Software Processes Used in University, Government, and Industry: A
Systematic Review
Caroline Guterres Silva, Evandro Luis Fensterseifer Filho and Lisandra Manzoni Fontoura
Computer Science Post Graduate Program, Federal University of Santa Maria (UFSM),
Avenida Roraima, nº1000, Santa Maria, RS, Brazil
Keywords: Software Process Development, Agile Methods, Plan-driven Methodology, Hybrid Methodology.
Abstract: Software processes are essential for software development organizations to deliver quality software. There
are currently several software processes to meet different needs. However, it is difficult to find in the
literature software processes focused on university projects involving other institutions, such as government
and industry. This article aims to conduct a systematic literature review to identify the characteristics and
limitations of agile and plan-oriented methodologies, which processes were used in software development
projects and to establish a relationship between organizational characteristics and best methodologies
successful. As a research method, we conducted a systematic study of the literature associated with a
snowball strategy, identified and structured the literature on the use of agile and plan-oriented
methodologies. We selected 12 studies using the systematic review and added 5 more using the snowball
method, totaling 17 selected articles. We note that there is no specific methodology to be used in software
development, each organization has its characteristics. The lack of specific processes for university projects
is evident, and the differences between this environment and industry require processes tailored. Beside, a
large number of projects use practices of more than one method, called hybrid methodologies, to exploit the
best of agile and plan-oriented methodologies.
1 INTRODUCTION
In the late 1970s, the software crisis occurred,
leading to a change in the way software was
developed, requiring companies to conduct their
projects in a standardized way (Pressman, 2011).
Since then, various software development methods
have emerged, and since the mid-1990s, various
processes have been proposed.
In general, software processes can be grouped
into two different approaches according to their
characteristics, which are: plan-driven (or
traditional) and agile methods (Silva, Oliveira,
Canedo & Martins 2016). Agile methods focus on
people rather than processes, communication, and
interaction between people. Less documentation is
created, and code is seen as part of the
documentation. On the other hand, plan-driven
methodologies focus on predictability and detailed
planning. To define the process to be used in each
project, it is necessary to consider the characteristics
of each methodology and the application context.
University projects are different from
government and industry projects (Abbas, Avdic,
Xiaobao, Hasan, & Ming, 2018). Identify the
characteristics of each project, such as developer
profile, work time, criticality, team size; It is
relevant to define the most appropriate processes for
each development (Silva & Melo, 2016).
Besides, today projects involving more than one
of these organizations are common, following the
Triple Helix model, especially in projects involving
science, research, and innovation. This model
focuses on university-industry-government relations
as a strategy to encourage the dynamics of
innovation (Mineiro, Souza, Vieira, Castro & Brito
2019).
Therefore, rethinking and redesigning the
software development process is an essential task to
address different application contexts, executing it
more effectively, thereby reducing software
development costs and increasing end-product
quality and customer satisfaction (Canedo, Martins,
Oliveira & Silva, 2016).
314
Silva, C., Filho, E. and Fontoura, L.
Software Processes Used in University, Government, and Industry: A Systematic Review.
DOI: 10.5220/0009419203140321
In Proceedings of the 22nd International Conference on Enterprise Information Systems (ICEIS 2020) - Volume 2, pages 314-321
ISBN: 978-989-758-423-7
Copyright
c
2020 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
In this sense, it is essential to analyze the ideal
characteristics of the use of each of the process
approaches, the characteristics of projects developed
in universities, government, and industry to establish
a relationship between the characteristics of process
approaches versus the characteristics of
project/organization.
Therefore, the purpose of this paper is to
investigate the characteristics and limitations of
using agile and planned methods and which
processes are used in software projects involving at
least one of these organizations (university-business-
government).
To this end, a systematic literature review and
snowballing technique were applied as a research
methodology to identify studies related to the area
that meet the research objectives.
The paper was organized as follows: Section 2
describes a background with concepts relevant to the
understanding of the work. Section 3 describes the
research methodology, and section 4 describes the
final considerations and future work.
2 BACKGROUND
The term Triple Helix was coined by Henry
Etzkovitz in the 1990s to describe the model of
innovation based on the Government-University-
Enterprise relationship (Etzkowitz, 1994). The
authors Etzkowitz and Zhou (2017) define that
Triple Helix as a model of innovation in which the
university/academy, industry, and government
interact to promote development through innovation
and entrepreneurship.
This representation seeks the production of new
knowledge, technological innovation, and economic
development through dynamic processes of
experiences in the relationships between science,
technology, research, and development, in a spiral of
endless transitions (Mikosz, 2017). Based on this
assumption, it is analyzed that university-industry-
government interactions, which form a “triple helix”
of innovation, are critical points for knowledge-
based economic growth and social development
(Etzkowitz & Zhou, 2017).
Given the scenario described, using
methodologies in the implementation of projects that
meet the diversity of this market with precision and
without fail is paramount (Silva & Melo, 2016).
Cereci and Karakaya (2018), define that software
development methodologies are used to organize
and monitor the software process.
Currently, it is considered that there are two
main approaches related to software processes,
which are: plan-driven methodologies and agile
methods (Fowler, 2005).
The basic idea of the plan-driven methodology is
that projects are relatively simple, predictable, and
linear with clearly defined boundaries, which
facilitates detailed planning and follow-up without
significant changes (Boehm & Turner, 2003). Plan-
driven methodologies focus on planning, and work
begins by collecting and documenting a complete set
of requirements, followed by the development and
inspection of high-level architectural designs
(Mushashu & Mtebe, 2019).
Agile methods, according to Koskella (2003), are
related to rapid software development focusing on
less time in analysis and design, thus being an
iterative and incremental approach. According to
Pressman (2011), the agile methodology employs
simplicity in development, focused on customer
satisfaction, with small and motivated teams.
Mamoghli and Cassivi (2019) describe that the
implementation of agile practices allows gaining
experience with software throughout the project. In
this development, communication between
developers and clients is prioritized, giving
preference to delivery over project analysis.
However, according to Comfort and Amaral
(2016), due to an innovation environment, the form
of software development has changed, implying new
strategies and techniques to combine simplicity,
speed, and flexibility.
According to Kruchten (2011), due to routine
and constant changes in software design
requirements, the team should use a dynamic and
adaptive software process. Software projects are
affected by various factors such as cost, scope,
quality, and success criteria vary from project to
project. Adaptive processes can facilitate these
changes.
Hybrid methodologies, that is, combining
practices from agile and traditional methods, have
also been used to deal with the dynamism of specific
projects, increase productivity, and improve the
quality of the final product. Hybrid methodologies
can be characterized by the combined adoption of
principles, practices, techniques, and tools from
different methodologies to adapt management to the
context of software design and provide the balance
between flexibility and predictability, reducing risk
and increasing innovation (Conforto, Amaral, Silva,
& Rebentisch, 2015).
In general, to define the most appropriate
processes for developing a project, it is necessary to
Software Processes Used in University, Government, and Industry: A Systematic Review
315
consider the project objectives, the development
team, and the software business domain. Silva et al.
(2015) state that traditional and agile methods have
their advantages and disadvantages so the choice of
one depends on the context of the application.
Given this Silva and Melo (2016) highlight that it
is necessary to have a clear understanding of the
characteristics of the project, of the structure and
strategy of the company when defining the process.
These understandings will support the definition of
the best and most appropriate practices of each
methodology to be associated with the achievement
of the project objective (Silva & Melo, 2016).
3 RESEARCH METHODOLOGY
A systematic literature review aims to provide a fair
assessment of a research topic using a reliable,
rigorous, and auditable review methodology
(Kitchenham, 2004). This review evaluates and
interprets the relevant literature available to
understand and analyze the development
methodologies used in projects in universities,
companies, and governments. This study followed
the guidelines proposed by (Kitchenham and
Charters, 2007), which involve three main phases:
planning, conducting, and reporting the review
results.
After SLR, we performed a manual search using
the snowballing guidelines proposed by Wohlin
(2014), to perform an analysis of primary studies
and obtain secondary studies in the face of the
research proposal.
3.1 Planning the Review
This step aims to define the search plan, determining
the issues of interest, data sources, strategy and
search terms, inclusion and exclusion criteria,
detailed below.
The quality of the systematic review is related to
the proper definition of the research questions. The
questions guide the review, so they are elaborated to
meet the proposed objectives (Kitchenham, 2004).
For this research, we defined the following
questions:
RQ1: What are the characteristics and
limitations of plan-driven and agile methodology?
RQ2: What are the characteristics of each
organization (university, government, and industry)?
RQ3: What methodologies are used in projects
developed at universities, government, and industry?
RQ4: What works describes the use of hybrid
development methodologies?
For the analysis and selection of primary studies,
we searched the following sources: IEEE, ACM, and
Google Scholar. To perform the search, we define
the search strings, in Portuguese and English, using
the logical operators “AND” and “OR”; so the
search string used was:
(“software development” AND “process” AND
(university OR company OR industry OR govern)
AND ("agile method" OR "planned methodology"
OR hybrid))
We have defined a set of precise selection
criteria (inclusion and exclusion) to select the most
relevant articles for systematic review, ie, those that
help answer the survey questions. Studies were
selected according to the following criteria:
1. Articles describing software processes
adopted in software development projects
involving universities/academia, government
and /or industry;
2. Case studies involving the adoption of
software processes by organizations;
3. Articles published between 2013 and 2019;
4. Works wrote in Portuguese or English;
The exclusion criteria defined were:
1. Articles outside the scope of the research;
2. Articles other than Portuguese or English;
3. Published outside the defined date range;
4. Availability of title and abstract only;
5. Full document access unavailable;
6. Duplicate works.
3.2 Conducting the Review
According to the research protocol explained earlier,
we searched the databases and retrieved the relevant
studies. Using search strings, we analyze the title
and summary of each search and apply the exclusion
criteria. This first round resulted in 24 candidate
articles.
In the second iteration, we read the articles in
their whole to make sure the papers cover the scope
of the research. In this analysis, 3 articles were
excluded because they were duplicate, and 6 articles
did not cover the scope of the search. Also, 2 articles
were not found full text, which was deleted,
resulting in 12 articles selected.
The snowballing technique was used (Wohlin,
2014), which refers to the use of reference lists of
selected articles or citations of these articles, that is,
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316
it allows the search of works from references of
selected articles through a systematic review. It is
possible to refine the searches with the articles being
cited, thus allowing us to find new articles. The
application of Snowballing allowed the selection of
5 new works, thus totaling 16 works in all.
After selecting the articles, data were extracted,
considering the questions defined in the research.
Besides, we extracted information such as year of
publication, authors, proposal of each study and
source of publication, and the research method used.
Table 1 lists the resulting works.
After data extraction, a synthesis of such data
was performed to facilitate data analysis. The
synthesis lists the characteristics of each
methodology, as well as its limitations and
characteristics. Based on the similarity of the
extracted data, a categorization was performed for
each research question.
3.3 Reporting the Results
This section summarizes the search results. The
analysis of the information is presented, considering
each research question.
RQ1: What are the characteristics and
limitations of plan-driven and agile methodology?
The authors Jusoh, Gorment, Nor and Muhamad
(2017) [E08] describe that agile methodology is
widely used, especially in the education sector,
because it contributes to reducing waste, increasing
speed, as well as improving productivity, decision
making and confidence.
Already the authors Vijayasarathy and Butler
(2016), in addition to an online survey, state that the
approaches are used in statistics with a small number
of employees in low budget and medium or high
critical projects, in a single and small team.
Meanwhile, traditional approaches are used by
organizations with large numbers of employees,
high-budget and risky projects, and in medium and
multiple teams.
The authors Boehm and Turner (2003) define
several characteristics that can be used to choose
between these two approaches, which are: as
application characteristics (size and environment);
management resources, including customer
relations, planning and control; technical
characteristics, including requirements, development
and testing approaches; and personal resources,
including customer, developer, and organizational
culture particularities. In Table 2, the characteristics
and limitations of agile and plan-driven
methodology are summarized.
RQ2: What are the characteristics of each
organization (university, government, and industry)?
In the university, authors Cereci and Karakaya
(2018) [E01] report that meetings occur less
frequently because people work part-time on
projects, reconciling them with academic activities.
Also, there are not always exist end users to perform
software testing.
Brondani, Mello, Fontoura (2019) [E08] state
that university teams are composed of workers with
different skill levels, including undergraduate,
graduate, and highly experienced researchers. These
teams, in addition to focusing on development
activities, need to investigate highly complex
research solutions. Another characteristic pointed
out by the authors is the high turnover of the team..
As they develop projects in partnership with
different organizations, the team is unfamiliar with
the business domain, making it challenging to define
software requirements.
According to Dias, Kodikara, and Jayawardena
(2013) [E02], academic institutions focus on
learning, research, and innovation, as the result of
research projects intended to works publications.
Already in organizational contexts, Cereci and
Karakaya (2018) [E01], who report that work is
done full time, software development is for-profit
and limited budget product delivery (Dias, Kodikara
& Jayawardena, 2014) [E02]. Kuhrmann et al.
(2019) [E05] declare that company policy must be
strictly followed, and this often limits the choice of
the most appropriate process.
When referring to the government, it is possible
to verify aspects related to government laws, and the
need for transparency in data and control of internal
organs related to the institution (Dos Santos and
Canedo, 2014) [E06].
In the case studies by the authors, Benedicenti et
al. (2016) [E07], describe how army software
development should be of high quality and have
specific and complex requirements.
Cotugno and Messina (2014) [E17] describe that,
in military environments, system reliability is
essential. The criticality of systems is usually high.
Planning costs must be within budget, and there is a
need to follow software development standards.
Table 3 shows the characteristics of each institution.
RQ3: What methodologies are used in projects
developed at universities, government, and industry?
Table 3 describes the methods proposed by the
works selected by the organization in which they
were applied.
Software Processes Used in University, Government, and Industry: A Systematic Review
317
Table 1: All the papers included in the SLR.
Id Authors Year Title
E01 Cereci and Karakaya 2018
Need for Software Development Methodology for Research Based Software
Projects
E02 Dias et al. 2013
The Need for Novel Development for Software Projects in Universities: A Sri
Lankan Case Study
E03
Dias, Kodikara, and
Ekanayaka
2014 Differences between universities and industry in software development
E04 Turke, France, and Rumpe 2014 Limitations of Agile Software Processes
E05 Kuhrmann et al. 2019 Hybrid Software Development Approaches in Practice: A European Perspective
E06 Dos Santos, and Canedo 2014 Development Methodology Case Study: Brazilian Electoral Justice
E07 Benedicenti et al. 2016 Applying Scrum to the Army - A Case Study
E08 Brondani et al. 2017 A Case Study of a Software Development Process Model for SIS-ASTROS
E09 Vijayasarathy and Butler 2016
Choice of Software Development Methodologies Do Organizational, Project and
Team Characteristics Matter?
E10 Mushashu and Mtebe 2019
Investigating Software Development Methodologies and Practices in Software
Industry in Tanzania
E11 Awad 2005
A Comparison between Agile and Traditional Software Development
Methodologies
E12
Fitriani, Rahayue and
Sensuse
2016 Challenges in Agile Software Development: A Systematic Literature Review
E13 Spundak 2013 Mixed agile/traditional project management methodology reality or illusion?
E14 Riesener, Dölle, and Ays 2018
Hybridization of Development Projects Through Process-related Combination of
Agile and Plan-Driven Approaches
E15
Klunder, Hohl, Fazal-Baqaie,
Krusche, Küpper, Linssen &
Prause
2017
HELENA study: Reasons for combining agile and traditional software development
approaches in german companies
E16
Marinho, Noll Richardson
and Beecham (2019)
2019
Plan-Driven Approaches Are Alive and Kicking in Agile Global Software
Development
E17 Cotugno and Messina 2014 Adapting SCRUM to the Italian Army: Methods and (Open) Tools
Table 2: Characteristics and limitations of plan-driven and agile methodologies.
Characteristics Limitations
Agile methodology
Turke, France and Rumpe (2014) [E04]; Fitriani, Rahayue and Sensuse
(2016) [E12]:
• Customer communication;
• Software requirements evolve as software is developed;
• Change-adapted software development process;
• Project visibility can be achieved mainly through the delivery of
increments and some metrics;
• Software can be developed in increments.
Awad (2005) [E11]:
• Customer collaboration.
Dos Santos and Canedo (2014) [EO6]:
• Well defined roles;
• Anticipated deliveries of key system features;
• Simplicity;
• Deliver frequently running software.
Turke, France and Rumpe (2014) [E04]:
• Distributed development environment;
• Development involving several teams;
• Limited to software with high criticality;
• Complex software development.
Awad (2005) [E11]:
• Large scale software.
Mushashu and Mtebe(2019) [E10]:
• Lack of documentation;
• Insufficient software design.
Dos Santos and Canedo (2014) [EO6]:
• Requires team members greater skill and
responsibility.
Plan-driven
methodology
Spundak (2013) [E13]:
• Formal documentation;
• Used in critical projects;
• Work control;
• Projects with high criticality;
• Focus on verification and validation;
• Used in larger projects.
Spundak (2013) [E13]:
• Robustness;
• Project isolated from its environment;
• Time constraints;
• Uncertainty in setting goals.
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Table 3: Characteristics of each institution and methods used.
Given this information, it was found that in the
university environment, according to the study by
authors Cereci and Karakaya (2018) [E01], the
methodologies are similar to the prototyping and
software development process is based on
experiences from other projects. According to Dias
et al. [03] describes that projects carried out at a
university use whiteboard to draw diagrams and
concept maps to illustrate their ideas.
According to Dias, Kodikara, and Ekanayaka
(2013) [E02], there is no standard method to be used
in the university context, which focuses on
innovation, research, and learning.
Brondani et al. (2019) [E08] point out that in the
development of a project for the government, carried
out at a university, a hybrid methodology was used.
Practices related to plan-driven methodologies were
used for the activities of analysis, design, and
verification activities, supporting the development of
documents related to each phase of the project, as
the condition of the project contract required formal
deliverables. Agile methodologies were used to
manage implementation and testing activities,
emphasizing short development cycles, team, and
end-user communication and collaboration
principles, enabling incremental deliveries, and
change requests without affecting the project.
Regarding industries, Kuhrmann et al., (2019)
[E05] state that traditional and agile methodologies
are used, with a more significant predominance of
the cascade and scrum method of structure, as well
as Kanban.
In a research conducted by the authors Dias et al.
(2014) [E03], they observed that the industries that
participated in the interview, use the Scrum software
development standard, emphasizing on-going user
engagement to understand requirements and improve
as feedback
In contrast, in a study by the authors Klunder et
al. (2017) [E15] and Marinho et al. (2019) [E16],
they report that most projects use a combination of
agile and traditional approaches called the hybrid
methodology.
Authors Mushashu and Mtebe (2019) [E10],
describe that the methods chosen by companies are:
plan-driven methodologies, such as cascade and
prototyping method.
In the context related to government, Dos Santos
and Canedo (2014) [E06] report that agile methods
are widely used because they are objective, roles are
well defined, easy to learn and provide project
visibility to the team. The authors describe some
aspects of implementing agile government-related
project methodologies such as response to changes,
delivery of key system functionality, increased
customer collaboration in the development process,
and the possibility of effort estimation.
RQ4: What works describes the use of hybrid
development methodologies?
Theocharis et al. (2015) argue that instead of
using only traditional or agile processes individually,
various methods should be combined to adapt their
development process to a specific context. Thus, it is
considered that the combination of agile and plan-
driven methods should be used to leverage the
strengths of both approaches. The authors describe
that agile methods emphasize communication,
knowledge sharing, and project visibility. The plan-
driven methodology proposes detailed planning,
control, and estimation of tasks.
Software Processes Used in University, Government, and Industry: A Systematic Review
319
Riesener et al. (2018) [E14] describe that plan-
driven development processes are described by
attributes such as predictability and stability. On the
other hand, agile processes apply to projects with
many requirements changes and where the customer
is heavily involved in the development process.
Given this perspective, it is suggested to adopt
hybrid development approaches, which will allow
the benefits of both methodologies, providing secure
management and a flexible environment (Kuhrmann
et al., 2019) [E05]. Thus, it is necessary to balance
the need for planning and control with time and
flexibility when adopting different methodologies
Marinho et al. (2019) [E16].
The authors Comfort and Amaral (2016) argue
that the adoption of hybrid methodologies proves
improvements in process performance, especially
issues related to added value, flexibility, and
accuracy of project information.
The authors Vijayasarathy and Butler (2016)
[E09] describe that the choice of a methodology for
a project depends on the type of organization,
project characteristics, and team. According to the
research described by the authors, 45.3% of the
projects use hybrid approaches, which are relevant
to organizations of different sizes, with medium and
high criticality budget and in small teams.
Brondani et al. (2019) [E08] used a hybrid
approach in which contract assets (deliverables)
were managed using planned approaches, while
short development cycles were defined to manage
internal deliveries, bringing agility.
4 CONCLUSION
This research discussed the importance of adequate
methods for the specifications of each context and
project in software development, as well as the
appropriate combination of methods proposed by
different approaches, leveraging their potentials and
consequently improving the quality of the software
process. There is no single methodology that can
cover the needs of all software projects, as well as
different contexts.
Plan-driven and agile methodologies have their
advantages and disadvantages, so it is not possible to
standardize and claim that one approach is better
than another. Some factors influence the choice of
software methodologies, such as project type,
project size, project duration, level of understanding
of user requirements, project complexity, customer
involvement, and team size.
It is observed that, by answering the questions
raised, there is a lack of studies related to projects
developed in universities. This issue is understood to
be necessary, especially at a time when the
university is no longer having a secondary, though
important, social role in providing higher education
and research, and is assuming a primary role
equivalent to that of industry and government, as a
generator of new industries and companies.
As future work, it is proposed to expand the
research to deepen the requirements for a process
involving university and government and/or
industry.
ACKNOWLEDGEMENTS
We gratefully acknowledge financial support from
CAPES-Brazil, and the Brazilian Army for the
financial support through the SIS-ASTROS Project
(813782/2014), developed in the context of the PEE-
ASTROS 2020.
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