Swarm Intelligence among Humans

The Case of Alcoholics

Andrew Schumann

and Vadim Fris

Department of Cognitivistics, University of Information Technology and Management in Rzeszow,

Sucharskiego 2, 35-225, Rzeszow, Poland

Private Health Unitary Enterprise “Iscelenie”, Kazinca 120, 220000 Minsk, Belarus

Keywords: Swarm Intelligence, Swarm Computing, Alcoholic, Illocutionary.

Abstract: There are many forms of swarm behaviour, such as swarming of insects, flocking of birds, herding of

quadrupeds, and schooling of fish. Sometimes people behave unconsciously and this behaviour of them has

the same patterns as behaviour of swarms. For instance, pedestrians behave as herding or flocking, aircraft

boarding passengers behave as ant colony, people in escape panic behave as flocking, etc. In this paper we

propose a swarm model of people with an addictive behaviour. In particular, we consider small groups of

alcohol-dependent people drinking together as swarms with a form of intelligence. In order to formalize this

intelligence, we appeal to modal logics K and its modification K'. The logic K is used to formalize

preference relation in the case of lateral inhibition in distributing people to drink jointly and the logic K' is

used to formalize preference relation in the case of lateral activation in distributing people to drink jointly.

1 INTRODUCTION

Usually, a social behaviour is understood as a

synonymous to a collective animal behaviour. It is

claimed that there are many forms of this behaviour

from bacteria and insects to mammals including

humans. So, bacteria and insects performing a

collective behaviour are called social.

For example, a prokaryote, a one-cell organism

that lacks a membrane-bound nucleus (karyon), can

build colonies in a way of growing slime. These

colonies are called ‘biofilms’. Cells in biofilms are

organized in dynamic networks and can transmit

signals (the so-called quorum sensing) (Costerton,

Lewandowski, Caldwell, Korber, 1995). As a result,

these bacteria are considered social. Social insects

may be presented by ants – insects of the family

Formicidae. Due to a division of labour, they

construct a real society of their nest even with a

pattern to make slaves (D'Ettorre, J. Heinze, 2001).

Also, Synalpheus regalis sp., a species of snapping

shrimp that commonly live in the coral reefs,

demonstrates a collective behaviour like ants.

Among shrimps of the same colony there is one

breeding female, as well, and a labour division of

other members (Duffy, 2002). The ant-like

organization of colony is observed among some

mammals, too, e.g. among naked mole-rats

(Heterocephalus glaber sp.). In one colony they

have only one queen and one to three males to

reproduce, while other members of the colony are

just workers (Jarvis, 1981). The same collective

behaviour is typical for Damaraland blesmols

(Fukomys damarensis sp.), another mammal species

– they have one queen and many workers (Jacobs, et

al., 1991; Jarvis, Bennett, 1993).

All these patterns of ant-like collective behaviour

(a brood care and a division of labour into

reproductive and non-reproductive groups) are

evaluated as a form of eusociality, the so-called

highest level of organization of animal sociality

(Michener, 1969). Nevertheless, it is quite

controversial if we can regard the ant-like collective

behaviour as a social behaviour, indeed. We can do

it if and only if we concentrate, first, on outer stimuli

controlling individuals and, second, on ‘social roles’

(‘worker’, ‘queen’, etc.) of individuals as functions

with some utilities for the group as such, i.e. if and

only if we follow, first, behaviourism which

represents any collective behaviour as a complex

system that is managed by stimulating individuals

(in particular by their reinforcement and

punishment) (Skinner, 1976) and, second, if and

only if we share the ideas of structural functionalism

Schumann A. and Fris V.

Swarm Intelligence among Humans - The Case of Alcoholics.

DOI: 10.5220/0006106300170025

In Proceedings of the 10th International Joint Conference on Biomedical Engineering Systems and Technologies (BIOSTEC 2017), pages 17-25

ISBN: 978-989-758-212-7

which considers the whole society as a system of

functions (‘roles’) of its constituent elements

(Parsons, 1975). In case we accept both

behaviourism and structural functionalism, we can

state that a collective animal behaviour has the same

basic patterns from ‘social’ bacteria and ‘social’

insects to humans whose sociality is evident for

ourselves.

However, there are different approaches to

sociality. One of the approaches, alternative to

behaviourism and structural functionalism, is

represented by symbolic interactionism. In this

approach, a collective behaviour is social if in the

process of interaction it involves a thought with a

symbolic meaning that arises out of the interaction

of agents (Beni, Wang, 1969). In other words, social

behaviour is impossible without material culture,

e.g. without using some tools which always have

symbolic meanings. Obviously, in this sense the

collective behaviour of ants cannot be regarded as

social. There are no tools and no symbolic meanings

for the ants.

But not only humans perform social behaviour in

the meaning of symbolic interactionism. It is known

that wild bottlenose dolphins (Tursiops sp.)

“apparently use marine sponges as foraging tools”

(Krützen, Mann, Heithaus, Connor, Bejder, Sherwin,

2005) and this behaviour of them cannot be

explained genetically or ecologically. This means

that “sponging” is an example of an existing

material culture in a marine mammal species and

this culture is transmitted, presumably by mothers

teaching the skills to their sons and daughters

(Krützen, Mann, Heithaus, Connor, Bejder, Sherwin,

2005).

Also, chimpanzees involve tools in their

behaviours: large and small sticks as well as large

and small stones. In (Whiten, Goodall, McGrew,

Nishida, Reynolds, Sugiyama, Tutin, Wrangham,

Boesch, 1999), the authors discover 39 different

behaviour patterns of chimpanzees, including tool

usage, grooming and courtship behaviours. It is a

very interesting fact that some patterns of

chimpanzees are habitual in some communities but

are absent in others because of different traditions of

chimpanzee material cultures (Whiten, Goodall,

McGrew, Nishida, Reynolds, Sugiyama, Tutin,

Wrangham, Boesch, 1999). Hence, we see that the

collective behaviour of chimpanzees can be

evaluated as social, as well.

So, within symbolic interactionism we cannot

consider any complex collective behaviour, like the

ant nest, as a social behaviour. The rest of complex

behaviours can be called a swarm behaviour. Its

examples are as follows: swarming of insects,

flocking of birds, herding of quadrupeds, schooling

of fish. In swarms, animals behave collectively, e.g.

in schools or flocks each animal moves in the same

direction as its neighbour, it remains close to its

neighbours, it avoids collisions with its neighbours

(Viscido, Parrish, Grunbaum, 2004).

A group of people, such as pedestrians, can also

exhibit a swarm behaviour like a flocking or

schooling: humans prefer to avoid a person

conditionally designated by them as a possible

predator and if a substantial part of the group (not

less than 5%) changes the direction, then the rest

follows the new direction (Helbing, Keltsch, Molnar,

1997). An ant-based algorithm can explain aircraft

boarding behaviour (John, Schadschneider,

Chowdhury, Nishinari, 2008). Under the conditions

of escape panic the majority of people perform a

swarm behaviour, too (Helbing, Farkas, Vicsek,

2000). The point is that a risk of predation is the

main feature of swarming at all (Abrahams, Colgan,

1985; Olson, Hintze, Dyer, Knoester, Adami, 2013)

and under these risk conditions (like a terrorist act)

symbolic meanings for possible human interactions

are promptly reduced. As a consequence, the social

behaviour transforms into a swarm behaviour.

Thus, we distinguish the swarm behaviour from

the social one. The first is fulfilled without symbolic

interactions, but it is complex, as well, and has an

appearance from a collective decision making. In

this paper, we will show that an addictive behaviour

of humans can be considered a kind of swarm

behaviour, also. The risk of predation is a main

reason of reducing symbolic interactions in human

collective behaviours, but there are possible other

reasons like addiction. An addiction increases roles

of addictive stimuli (e.g., alcohol, morphine,

cocaine, sexual intercourse, gambling, etc.) by their

reinforcing and intrinsically rewarding.

It is known that any swarm can be controlled by

replacing stimuli: attractants and repellents

(Adamatzky, Erokhin, Grube, Schubert, Schumann,

2012), therefore we can design logic circuits based

on topology of stimuli (Schumann, 2016). For

swarms there are no symbolic meanings and the

behaviour is completely determined by outer stimuli.

In this paper, we will consider how the alcohol

dependence syndrome impacts on the human

behaviour.

We claim that alcohol-dependent humans

embody a version of swarm intelligence (Beni,

Wang, 1969; Schumann, 2016; Schumann,

Woleński, 2016) to optimize the alcohol-drinking

behaviour. Our research is based on statistic data

BIOSIGNALS 2017 - 10th International Conference on Bio-inspired Systems and Signal Processing

which we have collected due to the questionnaire of

107 people who sought help for their alcohol

dependence at the Private Health Unitary Enterprise

“Iscelenie,” Minsk, Belarus.

In Section II we consider some basic features of

collective behaviour of alcohol-addicted people. In

Section III we formalize preference relations for

their swarm intelligence.

2 BASIC FEATURES OF SWARM

INTELLIGENCE OF

ALCOHOL-DEPENDENT

PEOPLE

According to our survey, all the respondents have

affirmed that they prefer to drink in small groups

from 3 to 7 people, but the same respondents can

join different small groups in due course. The

number of stable friends to drink commonly is from

2 to 5. The alcohol-addicted people distinguish their

groups from relatives or colleagues and 63% of the

respondents think that their family and job hinder

them to drink safely.

Thus, these small groups from 3 to 7 people can

be regarded as human swarms which help their

members to drink safely and to logistically optimize

the task to drink. 85% of the respondents have

responded that members of the group can pay for

drinks if the respondent does not have money and

91% of the respondents have claimed that they can

buy alcohol for somebody from the group who does

not have money. So, we deal with a form of

solidarity in helping to drink.

35% of the respondents drink in groups

consisting only of men and 65% drink in mixed-

gender groups. In the meanwhile, a sex/gender

behaviour is mainly reduced in these groups.

In the case of involving new members into

groups the main reasons are as follows: they are

neighbours or colleagues and they can treat/pay.

Entering new groups is possible if a

friend/acquainted has invited to join them because it

is more safe and interesting for the respondent to

join the new group. Without an invitation it is

impossible to enter the group.

Groups are very friendly and the only reason to

expel somebody from the group is that (s)he quarrels

(in particular, (s)he does not want to pay). 32% of

respondents have noticed that it would be better to

expel one member in their groups.

Only 28% of respondents have stated that in their

groups there are leaders. They are men or women

more than 40 years old. The leadership consists in a

support of the group to drink together.

We have discovered that alcoholics form a

network consisting of several small groups. And the

task of optimizing common drinks is solved not by a

small group, but by the whole network, i.e. by

several groups whose members are interconnected.

The point is that each small group of alcoholics

appears and disappears under different conditions,

but the network, these alcoholics belong to, is almost

the same. We have studied that small groups of

alcohol-addicted people are not stable and, by

exchanging their members, they can fuse or split in

the optimization of drinking. The same behavioural

patterns are observed in the slime mould

(Schumann, 2015, 2016): fusing and splitting in

front of attractants to optimize their occupation.

Outer stimuli (attractants) for the slime mould are

pieces of nutrients scattered before this organism.

Attractants for alcoholics are represented by places

where they can drink in small groups safely: flat or

outside. 38% of the respondents prefer to drink at

the same place and 62% at different places. The

arguments in choosing the places are as follows: the

short distance from the home, low price, quality of

drinks.

To sum up, the alcohol-dependent people

realizes a version of swarm intelligence to optimize

drinking in the way of fusing or splitting the groups

under different conditions. In case the groups are

rather splitting, we face a lateral activation effect;

and in case the groups are fusing, we deal with a

lateral inhibition effect of alcoholic networks.

Small groups of alcoholics are considered by us

as kind of human swarms. These swarms build a

network and within the same network alcoholics can

freely move from one swarm to another. As a

consequence, the swarms fuse or split.

3 PREFERENCE RELATIONS

FOR SWARM INTELLIGENCE

OF ALCOHOL-DEPENDENT

PEOPLE

So, the alcohol-addicted people prefer to drink in

small groups from 3 to 7 persons. These groups are

said to be agents of swarm intelligence (that is really

intelligence, because an appropriate network of

alcoholics solves always optimization tasks to drink

effectively). Each agent is virtual, namely with an

unconscious collective decision-making mechanism

that is decentralized and distributed among all

Swarm Intelligence among Humans - The Case of Alcoholics

members of the group. The same situation of

distribution of intelligence is observed in any

swarm. The agents are denoted by small letters i,

j,… As well as all swarms, these agents can fuse and

split to optimize a group occupation of attractants.

Usually, there are many agents who communicate

among themselves by exchanging people (their

members), e.g., someone can be a member of agent i

today and later became a member of agent j.

The places where agents i, j,… (appropriate

small groups of alcohol-dependent humans) can

drink safely are called attractants for swarm

intelligence. The attractants are denoted by S, P, ...

There are two different ways in occupying

attractants by swarm agents: (i) with high

concentration of people (lateral inhibition effect) at

places of meeting and (ii) with low concentration of

people (lateral activation effect) at places of meeting

(Jones, 2015; Schumann, 2016). In the first case

much less attractants are occupied. In the second

case much more attractants are occupied. For

instance, in snow winter there are less attractants

(places to drink jointly and safely) and this causes a

lateral inhibition effect in alcoholic swarming. In

sunny summer there are more attractants (places to

drink in a group) and this implies a lateral activation

effect in alcoholic networking.

Lateral inhibition and lateral activation can be

detected in any forms of swarm networking. For

example, this mechanism is observed also in the true

slime mould (plasmodium) of Physarum

polycephalum. The plasmodium has the two distinct

stages in responding to signals: (i) the sensory stage

(perceiving signals) and (ii) the motor stage (action

as responding). The effect of lateral activation in the

plasmodium is to decrease contrast between

attractants at the sensory stage and to split

protoplasmic tubes towards two or more attractants

at the motor stage (Fig. 1A). The effect of lateral

inhibition is to increase contrast between attractants

at the sensory stage and to fuse protoplasmic tubes

towards one attractant at the motor stage (Fig. 1B).

In human groups there are (i) the one sensory

stage consisting in perceiving signals (as well as for

the plasmodium) and the following two motor stages

consisting in actions as responding: (ii) illocutionary

stage and (iii) perlucotionary stage.

For the first time the well-known 20

-century

philosopher John L. Austin has investigated speech

acts as a way of coordination for human behaviour

by a verbal communication as well as by a non-

verbal communication (e.g. by gestures or mimics).

His main philosophical claim that was accepted then

by almost all later language philosophers has based

on the idea that we coordinate our joint behaviour by

Figure 1: The two plasmodia propagate protoplasmic tubes

towards three attractants denoted by black circles: A.

Lateral activation. The splitting of protoplasmic tubes of

each plasmodium. B. Lateral inhibition The fusion of two

plasmodia by the fusion of their protoplasmic tubes.

illocutionary acts – some utterances which express

our intentions and expectations to produce joint

symbolic meanings for symbolic interactions: “I

hereby declare,” “I sentence you to ten years'

imprisonment”, “I promise to pay you back,” “I pray

to God”, etc. These utterances can produce an effect

on the hearer that is called a perlocutionary act.

Hence, according to Austin, in order to commit a

group behaviour, the humans should start with

illocutionary acts (uttering illocutions) to coordinate

their common symbolic meanings. As a result, their

group behaviour appears as a kind of perlocutionary

act grounded on previous illocutionary utterances.

Thus, the motor stage for the plasmodium is just

a direct behaviour, while the motor stage for the

humans starts from illocutionary acts to produce

symbolic meanings for performing an interaction

and then this stage is continued in perlocutionary

acts (a direct coordinated behaviour of a human

group).

Attractants S, P, ... are detected by alcoholics at

the sensory stage. Then alcoholics perform

illocutionary acts to share preference relations on

detected attractants. Later they commit

perlocutionary acts to occupy some detected

attractants. A data point S is considered empty if and

only if an appropriate attractant (the place denoted

by S to drink within a group) is not occupied by the

group of alcohol-dependent people. Let us define

syllogistic strings of the form SP with the following

interpretation: ‘S and P are comparable positively’,

and with the following meaning: SP is true if and

only if S and P are reachable for each other by

members of the group i and both S and P are not

empty, otherwise SP is false. Let S be a set of all

true syllogistic strings.

Now we can construct an illocutionary logic of

alcohol-dependent people. In this logic we deal with

preference relations about detected attractants

from S.

BIOSIGNALS 2017 - 10th International Conference on Bio-inspired Systems and Signal Processing

3.1 Agents in Case of Lateral

Inhibition

Let us construct an extension of modal logic K,

please see (Bull, Segerberg, 1984) about K, for

preference relations of agents in case of lateral

inhibition. Let ‘A’ and ‘B’ be metavariables ranging

over syllogistic letters S, P, ... or over standard

propositional compositions of syllogistic letters by

means of conjunctions, disjunction, implication,

negation. Let us introduce two modalities



and



with the following meaning:



A 



i.e.,



A is modally stronger and



A is modally

weaker, e.g.,



A means ‘I like A’ (or ‘I desire A’)

and



A means ‘maybe A’ (or ‘it can be A’). So, the

performative verb of



is stronger and the

performative verb of



is weaker with the same type

of performativity (modality) to prefer A (Schumann,

Woleński, 2016).

In our logic K for preference relations we have

also only two axioms as in the standard K (the

inference rules are the same also):

Necessitation Rule:

If A is a theorem of K, then so is



Distribution Axiom:



(A  B)  (



A 



B).

The operator



can be defined from



as follows:



A ::= 



A,

where



are any performative verbs for expressing a

preference relation with a strong modality: ‘like’,

‘want’, ‘desire’, etc.

Now let us add countable many new one-place

sentential connectives



to the language of K:

if A is a formula, then



is a formula, too.

These



are read as follows: “the k-th

utterance of preference relation uttered by agent i to

fulfil an illocutionary act”. The weaker modality



is defined thus:



A ::= 



A.

We assume that



and



satisfy the

necessity rule and distribution axiom as well.

Let us denote the new extension by Ki.

Now let us define in Ki the four basic preference

relations as atomic syllogistic propositions: k

(all S

are P), k

(some S are P), k

(no S are P), k

(some S are

not P). They are defined as follows.

(all S are P) ::=



(S  P)

(1)

The atomic proposition k

(all S are P) means: “for

agent i, alternative P is at least as good as alternative

S by the k-th utterance”. In the model of alcohol-

addicted swarms it means: “for the grouping of

alcohol-dependent people i, alternative P is at least

as good as alternative S at the k-th utterance”.

Let us define a model M.

Semantic meaning of k

(all S are P):

M = k

(all S are P) ::= at the utterance k uttered

by i, there exists a data point A  M such that AS 

S and for any A  M, if AS  S, then AP  S.

Semantic meaning of k

(all S are P) in alcohol-

addicted swarms: there is a group of alcoholics i at a

place A such that places A and S are connected by

exchanging of some members of i and for any place

A, if A and S are connected by exchanging of some

members of i, then A and P are connected by

exchanging of some members of i.

(some S are P) ::=



(S  P)

(2)

The atomic proposition k

(some S are P) means:

“for agent i, alternative P is not at least as bad as

alternative S by the k-th utterance”. In the model of

alcohol-addicted swarms it means: “for the grouping

of alcohol-dependent people i, alternative P is not at

least as bad as alternative S at the k-th utterance”.

Semantic meaning of k

(some S are P):

M = k

(some S are P) ::= at the utterance k

uttered by i, there exists a data point A  M such

that both AS  S and AP  S.

Semantic meaning of k

(some S are P) in alcohol-

addicted swarms: there exists a group of alcoholics i

at A such that A and S are connected by exchanging

of some members of i and A and P are connected by

exchanging of some members of i.

(no S are P) ::=



(S  P)

(3)

The atomic proposition k

(no S are P) means:

“for agent i, alternative P is at least as bad as

alternative S by the k-th utterance”. In the model of

alcohol-addicted swarms: “for the grouping of

alcohol-dependent people i, alternative P is at least

as bad as alternative S by the k-th utterance”.

Semantic meaning of k

(no S are P):

M = k

(no S are P) ::= at the utterance k uttered

by i, for all data points A M, AS is false or AP is

false.

Semantic meaning of k

(no S are P) in alcohol-

addicted swarms: for all groups of alcoholics i at

places A, A and S are not connected by exchanging

of some members of i or A and P are not connected

by exchanging of some members of i.

Swarm Intelligence among Humans - The Case of Alcoholics

(some S are not P) ::=



(S  P)

(4)

The atomic proposition k

(some S are not P)

means: “for agent i, alternative P is not at least as

good as alternative S by the k-th utterance”. In the

alcohol-addicted swarms: “for the grouping of

alcoholics i, alternative P is not at least as good as

alternative S by the k-th utterance”.

Semantic meaning of k

(some S are not P):

M = k

(some S are not P) ::= at the utterance k

uttered by i, for any data points A  M, AS is false

or there exists A  M such that AS  S and AP is

false.

Semantic meaning of k

(some S are not P) in

alcohol-addicted swarms: for all groups of

alcoholics i at places A, A and S are not connected

by exchanging of some members of i or there exists

place A such that A and S are connected by

exchanging of some members of i and A and P are

not connected by exchanging of some members of i.

We can distinguish different swarms according

to the acceptance of stronger or weaker modality:

Weak Agent:

agent i prefers



A instead of



iff



A 



Strong Agent:

agent i prefers



A instead of



iff



A 



An example of the weak agent: (s)he prefers not

to like not-A instead of that to like A. An example of

the strong agent: (s)he prefers to desire A instead of

that to accept A.

Hence, in logic Ki we have the four kinds of

atomic syllogistic propositions: k

(all S are P),

(some S are P), k

(no S are P), k

(some S are not P)

for different k, i, S, and P. All other propositions of

Ki are derivable by Boolean combinations of atomic

propositions. Models for these combinations are

defined conventionally:

M = A iff A is false in M;

M = A  B iff M = A or M = B;

M = A  B iff M = A and M = B;

M = A  B iff if M = A, then M = B.

Proposition 1. Logic Ki is a conservative

extension of K.

Proposition 2. In Ki, the conventional square of

opposition holds, i.e. there are the following

tautologies:

(all S are P)  k

(some S are P);

(no S are P)  k

(some S are not P);

(k

(all S are P)  k

(no S are P));

(some S are P)  k

(some S are not P);

(all S are P)  k

(some S are not P);

(k

(all S are P)  k

(some S are not P));

(no S are P)  k

(some S are P);

(k

(no S are P)  k

(some S are P)).

Proof. It follows from (1) – (4).

The fusion of two swarms i and j for universal

affirmative syllogistic propositions is defined in Ki

in the way:

(all S

are P); m

(all S

are P)

(km)



(all (S

 S

) are P)

The splitting of one swarm ij is defined in Ki thus:

(km)



(all S are (P

 P

))

(all S are P

); m

(all S are P

)

Hence, the illocutionary logic Ki describes the

preference relations of alcoholics towards attractants

under the conditions of lateral inhibition.

3.2 Agents in Case of Lateral

Activation

When the concentration of attractants (different

places of grouping for common drinks) is high, the

logic K for preference relations is unacceptable.

Instead of K we will use its modification K' (with

the same inference rules) (Schumann, 2013;

Schumann, Woleński, 2016):

Necessitation Rule:

If A is a theorem of K', then so is



Distribution Weak Axiom:



(A  B)  (



A 



B).

Now let us construct K'i by adding countable one-

place sentential connectives



and



to the

language of K' and then define the four basic

preference relations k

(all S are P)', k

(some S are P)',

(no S are P)', k

(some S are not P)' in the following

manner:



(S, P)' ::=



(S  P)

(5)

The atomic proposition



(S, P)' means

(Schumann, Woleński, 2016): “for agent i,

alternative P is at least as good as alternative S by

BIOSIGNALS 2017 - 10th International Conference on Bio-inspired Systems and Signal Processing

the k-th utterance”. In the model of alcohol-addicted

swarms: “for the group of alcoholics i, alternative P

is at least as good as alternative S by the k-th

utterance”.

Let us define a model M'.

Semantic meaning of



(S, P)':

M' =



(S, P)' ::= there exists a data point A

M' such that AS  S and for any A M', AS  S and

AP  S.

Semantic meaning of



(S, P)' in alcohol-

addicted swarms: there is a string AS and for any

place A which is reachable for S and P by

exchanging of members of i, there are strings AS and

AP. This means that we have an occupation of the

whole region where the places S and P are located.

(some S are P)' ::=



(S  P)

(6)

The atomic proposition k

(some S are P)' means

(Schumann, Woleński, 2016): “for agent i,

alternative P is not at least as bad as alternative S by

the k-th utterance”. In the model of alcohol-addicted

swarms: “for the group of alcoholics i, alternative P

is not at least as bad as alternative S by the k-th

utterance”.

Semantic meaning of k

(some S are P)':

M' = k

(some S are P)' ::= for any data point

A M', both AS is false and AP is false.

Semantic meaning of k

(some S are P)' in

alcohol-addicted swarms: for any place A which is

reachable for S and P by exchanging of members of

i, there are no strings AS and AP. This means that the

group of alcoholics cannot reach S from P or P from

S immediately.

(no S are P)' ::=



(S  P)

(7)

The atomic proposition k

(no S are P)' means

(Schumann, Woleński, 2016): “for agent i,

alternative P is at least as bad as alternative S by the

k-th utterance”. In the model of alcohol-addicted

swarms: “for the group of alcoholics i, alternative P

is at least as bad as alternative S by the k-th

utterance”.

Semantic meaning of k

(no S are P)':

M' = k

(no S are P)' ::= there exists a data

point A  M' such that if AS is false, then AP  S.

Semantic meaning of k

(no S are P)' in alcohol-

addicted swarms: there exists a place A which is

reachable for S and P by exchanging of members of

i such that there is a string AS or there is a string AP.

This means that the group of alcoholics i occupies S

or P, but not the whole region where the places S

and P are located.

(some S are not P)' ::=



(S  P)

(8)

The atomic proposition k

(some S are not P)'

means (Schumann, Woleński, 2016): “for agent i,

alternative P is not at least as good as alternative S

by the k-th utterance”. In the model of alcohol-

addicted swarms: “for the group of alcoholics i,

alternative P is not at least as good as alternative S

by the k-th utterance”.

Semantic meaning of k

(some S are not P)':

M' = k

(some S are not P)' ::= for any data

point A M', AS is false or there exists a data point

A  M' such that AS is false or AP is false.

Semantic meaning of k

(some S are not P)' in

alcohol-addicted swarms: for any place A which is

reachable for S and P by exchanging of members of

i there is no string AS or there exists a place A which

is reachable for S and P by exchanging of members

of i such that there is no string AS or there is no

string AP. This means that the group of alcoholics i

does not occupy S or there is a place which is not

connected to S or P by exchanging of members of i.

Models for the Boolean combinations of atomic

proposition of K'i are defined thus:

M' = A iff A is false in M';

M' = A  B iff M' = A or M' = B;

M' = A  B iff M' = A and M' = B;

M' = A  B iff if M' = A, then M' = B.

Proposition 3. Logic K'i is a conservative

extension of K'.

Proposition 2. In K'i, the unconventional square

of opposition holds, i.e. there are the following

tautologies:

(all S are P)'  k

(no S are P)';

(some S are P)'  k

(some S are not P)';

(k

(all S are P)'  k

(some S are P)');

(no S are P)'  k

(some S are not P)';

(all S are P)'  k

(some S are not P)';

(k

(all S are P)'  k

(some S are not P)');

(no S are P)'  k

(some S are P)';

(k

(no S are P)'  k

(some S are P)').

Proof. It follows from (5) – (8).

Now, let us consider pairs



A and



A,

where different performative verbs



and



occur and these verbs belong to different groups of

illocutions in expressing a preference relation, i.e.,

both cannot be simultaneously representatives,

directives, declaratives, expressive, or comissives.

Swarm Intelligence among Humans - The Case of Alcoholics

For instance, ‘believing’ and ‘knowing’ are both

representatives and ‘ordering’ and ‘insisting’ are

both directives. Assume, ‘believing’ be denoted by



and ‘advising’ by



. Notice that ‘assuming’

is modally weaker than ‘believing’, and ‘advising’ is

modally weaker than ‘insisting’. So, ‘assuming’ can

be denoted by



, and ‘advising’ can be denoted by



, such that



A 



A and



A 



A. The construction



A 



A

(respectively,



A 



A) fits the situation

that a belief that A is ever stronger than some other

illocutions (belonging to other illocution groups)

related to not-A.

Let us distinguish different swarms according to

the acceptance of stronger or weaker modality:

Meditative Agent:

(i) agent i prefers



A instead of



A iff



A 



A; and (ii) agent i prefers



A

instead of



A iff



A 



A.

Active Agent:

(i) agent i prefers



A instead of



A iff



A 



A; (ii) and agent i prefers





instead of



A iff



A 



A.

An example of the meditative agent: (s)he

prefers to believe that not-A instead of that to order

that A. An example of the active agent: (s)he prefers

to insist that A instead of that to believe that not-A.

The fusion of two swarms i and j universal

affirmative syllogistic propositions is defined in K'i

as follows:

(all S

are P)'; m

(all S

are P) '

(km)



(all (S

 S

) are P)

The splitting of one swarm ij is defined in K'i:

(km)



(all S are (P

 P

))

(all S are P

); m

(all S are P

)

The illocutionary logic K'i is to express the

preference relations of alcoholics towards attractants

under the conditions of lateral activation.

4 CONCLUSIONS

We have shown that a habit of joint drinking of

alcohol-addicted people in small groups can be

considered a swarm behaviour controlled by outer

stimuli (places to drink jointly). These swarms can

be managed by localization of places for meeting to

drink. Generally, the logic of propagation of groups

of alcoholics has the same axioms as the logic of

parasite propagation for Schistosomatidae sp.

(Schumann, Akimova, 2015) as well as the same

axioms as the logic of slime mould expansion

(Schumann, 2015, 2016). The difference is that

instead of syllogistics for Schistosomatidae sp.

(Schumann, Akimova, 2015) and for slime mould

(Schumann, 2016), where preference relations are

simple and express only attractions by food, we

involve many performative actions (verbs), which

express a desire to drink together, within modal

logics Ki and K'i. The logic Ki is used to formalize

lateral inhibition in distributing people to drink

jointly and the logic K'i is used to formalize lateral

activation in distributing people to drink jointly.

The main outcome of our research is to show that

some forms of human group behaviour are not social

in fact. A kind of unsocial group behaviours is

designated by us as swarm behaviour. Many forms

of human swarming have recently been studied –

from crowds of people in escape panic (Helbing,

Farkas, Vicsek, 2000) to aircraft boarding (John,

Schadschneider, Chowdhury, Nishinari, 2008).

However, some stable patterns of interconnected

people have never been analyzed as a swarm.

We have proposed to consider a network of

coordinated alcoholics as human swarming. The

reasons are as follows: (1) their behaviour is

controlled by replacing stimuli: attractants (places

where they can drink jointly and safely) and

repellents (some interruptions which can appear for

drinking); this control is executed by the same

algorithms as for standard swarms from social

bacteria to eusocial mammals; (2) the behaviour of

alcoholics is collective and even cooperative, but it

is subordinated to the only one uncontrolled

intention, namely, how to drink; so, this motivation

bears no symbolic meanings in the terms of

symbolic interactionism (Blumer, 1969) and, then, it

cannot be evaluated as social.

Each alcoholic realizes a group adaptation and

belongs to a network of people with the same

addiction. This network allows its members to

optimize the task to drink. Therefore, it is a

substitute of social groups (from family to other

institutions) and it is a displacement of standard

social behavior.

One of the effective means to recover alcoholism

is a back replacement of ways of group optimization

how to drink by that how not to drink. It is possible

within a network of the so-called Alcoholics

Anonymous where alcoholics can help each other to

stay sober.

BIOSIGNALS 2017 - 10th International Conference on Bio-inspired Systems and Signal Processing

ACKNOWLEDGEMENTS

The project was supported by FP7-ICT-2011-8.

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