Researching Human and Organizational Factors Impact for Decisions
on Software Quality
Luis Fernández-Sanz
1
, Josefa Gómez-Pérez
1
, Teresa I. Diez-Folledo
1
and Sanjay Misra
2
1
Dept. of Computer Science, University of Alcalá, Edificio Politécnico, Campus Universitario, Alcalá de Henares, Spain
2
Covenant University, Ota Ogun, Nigeria
Keywords: Software Quality, Quality Assurance (QA), Human Resources, Organizational Factors, Stakeholders,
Quantitative Research, Qualitative Research, Decision Making Processes.
Abstract: Quality is an essential factor for European competitiveness as low price strategies based on low labour costs
can be difficult to implement. Although software quality assurance has a long tradition, there is a lack of
research on some practical aspects. In particular, the extended study of the influence of human and
organizational factors (HOF) on the quality of software development, maintenance and management has been
neglected. However, different studies have identified these as key factors in software projects with impact in
terms of cost, quality and results measuring quantitative and qualitatively their impact. As part of the Iceberg
project, funded under the Marie Curie IAPP EU-funded program, some relevant evidences of the influence of
HOF on software quality has been reviewed and analysed to discuss the challenges in this area confirming the
need of promoting deeper and wider research efforts.
1 INTRODUCTION
Software has become an essential asset for European
companies, organizations and society. Software is an
important part of ICT not only in information systems
but also as an embedded component of many products
or services. It is the distinctive part of products and
services enabling them to be competitive or
innovative. So software quality is strategic for all
European stakeholders. A compilation of incidents by
Peter Neumann (“Inside risks”) from the 1980s to
today shows there is room for improvement in
software quality. For European industry,
competitiveness in software depends on innovation
and quality given that prices cannot be reduced
without impacting the workforce. Therefore, Europe
should lead all aspects of software quality both in
research and practice.
Advances in software engineering and quality
have led to relevant techniques, methods, and tools:
process models and methods (e.g. CMMI, ISO/IEC
15504, agile methods, etc.), quality assurance
techniques and methods (software testing, review
processes, metrics, quality models, etc.), etc. Many of
them have been successfully implemented but are
extremely focused on technical aspects.
However, the workforce represents the main cost
of any project: professional software development is
mainly a social activity. Only a small percentage of
studies have addressed human factors and their
impact on software, maybe because it requires a
multidisciplinary approach, with strong links to
industry, practitioners and professional bodies.
Although software quality assurance has a long
tradition, there is a lack of research on this practical
aspect. In particular, the extended study of the
influence of human and organizational factors (HOF)
on the quality of software development, maintenance
and management has been neglected. Thus project
and corporate managers do not have the basis for
decision making methods to forecast their effects on
quality results of software development.
For example, some research works have revealed
problems in training, performance and good practice
in organizations as well as in professionals’ attitudes
in software testing or impact of training in software
professionals: unsystematic test case design leads to
35% of unnecessary cases while covering less than
50% of functions (Jones, 1998), at least 10 days of
annual training increase productivity in 8%
(Fernandez-Sanz and Misra, 2012), etc. These are
clear indications which may feed decision models for
managers to decide investment in human and
organizational aspects of software quality.
However, wider and deeper analysis is needed as
we will show in next sections. In the end, this lack of
Sanz, L., Pérez, J., Díez-Folledo, T. and Misra, S.
Researching Human and Organizational Factors Impact for Decisions on Software Quality.
DOI: 10.5220/0006003702830289
In Proceedings of the 11th International Joint Conference on Software Technologies (ICSOFT 2016) - Volume 1: ICSOFT-EA, pages 283-289
ISBN: 978-989-758-194-6
Copyright
c
2016 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
283
more comprehensive data implies a lack of firm
evidence for managers and organizations to help them
to organize and optimize the performance of the main
resource: software professionals.
The problem in particular arises from the fact that
the extended study of the influence of human and
organizational factors on the quality of software
development, maintenance and management has been
neglected in the research spheres as well as in the
industry and practitioners’ world. Obviously this
situation is a consequence of several contributing
causes, some of them related to the difficulty of this
type of research (e.g. it usually requires a cooperative
and multidisciplinary approach, with good
connections to relevant stakeholders outside the
academia as well as the need of coping with local
variations and conditions) but others with the disdain
of the researchers and industry to work on this topic
(e.g. a proposal on HOF and software quality was
poorly assessed by an EU COST program evaluator
because it was not “real research, just something to
leave to industry”). This is a paradoxical situation
because there are many evidences that confirm that
HOF are connected to the most expensive parts of
software projects. In parallel managers still insist on
investing more money in technical aspects with
reduced ROI, always trying to find and buy a "silver
bullet" normally with the shape of a new tool or
development environment. A contradictory view
when considering results of a complete study of factor
influencing productivity (Trendowicz and Münch,
2009): success of software projects still relies upon
humans while second most commonly considered
factors are tool and method but even the best tool or
method alone is not a silver bullet and cannot be a
substitute for skilled people and effective work
organization.
Obviously the ideal situation would be one where
studies calculating ROI or other economic indicators,
similar to some already created for specific software
quality assurance (SQA) or software engineering
methods or approaches (e.g. (Rico, 2004)) could be
available for guiding managers’ decisions on HOF
and software quality. However, this has not been still
possible for the general set of software quality trade-
off (Barney et al, 2012), 61% of the research is
providing non-empirically assessed solution
proposals and only 28% offers empirical evidence.
This paper is organized as follows. Section 2
reviews the general panorama of the literature
contributions to the study of HOF in software quality
focusing on evaluating the impact of factors on
software quality results. Section 3 analyses some
relevant contributions to detect and discuss the
challenges in the field of HOF to overcome the poor
state of development of research. Final Section 4
outlines some conclusions and suggests actions for
future work in the area.
2 GENERAL ANALYSIS OF
CONTRIBUTIONS
Searching literature to find contributions where the
relationship between HOF and software quality is
identified and analysed is not an easy task. Terms for
searching literature databases are less precise and
concise than the ones used in m ost technical topics in
software engineering. Moreover, a term like "human"
is frequently used in the field of HCI (Human-
Computer Interaction) and the development of
effective UI (user Interfaces) thus populating search
results with a good number of references which do not
address our perspective. This trend is also seen in
compilation of contributions like (Saaed, 2014) where
26 academics and practitioners present practice
reports, discussions, inherent issues, implementation
strategies, latest research, as well as case studies from
around the world focusing on the human factors
aspect of software design and development (but not
exactly addressing software quality).
It is worth mention that there was a seminal
initiative by DeMarco and Lister with their book
Peopleware (Demarco and Lister, 1999) already in
1987, where they grouped under this expression all
people's related issues: teamwork, group dynamics,
organizational factors, with a special focus on
productivity and all types of factors related to people
who work in software projects. This happened many
years after Brooks stated in the Mythical Man Month
book (Brooks, 1975) that product quality is strongly
affected by organization structure. Others (Nygaard,
1986) (Naur, 1991) had also remarked the human, the
social side of cooperation in teams and working
environments of software development. In many
cases, HOF have been present in studies as linked to
the pair productivity and quality (Fernandez-Sanz and
Misra, 2011) but the side of quality has frequently
attracted less attention and detailed data than the
productivity one. However, an early literature review
of productivity factors in software projects also
confirmed that soft or human-related factors in
software engineering are often not analysed with
equal detail as more technical factors (Wagner and
Ruhe, 2008). This study also outlined an important
cross-relationship between quality and productivity:
the quality of the product influences motivation and
hence productivity. The relationship between social
ICSOFT-EA 2016 - 11th International Conference on Software Engineering and Applications
284
issues and productivity has been also analysed in
(Yilmaz and O’Connor, 2012), where it is suggested
that social capital is essential for building highly
productive development environments.
The permanent problem is the lack of continuance
of this line of action. However, there was a new
impulse some years ago when some researchers
insisted on promoting a wider variety of research
approaches to deal with the undeniably social nature
of software development. The consideration of social
sciences methods and their adaptation to software
engineering resulted in their acceptance in the
software engineering research mainstream: e.g.
qualitative research with examples like ethnographic
methods, etc. (Dittrich et al, 2010).
Although there is not a definitive and clear review
of the research contributions to the connection
between HOF and software quality, other works have
tried to cover the relationships between HOF and
similar aspects of software engineering and
development. A systematic literature review (SLR)
that covered papers published in 2000-2010
(Pirzadeh, 2010) was carried out to identify human
factors and their impact on development process. The
SLR concludes that despite HOF impact on process
success, performance and quality, there is an evident
lack of primary and secondary studies on HOF: again
software engineering studies still tend to be mainly
focus on technical context. It also confirms that most
researchers in this area think that HOF are the centre
of development process.
The results presented in (Seth, 2015), empirically
collected in 13 software companies, suggest that the
human factor is the basis of software quality.
Regarding organizational factors, the author
concludes that structures, mode of operation and
communication channels contribute to success or
failure in the software quality construction process.
Another area which has leaded to a more intensive
study of HOF is agile development. Based on closely
related-to-HOF foundations, agile methods have
high-lighted their impact on results. Although agile
paradigm was firstly launched without a sustained
effort on sound empirical evidences, more relying on
conviction and direct observation of promoters, this
area has been finally able to produce studies in impact
publications (Dyba and Dingsoyr, 2008).
Although many works have tried to establish
relationships between psychological factors and
performance when developing or testing software,
only a few empirical studies have been carried out to
study the influence of these specific factors on
software quality. Moreover, the context of the studies
is frequently defined as a project with non-
professional participants (students). Although it is
frequently used in other disciplines like psychology,
this approach has generated a point of controversy,
attracting obvious criticism if the study is not
addressed at the behaviour of novice or non-experts
(Kitchenham et al, 2012). For instance, (Acuña et al,
2009) presents a quasi-experiment that analyses the
relationships between personality and software
product quality based on responses to questionnaires
by computing students that work in teams. Sometimes
the factor is motivation where there is a good number
of identified studies in a SLR (Beecham et al, 2008).
Cultural factors and collaboration have gained
especial relevance after the generalization of Global
Software Development (GSD) projects and the
corresponding research studies to optimize results as
well as overcome detected barriers which hinder the
performance in multinational settings (e.g. see the
tertiary study on SLR on GSD (Verner et al, 2012)).
3 ANALYSIS OF RELEVANT
CONTRIBUTIONS
Although the general review of contributions on HOF
in software quality may lead to the impression that
there is an acceptable population of contributions, this
is not the case of the studies pursuing the
determination of a clear impact relation to software
quality. It is extremely difficult to find sound work
based on the quantitative analysis of impact of HOF
in direct quality results. Obviously this varies from
one studied aspect to other.
The analysis of the quality in GSD deserves a
special mention in our review. According to (Misra
and Fernández, 2011) (Misra et al, 2013), one of its
major drawbacks is that low quality software can be
produced due to the negative impact of people issues
on this type of projects. Software is developed
through teams, from multiple geographic locations,
different cultures, languages, etc. Thus, HOF such as
communication, knowledge management,
coordination, collaboration and group awareness trust
are key to improve the quality of the software.
Connected to GSD, (Thomas et al, 1996) is one of the
few studies that empirically address the effect of
cultural diversity in software quality. The aim of that
work is at identifying cultural factors that impact on
quality, and to give recommendations and guidelines
for software process improvement.
There is little empirical evidence of the effects of
organizational factors on software quality. (Lavallée
and Robillard, 2015) provides the outcomes of a study
carried out in a professional environment. It shows
Researching Human and Organizational Factors Impact for Decisions on Software Quality
285
that certain organizational factors, that might not
affect project success, negatively affected software
quality. And quality factors can have a major impact
on maintenance costs. Similarly, other papers
(Mathew, 2007) (Leung, 2001) (Jaktman, 1998) stress
that the impact of the organizational culture on
software quality has been ignored by researchers in
academia and industry. However, there is a more
direct relationship in (Nagappan et al, 2008) where
authors investigate the relationship between
organizational structure and software quality by
proposing a set of eight measures that quantify
organizational complexity. The results of that work
provide empirical evidence that the organizational
metrics are related to, and are, effective predictors of
failure-proneness. (Ryan and O’Connor, 2013)
present an empirical study that shows how social
interaction is key in software development teams.
The influence of motivation has been theoretically
analysed in many studies (Beecham et al, 2008)
(Griesser, 1993) (Basili and Reiter, 1979). Empirical
studies on motivation are difficult to find because it is
hard to quantify. Although organizations are aware of
its importance, they normally focus on other factors
that are easier to measure.
Given the difficulty of analysis of HOF in
organizations, many studies rely on the use of surveys
and questionnaires to collect information or other
approaches like Delphi studies. Although this is a
valid instrument for this type of research, it is not as
effective as controlled experiments or quasi-
experiments.
One important observation is that empirical
research works in this area usually rely on case
studies as methodological approach. Although case
studies are very useful methods, they help to
investigate a single entity in a particular period of
time. Other disadvantage of case studies is that the
data collection and analysis are more open to
interpretation and research bias. This is why the use
of other types of empirical and theoretical research
methods is needed.
In a first revision looking for empirical studies
that connect HOF and software quality, a low
percentage (around 5%) of the revised papers carried
out controlled experiments. The searching has been
carried out looking for keywords such as empirical,
survey, quality, human factors, etc. in the main
databases (IEEExplore, ACM, Google Scholar,
Springerlink, etc.). One of these mentioned controlled
experiments is carried out in (Bernárdez et al, 2014),
where the performance of two groups of students is
compared to analyse the effects of mindfulness on the
development of conceptual models. A good example
of a quantitative study with data taken from industry
(although only in one company) and creating a
decision model can be found in (Krishnan et al,
2000): personnel capability is identified as a clear
positive and quantified impact on the quality of the
product.
One of the area where there are promising
advances is software testing. Recent interest by
industry on testing during the recent economic crisis
has been synergetic with the existing tradition of
research. Relevant connections between HOF in
testing and quality results have been detected by
contributions in the specific literature. For instance,
(Fernández-Sanz and Misra, 2012) focuses on the
proper generation of test cases and shows the results
from experiences with more than 70 software
professionals. Relevant trade-off connection was
detected: software practitioners with specific trained
in testing were better than the untrained ones in
detecting defects and in being more efficient: less
repetition of similar test cases which do not offer
detection value (average repeated test cases was more
than 50%). Moreover, it showed the inconsistency of
test case design to their own rank of priority for
functionality. Another example is the survey in (Kanij
et al, 2014) where participated more than 100
software testing practitioners concluding with
evidence that HOF are essential to improve the
performance of software testers. Also, the empirical
study shown in (Krishnan et al, 2000) remarks that
personnel capability has significant positive impact
on the quality of the product. The survey presented in
(Fernández-Sanz et al, 2009) investigates the
influence of 23 factors on testing performance. It
reveals that training and other soft factors have a
positive effect on the results. The qualitative
approaches have also started to be present in the
testing with studies working with the ethnographic
research approach (Rooksby et al, 2009) (Martin et al,
2007).
4 CONCLUSIONS
As a conclusion, we want to support that a sustained
effort on researching HOF as a key factor is essential
for making relevant informed decision for trading-off
investments in software quality. HOF are usually
overlooked in software engineering because the
relationship to software development is complex to
investigate and involve many different domains. This
is not a recent idea (Siakas and Georgiadou, 2002) but
the pass of time has not leaded to a much better
situation. Academia and researchers who are
ICSOFT-EA 2016 - 11th International Conference on Software Engineering and Applications
286
frequently self-confined to strict branches of
knowledge are not much inclined to work in
multidisciplinary projects and teams. But this should
not preclude the work on HOF: our analysis confirms
they are frequently more influential in terms of costs
and effects than many other technical topics
extensively studied.
Other engineering branches even less exposed to
the influence of human resources than software
development have accepted in a natural way that they
need to study in a formal and scientific way the
impact of HOF on quality. A clear case is aviation
maintenance and inspection where the studies e.g. on
human error management (Latorella and Prabhu,
2000) (Xavier, 2005) cumulate a long path of
scientific contributions leading to its implementation
as best practices in companies and regular
compulsory training programs for all employees in
the area. Why do not we think in analysing human
errors in software development too by studying
successful methods tested in other disciplines?
Software quality would benefit from the work in
other similar engineering areas without forgetting that
it is always necessary to be cautious when adapting
them to the very specific case of software projects.
They study the factors which determine the best
results for total quality management (TQM)
(Shahraki et al, 2011) even determining that the main
explanation for TQM failure is the lack of attention to
human side (Edwards and Sohal, 2003). They are also
giving us interesting clues on the impact of HOF and
there are already studies working on the area of
software quality confirming that employee
empowerment is the factor with highest impact on
customer satisfaction (Parzinger and Nath, 2000) or
the especial role of leadership styles (Parzinger et al,
2001).
We would like to see more researchers and more
work in HOF as an inspiration for the area of software
quality. We agree with (Barney et al, 2012): without
empirical research, practitioners, managers and
researchers are unable to determine which approach
is the most suitable for a given context. HOF is the
least explored and analysed area. Greater empirical
research is needed: while there is a wide range of
proposed solutions, the lack of empirical evidence
implies only limited comparisons and evaluations are
possible between options. This research could be hard
to do if there is not a change in perceptions by experts
and funding agencies’ evaluators: they should also
review their assumptions to avoid this field remained
improperly explored, keeping software engineering
out of the largest and most important asset for
efficiency and effectiveness: people and their
organizations.
This analysis resulted from research during the
Iceberg project, aimed at providing new research
skills and broad horizons in the evaluation of
Software Quality Assurance investment oriented to
support decision-making through a model-based
process. As a continuation of this work, a specific
SLR on HOF and software quality is in progress as
well as the creation of an inventory of evidences of
impact. Both should act as basis for further work on
decision models. This database will hopefully serve
as reference of the specific identified trade-offs
between HOF and software quality given visibility to
the area, attracting new researchers and industry
managers.
ACKNOWLEDGEMENTS
This work has been partially funded by European
Commission for project ICEBERG no. 324356 (7h
Framework Programme IAPP Marie Curie program).
REFERENCES
Acuña S., Gómez M., Juristo N. 2009. How do personality,
team processes and task characteristics relate to job
satisfaction and software quality?, Information and
Software Technology, v.51 n.3, p.627-639.
Barney, S., Petersen, K., Svahnberg, M., Aurum, A., &
Barney, H. 2012. Software quality trade-offs: A
systematic map. Information and Software Technology,
54 vol. 7, 651-662.
Basili, V.R., Reiter Jr., R.W. 1979. An Investigation of
Human Factors in Software Development. Computer
12(12), pp. 21–38
Beecham S., Baddoo N., Hall T., Robinson H., Sharp H.
2008. Motivation in Software Engineering: A
systematic literature review, Information and Software
Technology, Volume 50, Issues 9–10, pp. 860-878
Beecham, S., Baddoo, N., Hall, T., Robinson, H., Sharp, H.
2008. Motivation in Software Engineering: A
systematic literature review. Information and Software
Technology 50(910), pp. 860–878
Bernárdez B., Durán A., Parejo J.A., Ruiz-Cortés A. 2014.
A controlled experiment to evaluate the effects of
mindfulness in software engineering. In Proceedings of
the 8th ACM/IEEE International Symposium on
Empirical Software Engineering and Measurement
(ESEM '14). ACM, New York, NY, USA, Article 17,
10 pages.
Brooks, F. P. 1975. The mythical man-month. Reading,
MA: Addison-Wesley.
Researching Human and Organizational Factors Impact for Decisions on Software Quality
287
Demarco, T., Lister T. 1999. Peopleware: Productive
Projects and Teams, Dorset House, 2
nd
edition
Dittrich Y., Sharp H., Theophilus H.W., De Souza C.,
Korpela M., and Singer J.. 2010. Cooperative and
human aspects of software engineering: CHASE 2010.
SIGSOFT Softw. Eng. Notes 35, 5, pp. 27-29
Dyba T., Dingsoyr T. 2008. Empirical studies of agile
software development: A systematic review,
Information and Software Technology, Volume 50,
Issues 9–10, pp. 833-859
Edwards R., Sohal A.S. 2003. The human side of
introducing total quality management: Two case studies
from Australia. International Journal of Manpower, 24,
5, pp.551-567.
Fernández-Sanz L., Villalba M.T., J Hilera J.R., Lacuesta
R. 2009. Factors with Negative Influence on Software
Testing Practice in Spain: A Survey, Volume 42 of the
series Communications in Computer and Information
Science pp 1-12.
Fernández-Sanz, L., Misra, S. 2011. Influence of human
factors in software quality and productivity. In
Computational Science and Its Applications-ICCSA pp.
257-269. Springer Berlin Heidelberg.
Fernandez-Sanz, L.; Misra, S. 2012. Practical Application
of UML Activity Diagrams for the Generation of Test
Cases. Proceedings of the Romanian Academy, Series
A, vol. 13, no 3, p. 251-260.
Griesser, J.W. 1993. Motivation and information system
professionals. Journal of Managerial Psychology 8(3),
pp. 21–30
Jaktman C. B. 1998. The influence of organisational factors
on the success and quality of a product-line
architecture. Proceedings of ASWEC '98: Aus. Software
Engineering Conference, pp. 2-11
Jones, T. Capers. 1998 Estimating software costs. McGraw-
Hill, Inc.
Kanij, T., Merkel, R., Grundy, J. 2014. A Preliminary
Survey of Factors Affecting Software Testers. 23rd
Australian Software Engineering Conference
(ASWEC), 2014, vol., no., pp.180-189.
Kitchenham B. A. et al. 2012. Preliminary guidelines for
empirical research in software engineering. IEEE
Transactions on Software Engineering, vol. 28, no. 8,
pp. 721-734
Krishnan M. S., Kriebel C. H., Kekre S., and
Mukhopadhyay T. 2000. An Empirical Analysis of
Productivity and Quality in Software Products. Journal
Management Science, vol. 46 Issue 6, pp. 745-759
Krishnan, M. S., Kriebel, C. H., Kekre, S., Mukhopadhyay,
T. 2000. An empirical analysis of productivity and
quality in software products. Management
science, 46(6), pp. 745-759.
Latorella, K. A., Prabhu, P. V. 2000. A review of human
error in aviation maintenance and inspection.
International Journal of Industrial Ergonomics, 26(2),
pp. 133-161.
Lavallée M, Robillard P.N. 2015. Why Good Developers
Write Bad Code: An Observational Case Study of the
Impacts of Organizational Factors on Software Quality.
International Conference on software Engineering
(ICSE2015),
pp. 16-24
Leung H. 2001. Organizational factors for successful
management of software development. Journal of
Comp. Info. Systems, vol. 42, pp. 26-37.
Martin, D., Rooksby, J., Rouncefield, M., Sommerville, I.
2007. Good Organisational Reasons for Bad Software
Testing: An Ethnographic Study of Testing in a Small
Software Company. International Conference on
Software Engineering, ICSE pp. 602-611
Mathew J. 2007. The relationship of organisational culture
with productivity and quality. A study of Indian
software organisations, vol. 29, pp. 677-95.
Misra S., Colomo-Palacios R., Pusatli T., Soto-Acosta P.
2013 A discussion on the Role of People in Global
Software Development. A discussion on the role of
people in global software development. pp. 525-531.
Misra, S. Fernández L. 2011. Quality Issues in Global
Software Development. The Sixth International
Conference on Software Engineering Advances ICSEA
Nagappan N., Murphy B, Basili V. 2008. The influence of
organizational structure on software quality an
empirical case study. Proceedings of the 30th
international conference on Software engineering, pp.
521-530
Naur, P. 1991. Computing: A Human Activity.
AddisonWesley.
Nygaard, K. 1986. Program Development as a Social
Activity. Information Processing 86. IFIP, pp. 189-
198.
Parzinger, M. J., Nath, R. 2000. A study of the relationships
between total quality management implementation
factors and software quality. Total Quality
Management, 11(3), pp. 353-371.
Parzinger, M. J., Nath, R., Lemons, M. A. 2001. Examining
the effect of the transformational leader on software
quality. Software Quality Journal, 9(4), pp. 253-267.
Pirzadeh L. 2010. Human Factors in Software
Development: A Systematic Literature Review.
Doctoral dissertation.
Rico, D. F. 2004. ROI of software process improvement:
Metrics for project managers and software engineers.
J. Ross Publishing.
Rooksby, J., Rouncefield, M., Sommerville, I. 2009.
Testing in the wild: The social and organisational
dimensions of real world practice. Computer Supported
Cooperative Work (CSCW), 18(5-6), pp.559-580.
Ryan, S and O'Connor, R. 2013. Acquiring and sharing
tacit knowledge in software development teams: An
empirical study. Information and Software Technology,
55 (9). pp. 1614-1624.
Saaed S. 2014. Human Factors in Software Development
and Design, IGI Global.
Seth F.P. 2015. Empirical Studies on Software Quality
Construction: Exploring Human Factors and
Organizational Influences. Doctoral dissertation.
Shahraki, A., Konarizadeh, M., Paghaleh, M. J., Zarei, M.
2011. HRM effects on TQM. Business Management
Dynamics, 1(3), pp. 1-12.
ICSOFT-EA 2016 - 11th International Conference on Software Engineering and Applications
288
Siakas, K. V., Georgiadou, E. 2002. Empirical measure-
ment of the effects of cultural diversity on software
quality management. Software Quality Journal,10(2),
pp. 169-180.
Thomas S. A., Hurley S. F. and Barnes D. J.. 1996. Looking
for the human factors in software quality management.
International Conference on Software Engineering:
Education and Practice, pp. 474-480
Trendowicz, A., Münch, J. 2009. Factors Influencing
Software Development Productivity—Stateofthe
Art and Industrial Experiences. Advances in computers,
77, 185-241.
Verner J. M., Brereton O. P., Kitchenham B. A., Turner M.
and Niazi M. 2012. Systematic literature reviews in
global software development: A tertiary study. 16th
International Conference on Evaluation & Assessment
in Software Engineering, pp. 2-11.
Wagner, S., Ruhe, M. 2008. A systematic review of
productivity factors in software development. language,
Technischen Universität Münche, TUM-I0832 Report
Xavier, A. J. 2005. Managing human factors in aircraft
maintenance through a performance excellence
framework. (Doctoral dissertation, Embry-Riddle
Aeronautical University).
Yilmaz, M. and O'Connor, R. 2012. Social Capital as a
Determinant Factor of Software Development
Productivity: An Empirical Study Using Structural
Equation Modeling. Int. J. Hum. Cap. Inf. Technol.
Prof. 3, 2, 40-62.
Researching Human and Organizational Factors Impact for Decisions on Software Quality
289
