling can initiate two basic

behaviours namely consume() and compete().

Winning a competition means higher ranking.

Higher ranking means higher probability for food.

Figure 1: Agent interaction with two basic behaviours

{consume, compete}

From a game theoretical perspective we can view

the consumption of food as a simple

consumer/producer problem where we have a

number of consumers that are dependent on a

limited resource. In our simulated environment food

items is delivered regularly. Upon delivering food

the most dominant contestant will take its share first

and then left the remains its co-siblings.

2.2 Game theory and strategy

selection

For each game contestants can choose to alter

between different strategies for survival. Common

strategies are transgress or retreat. Each chosen

strategy has its obvious payoffs and costs dependent

on the outcome of the game.

USING A GAME THEORETICAL APPROACH FOR EXPERIMENTAL SIMULATION OF BROOD REDUCTION -

Conflict and co-operation, effect on brood size with limited resources

221

)](

)(

)([

)(

)(),,(

∂

++∂

++=

mfmfmf

mfmfmfmmmf

CBA

CBACBA

In a game where each opponent can choose

between two strategies four combination of payoffs

are possible as seen in (Krebs, Davies 1984). If one

player choose to retreat ( R ) the cost for that player

will be zero or minimum even if he looses the game.

The same goes for the opponent who is winning the

game. However if both players choose to transgress

the cost for each player will affect their immediate

fitness with cost –c1, -c2. Gains during winning are

described as g1, g2.

A winning in our simple game means higher

ranking and therefore better positioning within the

nest whenever prey is delivered. A dominant chick

in our game determines how food portions to pass on

to other subordinate chicks in order to maximize its

own inclusive fitness. This works exactly the same

as the method used for portioning prey as seen in

(Mock et al 1998).

Figure 2: Payoffs in two-player games with fixed

strategies

The following equations is taken from (Mock et al

1998).

1. For two sibling games :

A:s portion of prey is (p)

B:s portion of prey is (1-p)

(4)

(5)

2. For three sibling games :

A:s portion of prey: m

=Mq

B:s portion of prey : m

=Mp(1-q)

C:s portion of prey : m

´C

=M(1-p)(1-q)

(6)

In extension to the two above equations a logistic

sigmoid function was added to calculate mass m(w)

(7) with respect to intake of energy (w) which is the

transfer function for most birds (Ricklefs 1969).

Both (L) and k are constants representing bias and

increase in growth.

(7)

)(

−

3 THE PROBABILISTIC MODEL

As our model is based on former known theories

about sibling rivalry and intra-familiar conflicts we

need to state predictions about how the agent will

respond to certain conditions within the

environment. Such events could be lower resource

such as lower prey intensity, lower size advantage

etc.

3.1 Sibling size hierarchy and

likelihood to win a conflict

Siblings that have a size advantage is more likely to

win a conflict because of less resistance from the

minor chick (Smith, Graeme, Crosswell 2001)..

Sibling size hierarchy is also of major importance in

hatching asynchrony where younger chicks are

sometimes doomed to starvation by selfish older and

much bigger chicks as seen in (Vinuela 2000). In

our simulation we put this as a proportional measure

(8) between the sum of chicks total weight

m(i)+m(j) in relation to the contestants weight m(i)

)(

)(),(

BABA

mfmfmmf +=

)()(

)(

),(

jmim

jipw

(8)

)](

)([

∂

+∂

mfmf

Larger chicks will have a natural size advantage

to minors in proportion pw(i,j) (8). Using the

probability measure as input to our stochastic

process we rank each chick accordingly to winnings

or loss for each game. Rankings are later used to

determine most dominant chick upon the event of

feeding.

Probability for ranking as most dominant (9) is

determined by the dominant chicks ranking in

relation to the remaining chicks within the same

brood. Rankings are always set at a bias level in the

ICEIS 2005 - ARTIFICIAL INTELLIGENCE AND DECISION SUPPORT SYSTEMS

222

beginning of the simulation. Bias is needed to insure

non-negative ranking values due to increased loss.

Growth for chick A,B,C with prey density 0.25 of

maximum (M)

200

400

600

800

1000

101

111

121

Days

Mass (g)

Serie1

Serie2

Serie3

Expected fitness for chick A,B,C with prey

density 0.25 of maximum (M)

0,5

1,5

105

118

Da ys

Fitness

Ser ie1

Ser ie2

Ser ie3

)()(

)(

),(

jrir

jipdom

(9)

If stochastic process for determining domination

gives advantage to chick (i) in both cases {chick A-

Chick B} and {Chick A-Chick C} then chick (i) will

win domination game and get the best position for

next feeding round. If no chick is winning more than

one domination game the chick with the highest

ranking will be ranked as dominant.

4 RESULTS

4.1 Evaluation of Parkers

optimisation algorithm for

inclusive fitness

The purpose of the first test aims to show how food

is distributed by the dominant chick holding the

criteria for maximization of inclusive fitness. When

the first dominating chick is leaving for fledging the

simulation shifts from three sib co-operation to two

sib co-operation.

Treshold for fledging is set to 800 grams. Initial

weight for each chick is 50 grams. The time scale

represents the number of days within the nest until

fledging. Domination stays the same throughout the

whole test. Chick A is dominating food distribution

from start. Simulation were performed with altered

prey density. Graph 4.1.1 shows growth and fitness

rate with prey density 0.25. Graph 4.1.2 shows

growth and fitness rate with prey density 0.5.

4.1.1 Observations during the test

In the first test with prey density 0.25 Chick C is

likely to suffer from starvation considering the slow

growth rate. As expected the mass curve for chick B

is much closer to A than C. However mass and

fitness curves for prey intensity 0.5 shows higher

increase of mass for chick C. As food abundance

increase portions will be shared more equally

between chicks.

Graph 4.1.1: Growth and fitness for Chick A, B, C with

low prey density k= 0.25

Growth for chick A,B,C with prey density 0.5

200

400

600

800

1000

Da ys

Mass (g)

Serie1

Serie2

Serie3

Expected fitness for chick A,B,C with prey densit

0.5 of maximum (M)

0,2

0,4

0,6

0,8

1,2

Serie1

Serie2

Serie3

Graph 4.1.2: Growth and fitness for Chick A,B, C with

medium prey density k=0.5

4.2 Simulating synchronized hatching

with medium prey density (k=0.5)

In this test algorithms for conflicting behaviours

were activated which means that rankings were

altered dependent on winnings through out the

simulation. Shifted rankings also means that

domination were altered amongst sibs during

feeding. Low food abundance resulted in starvation

shifting from 10-30% amongst siblings within the

brood. Graph 4.2.1-Graph 4.2.2 shows mass, fitness

and rankings for all three siblings. Note that

deviation listed in the table represents a mean value

for all deviations acquired during all ten simulations.

Table I: Synchronized hatching with medium prey density

k=0.5. Running 10 simulations

Chick Fledging

(days)

Fledged Starved Ranking

(mean)

Ranking

(dev)

A 45.75 8 2 20.5 1.97

B 48.67 7 3 19.49 1.243

C 48.56 9 1 20.48 2.06

Growth for synchronized birth with

medium prey density (K = 0.5)

500

1000

Days

Mass (g)

Serie1

Serie2

Serie3

Fitness for chick A,B,C synchronized birth with

medium prey density (K = 0.5)

0,5

1,5

Days

Fitness

Ser ie 1

Ser ie 2

Ser ie 3

Graph 4.2.1: Growth and fitness for synchronized hatching

with medium prey density k= 0.5

USING A GAME THEORETICAL APPROACH FOR EXPERIMENTAL SIMULATION OF BROOD REDUCTION -

Conflict and co-operation, effect on brood size with limited resources

223

Graph 4.2.2: Rankings for synchronized hatching with

prey density k=0.5

4.3 Simulating hatching asynchrony

with medium prey density (k=0.5)

In this test each agent was activated asynchronous

with a time delay of 3 tics in between each chick. In

practical terms this means starting threads in Java

asynchronous. Each tic corresponds to one day in a

reality setting. The results shows a definite

starvation for the latest hatched chick C which also

has the smallest size advantage in proportion to A, B

upon hatching. As expected chick A gets the highest

ranking followed by B and C. Growth, fitness and

rankings are shown in graph 4.3.1-4.3.2.

Table II: Hatching asynchrony with medium prey density

k=0.5. Running 10 simulations

Chick Fledging

(days)

Fledged Starved Rank

(mean)

Ranking

(deviation)

A 46,9 10 0 21,28 2,1183

B 49,9 10 0 19,74 1,8052

C (-) 0 10 19,50 0,786

Growth Chick A,B,C - Asynchronized

hatching, medium prey density (K = 0.5)

500

1000

Days

Mass (g)

Serie1

Serie2

Serie3

Fitness Chick A,B, C - Asynchronized

hatching, medium prey density (K =

0.5)

0,5

1,5

Days

Fitness

Serie1

Serie2

Serie3

Graph 4.3.1: Growth and fitness for hatching

asynchrony with medium prey density k=0.5.

Rankings Chick A,B,C - Asynchronized

hatching, medium prey

density (K = 0.5)

Days

Ranking

Serie1

Serie2

Serie3

Graph 4.3.2: Rankings for hatching asynchrony with

medium prey density k=0.5

4.4 Simulating hatching asynchrony

with high prey density (k= 0.7)

In the fourth test hatching asynchrony was

performed for higher prey density 0.7. With higher

food abundance all chicks reached to the state of

fledging. The growth rate was also higher for all

three siblings. Fledging for chick A only took 30,2

days, chick B 34,2 days and chick C 39,6 days on

average. This is of course just a theoretical measure.

Growth, fitness and rankings are shown in graph

4.4.1-4.4.2.

Rankings for Chick A, B, C with synchronized birth

and prey intensity 0.5

Days

Ranking

Serie1

Serie2

Serie3

Table III: Hatching asynchrony with high prey density

k=0.7. Running 10 simulations

Chick Fledging

(days)

Fledged Starved Ranking

(mean)

Ranking

(deviation)

A 30.2 10 0 21.66 1.514

B 34.2 10 0 20.31 1.461

C 39.6 10 0 17.34 2.197

Growth Chick A, B, C, Asynchronized hatching

high prey density (K = 0.7)

200

400

600

800

1000

Days

Mass (g)

Serie1

Serie2

Serie3

Fitness Chick A,B,C Asynchronized hatching,

high prey density (K = 0.7)

0,2

0,4

0,6

0,8

1,2

Days

Fitness

Serie1

Serie2

Serie3

Graph 4.4.1: Growth and fitness for hatching asynchrony

with high prey density k=0.7

Rankings for chick A,B,C, Asynchronized hatching,

high prey density (K = 0.7)

Days

Ranking

Serie1

Serie2

Serie3

Graph 4.4.2: Rankings for hatching asynchrony with high

prey density k=0.7

5 DISCUSSION

Mocks theory relies on the assumption that the most

dominant chick controls food distribution amongst

co-siblings. The theory also assumes that dominance

hierarchy is fixed through out the simulation. In our

simulation we have chosen to allow alterations of

dominance between siblings as a result of winnings

and loss. It is consistent with the results that there is

a correlation between rankings and the amount of

parental investment that the chick receives. In cases

of simulated hatching asynchrony the latest hatched

chick is likely to get a lower ranking because of the

natural size hierarchy and lower chances of winning

a food/dominance contest.

In a realistic setting it is likely that parents will

have a greater influence in portioning food partly

affected by begging patterns produced by each

offspring (Kölliker 2001). Begging models needs to

be considered in order to get a more accurate results

ICEIS 2005 - ARTIFICIAL INTELLIGENCE AND DECISION SUPPORT SYSTEMS

224

for actual distribution. The influence of begging

models is also a stressed in (Mock, Parker 1998) .

6 CONCLUSIONS

From the first simulations with three sib and two sib

co-operation it follows that Mocks principles of

inclusive fitness behaves as expected. When food

abundance is low the chick with the lowest rank is

likely to suffer from starvation. When agents were

started in synchrony performed simulations shows

that any chick may suffer from starvation if food

resources are poor. However, when agents were

started in asynchrony it is also consistent with the

results that the latest hatch sibling dies due to

starvation in most cases.

Our first experimental model for brood reduction

has shown some interesting results that could be

useful for simulation of incubation behaviours such

as hatching asynchrony but of course the model

needs further refinement in describing state and

policy variables for each agent. Further research is

needed to describe dominance/ranking and learning

processes for each agent. In our simulation we have

not yet considered important component of learning

strategies for competition. Conflicting behaviours

have a degree of learning and adaptation. Adaptation

to conflicting behaviours needs to be considered if

the experimental model for brood reduction should

be representative for any real world situation.

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Bergstrom, T, R., 2000. Evolution of Behaviour in Family

Genes, University of California at Santa Barbara,

Economics Working Paper Series 1143, Department of

Economics, UC Santa Barbara.

Krebs JR, Davies N B, 1984, Behavioural ecology – An

Evolutionary Approach, Blackwell scientific

publications

Kölliker M, Richner H, 2001, Parent-Offspring Conflict

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Lamey T C, Mock Douglas W 1991, Nonaggressive brood

reduction in birds, Acta Congressus, Internationalis

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Mock D, Parker GA, Schwagmeyer P L 1998, Game

theory, Sibling rivalry and Parent-Offspring conflict ,

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in Birds: Economical tracking in a temporally varying

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nestling growth, Behavioural Ecology, 48, pp 333-

343

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Conflict and co-operation, effect on brood size with limited resources

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