Simulating Digital Businesses Using an

Agent Based Modeling Approach

Aneesh Zutshi

, Antonio Grilo

and Ricardo Jardim-Gonçalves

UNIDEMI, Faculdade de Ciencias e Tecnologia, Universidade Nova de Lisboa, Caparica, Portugal

UNINOVA, Faculdade de Ciencias e Tecnologia, Universidade Nova de Lisboa, Caparica, Portugal

Keywords: Digital Business Models, Agent Based Modeling, Business Forecasting, Business Simulation.

Abstract: This paper proposes a complex systems approach to understand the growth and decline of Digital

Businesses. Digital Businesses are characterised by unique factors such as a highly networked online

customer base, where word of mouth spreads very fast, and minimal cost of incremental users due to

economies of scale. Thus online businesses peak and plummet rapidly making it difficult to fathom their

success. Through an Agent Based Modeling approach we propose that online businesses can be represented

as simulation models which can enable forecasting, what-if analysis and optimization of business

parameters.

1 INTRODUCTION

Digital businesses encompass the entire gamut of

ventures, from online sale of products and services

to social collaboration platforms, and have become a

vital engine for the new economy. Understanding

this new economy has been a challenge for

companies that were tuned to the traditional ways of

doing business and were armed with traditional

product development and marketing philosophies.

Most companies that rushed into the dot-com bubble

in the early part of the last decade perished

(Goodnight & Green 2010). However, we also saw

the emergence of new business giants such as

Google and Amazon, who did the right things at the

right time to emerge as winners.

Today Digital Business managers often rely on

experience and intuition to set up business models

and pricing strategies. Though marketing surveys,

have been traditionally used in gauging consumer

willingness to pay, a big challenge is to predict

business growth, customer adoption and customer

response to specific business and pricing models.

Online Businesses are complex interacting systems

where online users interact and share opinions and

experiences at a rate far greater than traditional brick

and mortar businesses. These user opinions are

shared through offline and online word of mouth

(WOM) channels, in addition to various marketing

channels. Customer Satisfaction is a key to spread of

positive or negative WOM, which influences new

customer adoption rate. System Dynamics have

often been used to model consumer adoption

(Stermann 2000). However System Dynamics

require the rules of the behavior to be written at a

higher level, such as how the whole population of

consumers will respond to a marketing activity

rather than how a particular individual will respond

(Rand & Rust 2011).

Online businesses are examples of a complex

system, where the behavior of individual users can

be used to model the growth or decline of a business

proposition (Zutshi et al. 2014a). This could provide

an analytical approach to develop models that can be

used by businesses as a decision support system.

Such models can perform a range of objectives, such

as making business forecasts, calculating the

implications of a change in product pricing,

optimization of different price plans, and simulating

the impact of a change in the Business Model.

Agent Based Modeling is the most appropriate

tool to implement this complex systems approach.

Agent Based Modeling is a new computational

method through which macro-level consequences

are explained through simplified representation of

micro level interactions between agents that

represent real life entities (Zutshi et al. 2013). These

autonomous agents represent online users with

165

Zutshi A., Grilo A. and Jardim-Gonçalves R..

Simulating Digital Businesses using an Agent Based Modeling Approach.

DOI: 10.5220/0005121301650171

In Proceedings of the 11th International Conference on e-Business (ICE-B-2014), pages 165-171

ISBN: 978-989-758-043-7

 2014 SCITEPRESS (Science and Technology Publications, Lda.)

individual characteristics as well as independent

internal decision making capabilities.

In this paper, we propose a Dynamic Agent

Based Modeling Framework (DYNAMOD), that

incorporates Agent Based Modeling (ABM)

techniques to develop and test digital business

models that can be potentially applied to a variety of

online market scenarios. We also make a discussion

on how to manage probabilities from the simulation

results using probability management techniques.

New tools and techniques are necessary to help

model the complex nature of online products and

services (Zutshi et al. 2012; Grilo et al. 2012).

Hence we need to develop a customizable simulation

environment that can capture the dynamics of an

online market, and provide Business Managers with

tools to simulate and forecast, thus aiding to perfect

their Business Model. Online markets can be

represented as a network of interconnected online

users which share positive and negative feedbacks

and respond to different online products and

services. If the behavior of individual agents can be

sufficiently well modeled, then a large range of

application possibilities open up such as forecasting,

what-if analysis and business model simulation.

2 ABM IN BUSINESS

ABM is build on proven, very successful techniques

such as discrete event simulation and object oriented

programming (North & Macal 2007). Discrete-event

simulation provides a mechanism for coordinating

the interactions of individual components or

“agents” within a simulation. Object-oriented

programming provides well-tested frameworks for

organizing agents based on their behaviours.

Simulation enables converting detailed process

experience into knowledge about complete systems.

ABM enables agents who represent actors, or

objects, or processes in a system to behave based on

the rules of interaction with the modelled system as

defined based on detailed process experience.

Advances in computer technology and modelling

techniques make simulation of millions of such

agents possible, which can be analysed to make

analytical conclusions.

The literature review reveals that applications of

ABM have been made to model specific areas of

Business (Zutshi et al. 2014b). These include

prediction of financial distress (Cao & Chen 2012),

product adoption [(S. Kim et al. 2011), (Diao et al.

2011)], consumer behaviour [(Vanhaverbeke &

Macharis 2011)], market share (Kuhn et al. 2010),

Urban Management (Gao et al. 2012) and demand

forecasting (Ikeda et al. 2004). (Kuhn et al. 2010)

demonstrated the possibilities of predicting market

share based on certain BM attributes of Frontier

Airlines. (Bellman et al. 2013) addresses the issue of

capturing Internet behaviour to deliver relevant

advertisements. ABM approaches can also be used

for modeling user response to different sources of

advertising. It can also be used to model response to

identify the most critical target groups,

complementing traditional approaches for the same.

(Roozmand et al. 2011) propose an Agent Based

Model to simulate consumer decision making based

on culture, personality and human needs and relates

them to car purchase decisions. Tesfatsion

introduced Agent-Based Computational Economics

(ACE) as the computational study of dynamic

economic systems modeled as virtual worlds of

interacting agents. (Somani & Tesfatsion 2008)

have applied ACE to retail and wholesale energy

tradings in the Power Markets. In this paper we

extend the concept of Agent-Based Computational

Economics, to develop DYNAMOD- An Agent

Based Modeling Framework for online Digital

Business Models.

3 OTHER RELEVANT AREAS OF

RESEARCH

3.1 Diffusion of Innovations

Diffusion of Innovations has been an active research

area and reflects adoption decisions made by

individual consumers. These decisions are made in a

complex, adaptive system and result from the

interactions among an individual's personal

characteristics, perceived characteristics of the

innovation, and social influence (Schramm et al.

2010). There are two major approaches to modeling

diffusion: econometric and explanatory. The concept

of Econometric Modeling was first introduced by

(Bass 1969). Econometric approaches forecast

market uptake by modeling the timing of first-

purchases of the innovation by consumers and are

more applicable when market growth rate and

market size are of primary interest. Explanatory

approaches, as first proposed by (Gatignon 1985)

establish that the diffusion of a product in a defined

market is equivalent to the aggregation of individual

consumer adoption decisions. The adoption

decisions are dependent on: Personal characteristics,

ICE-B2014-InternationalConferenceone-Business

166

perceived product characteristics, and social

influence.

In earlier works, diffusion of innovation has been

approached with mathematical modeling

(Goldenberg 2001; Goldenberg et al. 2010;

Goldenberg et al. 2007). However as computational

powers increased, relatively recent attempts have

been made to complement these classic approaches

with Agent Based Modeling tools. (Delre et al.

2007; Stonedahl et al. 2008; Diao et al. 2011). We

have used these works as the basis for developing

the DYNAMOD model with the application of

specific characteristics that relate to online

businesses.

3.2 Word of Mouth

Literature has assumed word of mouth (WOM) to be

the influence of neighbors over an individual (Feng

& Papatla 2011). This is a relevant assumption for

offline word of mouth since such communication is

mostly limited by geographical location. (Keller

2006) estimates that 90% of WOM conversations for

traditional goods and services takes place offline.

Word of mouth communication is more effective

when the transmitter and recipient of information

share a relationship based on homophily (tendency

to associate with similar persons), trust and

credibility.

(Feng & Papatla 2011) state that the incentive to

spread word of mouth reduces if a product gets well

known. They go further to deduce that elevated

awareness is created by a high advertising budget,

reduces the word of mouth propagation. They also

deduce that highly satisfied or highly dissatisfied

customers are likely to engage in more word of

mouth than other customers. The DYNAMOD

model incorporates this by ensuring that agents with

a high or low satisfaction score have a greater

influence on their neighbours.

(Goldenberg et al. 2007) state that for a

traditional product, negative word of mouth spreads

up to 2 levels of agent chains but a positive word of

mouth can go on spreading much further. They also

predict that the net effect of advertising at early

stages when the product is still not stable could

enable a larger creation of negative influence, which

could possibly reduce the subsequent market uptake

of a product. Thus at an early stage digital products

can be negatively impacted by a high degree of

advertisement and subsequent adoption, especially

when the product is still at a rudimentary state.

While the extent may vary, there is general

agreement in the literature that a dissatisfied

customer influences others more than a satisfied one

(Herr & Kardes 1991). This consensus is built both

on evidence that dissatisfied customers communicate

with others more than satisfied ones and that

recipients of this communication place more weight

on negative information.

Thus the DYNAMOD model incorporates these

findings by incorporating them into the way Word of

Mouth propagates amongst the user Agents.

3.3 Network Structure

Cellular Automata, is a form of lattice network and

has been used by numerous authors to

mathematically model word of mouth. They

represent users as cells in a cellular grid like

network, with each a cell getting influenced by static

neighbouring cells surrounding them. (Goldenberg

2001) used cellular automata and introduce the

concept of strong ties and weak ties while discussing

word of mouth. However the static nature of the

network makes it unsuitable to represent the

dynamic nature of online user networks. Another

form of a network is a random network where the

cell distance is randomly distributed. Another

common network methodology is the small-world

network which starts with a random network

randomly rewiring some of the edges (Stonedahl &

Rand 2010).

In the case of DYNAMOD, we shall be using a

dynamic random network where user agents start

being randomly distributed over a flat world, and get

influenced by agents in a fixed radius. However the

agents themselves slowly make random walks, and

thus the agents within their sphere of influence keep

changing. This represents an online world where

users constantly meet the opinion of new users

through online posts and forums.

4 THE DYNAMOD

FRAMEWORK

4.1 DYNAMOD Components

The DYNAMOD Framework has been developed

based on the academic literature collected regarding

the unique aspects of an online business. Its purpose

is to provide researchers and companies engaged in

online businesses with a tool for quickly developing

Computational Modeling Systems that can represent

their Business Models and their Business

Environment, in order to perform advanced

simulations for predicting business growth

SimulatingDigitalBusinessesusinganAgentBasedModelingApproach

167

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ICE-B2014-InternationalConferenceone-Business

168

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. Each Agent responds differently to

these different sources of influence. Through a

sample survey we gather the value of these 3

coefficients for every respondent and then compute

the mean and standard deviation values. These

values are then used to assign these coefficients to

these agents.

Network Effect Coefficient: In order to model the

network effects, we have introduced a network

effect coefficient (N-COF) in our model (See Figure

3). When the percentage of users who are clients

within the neighbourhood of an agent is below the

critical membership lower limit, the value of the

network coefficient is -0.5. This causes a slowdown

in the adoption requirement, owing to a chilling

effect of network externalities (Goldenberg et al.

2010). Within the critical membership range, the

coefficient moves from -0.5 to +0.5, and we begin to

see a higher growth rate. Network effects tend to

cause a hockey stick growth pattern to be more

skewed. In the case of double sided network effect.

Viral Marketing

is added to increase the influence

rate for such products that have a high viral

marketing. The Viral Marketing coefficient is

triggered if a large percentage of respondents state to

having become clients based on automated mails

from acquaintances.

Once an Agent becomes a Client, then onwards,

the key parameter will be the Satisfaction and not

Influence. The satisfaction level will not be

influenced by neighbours or advertisements but

rather be a function of the product’s utility. In this

model we have used the satisfaction scores that have

been collected from sample surveys. Hence:

If A

= Client, A

Influence

= A

Satisfaction

(1.)

And A

continues to remain a client unless

Satisfaction

< 0.25. In this current model, once the

user stops being a client, he doesn’t become a client

a second time. However this is specific to the

context of the business being modeled.

5 STEPS FOR DEVELOPMENT

OF AN ABM MODEL

The following steps outline a generic approach to

developing an Agent Based Model for an online

business.

1. Identification of the Scope and Objectives of

the Model like forecasting future market

penetration, forecasting revenue based on

changes in pricing, optimization of pricing

bundles, predicting customer adoption based

on optimizing marketing mix, etc.

2. Identification of Business Model Components

& associated variables that define the

business case.

eg. Pricing, Product offering, Product

characteristics - like Network Effects, Viral

Marketing.

3. Identification of Agents and Agent

Parameters.

eg. Buyers, Sellers, Facilitators

4. Model initialization through data obtained

sample surveys.

eg. Market size, Average willingness to pay,

product satisfaction, WOM influence.

5. Develop the model and validate it using the

DYNAMOD Framework.

6. Obtain historical records of the growth data.

Divide the data into initialization and

validation phase.

7. Initialise the model coefficients. Run the

simulation model to ensure the simulation

output is as close to the validation phase

historical data as possible by adjusting the

model coefficients.

8. Compare the simulated data with the

Validation data. Compare the accuracy of

this forecast with other methods like ARIMA.

If the forecast is acceptable them the model is

set to be complete and ready for use.

SimulatingDigitalBusinessesusinganAgentBasedModelingApproach

169

9. Use the Model as required, by changed the

relevant business model parameters and

measuring the impact.

6 CONCLUSION

This paper discusses a novel approach of studying a

digital business as a complex system, and using an

Agent Based Modeling approach to develop specific

purpose simulators that can be used for a wide

variety of what-if scenarios and as a tool for

optimization of Business Parameters. This approach

has already been implemented by our research group

for some online case studies such including

facebook.com, custojusto.pt and vortal.biz.

ACKNOWLEDGEMENTS

We acknowledge custojusto.pt and vortal.biz for

providing us case studies to validate the model.

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