DETERMINING COOPERATION IN MULTIAGENT SYSTEMS

WITH CULTURAL TRAITS

Stefan Heinrich, Stefan Wermter

Department of Informatics, Hamburg University, Hamburg, Germany

Markus Eberling

Department of Computer Science, University of Paderborn, Paderborn, Germany

Keywords:

Adaptation, Altruism, Cooperation, Cultural traits, Multiagent Systems.

Abstract:

Achieving cooperation among autonomous and rational agents is still a major challenge. In the past, altruistic

cooperation was generally explained through genetic kinship relations. However, the theory of ‘cultural kin’

is an approach that tries to explain altruism through cultural relatedness. To promote cooperation among

autonomous and rational agents, this work transfers the idea of cultural characteristics, which beneﬁts social

behaviour, to multiagent systems (MAS). Accordingly, agents are characterised by cultural traits, which they

can imitate from their neighbours and are supposed to solve tasks, for which they need the cooperation of

other agents in most cases. The interaction of cooperation and cultural trait propagation will be investigated

in a theoretical analysis and in an empirical simulation in a particular developed framework. As a novelty,

schemata will be analysed that are beyond the well-studied one-to-one interaction.

1 INTRODUCTION

During the last years the interest in multiagent sys-

tems has increased noticeably (Shoham and Leyton-

Brown, 2008). The idea of solving problems by dis-

tributing them among autonomous agents was taken

up continually in theoretical and practical contexts.

Moreover, problem areas have emerged, in which

autonomous entities are supposed to optimally ex-

ploit limited resources through the use of coopera-

tion (for example bandwidth or computation capac-

ity of peer-to-peer networks). An issue, which is still

not satisfactorily dealt with, is how cooperation can

be achieved among those autonomous and rational

agents, if there is the appeal of cheating.

The contribution of this work is an analytical anal-

ysis of a modelled multiagent system, which was pro-

posed similarly in (Hales, 2001; Klemm et al., 2005)

and (Eberling, 2009). The agents of such a MAS

carry several cultural traits but have only limited local

knowledge of their neighbours’ traits. Additionally,

our agents hold weightings of theirs traits, which are

completely invisible to others. Every agent randomly

and continuously receives jobs, most of which he can

only solve with the help of cooperating and altruistic

partners. Similar to the prisoner’s dilemma, the global

beneﬁt for all agents strongly increases if coopera-

tion – preferably of a reciprocal nature – takes place.

Agents adapt to their best neighbours through imita-

tion, which implies that particular trait values will be

propagated more intensively than others. However we

will show that this propagation of cultural traits is lim-

ited by the agents’ fundamental disposition to cooper-

ate. The model’s dynamics and the model itself have

been discussed for several decades but the new ana-

lytical approaches provide a better understanding of

these models and cooperation in MAS in general.

In the ﬁeld of biology and other disciplines expla-

nations for cooperation and reciprocal altruism were

initially found exclusively in the kinship relations:

supporting related organisms - even at one’s own ex-

penses - will serve the own genes and thus indi-

rectly yourself (Axelrod and Hamilton, 1981; Trivers,

1971). Cultural norms, which seem to be responsible

for altruism in the absence of genetic relatedness, and

their propagation in societies, was a topic of inten-

sive research during the last decades (Allison, 1992;

Axelrod, 1986; Axelrod, 1997; Binmore, 1998; Boyd

and Richerson, 1985; Delgado, 2002). In conjunction

with norms, ideas and behavioural patterns were un-

173

Heinrich S., Wermter S. and Eberling M..

DETERMINING COOPERATION IN MULTIAGENT SYSTEMS WITH CULTURAL TRAITS.

DOI: 10.5220/0003142801730180

In Proceedings of the 3rd International Conference on Agents and Artiﬁcial Intelligence (ICAART-2011), pages 173-180

ISBN: 978-989-8425-41-6

 2011 SCITEPRESS (Science and Technology Publications, Lda.)

derstood as cultural traits, which represent a cultural

relatedness (Dawkins, 1976). Under the metaphor of

cultural evolution (Heylighen, 1992), cooperation on

the basis of cultural traits as well as their propaga-

tion were further analysed. Transferred to the con-

text of artiﬁcial societies or in particular to multiagent

systems, they were increasingly labelled as ‘features’,

‘memes’ or ‘tags’.

With his Swap Shop Framework, Hales (Hales,

2001) analysed the cooperation in artiﬁcial societies:

agents shared resources that were essential for sur-

vival on the basis of cultural relatedness (memetic

kin). For this reason each agent carried three cultural

traits memes including an altruistic trait and was able

to learn traits from his neighbours. In Hales empiri-

cal analysis, setups with cultural evolution as well as

with genetic evolution lead to an identical dominance

of single groups with a speciﬁc trait-setting. Never-

theless, they occurred much faster within the cultural

evolution which provides some evidence of the im-

pact of cultural traits. Furthermore, he found out that

the distribution of resources through cultural evolu-

tion was more efﬁcient and lead to a more social be-

haviour.

On the basis of Axelrod’s Cultural Diffusion

Model (Axelrod, 1997) Klemm et al. evaluated un-

der which terms the propagation of cultural traits con-

verges to stable conditions and what those might look

like (Klemm et al., 2005). Their agents were con-

nected through a one-dimensional lattice and had var-

ious features, which they infrequently adapted to a

feature of one of their neighbours. The adaptation

was only depending on a initial existence of a com-

mon feature. Depending on the amount of possible

traits per feature and the amount of the features them-

selves, the simulation arrived at an equilibrium: for an

initially high diversity of the features in a polarised

condition (several small homogeneous groups had

evolved) and for an initially low diversity in a glob-

alised condition (consistently homogeneous agents).

For each setting Klemm et al. determined a threshold,

under which a polarisation and over which a global-

ization occurred.

From the literature, we can adopt valuable ap-

proaches, which follow the idea empirically or ana-

lytically in small cases. With our work, we want to

go a step further and contribute analytical results for

more than a one-to-one interaction scheme.

In the next section we will formally present our

model. In section 3 we will present a theoretical anal-

ysis of the model and subsequently demonstrate some

substantiating experiments in section 4. In the last

section we will draw a conclusion and give an outlook

to future work.

2 THE MODEL

In this section we will outline our formal model. The

major aim of our concept is a multiagent system,

which follows the ideas of the literature (see above)

but still remains computable. In particular, we use

discrete ranges of sizes which are large enough but

ﬁnite for all parameters.

2.1 Formal MAS Description

Deﬁnition 1 (World). The world which contains the

agents A is a two-dimensional square lattice of a ﬁ-

nite size m × n with the following parameters:

• |A| = m · n: the number of agents is deﬁned by the

size of the lattice; every cell represents an agent

• Moore neighbourhood relation (see Figure 1)

• z ∈ N: range dimension of cultural trait values

• the world is a torus in order to avoid boundary

problems, therefore cell (m+1,n+1) = cell (1,1)

The dynamics of the world is divided in discrete time

slots (t), so-called rounds. At the outset the world is

initialised with the parameters and is static in the size

of the lattice, and thereby in its size of population.

All agents are distinctly deﬁned by their position in

the world. The neighbours are the set of agents who

are known and available for interaction. The range

dimension of cultural trait values deﬁnes the range

{

1,...,z

}

, in which the values of cultural traits can

be located.

Figure 1: Moore neighbourhood.

Deﬁnition 2 (Agent). An agent a ∈ A is deﬁned as

a =



N , f , g,q, s



with:

• N ⊆ A: neighbours of a, according to the neigh-

bourhood relation

• f = (u, v,w), u,v,w ∈

{

1,...,z

}

: cultural traits

• g = (g

), g

∈ ]0,1[, g

+ g

= 1: trait weightings

• q ∈

{

0,...,z − 1

}

: altruism threshold

• s ∈ Z: score, counting rewards and costs

The position of the agents results from the initialisa-

tion of the world. At the beginning the score is at 0

and the agents’ cultural traits are randomly selected

ICAART 2011 - 3rd International Conference on Agents and Artificial Intelligence

174

from the uniform distribution U(1,z). To determine

the weightings, the range [0,1] is divided at the in-

tersections ζ

and ζ

to receive three weightings ac-

cording to the length of the intervals [0,ζ

], [ζ

,ζ

and [ζ

,1]. Those weightings are randomly assigned

to the weightings g

, g

, and g

. The altruism thresh-

old deﬁnes the largest value of cultural difference, up

to which a cooperation is agreed on, and in this ap-

proach is a free variable (details below).

Deﬁnition 3 (Jobs). The set J is made of jobs j =

a,e

with:

• a ∈ A: agent to whom the job was assigned

• e ∈



1,...,



+ 1



: effort (amount of agents

needed) to solve the job

For solving an assigned job, the agent receives 2 · e

points. Every agent involved in solving this job, has

to pay costs of one point.

2.2 Behavioural Heuristics

Taken from the knowledge about human social be-

haviour, all agents follow two fundamental be-

havioural heuristics, which psychologists and sociol-

ogists assume to be most likely (Allison, 1992; Cial-

dini, 1994; Noble and Franks, 2004):

1. Be good to your close relatives (agents expect a

higher reciprocity from similar agents)

2. Imitate those who are successful (these agents

seem to have traits, which make them more suc-

cessful)

Implementing heuristic 1 means that every agent b ∈

cooperates with agent a, if the values of the cul-

tural traits do not vary widely from the values of the

cultural traits of agent a. This results in an amount of

cooperating agents (friends) F

of agent a with:



b ∈ N

|div(a,b) ≤ q



(1)

div(a,b) = |u

− u

| · g

u,a

+ |v

− v

| · g

v,a

(2)

+ |w

− w

| · g

w,a

Heuristic 2 is implemented through the follow-

ing procedure: all agents adapt their cultural traits

to the traits of the best agent in their neighbourhood.

With the probability ρ

agent a adapts his traits to his

neighbour b

∗

∈ N

with the highest score s

, as fol-

lowing:

(

− u

) · (1 − g

u,a

)

, iff u

≤ u

− u

) · (1 − g

u,a

)

, iff u

> u

(3)

(

− v

) · (1 − g

v,a

)

, iff v

≤ v

− v

) · (1 − g

v,a

)

, iff v

> v

(4)

(

− w

) · (1 − g

w,a

)

, iff w

≤ w

− w

) · (1 − g

w,a

)

, iff w

> w

(5)

therefore ρ

is deﬁned by:

= P(Adapt.) =

(



1 −

1+(s

−s

)



, iff s

> s

0, else

(6)

To have the agents adapt their traits exclusively to

the actual situation, the adaptations take place sorted

in ascending order according to the scores (see Ober-

vation 1).

Observation 1 (X-Over-Freedom of Adaptations). If

an agent a adapts his cultural traits to the traits of

agent b then there exists no agent c who still would

need to adapt to the traits of agent a. If there exists

such an agent c, then as a necessary condition, agent

a is more successful than agent c. Furthermore, the

score of agent a is greater than the score of agent s,

i.e. s

< s

. As A is sorted ascendingly according to

s, agent c is dealt with before agent a.

2.3 Scenario Description

In every round, all agents evaluate their neighbour-

hood and in particular determine the amount of neigh-

bours which are willing to cooperate (friends F ).

Subsequently all agents get





+ 1



jobs to solve.

An agent has no limit with regard to the amount of

jobs he is able to solve per round. Only this agent

to whom the job was assigned is rewarded, while the

others, who were requested and accepted to help, have

to pay the costs. However, if an agent is not able to

ﬁnd enough cooperating partners to solve a job, the

job will be discarded. At the end of each round every

agent identiﬁes his best neighbour (role model) and

possibly adapts his cultural traits. For the outline see

Algorithm 1.

3 ANALYTICAL APPROACH

In this section the propagation of cultural traits will

be analysed in detail. Klemm et al. have empiri-

cally investigated that a propagation of cultural traits

in a multiagent system can lead to a globalisation (all

agents become increasingly homogeneous) or a po-

larisation (many small clusters) (Klemm et al., 2005).

By the MAS introduced in section 2, we analyse the

propagation and thereby examine small cases of the

adaptation convergence in detail. Subsequently, we

will explore how many adaptation steps need to be

DETERMINING COOPERATION IN MULTIAGENT SYSTEMS WITH CULTURAL TRAITS

175

performed until the cultural traits become adequately

similar. For a universal analysis the criterion ade-

quately similar is set on identical – with a deviation

of 0. Moreover, due to a restricted deﬁnition, only the

agents which are neighbours – thus know each other

and are able to interact – are considered. In the small-

est case (by disregarding the neighbourhood relations)

only two agents will interact with and imitate each

other.

Algorithms 1: Simulation.

1: Initialize m × n agents with traits f and weightings g

randomly

2: loop

3: for all agents a ∈ A do {Neighbourhood Evalua-

tion}

4: Determine F

5: end for

6: for all agents a ∈ A do {Job Solving}

7: Generate jobs J

randomly

8: for all jobs j ∈ J

9: if |F

| ≥ e

then

10: Determine and score payoff

11: end if

12: end for

13: end for

14: for all agents a ∈ A do {Imitation}

15: select b

∗

∈ N

16: with probability ρ

: adapt f

towards f

∗

17: end for

18: end loop

3.1 Convergency in 1 to 1 Adaptation

Taken into consideration are two agents a ∈ A and

b ∈ A with the assumption that a and b only adapt

to each other in each round. Accordingly, three cases

can be differentiated (see Figure 2):

a. Agent a adapts his cultural traits only to the traits

of agent b.

b. Agent a and b mutually adapt their cultural traits.

c. Agent b only adapts his cultural traits to the traits

of agent a.

a b

(a) Agent a to b

a b

(b) Mutually

a b

Figure 2: Cases of the 1 to 1 adaptation.

Subsequently, the analysis is restricted to the cul-

tural trait u. The analysis of the cultural traits v and

w follows analogously. As additional requirement ap-

plies: g

u,a

≥ g

u,b

. According to Section 2.2 the dis-

tance δ =

− u

can be deﬁned and the adapta-

tion formula can be simpliﬁed (for a better readability

γ = g

u,a

is deﬁned). According to case (a) agent a ex-

clusively adapts to agent b, therefore it follows (see

Observation 2):

t+1

= δ

+ b(0 − δ

) · (1 − γ)c = bδ

γc (7)

Observation 2. For u

and u

applies: u ∈

{

1,...,z

}

The adaptation is performed in the direction of u

therefore in this adaptation step u

and therewith δ

do change but u

remains constant.

From δ =

− u

and u

≤ u

follows: δ = u

− u

and −δ + u

= u

. Consequently applies:

t+1

= u

+ d(u

− u

) · (1 − g

u,a

)e (8)

−δ

t+1

+ u

= −δ

+ u

+ d(u

− (−δ

+ u

)) · (1 − g

u,a

)e (9)

−δ

t+1

+ u

= −δ

+ u

+ d(u

+ δ

− u

) · (1 − g

u,a

)e (10)

−δ

t+1

= −δ

+ d(0 + δ

) · (1 − g

u,a

)e (11)

t+1

= δ

+ b(−(0 + δ

) · (1 − g

u,a

))c (12)

t+1

= δ

+ b(0 − δ

) · (1 − g

u,a

)c (13)

From δ =

− u

and u

> u

follows: δ = u

− u

and δ + u

= u

. Consequently applies:

t+1

= u

+ b(u

− u

) · (1 − g

u,a

)c (14)

t+1

+ u

= δ

+ u

+ b(u

− (δ

+ u

)) · (1 − g

u,a

(15)

t+1

+ u

= δ

+ u

+ b(u

− δ

− u

) · (1 − g

u,a

(16)

t+1

= δ

+ b(0 − δ

) · (1 − g

u,a

)c (17)

With the simpliﬁcation γ = g

u,a

it follows:

t+1

= δ

+ b(0 − δ

) · (1 − γ)c (18)

Every adaptation step is decreasing the distance δ

depending on the weighting γ of the adapting agent.

Keeping in mind that γ ∈ ]0,1[, the adaptation steps

result in:

step 1 : bδγc

step 2 : bbδγc · γc ≤ bδγ

step 3 : bbδγ

c · γc ≤ bδγ

...

step t : bδγ

In the next step the point of time in which the cul-

tural traits (u) of the agent a and b become equal is

searched for. That is the number τ of the adaptation

steps according to which the difference is δ = 0. A

ICAART 2011 - 3rd International Conference on Agents and Artificial Intelligence

176

sufﬁcient condition is:

bδγ

c = 0 (19)

δγ

< 1 (20)

δ <

= (γ

−τ

) (21)

log

(γ

−1

)

(δ) =

lg(δ)

lg(γ

−1

)

lg(δ)

−lg(γ)

< τ (22)



lg(δ)

−lg(γ)



= τ (23)

The derivation for case (c) follows analogously.

The case (b) can be estimated with case (a), as the

adaptation cannot take longer at the same distance δ

and a smaller or equal weighting (see Observation 3).

Observation 3 (Duration of 1 to 1 Adaptation).

With the condition g

u,a

≥ g

u,b

, it follows: The adap-

tation of the cultural traits of agent a to the traits of

agents b takes at least as long as a mutual adapta-

tion or the adaptation of the cultural traits of agent b

to the traits of agent a. Let us assume, at any point

of the adaptation, agent b adapts his cultural traits

to the traits of agent a. However, as agent b has a

weighting of g

u,b

≤ g

u,a

at his command it follows di-

rectly that δ

= δ

+ b(0 − δ

) · (1 − g

u,b

) leads to

an approximation that is larger than or equal to the

approximation of the inverted case a to b. This obser-

vation implies that at any point of time an adaptation

from b to a does not cannot need more steps.

Thus, case (a) is the worst case in the 1 to 1 con-

vergence. If the weightings of the cultural traits are

equal, then the worst case is equivalent to the best

case: every agent reduces the distance with about the

same ratio.

3.2 Convergence in k to 1 Adaptation

If those k agents are considered, which interact with

agent a, three cases of convergence can be distin-

guished as well (see Figure 3). The number k of

agents in consideration depends on the neighbour-

hood relation, which implies that some agents in the

world can interact with agent a.

a. Agent a adapts his cultural traits only to the traits

of agent b

with i ∈

{

1,...,k

}

, while all other

agents b

with j ∈

{

1,...,i − 1, i + 1,k

}

adapt

their traits to the traits of agent a.

b. The agents a and b

with i ∈

{

1,...,k

}

mutually

adapt their cultural traits to each other. All other

agents adapt their traits to the traits of agent a.

c. All agents b

with i ∈

{

1,...,k

}

adapt their cul-

tural traits only to the traits of agent a.

a b

(a) Agent a to b

a b

(b) Mutually

a b

to a

Figure 3: Cases of the k to 1 adaptation.

Table 1: Examples for case (a) of the k to 1 adaptation.

t u

0 1 5 9

1 1 2 6

2 1 1 3

3 1 1 2

4 1 1 1

t u

0 1 5 1

1 1 2 4

2 1 1 3

3 1 1 2

4 1 1 1

u,b

= g

u,a

= g

u,b

For the analysis of case (c) the equation of the

1 to 1 adaptation for all agents (b

,...,b

) can be

adopted. However, the number of adaptation steps τ

until convergence depends on the largest distance of

all agents towards agent a.

τ = max(τ(b

),.. .,τ(b

)), (24)



lg(δ

)

−lg(γ

)



= τ(b

), δ

− u

, γ

= g

u,b

In the cases (a) and (b) it needs to be considered

that the cultural trait value (of u) of the agent b

can be

smaller than the cultural trait value of agent a and his

cultural trait value can be smaller than the values of

another agent b

(see Table1, left side). Another pos-

sible extreme is that the agents b

and b

have identical

cultural trait values and do equally differ from agent

a (see example in Table 1, right side).

Subsequently, the adaptation of b

over a to b

needs to be computed. For that reason the number

of adaptation steps can be added up and descriped as

following:

τ = τ(b

)

+ max(τ(b

),.. .,τ(b

i−1

),τ(b

i+1

),.. .,τ(b

)),

(25)



lg(δ

)

−lg(γ

)



= t(b

), δ

− u

, γ

= g

u,b

3.3 Convergence in Unrestricted

Adaptation

To expand the observation of the convergence in unre-

stricted adaptation of ﬁnite k agents, it is important to

emphasise that role models can change in the course

of the adaptation or even after a complete adaptation

DETERMINING COOPERATION IN MULTIAGENT SYSTEMS WITH CULTURAL TRAITS

177

Table 2: Example for case (b) of the unrestricted adaptation.

t Agent b

Agent b

u RM u RM u RM u RM

0 1 - 4 b

3 b

2 b

1 1 - 2 b

4 b

3 b

2 1 - 3 b

2 b

4 b

3 1 - 4 b

3& b

2 b

u,b

, ∀b

∈ {b

,...,b

},RM = Role Model

to a particular agent. Due to this circumstance two

cases, which need to be analysed separately, emerge

(see Figure 4).

a. For all agents applies: The role models do not

change, although it is possible that several agents

share the same model.

b. The role models of one agent can change. It is

possible, in particular, that the models alternate

cyclically.

(a) Identical order

t=0: t=1:

t=2:

(b) Alternating order

Figure 4: Cases of the unrestricted adaptation.

To be able to analyse an unrestricted adaptation

between k agents with identical order (case (a)), a de-

composition of the problem can be used. Due to the

cyclic freedom of a model-follower relation (see Ob-

servation 1) for every model a k to 1 convergence to

his followers can be computated. As all adaptations to

different role models happen simultaneously, an up-

per bound can be identiﬁed:

τ = 2 · max(τ(b

),.. .,τ(b

i−1

),τ(b

i+1

),.. .,τ(b

)) − 1

(26)



lg(δ

)

−lg(γ

)



= τ(b

), δ

− u

, γ

= g

u,b

An alternating adaptation between k agents (case

(b)) does not result in a guaranteed bound for a con-

vergence. In the worst case the order of the mod-

els can vary after each round, so that the same cul-

tural trait values remain in various agents. Table 2

shows an example for such an arrangement which

could never lead to a convergence.

As a result it can be stated that a convergence to

identical cultural traits can emerge, if a single agent is

the role model during the adaptation steps or if there

exists an invariant hierarchy between the agents. If

there are several models which also alternate, then a

convergence cannot be guaranteed.

4 EMPIRICAL VALIDATION

This section presents some empirical results to under-

line our analytical approach. We have simulated a lat-

tice with 64 · 64 = 4096 agents over 500 rounds in

a framework developed particularly for this purpose.

The range dimension of cultural trait values was set to

z = 64 whereby the cultural trait values of all agents

were situated in {1,. ..,64}. All cultural traits were

weighted equally with g

= g

. According

to section 2.3, the agents had to solve jobs and were

able to adapt to their neighbours.

4.1 Inﬂuence of Altruism Threshold

Subsequently, we will describe the results of the vari-

ation of the altruism threshold q, which was the same

for all agents. The graphs in Figure 5 show the ﬁrst

100 rounds of the simulation and are the results of 100

independent runs, which were averaged.

For a conﬁguration of the altruism threshold with

q = 24, almost 100% of the jobs were already solved

after 25 rounds. In addition, in the case of such altru-

istic agents, a stable state is reached soon, so that after

a few rounds a solved job rate of 97% is reached. Ev-

ery smaller setting of q leads to a slower development

towards stable states and also to a smaller job solving

rate. Nonetheless, the simulation shows that even for

small values of q a lower bound with 72% of solved

jobs is reached: The solved job rate of q = 0 and q = 4

runs identically after 30 rounds - the only difference

is a slower convergence to this stable state for q = 0.

To measure the intensity of the cultural trait prop-

agation, we determined and averaged the extent of

the adaptation steps for every trait and agent in every

round. The cultural trait propagation in the settings

q = 0, q = 4 and q = 8 comes to a stagnancy: af-

ter 30 rounds no distinctive adaptations can be identi-

ﬁed. In this process the curves approximate varyingly

quick to the zero line: For q = 8 most quickly and for

q = 4 and q = 0 increasingly slower. For the settings

q = 16 and q = 24 a continuous adaptation, which

only slowly gets smaller, takes place.

For each cultural trait, we computed the mean

and the standard deviation of the trait values over

all agents to measure the ‘trait diversity’. Averaged

over the traits u, v and w, the standard deviation of

the cultural trait diversity points out that the trait va-

riety in small settings of q hardly decreases. After a

minor adaptation wave in the ﬁrst 10 rounds, the di-

versity starts to increase and ﬁnally remains consis-

tent. For larger values of q the cultural trait variety

continuously decreases until it stagnates for q = 16 at

σ = 11.78 and for q = 24 at σ = 4.34.

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q=0 q=4 q=8 q=16 q=24

0 20 40 60 80 100

100

Round [t]

Solved Jobs Rate [%]

(a) Job solving: Jobs solved rate per round.

0 20 40 60 80 100

Round [t]

Avg. Trait Adaptation Rate [z]

(b) Cultural trait propagation: Average trait adaptation rate

per round.

0 20 40 60 80 100

Round [t]

Avg. Std.Dev. of Trait Value Diversity [z]

(b) Cultural trait propagation: Average standard deviation

of cultural trait value diversity per round.

Figure 5: Simulation results for variation of the altruism

threshold q.

4.2 Shape of Polarisation and

Globalization

In Figure 6 snapshots of the state of the world at the

points of time t = 10 and t = 100 are compared (al-

ways for the upper and lower extreme of the varied

parameter q). Those snapshots were recorded for typ-

ical runs of the parameter characteristics and are rep-

resentative for all runs. Each cell represents an agent,

for whom the cultural trait values were transferred to

the RGB-colour-values (red = 256/z ·(u −1),green =

256/z · (v − 1),blue = 256/z · (w − 1)). In the initial

state t = 0 snapshots show a unstructured distribution

of all colours (not displayed). The purpose of this il-

lustration is a visual comparison for surveying trait

similarities in parts of and in the whole world respec-

tively.

(a1) q = 0, t = 10 (b1) q = 24, t = 10

(a2) q = 0, t = 100 (b2) q = 24, t = 100

Figure 6: Comparison of state snapshots of typical runs for

variation of the altruism threshold q.

Those snapshots of the states of the world reveal

that for small q many small sections with similar cul-

tural trait values emerge. Already after ten rounds

a polarised world for q = 0 has formed, which con-

tains clusters that are almost as large as a Moore-

neighbourhood (3×3 agents). For large q the margins

of smaller areas appear blurred, and with increasing

numbers of rounds continuously larger areas with av-

erage cultural trait values emerge. In this process the

cultural traits gradually spread over the whole world:

the agents don’t face a stable cultural trait conﬁgura-

tion until the whole world has become homogeneous.

Accordingly, a globalisation evolves.

DETERMINING COOPERATION IN MULTIAGENT SYSTEMS WITH CULTURAL TRAITS

179

5 CONCLUSIONS & FUTURE

WORK

To determine cooperation in multiagent systems with

cultural traits, this work explored trait propagation

and its interaction with cooperation. In contrast to

only empirical work (Hales, 2001; Klemm et al.,

2005), our analytical approach showed that in a MAS

with cultural traits: 1. It is possible that distinctive

traits will spread completely over a population and

converge to a speciﬁc traits setting. 2. Under certain

conditions, a propagation can stagnate. Through em-

pirical experiments we have found that the basic dis-

position for altruistic behaviour of course has a major

inﬂuence on the propagation of traits and thus in sec-

ond place positively affects the cooperation and vice

versa. Above all, these results conﬁrm the claim by

(Klemm et al., 2005) that there is a threshold, which

divides between polarisation and globalisation. If the

willingness to cooperate, and thereby conﬁdence and

sympathy are generally high, the cultural traits spread

quickly over the whole population and evoke more

conﬁdence and sympathy. In the case of very selﬁsh

agents who are unwilling to cooperate, the existence

of more successful agents in the neighbourhood leads

to a only local cultural trait propagation and thereby

to more cooperation within this cluster.

In future work agents can to a minor degree ran-

domly replace cultural traits through completely dif-

ferent ones (mutation) and will be able to get to know

new agents and abandon existing contacts (mobil-

ity). Furthermore, agents will possess various abil-

ities, so that jobs, which require various abilities,

can be solved only by distinctive cooperation partners

(see (Eberling, 2009; Edmonds et al., 2009)). Addi-

tional work in this ﬁeld could contribute to explain

the accomplishment of cooperation in networks with

many individuals and many different cultural traits.

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