REPUTATION BASED INTELLIGENT AGENT NEGOTIATION
FRAMEWORKS IN THE E-MARKETPLACE
Malamati Louta
Technological Educational Institute of Western Macedonia, Koila, Kozani, Greece
Ioanna Roussaki
School of Electrical and Computer Engineering, National Technical University of Athens, 9 Heroon Polytechneiou Str,
Athens, Greece
Lambros Pechlivanos
Department of International and European Economic Studies, Athens University of Economics and Business,
Athens,Greece
Keywords: Intelligent Agents, Negotiation Protocol & Model & Strategy, Ranking Mechanism, Reputation Mechanism.
Abstract: E-commerce is expected to achieve high market penetration if coupled with the appropriate technologies.
Mobile Agent Technology (MAT) may enhance the intelligence and improve the efficiency of systems in the
e-marketplace. Such a highly competitive and extremely dynamic market should encompass mechanisms for
enabling users (Buyers) to find the most appropriate service providers (Sellers), i.e., those offering adequate
quality services at a certain time period in a cost efficient manner. In this study, the Buyers’ decision on the
“best” Seller is based on a weighted combination of the evaluation of the quality of the Sellers’ offer
(performance related factor) and of their reputation rating (reliability related factor). Efficient negotiation
frameworks are enhanced with a Sellers’ collaborative reputation mechanism, which helps estimating their
trustworthiness and predicting their future behaviour, taking into account the Sellers’ past performance in
satisfying the Buyers’ expectations. In essence, Sellers are rated with respect to whether they honoured or
not the agreements they have established with the Buyers, thus introducing the concept of trust among the
negotiators. The reputation mechanism considers both first-hand information (acquired from the Buyer’s
past experiences with the Sellers) and second-hand information (disseminated from other Buyers’ based on
their own past experiences with the Sellers), while spurious reputation ratings are taken into account.
1 INTRODUCTION
In the liberalised and deregulated e-marketplace
some key factors for service providers’ success are
the following. First, the efficiency with which
services will be developed. Second, the quality level,
in relation with the corresponding cost, of new
services. Third, the efficiency with which the
services will be operated (controlled, maintained,
administered, etc.). The aim of this paper is, in
accordance with efficient service operation
objectives, to propose enhancements to the
sophistication of the negotiation functionality that
can be offered by e-commerce systems in open
competitive communications environments. This
study is based upon the notion of interacting
intelligent agents which participate in trading
activities on behalf of their owners, while exhibiting
properties such as autonomy, reactiveness, and
proactiveness, in order to achieve particular
objectives and accomplish their goals (He, 2003).
Automated negotiation is a very broad and
encompassing field. Thus, it is vital to understand
the dimensions and range of options available. When
building autonomous agents capable of sophisticated
and flexible negotiation, three broad areas need to be
considered (Faratin, 1998): (i) what negotiation
protocol and model will be adopted, (ii) what are the
issues over which negotiation will take place, and
5
Louta M., Roussaki I. and Pechlivanos L. (2006).
REPUTATION BASED INTELLIGENT AGENT NEGOTIATION FRAMEWORKS IN THE E-MARKETPLACE.
In Proceedings of the International Conference on e-Business, pages 5-12
DOI: 10.5220/0001426600050012
Copyright
c
SciTePress
(iii) what negotiation strategies will the agents
employ. The negotiation protocol defines the “rules
of encounter” between the agents (Rosenschein,
1994). Then, depending on the goals set for the
agents and the negotiation protocol, the negotiation
strategies are determined (Roussaki, 2003).
In the highly competitive and dynamic e-
marketplace users (Buyers) should be provided with
mechanisms that enable them to find the most
appropriate service providers (Sellers), i.e., those
offering the desirable quality of service at a certain
time period in a cost efficient manner. In this study
we present such mechanisms. As a first step, a
negotiation protocol to be employed in an automatic
multi-lateral, multi-issue negotiation model is
proposed and efficient negotiation strategies for
Business-to-Consumer e-commerce are presented. In
this framework, the roles of the negotiating agents
may be classified into two main categories that, in
principle, are in conflict. These two categories are:
the Buyer Agents (BAs) and the Seller Agents (SAs)
that are both considered to be rational and self-
interested, while aiming to maximise their owners’
profit.
A multi-round negotiation framework is
exploited, which demonstrates inherent
computational and communication advantages over
single step mechanisms in such complex
frameworks (Conitzer, 2003). In essence, the agents
hold private information, which may be revealed
incrementally, only on an as-needed basis. The
framework considered covers multi-issue contracts
and multi-party situations, while being a highly
dynamic one, in the sense that its variables,
attributes and objectives may change over time. The
designed negotiation strategies assume the case
where the negotiators face strict deadlines, and assist
agents to reach to a satisfactory agreement within
the specified time-limits.
E-marketplace is commonly perceived as an
environment offering both opportunities and threats.
Buyers’ or Sellers’ misbehaviour due to selfish or
malicious reasons can significantly degrade the
performance of the e-market. To cope with
misbehaviour the negotiators should be able to
automatically adapt their strategies to different
levels of cooperation and trust. Reputation
Mechanisms provide means of obtaining a reliability
rating of participants in e-marketplace environments
exploiting learning from experience concept and
serve as an incentive for good behaviour to avoid the
negative consequences of a bad reputation spreading
in the market.
In the context of this study, as a second step, the
proposed framework is enhanced by a Sellers’
collaborative reputation mechanism, which takes
into account the Sellers’ past performance in
consistently satisfying Buyers’ expectations. To be
more specific, the reputation mechanism rates the
Sellers with respect to whether they honoured or not
the agreements established with the Buyers, thus
introducing the concept of trust among the
negotiating parties. Most reputation based systems in
related research literature aim to enable parties to
make decisions on which parties to
negotiate/cooperate with or exclude, after they have
been informed about the reputation ratings of the
parties of interest. The authors in this study do not
directly exclude / isolate the Sellers that are deemed
misbehaving, but instead base the Buyers’ decision
on the most appropriate Seller on a weighted
combination of the evaluation of the quality of the
Sellers’ offer (performance related factor) and of
their reputation rating (reliability related factor).
The reputation mechanism considers both first-hand
information (acquired from the BA’s past
experiences with the SAs) and second-hand
information (disseminated from other BAs), while
spurious reputation ratings are taken into account.
The rest of the paper is structured as follows.
Section 2, presents the negotiation framework
adopted in detail. Different contract ranking
mechanisms are employed instead of the usual
alternating sequential offers pattern, while the
concept of decision issues is introduced. In Section
3, a collaborative reputation mechanism is presented
aiming to offer an efficient way of building the
necessary level of trust in the e-market. Finally, in
Section 4, conclusions are drawn and directions for
future plans are presented.
2 THE PROPOSED
NEGOTIATION FRAMEWORK
In order to create a successful negotiation
framework, the design of an appropriate protocol
that will govern the interactions between the
negotiation participants is necessary. Depending on
the specific negotiation problem that needs to be
solved, a protocol is the set of rules that
correspondingly constrain the proposals that the
negotiation parties are able to make. In this section,
we initially describe the adopted negotiation
protocol that is based on a ranking mechanism on
the Buyer’s side. Subsequently, an efficient dynamic
negotiation model is presented, based on the multi-
issue value scoring system introduced by Raiffa
(Raiffa, 1982), in the context of bilateral
negotiations. Based on the designed negotiation
protocol, the proposed multi-party, multi-issue,
dynamic model is exploited by the SA in its contract
generation process, and by the BA during the
ICE-B 2006 - INTERNATIONAL CONFERENCE ON E-BUSINESS
6
contract evaluation phase. Our focus is laid on the
rationale of the SA, while simplifying assumptions
are made regarding the BA’s logic. We consider that
a negotiation is successful, if a mutually acceptable
contract is reached within reasonable time. Since an
exhaustive exploration of the possible contract space
may form a computationally intensive task, the SAs
are provided with a mechanism enabling them to
find good (near optimal) solutions in reasonable
time, by means of computationally efficient
algorithms. The rest of this section is structured as
follows. In subsection 2.1, the designed negotiation
protocol and model are presented, while in
subsection 2.2 the basic elements of the negotiation
problem and the designed negotiation strategies are
provided.
2.1 Designed Negotiation Protocol &
Model
In the negotiation research literature, the interactions
among the parties follow mostly the rules of an
alternating sequential protocol in which the agents
take turns to make offers and counter offers
(Rubinstein, 1982). This model however necessitates
an advanced reasoning component on behalf of the
BA as well as the SA. In this study, we initially
tackle a simpler case where BA does not give a
counter offer to the SA, but ranks the SA’s offers
instead. This ranking is then provided to the SA,
which generates a new offer hopefully closer to a
mutually acceptable contract. This process continues
until an agreement is reached, or one of the parties
withdraws. This protocol is very efficient in case the
BA is not able to express the user
requirements/preferences in a completely quantified
way, while being capable of selecting, classifying or
rating the contract(s) proposed.
The protocol adopted can be described as
follows. Once the agents have determined the set of
issues over which they will negotiate, the
negotiation process consists of an alternate
succession of contract proposals on behalf of the SA
and subsequent ranking of them by the BA according
to its preferences and current conditions. Thus, at
each round, the SA sends to the BA
N contracts
(i.e.,
N packets consisting on n -plets of values of
the n contract issues), which are subsequently
evaluated by the BA and a rank vector is returned to
the SA. This process continues until a contract
proposed by the SA is accepted by the BA or one of
the agents terminates the negotiation (e.g., if the
time deadline is reached without an agreement being
in place). Even though negotiation can be initiated
by SAs or BAs, only the SAs propose concrete
contracts, as there is no counter offer generation
mechanism for the BAs. We hereafter consider the
case where the negotiation process is initiated by the
BA who sends to the SA an initial Request for
Proposal (RFP) specifying the types and nature of
the contract issues and the values of all non
negotiable parameters. The main issue is assumed to
be the price of the good/service under negotiation,
while various other issues may be considered as
well.
Subsequently, we propose a dynamic model for
agent negotiation that can be exploited by strategies
in order to construct contracts acceptable to the
opponent parties but which, nevertheless, maximise
the agent’s own utility function. The notation used
by this negotiation model is as follows. The agents
that represent Sellers are denoted by
{}
,...,
21
SSS =
and the ones that represent potential Buyers are
denoted by
{
}
,...,
21
BBB
=
. We introduce the notion
of decision issues (DIs), issues that even though
their values are not under negotiation and they are
not included in the contract parameters, they affect
the evaluation of the values of the contract issues.
Without being exhaustive, such issues may consist
of: the number of competitor companies, the number
of substitute or complementary products/services,
the quantity of product in stock, the number of
current potential buyers, the time until the
negotiation deadline expires, the resources
availability and restrictions, etc. The values of the
DIs may change overtime, depending on the e-
marketplace conditions and on the Seller’s and
Buyer’s state. The values of the DIs are denoted by
j
d
,
fj ,...,1
=
. We may now introduce the utility
function of the proposed framework as follows. Let
[
]
[
]
1,0,: →
a
i
a
i
a
i
MmU
denote the utility that agent
BSa ∪
∈
assigns to a value of contract issue
i
in
the range of its acceptable values. In order for the
utility function of any contract issue
i
for any
negotiator to lie within the range
[]
1,0
, the value of
issue
i must lie within the range of its acceptable
values. To ensure this, we introduce the notion of
value constraints, that is expressed as follows:
a
ii
a
i
Mcm ≤≤
. In case the value constraints hold for
all contract issues, the utility function can be used to
measure the satisfaction of a negotiator as far as the
proposed contract is concerned. Nevertheless, often,
the value constraints are not met for some contract
issues, thus constituting the contract completely
unacceptable, regardless of the utility level. In this
case, there is not much value in using the above
specified utility function to measure the satisfaction
degree of this negotiator, as the contract is
completely unacceptable. Thus, we may introduce a
value constraint validity vector:
[
]
a
i
a
VCVVCV =
,
REPUTATION BASED INTELLIGENT AGENT NEGOTIATION FRAMEWORKS IN THE E-MARKETPLACE
7
ni ,...,1=
, where
{}
1,0∈
a
i
VCV
, depending on whether
the value constraint for negotiating party
a
is met
for contract issue
i
(i.e.,
1=
a
i
VCV
) or not (i.e.,
0=
a
i
VCV
). The requirement of mere presence or
absence of a particular feature can be reduced to
value constraints and thus will not be further
analysed.
Let
a
i
w
be the importance of issue
i
for agent
a
,
where
1
1
=
∑
=
n
i
a
i
w
. Using the above notation, the
agent’s
a
utility function for a contract
{}
knkk
ccC ,...,
1
=
can be expressed by the following
equation:
()
()
∑
=
=
=
n
i
tt
jki
a
i
a
ik
a
k
dcUwCU
1
,
, where
k
tt
j
d
=
,
mj ,...,1=
is the value of decision issue
j
d
at the
time
k
t
, when contract
k
C
is proposed. It should be
mentioned that the utility function
()
k
tt
jki
a
i
dcU
=
,
may
be of any form (e.g., linear, polynomial, exponential,
quasilinear, etc.), as nonlinear formulations of the
overall utility function do not affect the basic ideas
of the model.
As already mentioned, the BA ranks the contracts
proposed by the SA. For the simplest ranking
function, the ranks that may be assigned to any
contract proposed are boolean variables, i.e., one
instance of the set
{}
rejectaccept,
. A second ranking
scheme may entail the identification of the contract
best suiting the Buyer’s needs without any further
classification of the contracts proposed, while in a
more sophisticated approach, the ranks lie within a
range
[]
rr
Mm ,
, where any contract rated with less
than
r
M
is not acceptable by the BA, while, when a
contract is rated with
r
M
, then the proposed by the
SA contract is accepted by the BA. In order to signal
the case where at least one value constraint is not
met for the BA for a certain contract, we introduce
another parameter called contract value constraints
validity that will be denoted by
a
k
CVCV
for contract
k
C
and is given by the following equation:
∏
=
=
n
i
a
ki
a
k
VCVCVCV
1
. Based on the previous analysis,
in case all value constraints are met for contract
k
C
,
it stands that
1=
a
k
CVCV
. On the other hand, in case
at least one value constraint is not valid for contract
k
C
, it stands that
0=
a
k
CVCV
, and then the particular
contract is definitely rejected.
Furthermore, the vector of the
1≥N contracts
proposed by the Seller agent
S to the Buyer agent
B
at time t is denoted by
{
}
t
N
tt
CCP ,...,
1
= , the
vector of the
n contract issues values proposed by
S to
B
at time
t
for the k -contract of this proposal
(
Nk ,...,1
=
) is represented by
{
}
t
kn
t
k
t
k
ccC ,...,
1
= , while
the value of issue
i
proposed by S to
B
at time t
for the
k -contract of this proposal is denoted by
t
ki
c
(
ni ,...,1
=
). Let now
{
}
t
N
tt
rrR ,...,
1
= be the vector of
ranking values that
B
assigns at time t to the
previous contracts proposal made by
S , and
t
k
r
(
Nk ,...,1
=
) be the rank that
B
assigns at time
t
to
the
k -contract of this proposal. The range of values
acceptable to agent
{}
BSa ,
∈
for issue i is
represented by the interval
[
]
a
i
a
i
Mm , .
A contract package proposal is accepted by
B
when at least one contract is rated with
r
M , while
the negotiation terminates in case the agent(s)
deadline is reached or when a boolean variable
expressing the wish of the agents to quit the
negotiation is set to true. If an agreement is reached,
then we call the negotiation successful, while in case
one of the negotiators quits it is called unsuccessful.
In any other case, we say that the negotiation thread
is active. A detailed presentation of the negotiation
protocol and model adopted can be found in
(Roussaki, 2004a).
2.2 Negotiation Problem and the
Designed Strategies
The objective of the negotiation problem on the
Seller’s side is to find a contract
final
C
},...,,{
21 nfinalfinalfinal
ccc
=
that maximises his/her
overall utility function
)(
final
S
CU
, i.e., the
satisfaction stemming from the proposed contract,
within the negotiation deadlines for both the BA and
the SA. Nevertheless, there are constraints on the
acceptable value ranges that should apply for both
negotiating parties, while their individual utilities
should be above a minimum acceptable threshold
(i.e.,
S
Accfinal
S
UCU
min
)( ≥
and
B
Accfinal
B
UCU
min
)( ≥
). Based
on the selected protocol and the proposed model,
designing a negotiation strategy can be reduced to a
decision problem on finding the contract package
proposal
{
}
111
,...,
1
+++
=
lll
t
N
tt
CCP of the N contracts
{
}
111
,...,
1
+++
=
lll
t
kn
t
k
t
k
ccC ( Nk ,...,1
=
) that should be
proposed by the SA to the BA in the next round
1
+
l ,
given the vector
{
}
lll
t
N
tt
CCP ,...,
1
= proposed by the SA
to the BA during the previous round
l , the vector
{
}
lll
t
N
tt
rrR ,...,
1
= of the ranking values
l
t
k
r (
Nk ,...,1=
)
that the BA assigns to the previously made by the SA
contract proposal at the negotiation round
l and the
value constraint validity vector
{
}
B
ki
B
k
VCVVCV =
(
ni ,...,1
=
) for at least one of the contracts proposed
subject to the SA’s related constraints and to the
ICE-B 2006 - INTERNATIONAL CONFERENCE ON E-BUSINESS
8
existent resource and computational limitations.
The complexity of the negotiation problem is
increased with regards to the number of the contract
issues involved and the range of their acceptable
values. In this respect, the design of computationally
efficient algorithms that may provide good (near-
optimal) solutions in reasonable time is required.
A detailed presentation of the proposed
negotiation strategies can be found in (Louta,
2004a), (Louta, 2004b), (Roussaki, 2004b). The
general idea is that all contracts
l
t
k
C
(
nk ,...,1=
) of a
negotiation round
l
are generated by the same
“source” contract that will be hereafter denoted as
l
t
C
0
. All contracts of the same round are generated so
that they correspond to equal utilities for the Seller.
Specifically,
N
contracts are proposed at each
negotiation round
l
, which yield the same utility
concession quantity
o
t
Θ
with respect to the source
contract
l
t
C
0
. Thus, the utility of the contracts
proposed is equal to
(
)
(
)
0
00
,,
0
t
t
t
S
t
t
k
S
dCUdCU
ll
Θ−=
,
while
(
)
(
)
00
1
,,
0
t
t
S
t
t
k
S
dCUdCU
ll
=
−
,
nk ,...,1=∀
. Utility
concession quantity
o
t
Θ
has been considered to be
constant and equal to
L
UU
S
Acc
tS
)(
min
,
max
0
−
for each
negotiation round, where
L
is the number of
negotiation rounds that could take place before the
SA’s negotiation deadline is reached. It has been
assumed that the values of all decision issues are
invariable for the entire negotiation procedure. It is
noted that in case an agreement between BA and SA
is feasible (that is there exist at least one contract
l
t
k
C for which it stands:
(
)
S
Acc
t
k
S
UCU
l
min
≥ and
(
)
B
Acc
t
k
B
UCU
l
min
≥ ), our approach will succeed in
identifying a mutually acceptable contract due to the
fact that as its deadline approaches, the SA concedes
up to its reservation value
S
Acc
U
min
.
Based on the RFP sent by the BA, the SA
proposes an initial contract
{
}
000
,...,
1
t
n
tt
ccC =
to the BA
at
0
tt =
, setting all contract issues at the values that
maximise the Seller’s utility (i.e., if
(
)
[
]
0,
0
>∂∂
i
t
k
S
cdCU
, then the SA sets
S
i
t
i
Mc =
0
, while in
case
(
)
[
]
0,
0
<∂∂
i
t
k
S
cdCU
, then the SA sets
S
i
t
i
mc =
0
).
The utility of the initial contract
0
t
C
for the SA is
denoted by:
(
)
0
0
0
,
max
,
tS
t
t
S
UdCU =
, as
0
,
max
tS
U
is the
maximum utility that can be achieved for the Seller,
given the values of the decision issues
{
}
0
0
t
j
t
dd =
at
time
0
tt =
. With respect to this initial contract
0
t
C
two distinct cases may be identified. First, no value
constraint violation exists and the Seller aims to find
a contract satisfying the Buyer’s utility constraint.
Second, value constraint violation occurs, in which
case the BA also provides its value constraint
validity vector
B
VCV
0
, while the SA, initially tries to
generate a contract that satisfies the BA’s value
constraints. Until a non value constraint violating
contract
l
t
C
is acquired, at each negotiation round
1>l
the source contract
l
t
C
0
is generated based on the
contract
1
0
−l
t
C
by distributing the utility concession
0
t
Θ
amongst the contract issues, whose values are
not acceptable to the BA. This process continues
until a non value constraint violating contract
l
t
C
is
produced, in which case the SA’s strategy is
modified in order to generate a mutually acceptable
contract within reasonable time.
3 REPUTATION MECHANISM
The establishment of trust is of outmost importance
in the highly dynamic e-marketplace, where small
players emerge and vanish, anyone can choose to be
anonymous, while users may participate in only a
few transactions that may be of relatively low value
and potential contracts may cross jurisdictional
boundaries, raising the difficulty of legal contract
enforcement.
Traditional models aiming to avoid strategic
misbehaviour involve Trusted Third Parties (TTPs)
or intermediaries (Atif, 2002) that monitor every
transaction, which is very costly and sometimes
impossible to apply due to the complexity and the
heterogeneity of the environment. Misbehaviour
means deviation from regular functionality. In the
most general case, it may be unintentional (due to
faults) or intentional in order for selfish parties to
take advantage of certain situations. Reputation
mechanisms are claimed to provide a “softer” notion
of security considered to be sufficient for many
multi-agent applications (Zacharia, 2000). In
essence, they discourage the parties involved from
misbehaving, since the gains expected by future
potential contracts establishment due to a higher
reputation rating can offset the loss incurred by
honouring the transaction terms. Dissemination of
reputation related information to a large number of
negotiating participants may multiply the expected
future gains of honest negotiation parties.
Our study is related to previous pertinent work in
the literature, since reputation based mechanisms is
a quite popular research field, attracting researchers
working in various different areas (Buchegger,
2005)
. In most cases, a reputation based mechanism
is used in order to automatically isolate a
misbehaving party. Thus, the goal of a reputation
system is to enable parties to make decisions on
which parties to negotiate / cooperate with or
exclude, after they have been informed about the
REPUTATION BASED INTELLIGENT AGENT NEGOTIATION FRAMEWORKS IN THE E-MARKETPLACE
9
reputation ratings of the parties of interest. Feedback
received from negotiating participants related to an
agent’s past behaviour may be formulated as a
reputation measure exploiting learning from
experience concepts. The reputation related
information obtained may be used by the parties in
order to adjust their decisions and behaviour. In this
study, Sellers that are deemed misbehaving are not
directly ostracised, but instead the Buyers’ decision
on the most appropriate Seller is based on a
weighted combination of the evaluation of the
Sellers’ offer quality (performance related factor)
and of their reputation rating (reliability related
factor). The agents may only use first-hand
information, based on their own experiences or they
may additionally exploit second-hand information
disseminated from other parties, which enables them
to identify misbehaving participants early enough.
In Section 3.1 the fundamental concepts of our
proposed collaborative reputation mechanism are
given, while Section 3.2 provides the mathematical
description of the reputation ratings and of the
Buyers’ decision.
3.1 Reputation Rating and Buyer
Decision Fundamentals
Assuming the presence of M SAs negotiating with a
BA for the terms and conditions of the provision of a
product / service, the BA can decide on the most
appropriate SA based on the evaluation of the SA’s
offer quality combined with an estimation of the
SA’s expected behaviour. In our approach this
estimation comprises the reliability related factor,
which is introduced in order to reflect whether the
Seller finally provides to the Buyers the product /
service that corresponds to the established contract
terms or not. The SA’s reliability is reduced
whenever the SA does not honour the agreement
contract terms reached via the negotiation process.
The SAs’ performance evaluation factor is based on
the fact that there may be different levels of
satisfaction with respect to the various SAs’ offers.
In this respect, there may be SAs that, in principle,
do not satisfy the BA with their offer.
The proposed reputation mechanism is
collaborative in the sense that it considers both first-
hand information (acquired from the Buyer’s past
experiences with the Sellers) and second-hand
information (disseminated from other Buyers). To be
more specific, each BA keeps a record of the
reputation ratings of the SAs it has negotiated with.
Additionally, a centralised component called
Reputation Manager (RM), maintains a collective
record of the SAs’ reputation ratings based on the
feedback given by the BAs on their experiences in
the e-market.
True feedback cannot be automatically assumed.
Second-hand information can be spurious (e.g.,
parties may choose to misreport their experience due
to jealousy or in order to discredit trustworthy
Sellers). In general, a mechanism for eliciting true
feedback in the absence of TTPs is necessitated.
According to the simplest possible approach that
may be adopted in order to account for possible
inaccuracies to the feedback provided to the RM by
the BAs (both intentional and unintentional), the BA
can mostly rely on its own experiences rather on the
SAs’ reputation ratings provided by the RM. To this
respect, SAs’ reputation ratings provided by the RM
may be attributed with a relatively low significance
factor. In the context of this study, we consider that
each BA is associated with a predetermined trust
level, which reflects whether the BA reports to the
RM its experiences with the SAs truthfully. To be
more specific, an honesty probability is attributed to
each BA, i.e., a measure of the likelihood that a BA
gives feedback compliant to the real picture
concerning service provisioning. Second-hand
information obtained from trustworthy BAs
(associated with a high honesty probability), are
given a higher significance factor, whereas reports
(positive or negative) coming from untrustworthy
sources have a small impact on the formation of the
SAs’ reputation ratings kept by the RM.
The BA uses the reputation mechanism to decide
on the most appropriate SA, especially in cases
where the BA doubts the accuracy of the information
provided by the SA. A learning period is required in
order for the RM and the BA to obtain fundamental
information for the SAs. In case reputation specific
information is not available to the BA (both through
its own experiences and through the RM) the
reliability related factor is not considered for the
Seller selection. At this point it should be noted that
the reputation mechanism comes at the cost of
keeping reputation ratings related information and
updating it after service provision has taken place.
3.2 Formulation of the Sellers
Reputation Rating System
Each Seller S may be rated in accordance with the
following formula:
)])([)(()()()( SrrESrrRlkSRRSRR
rprepost
−⋅
⋅
+
=
(1),
where
post
RR and
pre
RR are the Seller’s S reliability
based rating after and before the updating procedure.
It has been assumed that
post
RR and
pre
RR lie within
the
]1,0[ range, where a value close to 0 indicates a
misbehaving Seller.
)(Srr is a (reward) function
reflecting whether the service quality is compliant
with the picture established during the negotiation
ICE-B 2006 - INTERNATIONAL CONFERENCE ON E-BUSINESS
10
phase and
)]([ SrrE is the mean (expected) value of
the
)(Srr
variable. In general the larger the
)(Srr
value, the better the Seller behaves with respect to
the agreed terms and conditions of the established
contract, and therefore the more positive the
influence on the rating of the Seller. Factor
r
k
(
]1,0(∈
r
k ) determines the relative significance of the
new outcome with respect to the old one. In essence,
this value determines the memory of the system.
Small
r
k
values mean that the memory of the
system is large. However, good behaviour will
gradually improve the Seller’s S reputation ratings.
)(Rl
is a function of the Seller’s reputation rating
pre
RR and is introduced in order to keep the Seller’s
rating within the range
]1,0[ . In the current version
of this study,
)]1exp(1[
1
1
)( R
e
Rl −−⋅
−
=
, for which it
stands
1)(
0
→
→R
Rl and 0)(
1
→
→R
Rl .
It should be noted that Seller’s misbehaviour (or
at least deterioration of its previous behaviour) leads
to a decreased post rating value, since the
)])([)(( SrrESrr − quantity is negative. The )(Srr
function may be implemented in several ways. In the
context of this study, it was assumed without loss of
generality that the
)(Srr values vary from 0.1 to 1.
The reliability rating value of the Seller S is
updated after the user finally accesses the service.
This rating requires in some cases (e.g., when
consumption of network or computational resources
are entailed in the service provision process) a
mechanism for evaluating whether the service
quality was compliant with the picture promised
during the negotiation phase.
The Seller’s S reputation rating may be
calculated by the following formula:
)()()( SRRwSRRwSRR
RMRMBABA
⋅+⋅=
(2),
where
BA
RR
and
RM
RR
are the Seller’s S reputation
information concerning BA experiences and its
collective rating stored by the RM, respectively.
BA
RR is calculated based on equation (1), while
RM
RR is obtained through the following formula:
)])([)(()()()()( SrrESrrBTRlkSRRSRR
rprepost
−⋅
⋅
⋅+=
(3),
where
)(BT is the trust level attributed to the BA. It
stands
]1,0[)( ∈BT with level 1 denoting a fully
trusted BA.
Weights
BA
w
and
RM
w
provide the relative value
of the reputation rating of the Seller S as experienced
by BA and the reputation rating of the Seller S as
maintained in the RM component. It has been
assumed that weights
BA
w and
RM
w are normalized
to add up to 1 (i.e.,
1=+
RMBA
ww
), while
BARM
ww <
giving thus a higher significance value to the BA’s
own experiences.
According to the presented approach, the value
of
RM
w could be close to the value of
BA
w since
potential erroneous decisions (based on fake and
misleading feedbacks) are avoided by incorporating
to the formation of the
RM
RR
values the
trustworthiness of each BA. This way, the limitations
of the simplified approach (e.g., underestimation of
all BAs’ reports, even those reflecting the real
picture) are overcome. At this point it should be
noted that we have assumed that the trustworthiness
of each BA is known and is not modified in the
course of time.
Finally, the BA decides on the most appropriate
Seller S (i.e., the Seller best serving its current
service / product request) and selects the Seller that
maximizes the value of the following formula:
)()( SRRwCUwA
rfinal
B
pPR
⋅+⋅=
(4)
As you may observe,
PR
A
is an objective
function that models the performance and the
reliability of the Seller S. Among the terms of this
function there can be the overall anticipated user
satisfaction stemming from the final contract
reached within the negotiation phase, which is
expressed by the function
)(
final
B
CU with respect to
the contract proposed to the BA and the reputation
rating of the Seller S. Of course, one of the two
factors (anticipated user satisfaction or reputation
rating of the Seller S) can be omitted in certain
variants of the general problem version considered
in this paper. Weights
p
w and
r
w provide the
relative value of the anticipated user satisfaction and
the reputation related part. It is assumed that weights
p
w and
r
w are normalized to add up to 1 (i.e.,
1
=
+
rp
ww ).
4 CONCLUSIONS
This paper initially presented a dynamic multi-
lateral negotiation model and efficient negotiation
strategies based on a ranking mechanism that
replaces the counter offer complicated scheme. The
proposed framework covers multi-issue contracts
and multi-party situations, while being a highly
dynamic one in the sense that its variables, attributes
and objectives may change over time. The agents
hold private information which may be revealed
incrementally, only on an as-needed basis. The
designed strategies assume that the negotiators face
strict deadlines, which mostly is considered to be
private information. Since e-marketplace is
commonly perceived as an environment offering
REPUTATION BASED INTELLIGENT AGENT NEGOTIATION FRAMEWORKS IN THE E-MARKETPLACE
11
both opportunities and threats, in order to cope with
negotiating parties’ misbehaviour, as a second step,
the proposed framework is enhanced with a Sellers’
collaborative reputation mechanism, which helps
estimating their trustworthiness and predicting their
future behaviour, taking into account the Sellers’
past performance in consistently satisfying Buyers’
expectations. The reputation mechanism considers
both first-hand information (acquired from the
Buyer’s past experiences with the Sellers) and
second-hand information (disseminated from other
Buyers’ past experiences with the Sellers), while
spurious reputation ratings are taken into account.
The negotiation framework designed has been
adopted by self-interested autonomous agents and
has performed well, always converging to a
mutually acceptable contract, if any, due to the fact
that the Seller concedes to his reservation value as
his deadline approaches. Initial results indicate that
the designed strategies enhanced with the proposed
Sellers’ collaborative reputation mechanism achieve
higher social welfare levels with regards to
reputation independent frameworks, in case there are
Sellers prone to misbehaving. Future plans involve
the incorporation to our model of adaptive trust
ratings for the Buyers without predetermined values
and its extensive empirical evaluation against
existent negotiation and reputation models and
strategies and against the optimal solution that
maximizes the social welfare in multi-party e-
marketplace environments.
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