ANALYZING IMPACT OF INTERFACE IMPLEMENTATION
EFFORTS ON THE STRUCTURE OF A SOFTWARE MARKET
OSS/BSS Market Polarization Scenario
Oleksiy Mazhelis, Pasi Tyrväinen
University of Jyväskylä, Jyväskylä, Finland
Jarmo Matilainen
Mikkelin Puhelin Oyj, Mikkeli, Finland
Keywords: Vertical integration and disintegration, software implementation efforts, market polarization,
telecommunications software, operations support systems, business support systems.
Abstract: A vertical software market is usually subject to the process of disintegration resulting in a market where
different layers of software are provided by independent software vendors. However, as argued in this paper,
the process of this vertical disintegration may be affected by high investments to software interface
implementation and maintenance. Should the required efforts be large, the threshold for entering the market
increases, thereby hampering the vertical disintegration process. This study examines the impact of the
interface implementation efforts on the vertical market evolution in the case of the so-called operations support
systems and business support systems (OSS/BSS) software, which are employed by the telecom operators in
order to support their daily operations. The efforts are compared for two prototypical software vendors serving
incumbent operators and new operators respectively. Total efforts are an order of magnitude larger in the
former case. Furthermore, even if only latest network protocols are taken into account, the efforts are
significantly larger in the former case, therefore requiring several times greater number of employees to
implement them. Therefore, a conclusion is made that the OSS/BSS market is likely to polarize into the vertical
submarket of large software vendors serving incumbent operators, and the submarket of small vendors serving
young operators. The latter submarket, due to the lower entry threshold for new vendors is more likely to be
vertically disintegrated.
1 INTRODUCTION
Software markets generally develop from vertically
integrated towards vertically disintegrated (Macher
and Mowery, 2004). According to the model based
on the analysis of different verticals of the Finnish
software industry (Tyrväinen et al., 2004, 2008), for
instance, innovative software is initially developed
not by software vendors but in house by companies
representing the business in the market vertical in
order to automate and improve their business
processes and thereby achieve competitive
advantage over the competition in the specific
industry. Vertical disintegration implies that the
software is decomposed into horizontal layers;
software in different layers is provided by
independent software vendors and it is integrated
with the other layers via standardized interfaces.
Numerous vendors operate horizontally in multiple
industries, which provide a larger market for them
while some of vendors are still specialized to serve a
single industry.
Several factors such as high degree of customer-
specific tailoring, the need to coordinate innovation
efforts spanning over several layers in a vertical
(Mazhelis et al., 2007), etc., are likely to hamper the
vertical disintegration of the software. In this paper,
we focus on studying another potential hindering
factor, namely, the high complexity of the software
interfaces. We assume that, whenever a software
vendor provides software to a customer, this
software needs to be integrated with a number of
heterogeneous subsystems deployed by the
customer. If the number of integration interfaces is
80
Mazhelis O., Tyrväinen P. and Matilainen J. (2008).
ANALYZING IMPACT OF INTERFACE IMPLEMENTATION EFFORTS ON THE STRUCTURE OF A SOFTWARE MARKET - OSS/BSS Market
Polarization Scenario.
In Proceedings of the Third International Conference on Software and Data Technologies - SE/GSDCA/MUSE, pages 80-87
DOI: 10.5220/0001890200800087
Copyright
c
SciTePress
high, a vast amount of special knowledge is needed
in the vendor organization. High integration efforts
consume also the limited amount of compentent
employes of the vendor organization decreasing the
number of customers which it is capable to serve. As
a result, only few large vendors can survive in such
market, and the evolution towards horizontalized
market with standardized interfaces and established
standard architectures (see e.g., dominant design in
Murmann and Frenken 2006) may be delayed or
may never materialize.
The impact of the software interface
implementation efforts on the structure of the market
is studied in this paper on the example of the
telecom operator software. The so-called operations
support systems and business support systems
(OSS/BSS) are used by the telecom operators for
operating and monitoring their networks, as well as
for managing their performance, quality of service,
faults, configuration, roaming, accounting, customer
relationships, frauds, etc. (Terplan, 2001). Though
the OSS/BSS software has been used for several
decades, the software still remains to a large extent
vertically integrated. E.g. activation and
configuration software, performance and fault
management software is often produced by the
vendors of network element hardware.
In this paper, we study whether the high
complexity of the OSS/BSS software interfaces may
serve as a potential hindering factor for OSS/BSS
market horizontalization. We assume that OSS/BSS
software provided by a software vendor for an
incumbent operator needs to be integrated with a
large number of heterogeneous subsystems. Due to
the high interface implementation efforts, the
number of companies capable of providing
necessary integration decreases, and hence the
OSS/BSS market horizontalization may be delayed.
Based on the above assumption, a hypothesis is
made that the OSS/BSS market will split into the
submarket of incumbent operators with vertically
integrated systems, and the submarket of new
operators with vertically disintegrated systems.
Consequently, the OSS/BSS market is likely to be
polarized into many smaller players and few very
big players, serving two distinct types of customers
– respectively incumbent and new operators.
In order to verify the hypothesis, the interface
implementation efforts for incumbent and new
operators are compared in the paper. For this,
interface implementation efforts for the activation
and billing mediation segments are estimated. It is
found that the efforts needed for new operators are
significantly lower as compared with the efforts
required for the incumbents. As a result, a tentative
conclusion is made that the vertical disintegration is
more likely in the domain (submarket) of young
operators, and consequently, OSS/BSS market is
likely to become polarized into many small and few
very big software vendors.
The paper is organized as follows. In the next
section, an approach to interface implementation
efforts estimation is introduced. This appoach is
applied in section 3, in order to assess and compare
the efforts of implementing OSS/BSS mediation
interfaces. Some business implications of the results
of this study are provided in section 4, followed by
the conclusions in section 5.
2 INTERFACES AND THEIR
IMPLEMENTATION EFFORTS
In order to verify the hypothesis that the process of
market horizontalization may be hindered due to the
set of interfaces which need to be supported, we
consider the efforts which a software vendor needs
to devote to interface implementation and
maintenance. The effort estimations are employed as
an indicator reflecting the likely size of the software
vendors capable of providing these interfaces.
Higher interface implementation efforts resulting in
the greater size of the software vendors are assumed
to reduce the number of software vendors in the
market, and hence delay the horizontalization of the
market. Furthermore, horisontalization in two
submarkets can be compared on the basis of the
interface implementation efforts: the greater the
efforts, the more likely delays in the
horizontalization. Eventually, the submarket with the
lighter interface implementation efforts may
horizontalize while the submarket with greater
efforts may remain vertically integrated, thereby
resulting in a market polarization.
In this paper, an interface is defined as a stack of
protocols and associated data formats that govern a
communication between software subsystems.
Protocols in the stack may have different versions;
two interfaces comprised of the same protocols of
distinct versions are referred to as variations of the
interface.
Given an interface to be supported, human
resources are required not only to implement or
configure the software providing the interface, but
also afterwards – for maintenance, for
reconfiguration of a standardized interface, or in
order to perform new integration projects involving
ANALYZING IMPACT OF INTERFACE IMPLEMENTATION EFFORTS ON THE STRUCTURE OF A SOFTWARE
MARKET - OSS/BSS Market Polarization Scenario
81
the interface. Therefore, human resources are needed
for each interface for the entire lifetime of that
interface.
Below, the approach to estimating interface
implementation efforts is described, and the
OSS/BSS interfaces that are being analyzed are
introduced.
2.1 Estimating Interface
Implementation Efforts
Let us consider the total efforts a software vendor
devotes to interface implementation, namely:
The initial implementation of interfaces (i.e.
initial implementation of protocol stacks),
The development of the new variations of
interfaces (corresponding to new versions of
protocols),
Configuration of the interfaces for individual
customers (mainly data format are adapted to
the needs of an individual customer),
Maintenance of interfaces.
The efforts needed for implementing an interface
greatly depend on the type of protocols being used.
Many types of protocols may need to be
implemented, among them are proprietary, OSI
based (FTAM, CMISE/CMIP), CORBA, web-based
(HTTP, SOAP, LDAP, RADIUS), and other
standards-based protocols (FTP, GTP, MAP, etc.).
Besides, protocols may have several versions, hence
resulting in a number of coexisting interface
variations.
In order to assess the total interface development
and maintenance efforts, we need to first determine:
for each type of protocols, the number of
versions/variations;
for each variation, the efforts (initial, variant
development, configuration, maintenance)
needed.
The above estimates need to be time-stamped, so
that the year-by-year dynamics of the efforts could
be studied.
For each interface, by consulting publicly
available data and by inquiring domain experts, the
main types of the protocol stacks and the number of
protocol variations can be determined, and the
efforts needed for each of the variations may be
estimated. The number of protocols and their
variations are calculated as follows.
The number of new standard protocols
stdnew
N
of a specific type is equal to 1, if the protocol has
adopted during the specified period of time, and is
equal to 0 otherwise.
The number of new proprietary protocols
proprnew
N of a specific type developed within
period
(
)
stopstart
, yy
(in years) is estimated as:
(
)
()
,
,
startstop
typesprotocolall
total
total
yearperproprnewstopstartproprnew
yy
N
N
NyyN
′
−
′
×
×=
∑
(1)
where:
begin
Y
and
end
Y are the beginning and the end
of the protocol lifetime, respectively,
(
)
endstopstop
,min Yyy =
′
,
(
)
beginstartstart
,max Yyy
=
′
,
total
N is the total number of variations of a
specific type of protocols, and
yearperproprnew
N is the average number of new
proprietary protocols being developed each
year (assumed to be equal 2 in this study).
It is assumed for simplicity that protocol
variations are uniformly distributed throughout the
lifetime of the protocol. Then, for each protocol
type, the number of protocol variations
var
N for a
given period
(
)
stopstart
, yy
is estimated as:
(
)
()
,
,
startstop
beginend
total
stopstartvar
yy
YY
N
yyN
′
−
′
−
=
=
(2)
It is assumed that development of a new
variation also requires configuration, therefore
the number of configurations is
(
)
(
)
stopstartvarstopstartconf
,, yyNyyN
=
. It is further
assumed that all the interfaces require maintenance
efforts, which are constant during the lifetime of the
protocol, and are decreasing afterwards at the rate
negatively proportional to the time elapsed:
(
)
() ()
[]
()
()
()
()
()
()
⎪
⎩
⎪
⎨
⎧
>
−+
≤
=
=
+=
∫
′
′
end
end
endbeginnew
endbeginnew
new
beginvarvar
varnewstopstartmaint
if ,
1
,
if ,,
,
where,,
stop
start
Yt
Yt
YYN
YttYN
tN
tYNtN
dttNtNyyN
y
y
(3)
ICSOFT 2008 - International Conference on Software and Data Technologies
82
Here,
(
)
stopstartnew
, yyN denotes, depending on the
protocol, either
(
)
stopstartproprnew
, yyN
or
(
)
stopstartstdnew
, yyN
.
For each protocol type, the total interface
implementation efforts
e
within a period
(
)
stopstart
, yy
are estimated by summing the initial
implementation efforts
0
e , the efforts
var
e needed
for implementing variations, the configuration
efforts
conf
e , and the maintenance efforts
maint
e :
(
)
(
)
()
()
()
stopstartmaintmaint
stopstartconfconf
stopstartvarvar
stopstartnew0stopstart
,
,
,
,,
yyNe
yyNe
yyNe
yyNeyye
+
++
++
+=
(4)
Finally, the total interface implementation efforts
for all types of protocols within a period
(
)
stopstart
, yy
are estimated by summing up the
efforts of different types of protocols:
(
)
(
)
∑
=
typesprotocol all
stopstartstopstart
,, yyeyyE
(5)
The estimation of the interface implementation
efforts can be then used in estimating the size of the
software vendor organization. Namely, assuming a
specific percentage of employees devoted to
interface implementation efforts, the size of the
research and development (R&D) department(s) and
the total size of the organization can be estimated.
2.2 OSS/BSS Mediation Interfaces
In order to verify the hypothesis of OSS/BSS market
polarization into a horizontal submarket of many
smaller players and a vertical submarket of few very
big players, we consider the interfaces of their
respective customers – i.e. incumbent and new
operators.
The assumption is that the “older” the operator,
the larger number of heterogeneous subsystems the
operator has adopted and has to maintain; this
heterogeneity stems e.g. from the mergers and
acquisitions, upgrades to new versions and types of
equipment, etc. The incumbent operators have
highly complex systems composed of a large
number of diverse subsystems with complex (also
proprietary) interfaces between them. Young
operators who may have started with greenfield
implementation, on the other hand, are likely to
operate with a more manageable infrastructure with
a smaller number of harmonized subsystems where
standard interfaces are used more often. Interface
implementation efforts differ dramatically among
the two.
Another differentiation factor between
incumbent operators and young operators is the
change of business models. Incumbent operators
typically have a lot of business models which are
based on billable tickects collected from hardware.
Those tickets are then billed based on different
agreements with customers – this kind of business
model is for example the traditional fixedline PSTN
– business. Young operators often base their
business on flat rate business models, because the
volume’s doesn’t support heavy investments on
ticketing based systems. The business model is more
or less like any other service business for example
like Cable TV –business. This differentiation can be
seen in the amount of the interafaces and also in the
complexity in the interface structure.
As a result, new entrants (software vendors),
who have a rather limited number of personnel
available, are likely to be able to cover integration
work only in upcoming markets where the
integration work is simplified by the use of web-
based integration technologies (based on IETF
standards) as well as by the use of business process
management tools.
There are a number of interfaces present in
OSS/BSS systems; however, for simplicity, the
analysis in the paper is restricted to the four
interfaces, which need to be implemented by the
mediation software subsystems (see Figure 1 below):
Charging
– Collection interface between Mediation
and Network Elements (NEs)
– Charging interface between Mediation
and Billing Systems (also fraud, revenue
assurance, dataware, interconnect etc.
systems)
Configuration
– Configuration interface between
Mediation and NEs
– Activation interface between Mediation
and Service Order Management System
(e.g. inside CRM, Billing, sales
applications)
ANALYZING IMPACT OF INTERFACE IMPLEMENTATION EFFORTS ON THE STRUCTURE OF A SOFTWARE
MARKET - OSS/BSS Market Polarization Scenario
83
Figure 1: Interfaces implemented by the mediation software.
A product of a software vendor may interface
only with a few other types of physical entities
(network elements, billing systems, repositories,
etc.). However, for each of these interfaces, a variety
of application protocols may need to be supported,
ranging from proprietary protocols and flat files, to
FTP, telnet, CMISE/CMIP, to IETF protocols such
as HTTP, SOAP, LDAP, RADIUS etc. The data
may be transferred over various network protocols
(X.25, TCP/IP or UDP, SS7, etc.) using different
data presentation formats (ASN.1, TAP, IPDR,
NetFlow records, etc.). Moreover, each of the
protocol stacks may have numerous versions
resulting in numerous interface variations. As a
result, the software vendor may need to develop and
maintain hundreds of different interface variations.
3 POLARIZATION OF OSS/BSS
MARKET: COMPARING
EFFORTS OF INTERFACE
IMPLEMENTATION
The data used in this study originates from the
SmarTop project (http://www.jyu.fi/titu/smartop),
which explores the evolution of telecom operator
software focusing on the development of the
software market in this domain. Various data
collection techniques were employed including the
analysis of the Dittberner Associates’ OSS/BSS
Knowledgebase
(http://www.dittberner.com/reports/about53.php),
documentation by TeleManagement Forum
(http://www.tmforum.com/), and other publicly
available web-sources, also complemented with the
data gathered through interviews.
The collected data was used in order to estimate
the dynamics of interface implementation efforts,
which a mediation software vendor should be able to
devote if it is to serve i) the incumbent operators and
ii) the young operators. According to the data, a few
dozens of the protocol types and over three hundreds
of interface variations need to be supported if the
software is offered to the incumbent operators.
Based on the available data, interface
implementation efforts (in person-years) have been
estimated for approximately 60% of the protocol
types that are implemented by the mediation
software vendor. Furthermore, we assume that this
data obtained covers approximately 80% of the
variations implemented by the mediation software
vendor company. In order to compensate for the
protocols/variations which were left outside of
consideration, the resulting effort estimations were
scaled accordingly.
The results of effort estimation are shown in
Figure 2. In the graph, the efforts of interface
implementation are shown for two cases:
All types of interfaces are supported (dashed
line).
Only interfaces based on standard IETF
protocols (RADIUS, LDAP, HTTP, SOAP,
etc.) are supported (solid line).
The software vendors aiming at serving the
incumbent operators need to implement all types of
the interfaces; therefore, the efforts such a vendor
needs to devote are considered in the first case
(dashed line). On the other hand, the vendors serving
new operators may have to implement only a (IETF)
subset of the protocols, and therefore the
corresponding efforts are considered in the second
case (solid line). The total efforts in the first case
were found to be 32 times greater than the efforts in
the second case.
Mediation
NEs: switch, hlr, router, ldap, radius, e-mail
Billing mediation
Provisioning & Activation
mediation
Billing systems,
fraud mgt systems,
revenue assurance,
dataware sytsems,
Interconnect billing, etc.
Service Order
Management System
(e.g. in CRM)
Service Activation
Configuration Collection
Charging
ICSOFT 2008 - International Conference on Software and Data Technologies
84
Figure 2: Efforts devoted to interface implementation by a mediation software company. In red: all types of interfaces are
supported. In blue: only interfaces following IETF standards are supported.
The estimation of the interface implementation
efforts can be used in order to estimate the size of
the organization in both cases. Having assumed a
specific portion of staff devoted to interface
implementation efforts in the company’s R&D, the
size of the R&D department(s) and consequently the
total size of the organization can be estimated.
Assuming that 5-10% of personnel are dealing with
interface implementation and maintenance:
In the first case, the organization is likely to
have a few hundreds of employees.
In the second case, the size of the organization
is estimated to be a few dozens of employees
(assuming that all protocols are to be
developed within two years).
Therefore, only relatively big companies are
capable of serving the incumbent operators, due to
the large efforts required. Furthermore, since the
current players have been implementing interfaces
for many years and have accumulated a large
“interface portfolio”, it is unlikely that a new player
can compete with these players – the newcomer is
unlikely to possess enough resources for
implementing all (or a significant portion of) the
interfaces.
On the other hand, it is much easier for new
software vendors (especially those with highly
limited resources) to serve the new operators which
require only IETF interfaces to be implemented. As
a result, a significant number of newcomers are
likely to compete for the market of such new
operators.
It is important to note that in the process of
analyzing the mediation software interfaces, a
number of assumptions had to be made, such as the
assumptions on the number of types of the interfaces
and their variations, the assumption of the
homogenity of the interfaces across the operators of
the same kind (i.e. incumbents and commencing),
the assumption on the size of the R&D units in
relation to the overall size of the software vendors,
etc. Should some of the assumption be invalid, it
may adversely affect the result of comparing the
interface implementation efforts. Therefore, the
conclusion on the likelyhood of OSS/BSS market
polarization should be considered with care.
4 BUSINESS IMPLICATIONS
4.1 General
In the paper, the efforts of software interface
implementation and maintenance are considered as a
factor influencing the structure of the software
market. Higher interface implementation efforts play
the role of a threshold for the vendors entering the
market of incumbent operators thereby effectively
disabling the entries by small commencing vendors
(see also Figure 3 below). In a longer run, such a
threshold can be assumed to reduce the number of
software vendors in the market, causing a delay in
the vertical disintegration of this market.
Furthermore, according to the results of the
analysis, a market polarization scenario is likely
whenever a fraction of the customers in the market
require a large number of complex interfaces to be
supported, while the other customers request only a
small set of simpler interfaces, Therefore, a new
0
10
20
30
40
50
60
70
80
90
100
1990
19
9
1
19
9
2
1
9
93
1994
19
9
5
1
9
9
6
1
9
97
1998
19
9
9
2
0
00
2001
2002
20
0
3
2
0
04
2005
20
0
6
20
0
7
Yea
r
All protocols
Onl
y
IETF protocols
()
E
E
max
ANALYZING IMPACT OF INTERFACE IMPLEMENTATION EFFORTS ON THE STRUCTURE OF A SOFTWARE
MARKET - OSS/BSS Market Polarization Scenario
85
Figure 3: Incumbent operators are served by large software vendors, while the small vendors entering the OSS/BSS market
will target commencing operators.
software vendor entering such polarized market may
benefit from focusing on the submarket with the
lighter interface implementation efforts. This is
likely to increase the number of vendors in this new
segment, thereby increasing competition which can
be visible in form of wider variety of offering and
price erosion. This chain of events is likely to
benefit the new operators and lower the threshold for
new operators to enter the market, which will
increase the volume of the market segment.
4.2 Telecom OSS/BSS Software
Market
In summary, the achieved results suggest that the co-
existence of incumbent and new operators with
distinct requirements for the interfaces to be
implemented is likely to result in the co-existence of
a few big and a large number of small software
vendors serving these two types of operators.
The analysis points to a likelihood of niches in a
software market, especially if the software is
dependent of the use of specific hardware equipment
as the physical networks of the operators. Software
vendors that have long term partnerships with
incumbent companies that are active in the industry
(operators, software and hardware vendors) are
likely to possess richer knowledge of their legacy
technologies and systems, and these software
vendors are likely to maintain their position in their
segment of the market. However, this knowledge
does not guarantee that they sustain their positions in
the overall market: new solutions by new business
entrants starting with greenfield implementations
may require another set of competencies, for
example the ability to implement open source
solutions as a service for the young operators.
Furthermore, the competition comes not only from
the the old timer telecom software vendors, but also
from generic software providers.
5 CONCLUSIONS
According to industry evolution theories, a vertical
software market gradually undergoes the process of
vertical disintegration resulting in a set of horizontal
software layers with standard interfaces, where the
software at each layer can be provided by an
independent software vendor. However, due to
various reasons, the process of vertical disintegration
may be delayed, and in extreme cases may never
complete.
This paper suggests that the interfaces, which the
software at one or few of the layers needs to provide
may become an obstacle for the vertical
disintegration. Because of the great efforts that may
be needed for interface development and
maintenance, only few big software vendors may be
capable of competing in the market. As a result, the
conditions necessary for vertical disintegration may
never materialize.
The impact of interface implementation efforts
on vertical disintegration has been studied in this
paper in the case of the telecom OSS/BSS software.
The results of analysing the efforts support the
Software
vendor
Operator
Incumbent
operator
Commencing
operator
Complex vertical
intertwined legacy
systems
Streamlined or
standardized
layered systems
Integration of
new systems
requires
significant efforts
Integration of
new systems is
straightforward
Large
(incumbent)
vendors
Small
(entrant)
vendors
SW 1
…
…
Proc. 1 Vendor 1
SW nProc. n Vendor n
SW 1
Process 1
Process n
… SW n
HW kHW i … …
Vendor 1..n
Vendor i..k
Vertical software
Vertical software
ICSOFT 2008 - International Conference on Software and Data Technologies
86
hypothesis that, due to the co-existence of
incumbent operators with highly complex interfaces
and new telecom operators with relatively
lightweight requirements for the interfaces to be
implemented, the market of the OSS/BSS software
is likely to be split into two polarized submarkets:
the submarket of incumbent operators served by a
few large software vendors, and the submarket of
young operators served by a large number of small
software vendors. As a result of the difference in the
efforts, the submarket of young operators is likely to
horizontalize, while the submarket of incumbent
operators is likely to remain vertically integrated.
Besides prohibitively large interface
implementation and maintenance efforts, the vertical
disintegration of a software market may be
hampered by other obstacles, such as the internal
complexity of the business processes being
automated by the software, the need to maintain
compatibility with older systems, the need to comply
with the legislation mandating the use of specific
systems, etc. These factors, however, have been left
out of the scope of this paper, and therefore further
study is needed in order to address them.
ACKNOWLEDGEMENTS
The authors would like to thank Prof. Olli
Martikainen for valuable comments and suggestions,
as well as to Mirja Pulkkinen for her great efforts to
improve the paper. The study was conducted as a
part of SmarTop research project
(http://www.jyu.fi/titu/smartop) funded by The
Finnish Funding Agency for Technology and
Innovation (Tekes) and sponsored by Nokia Siemens
Networks, Tecnomen, Comptel, Nethawk, and
Mikkelin Puhelin.
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MARKET - OSS/BSS Market Polarization Scenario
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