A NEW METHOD FOR MONITORING INDUSTRIAL

PRODUCT-SERVICE SYSTEMS BASED ON BSC AND AHP

Michael Abramovici and Feng Jin

Ruhr-University Bochum, Universitätstr. 150, Bochum, Germany

Keywords: BSC, AHP, Monitoring, Industrial Product-Service System (IPS²), Performance Measuring.

Abstract: Driven by the increased competition pressure in the last few years, a number of manufactures are shifting

their focus from products towards Industrial Product-Service Systems (IPS²). However, the shift to IPS² is

also accompanied by risks. The monitoring of IPS² could support executives in identifying the IPS² risks in

time and could serve as the basis for optimizing future IPS². In this paper a new method for the hierarchical

monitoring of IPS² is developed based on Balanced Scorecard (BSC) and Analytic Hierarchical Process

(AHP). The performances and the imbalance degrees of IPS² on different levels are calculated to show IPS²

comprehensively. BSC is applied to define IPS²-specific perspectives and indicators. AHP is used to

construct a hierarchical monitoring structure and to generate weights for different IPS²-specific perspectives

and indicators. Finally a case study is introduced to validate this method.

1 INTRODUCTION

An Industrial Product-Service System (IPS²) is

defined as “an integrated offering of product and

service that delivers values in industrial application”

(Meier et al., 2010). It can also be considered as an

innovation that extends the traditional functionality

of a physical industrial product by incorporating

additional services (Baines et al., 2007). The shift to

IPS² can enhance competition and generate more

customer benefits, but complex combination among

different products and services in IPS² increases the

risks (Cook et al., 2006; Sundin et al., 2009). A

quick and precise monitoring of IPS² could support

executives in identifying the IPS² risks in time and

could serve as a basis for optimizing future IPS². At

present, however, executives of IPS² suppliers can

only gain IPS²-related information from reports

submitted by their employees. It largely impairs

executives’ work efficiency in monitoring IPS².

Hence, a new method for monitoring IPS² is

urgently needed.

This paper proposes a new hierarchical

monitoring method with three levels (i.e. the overall

IPS² level, the perspective level and the indicator

level) based on Balanced Scorecard (BSC) and

Analytic Hierarchical Process (AHP) for executives

to monitor IPS² quickly and precisely. BSC has been

applied to define IPS²-specific perspectives and

indicators. AHP has been used to construct the

hierarchical monitoring structure based on these

IPS²-specific perspectives and indicators and to

generate weights for them. In order to process the

indicators with different measurement units,

percentages are used to standardize the measurement

of different indicators. Furthermore, executives need

to know about the imbalances among the various

aspects, so that they can determine whether IPS² is

running in balance or not. Thus, the performances

and the imbalance degrees of IPS² on different levels

are both calculated to show the status of IPS²

comprehensively. To verify this new method, the

paper concludes with a case study about the

monitoring of micro-machining PSS.

2 RELATED WORKS

2.1 The Balanced Scorecard (BSC)

The Balanced Scorecard was introduced by Kaplan

and Norton (1992) as a management system to align

an organization’s performance measures with its

strategic plan and goals. As exclusive reliance on

financial measures in a management system is

insufficient, the BSC highlights a balance between

190

Abramovici M. and Jin F..

A NEW METHOD FOR MONITORING INDUSTRIAL PRODUCT-SERVICE SYSTEMS BASED ON BSC AND AHP.

DOI: 10.5220/0003483001900196

In Proceedings of the 13th International Conference on Enterprise Information Systems (ICEIS-2011), pages 190-196

ISBN: 978-989-8425-53-9

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

financial indicators and non-financial indicators

(Craig and Moores, 2010; Yang, 2009). The BSC

suggests that an organization should be evaluated

from four different perspectives: financial

perspective, customer perspective, perspective of

internal processes and perspective of learning and

growth. Each perspective considers several related

performance measuring indicators.

Though originally developed as a performance

measurement tool, the BSC has evolved into an

organizing framework, an operating system, and

even a strategic management system (Kaplan

and Norton, 1996). Of course, the choice and

definition of the perspectives and indicators depend

on the characteristics of the individual BSC

implementation. BSC can be adapted as a tool for

executives to monitor IPS², but the main weakness

that all indicators have the same weight hides the

different importance of the considered indicators.

2.2 The Analytic Hierarchical Process

(AHP)

The AHP method was developed by Saaty (1980) as

a tool for modeling the complex decision problems.

It allows both qualitative and quantitative

approaches to solve complex decision problems

(Wong and Li, 2008). In the qualitative aspect, the

problem is modeled to a hierarchy consisting of an

overall goal, a group of criteria and sub-criteria, and

a group of alternatives. In the quantitative aspect,

numerical weights for criteria are generated by

making pairwise comparisons among all criteria at

each level to distinguish in general the more

important criteria from the less important ones.

To improve validity recognizing that participants

may be uncertain or make poor judgments in some

of the comparisons, redundant comparisons are

involved in AHP. This redundancy can lead to

numerical inconsistencies. Saaty (1994) suggested

the error in these measurements is tolerable only

when it is of a lower order of magnitude (0.1) than

the actual measurement itself.

In order to distinguish the more important

indicators in the monitoring of IPS² from the less

important ones, the AHP method is mainly used to

generate weights for all indicators and perspectives

(Wang, 2009). The above-mentioned process of

weight generation and verification can ensure that all

weights are assigned meaningfully and objectively.

3 THE MONITORING METHOD

FOR IPS²

3.1 The IPS²-specific BSC

For the monitoring and measuring the performance

of IPS², executives require different information in

different perspectives. With reference to the

structure of BSC, as recommended by Kaplan and

Norton, four specific perspectives have been

considered for the IPS²-specific BSC: the customer

perspective, the perspective of IPS² lifecycle, the

perspective of IPS² resources and the financial

perspective (figure 1). The overall IPS² goal takes a

central position.

Figure 1: The IPS²-specific BSC perspectives.

In general, the fulfillment of customer needs and

customer satisfaction are the main goals of an IPS²

offering. The quality of the IPS² affects customer

satisfaction directly. The acquisition and integration

of different IPS² resources are prerequisites for each

successful IPS². They are also the foundation of the

innovation and creativity for IPS². Moreover, the

high efficiency of IPS² resources can reduce cost and

improve the financial status. Satisfied and loyal

customers can also lead to increased revenues, i.e.

improvement of the financial status. The balance of

these four perspectives can ensure a successful IPS².

In order to measure and monitor the IPS²

performance, several indicators have been defined

and assigned to considered perspective. In order to

explain the monitoring process clearly, only three to

four indicators have been shown in figure 2.

Generally, indicators can be divided into two

categories: quantitative indicators and qualitative

indicators (CIDA, 1996).

 Quantitative indicators can be defined as

measure of quantity, such as revenue of IPS².

 Qualitative indicators can be defined as

people’s judgments and perceptions about a

subject, such as customer satisfaction.

IPS² Goal

Financial

Do IPS² costs exceed

its budget?

Customer

how does the customer

see our IPS² and us?

IPS² Resources

Can we integrate IPS²

resources well?

IPS² Lifecycle

What is the current

status of IPS²?

A NEW METHOD FOR MONITORING INDUSTRIAL PRODUCT-SERVICE SYSTEMS BASED ON BSC AND AHP

191

Figure 2: The three-level structure of the monitoring method (adapted from Yuan and Chiu, 2009).

3.2 Three-level Structure of the

Monitoring Method

According to the structure of the IPS²-specific BSC,

a hierarchical structure incorporating three-levels

has been constructed for this monitoring method, as

shown in figure 2. The first level is the overall IPS²

goal. The second level shows four perspectives in

agreement with the IPS²-specific BSC. The third

level defines performance measuring indicators.

Usually the performance of an indicator is its

actual value. Since different indicators have different

measurement units, it is impossible to compare and

to integrate indicators with different units. Thus,

percentage is used to unify the measurement of all

indicators. In this method the performance of an

indicator can be calculated as follows:

If a>t is the most expected result

=(1−

−



) × 100%

(1)

If a<t is the most expected result

=(1+

−



) × 100%

(2)

Where : performance, : target, : actual value

As an example, the performance of “On-time

delivery of IPS²” indicator can be calculated using

(2) and based on the target finish time and the actual

finish time. All quantitative indicators can be

measured using similar calculation. However, for

qualitative indicators these two equations cannot be

used, but their principles must be kept. The

performance of qualitative indicators should be

manually measured according to their measurement

standards, and then converted to percentages.

The performance of indicators is the basis for the

further calculation. The performance of each

perspective is the weighted average of all indictors

under it. The overall performance is the weighted

average of its four perspectives.

Within the BSC method all indicators and

perspectives have the same weight. In fact different

indicators or perspectives have different weights.

The assignment of weights provides executives with

more precise information about the performance of

IPS². The AHP method is used to generate the

weights. Since indicators are organized by the

perspectives, the indicators in different perspectives

are not associative. The weights of perspectives and

the weights of indicators under each perspective

should be generated separately.

In order to show the imbalance among different

indicators or perspectives, the imbalance degree are

calculated using the method of standard variance

that is usually used as a measure of how far a set of

numbers are spread out from each other.

The hierarchical structure gives executives a top-

down view to monitor IPS². Based on the

performances of IPS² on these three levels,

executives can determine whether the IPS² has been

well implemented or not. At the same time the

imbalance degree show executives whether IPS² has

been implemented in a balanced way or not.

3.3 Methodology

By combining the BSC and the AHP method and

adapting them to IPS², a five-step calculation

method has been developed to generate the weights

of different indicators and perspectives, and to

calculate the performances and imbalance degrees of

IPS² on different levels.

The performances and imbalance degrees of the

overall IPS², the customer perspective, the IPS²

lifecycle perspective, the IPS² resources perspective

and the financial perspective must be calculated

IPS² Goal

Indicator

Level

Perspective

Level

IPS²

Level

Customer

Productivity improvement

of customer

Customer relationship

Customer satisfaction

…

IPS² Lifecycle

IPS² quality

On-time delivery of IPS²

Response to customer

needs

Cooperation with IPS²

component suppliers

…

IPS² Resources

Energy efficiency

Equipment efficiency

Efficiency of human

resources

Efficiency of external

resources

…

Financial

Purchase cost of IPS²

components

Cost of materials ratio

Revenue of IPS²

…

ICEIS 2011 - 13th International Conference on Enterprise Information Systems

192

separately. Since their calculation process are the

same, the customer perspective serves as an example

to explain this calculation method.

Step 1: Construct the Comparison Matrix

The comparison matrix is constructed based on the

pairwise comparisons of each two indicators. It is

the prerequisite for the calculation of weights. In

order to determine the quantitative matrix, a

standardized comparison scale of nine levels is used

(table1).

If the number of customer indicators is , the

pairwise comparison matrix is an × matrix .

Where 



represents relative importance between

indicator 



and 



. This matrix  satisfies:





>0,



= 1/



,, = 1,2,· · · ,.

Table 1: The comparison scale for the comparison matrix

(Saaty, 1980).

Element Numerical scale Meaning





1 



has equal importance as 



3 



has moderately more importance as 



5 



has strongly more importance as 



7 



has very strongly more importance as 



9 



has extremely more importance as 



2, 4, 6 and 8

Intermediate values between two

successive qualitative judgments

Step 2: Calculate the Weight Vector

The comparison matrix of the customer indicators is

the matrix . 



is the weight vector of customer

indicators. The weight of indicator 



can be

calculated as (3):









∑









where 



∑









and

∑









(3)

Step 3: Examine the Consistency Ratio

The consistency property of the matrix is then

verified to ensure the consistency of judgments in

the pairwise comparison. The Consistency Ratio

() are defined as (4):

=





(4)

where =









 (Consistency Index) is the average

consistency. 



is the maximum eigen value of

the comparison matrix, and  is the size of matrix.

 is the average random index taken as in Table 2.

If  < 0.1 , the comparison matrix is

considered to be consistent. In contrast, the matrix

results are inconsistent and it needs to be modified

for the further analysis.

Table 2: Random Index values for matrix (Saaty, 2008).

Size of matrix (n) 1 2 3 4 5

RI - - 0.58 0.9 1.12

Size of matrix (n) 6 7 8 9 10

RI 1.24 1.32 1.41 1.45 1.49

Step 4: Calculate the Performance

If the comparison matrix is consistent, it can be used

for the calculation of the performance of the

customer perspective. The performance of all

customer indicators should be calculated

beforehand. If 



={

,





,…,



} is the

performance vector of customer indicators, the

performance of the customer perspective can be

calculated using the following equation (5):





=

(





)

=



⋅



⊺

(5)

Step 5: Calculate the Imbalance Degree

In essence, the imbalance degree of the customer

perspective is the standard variance of all customer

indicators. Their weighted variance is calculated

using (6). Subsequently their standard variance can

be calculated using (7):







∑





(



−(



))







∑











(6)

Where

∑











=1, then:







=



(





− 



)

















(





− 



)







(7)

By using the same process, the performance of

the IPS² lifecycle perspective, the perspective of

IPS² resources and the financial perspective can be

calculated as 



,



and 



respectively. Their

imbalances can also be calculated as 



,



and 



The overall performance and imbalance degree

of IPS² can be calculated using equations (8) and

(9):





=



⋅



⊺

(8)

where 



is the performance vector of four

A NEW METHOD FOR MONITORING INDUSTRIAL PRODUCT-SERVICE SYSTEMS BASED ON BSC AND AHP

193

perspectives:





{





,



,



,



}

={



,



,



,



}





is the weight vector of perspectives











(





−



)







(9)

4 APPLICATION OF THE

PROPOSED METHOD

In order to verify this method, it has been

prototypically applied to monitor the micro-

manufacturing PSS (Product-Service System) that is

provided by MicroMan solutions Co. This IPS²

offers customers an integrated solution including

micro-machining technology and related services,

such as condition monitoring, financing, process

optimization, maintenance, training, and so on.

This monitoring method has been applied based

on the structure shown in figure 2. Tables 3-7 show

the comparison matrixes of customer indicators,

IPS² lifecycle indicators, IPS² resource indicators,

financial indicators, and perspectives respectively,

which are created by several experts in the field of

IPS². Their weight vectors are calculated using

equation (3) and are listed as follows:

 



={0.64,0.12,0.24}

 



={0.43,0.16,0.33,0.09}

 



={0.26,0.16,0.49,0.08}

 



={0.55,0.23,0.22}

 



={0.36,0.12,0.21,0.31}

Table 3: The comparison matrix of customer indicators.

Customer I

1 8 3

1/8 1 1/5

1/3 5 1

: Productivity improvement of customer

: Customer relationship, I

: Customer satisfaction

Table 4: The comparison matrix of IPS² lifecycle

indicators.

IPS² Lifecycle I

1 3 1 5

1/3 1 1/3 2

1 3 1 3

1/5 1/2 1/3 1

: IPS² quality, I

: On-time delivery of IPS²

: Response to customer needs

: Cooperation with IPS² component suppliers

Table 5: The comparison matrix of IPS² resource

indicators.

IPS² Resource I

1 2 1/3 3

1/2 1 1/4 2

3 4 1 5

1/3 1/2 1/5 1

: Energy efficiency, I

: Equipment efficiency

: Efficiency of human resources, I

: Efficiency of external resources

Table 6: The comparison matrix of financial indicators.

Financial I

1 2 3

1/2 1 1

1/3 1 1

: Purchase cost of IPS² components

: Cost of materials ratio, I

: Revenue of IPS²

Table 7: The comparison matrix of perspectives.

Perspective P

1 2 3 1

1/2 1 1/2 1/2

1/3 2 1 1/2

1 2 2 1

: Customer, P

: IPS² lifecycle, P

: IPS² resources, P

: Financial

In order to examine the consistency ratio of their

comparison matrix, their CR values are calculated as

follows:

 



=0.034

 



=0.018

 



=0.019

 



=0.016

 



=0.044

None of the values exceed 0.1. Thus, these five

matrixes are considered consistent, and the five

calculated weight vectors can be used to calculate

the performance and imbalance degree of IPS² on

different levels.

For a micro-machining PSS, the performance of

its all indicators have been calculated and listed in

column 5 of table 8. Column 4 shows the weight of

each indicator. The performance and imbalance

degree of each perspective have been calculated

using equations (5) and (7), and are listed in column

2. The overall performance and imbalance degree

have been calculated using equations (8) and (9)

based on the results of column 2. They are shown in

column 1 of table 8.

In comparison to the above calculation, the

monitoring process is a top-down process. From

column 1, executives can derive the overall status of

IPS². Critical values can be taken to identify those

IPS² that have poor performance or are not in

ICEIS 2011 - 13th International Conference on Enterprise Information Systems

194

Table 8: The calculation of the performances and imbalance degrees for a micro-machining PSS.

IPS² Perspective Indicator Weight Performance





=96.0%





=0.0879

Customer

(



=0.36)





=107.0%





=0.049

Productivity improvement of customer 0.64 110%

Customer relationship 0.12 95%

Customer satisfaction 0.24 105%

IPS² Lifecycle

(



=0.12)





=96.1%





=0.092

IPS² quality 0.43 100%

On-time delivery of IPS² 0.16 80%

Response to customer needs 0.33 100%

Cooperation with IPS² component

suppliers

0.09 85%

IPS² Resources

(



=0.21)





=85.4%





=0.042

Energy efficiency 0.26 84%

Equipment efficiency 0.16 95%

Efficiency of human resources 0.49 84%

Efficiency of external resources 0.08 90%

Financial

(



=0.31)





=90.3%





=0.013

Purchase cost of IPS² components 0.55 85%

Cost of materials ratio 0.23 113%

Revenue of IPS² 0.22 80%

balance. Usually 



should not fall below 95%

and 



should not exceed 0.1. Column 2 provides

executives with more detailed information of IPS²,

i.e. its four perspectives. Using critical values,

problematic perspectives can be found out easily.

The performance of each indicator in column 5

shows a concrete measurement of IPS². Executives

can find the concrete problem of a problematical

IPS² from the indicators whose performance is

insufficient. That way, executives can determine

problematic IPS² quickly and fix the problems

precisely by using the proposed hierarchical

monitoring method.

5 CONCLUSIONS

This paper has introduced a new method for the

hierarchical monitoring of IPS² based on BSC and

AHP to meet the IPS² monitoring requirements of

executives. The BSC method offers a framework to

comprehensively and precisely define IPS²-specific

perspectives and indicators. The assignment of

weights to different indicators and perspectives

gives executives an opportunity to monitor and to

measure the performance of IPS² by highlight in

indicators or perspectives with different weights, and

the AHP method ensures the generation of

meaningful and objective weights. Moreover, the

use of percentages as the unified measurement unit

eliminates the measurement differences among

different indicators and simplifies the expression of

IPS² performances. Next to performances, imbalance

degrees of IPS² have been calculated on different

levels to offer executives a fast view of whether IPS²

is running in balance or not.

The AHP employs a suitable method (i.e.

pairwise comparison matrix and consistency

examination) to ensure the generation of objective

weights. If, however, a comparison matrix is very

big, it is highly complex and a lot of time is needed

to adjust it to pass consistency examination. Thus,

an easier method for weight generation should be

added in future as an alternative to avoid having to

deal with too large comparison matrixes.

Since the main information, which is required by

executives in IPS² monitoring, originates from the

IPS² lifecycle management (LM) platform

(Abramovici et al., 2008; Abramovici et al., 2009), it

seems to be very efficient to integrate this

monitoring method in the IPS² LM platform. Thus,

in future, this monitoring method will be

programmed as a function module in the IPS² LM

platform to validate and to improve it in the actual

application by IPS² suppliers. As executives tend to

pay more attention to their products after the

economic crisis, the described monitoring method

can be adjusted and used further in other areas to

monitor different products or services.

A NEW METHOD FOR MONITORING INDUSTRIAL PRODUCT-SERVICE SYSTEMS BASED ON BSC AND AHP

195

ACKNOWLEDGEMENTS

We express our sincere thanks to the German

Research Foundation (DFG) for financing this

research within the Collaborative Research Project

SFB/TR29 on Industrial Product-Service Systems –

dynamic interdependency of products and services

in the production area.

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