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CHAPTER 8: CONCLUSION
8.0 Introduction
This chapter presents the conclusion of the study in several sections. The first section
summarises the findings of the study in relation to the objectives. The second section
discusses the managerial implications of this study while the third section provides
recommendations. The fourth section highlights the limitations of the study and
finally, the last section suggests future research directions.
8.1 A snapshot of summary findings
The purpose of the current study was to develop a performance evaluation framework
for assessing performance amongst public sector construction projects in developing
countries. In order to realise this objective, the researcher first conducted an extensive
review of the relevant literature in order to identify the existing body of knowledge in
the domain of performance measurement of construction projects. Based on the
review, performance indicator variables and the variables that influence project
success were identified and discussed with the experts in the area of construction
management. The variables were refined and a survey instrument was designed. This
was subsequently administered to clients, consultants and contractors who had been
involved in the CDF projects in the Western province, Kenya. The demographic
statistics regarding project characteristics and respondents’ profile were analysed
using Chi-square test of independence and one way Analysis of Variance (ANOVA).
The relevance of the performance indicator variables and success related variables
amongst CDF construction projects in Kenya was established through EFA, CFA and
SEM.
The study resulted in a set of KPIs that reflect the economic, social and environmental
dimensions of public sector construction projects. Further, the study identified and
confirmed a set of CSFs based on the KPIs which would enable the projects to
achieve performance on the identified KPIs. Finally, based on the two scales, one for
KPIs and the other for CSFs, a performance evaluation framework was developed.
The relationships on the developed framework were hypothesised and analysed using
SEM.
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These ensured that all the research objectives are addressed. A snapshot of summary
findings in relation to the objectives is given below.
The occurrence of time overrun, cost overrun and quality defects does not vary
on the basis of the type of CDF construction projects. All types of projects are
prone to these problems pointing towards the need for other factors to be
considered.
Respondents’ experience has no relationship with the occurrence of time
overrun, cost overrun and quality of defects on CDF construction projects.
Most of these projects are characterised by standard procedures which guide
the construction process.
The occurrence of time overrun and quality defects on CDF construction
projects does not vary with the project procurement method. However, the
occurrence of cost overrun varies across different procurement approaches.
This is because different procurement approaches have implications on how
project costs are computed and appropriated amongst different parties who are
responsible for undertaking construction.
Project performance of CDF construction projects are evaluated on the basis
of six KPIs namely project time, cost, quality, safety, site disputes and
environmental impact. These KPIs address the economic, social and
environmental dimensions of public sector construction projects.
Whilst not all the KPIs are significant in terms of their relationship with
project performance, there is significant evidence and support for
measurement of project performance on the basis of time, cost, quality and site
disputes.
There are six CSFs that influence success of public sector construction
projects: project-related factor, client-related factor, consultant-related factor,
contractor-related factor, supply chain related factor and external
environment-related factor.
All these six CSFs assessed are significant, providing empirical support for
considering them as factors that influence success of public sector construction
projects.
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The external environment related factor does not mediate the influence of the
remaining CSFs on project success.
Client related and project related factors; client related and consultant related
factors; and contractor related and supply chain related factors are inter-
correlated.
Success of public sector construction projects has a significant positive
association with overall project performance on the various KPIs. This
supports inclusion of the two concepts in the performance evaluation
framework for assessing performance of public sector construction projects.
These findings are briefly described in the following sections.
8.1.1 Summary findings regarding the relationship between projects’
characteristics, respondents’ profile and occurrence of time overrun, cost
overrun and quality defects.
In the exploratory study, it was found that majority of the projects funded under CDF
were Educational in nature followed by Health Care facilities while the number of
Industrial Estates and Agricultural Markets turned out to be the same. Most of these
projects were found to have been procured through the negotiated general contract
approach. With regard to cost overrun, time overrun and quality defects, it was found
that majority of projects got delayed but in most cases they met budgetary allocations
and quality specifications. With regard to respondents’ profile, majority of the
respondents were clients owing to their number in the target population, followed by
contractors and then consultants. Most of these respondents were found to posses
several years of experience in which they worked on relatively large projects as
evidenced by the value of the projects. These findings were confirmed in the study in
phase II, except that unlike in the exploratory study where the number of projects
under Industrial Estates and Agriculture was the same, the number of Industrial
Estates came out to be the least.
While examining the occurrence of time overrun, cost overrun and quality defects
across different types of projects in Phase II, it was found that the extent of
occurrence of cost overrun, time overrun and quality defects did not differ across the
161
different types of projects. Similarly, it was found that project procurement approach
did not have any effect on the occurrence of time overrun and quality defects.
However, the occurrence of cost overrun was found to be dependent on the type of
project procurement approach. While examining the relationship between
respondents’ experience and the incidences of time overrun, cost overrun and quality
defects, the results show that respondents’ experience has no effect on the occurrence
of any of the three indicators of project performance.
8.1.2 Summary findings regarding KPIs
The KPIs of overall project performance of CDF construction projects were assessed
at three levels. First, based on literature review and discussion with experts, a list of
35 performance related variables (shown in table 8.1) was identified. At the second
level, performance measurement variables were refined through EFA. This resulted in
27 performance variables which loaded into six dimensions of overall project
performance namely time, cost, quality, safety site disputes and environmental impact
as can indicated in table 8.1. The empirical findings of the study and the subsequent
analyses suggest that the performance of public sector construction projects does not
merely depend on the traditional internal criteria of time, cost and quality. It also
depends on another internal measure, safety and two external measures namely site
disputes and environmental impact. At the exploratory level, it was found that project
time is the most important KPI followed by cost while safety comes last in the order
of importance.
In the third step, the 27-variable six-factor of KPIs scale was further analysed using
CFA. The analyses resulted in a 17-item six construct measurement scale for CDF
construction projects. Test statistics of both first order and second order measurement
models are acceptable for performance measurement amongst CDF construction
projects. Table 8.1 summarises the findings of the three steps used in assessing KPIs.
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Table 8.1: Summary of the dimensions of KPIs and performance measurement variables in both survey I and survey II Literature review and discussion with experts (Performance variables)
Exploratory Study (Phase I) Confirmatory Study (Phase II)
PV1: There has not been any increase in the cost of raw materials during construction of this project. PV2: Labour costs more or less remained stable over the period of construction of the current project. PV3: The project experienced minimum variations and hence hardly any additional cost attributable to variations was incurred. PV4: The required equipments were available at pre budgeted rates. PV5: The amount/quantity of different type of resources required during the implementation phase matched with those estimated during planning stage. PV6: There were no incidences of fraudulent practices and kickbacks during project execution. PV7: There were no incidences of agitation by the trade unions in the current project. PV8: There were no serious dispute between the client and contractor due to non adherence to the specifications. PV9: Disputes were observed due to the frequent changes in the design of the current project. PV10: Dispute resolution meetings were often held during project execution. PV11: At time of project completion, there were no financial claims that remained unsettled from this project. PV12: This construction project has adversely affected the quality of groundwater level. PV13: All required resources for the project were delivered on time during execution of this project. PV14: A clear plan was formulated and an efficient planning and control system was designed to keep the current project up-to-date. PV15: No changes were introduced in the designs of the current during project execution. PV16: Harmonious relationship between labour and management existed in the project site and hence no work disruptions were reported during project
Dimension Items Dimension Items Time Performance (7)
TPV1: Timely delivery of resources TPV2: Harmonious relationship on site. TPV3: A clear plan was formulated. TPV4: No delays in securing funds. TPV5: No effect of weather and climatic conditions. TPV6: No design changes. TPV7: At handover there were no apparent defects
Time Performance (3)
TPV1: Timely delivery of resources TPV2: Harmonious relationship exists on site TPV4: No delays in securing funds
Cost Performance (6)
CPV1: Equipments at pre budgeted rates. CPV2: Stable labour costs CPV3: No increase materials cost CPV4: Minimum variations co CPV5: Adverse effect on quality of groundwater level. CPV6: No financial claims at completion.
Cost Performance (3)
CPV1: Equipments available at pre budgeted rates CPV2: Stable labour costs CPV3: No increase in materials cost
Site Disputes DPV1: No serious dispute Site Disputes DPV1: No serious
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execution. PV17: This project has led to air pollution in the adjoining areas. PV18: This project has led to depletion of the precious natural and mineral resources in the surrounding areas. PV19: There has been an increase in solid waste due to the construction of the current project. PV20: Accidents were often reported during project construction. PV21: Near misses occurred quite often during construction. PV22: Fatalities did occur on this project during construction. PV23: The construction work utilised environmentally friendly technology. PV24: This project has led to the increased release of toxic material. PV25: No delays were experienced in securing funds during project implementation. PV26: At the time of handover, the current project was free from apparent defects PV27: The project contractors were often called back during the Defects Liability Period to repair defects. PV28: Weather and climatic conditions did not have much impact on delaying the project. PV29: The current project has utilised reusable and recyclable materials in construction work. PV30: The right material was used for the construction work. PV31: Employees working in the current project possessed requisite skills and most of them had worked on similar kinds of projects in the past. PV32: A sound quality management system was strictly adhered to during project execution phase of the current project. PV33: Training was imparted to the workers in order to develop a positive attitude and also to enable them to apply the right method of work. PV34: All stakeholders associated with the current project supervised the quality of the project in all its phases. PV35: Proper medical facilities were available for people working on the project
Performance (4)
due to specifications. DPV2: Disputes due to the frequent changes DPV3: No incidences of trade union agitation DPV4: Dispute resolution meetings
Performance (3) protests by the community due to the nature of the project DPV2: Disputes due to frequent changes in designs DPV3: No incidences of trade union agitation
Environmental impact Performance (4)
EPV1: Project has led to air pollution. EPV2: Increased solid waste. EPV3: Utilised environmentally friendly technology. EPV4: Project has led to depletion natural resources.
Environmental impact Performance (3)
EPV1: Project has led to air pollution EPV2: Project has given rise to increase in solid waste EPV3: Utilised environmentally friendly technology
Quality Performance (3)
QPV1: Right material was used for the construction work. QPV2: A sound QMS adhered to. QPV3: Workers were trained on positive attitudes
Quality Performance (3)
QPV1: Right material was used for the construction work QPV2: A sound QMS was adhered to QPV3: Workers were trained on positive attitudes
Safety Performance (3)
SPV1: Accidents were reported. SPV2: Fatalities did occur. SPV3: Near misses occurred.
Safety Performance (2)
SPV1: Accidents were reported SPV2: Fatalities did occur.
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The results show that the cost construct has positive correlation with time construct
and negative correlation with quality construct. However, quality performance
deteriorates when cost performance improves. The second order measurement model,
shows that the quality constructs possesses the maximum explanatory power. It is
also the most reliable amongst the KPIs. However, all the other KPIs were also found
to have adequate explanatory power of overall project performance. This indicates
that the measurement items across all constructs may be considered as valid and
reliable which may be successfully utilized by the project managers while evaluating
construction projects. The CFA findings of the second order measurement model
reveal that cost is the most important followed by quality whereas safety comes last.
8.1.3 Summary findings regarding CSFs
The procedure of identifying and confirming CSFs was also carried out in three
stages, (literature review, exploratory phase and confirmatory phase), similar to the
stages enumerated in section 8.1.2. A list of 30 variables (shown in table 8.2)
influencing project success was identified based on literature review and discussion
with experts. These variables were subjected to EFA which yielded 27 success
variables loading in six components representing project success namely project
related, client related, consultant related, contractor related, supply chain related
and external environment related factors. Out of the six success factors, client
related, consultant related and contractor related factors are stakeholder based
whereas project related factor is based on project features and characteristics. Supply
chain related factor is based on management processes in terms of sourcing and
delivering of right materials and components in time and external environment
related factor addresses all environmental issues that affect project success. The
relative importance of the six CSFs varies. The results reveal that project related
factor is the most important factor followed by client related factor while contractor
related factor turns out to be the least in order of importance.
The 27-item six factor scale of CSFs was further analysed using CFA which resulted
in 17 item six construct scale of CSFs for CDF construction projects. Table 8.2
summarises the findings of the qualitative analysis, exploratory analysis and the
confirmatory analysis.
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Table 8.2: Summary of the CSFs and success variables in both survey I and survey II. Literature review and discussion with experts (Success Variables)
Exploratory Study (Phase I) Confirmatory Study(Phase II)
SV1: The location and Site conditions did not affect the construction of this project. SV2: Design Complexity of project (Type, size, nature and number of floors) has influenced the project cost and time. SV3: Project planning, Scheduling and control were adequately done on this project SV4: The client secured necessary funds for the project and hence there were no delays in material acquisition and payments to contractor. SV5: The client got the design documents approved on time for this project. SV6: The client had adequate experience on similar kind of projects. SV7: Information sharing and collaboration among project participants were adequate in the current project. SV8: The construction work adhered to the requisite Quality standards. SV9: Continuous monitoring of actual expenditures and project schedules and their comparison with the budget was done regularly. SV10: There was a formal organization structure for dispute resolution within the project organization. SV11: Site Managers possessed requisite skills necessary for the kind of projects executed. SV12: The contractor had adequate technical skills and experience on similar type of projects. SV13: The contractor used latest construction methods in the project. SV14: The community did not raise any social, political or cultural issues against construction of the current project. SV15: The project execution was adversely affected by the surrounding weather and climatic conditions. SV16: Macro- economic conditions (such as interest rates, inflation) did not
Dimension Items Dimension Items Project Related Factor (7)
PSV1: Influence of Design Complexity PSV2: Adhered to the requisite Quality standards. PSV3: Continuous monitoring of actual expenditures. PSV4: Formal dispute resolution structures. PSV5: Effect of location and Site conditions. PSV6: Adequate Information sharing and collaboration. PSV7: Adequate Project planning and, Scheduling.
Project Related Factor (4)
PSV1: Influence of Design Complexity PSV2: Adhered to the requisite Quality standards PSV3: Continuous monitoring of actual expenditures PSV4: Formal dispute resolution structures
Client related factor(5)
CSV1: Adequate experience on similar projects. CSV2: Cheap materials were used. CSV3: Project funds secured on time. CSV4: Client’s emphasis on time rather than quality. CSV5: Design documents approved on time.
Client related factor (3)
CSV2: Cheap materials were used CSV4: Client’s emphasis on time rather than quality CSV5:Design documents approved on time
External environment related factor (6)
ESV1: Community had no issues against the project. ESV2: Adversely affected by the surrounding weather.
External environment related factor (3)
ESV1: Community had no issues against the project ESV2: Adversely
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significantly affect the execution of this project. SV17: The project was affected by the Governance policy of the relevant government agencies which affects project success. SV18: The consultant was highly committed to ensuring construction work according to design specifications. SV19: There were adequate designs, specifications and documentations for the use of contractor. SV20: The client emphasized on completing the current project very fast without any reference to quality. SV21: The client tended to purchase construction materials at cheaper rate which led to the dilution of other project objectives. SV22: No variations in original design took place in the current project during construction phase. SV23: The level of technological sophistication considered in the project was satisfactory. SV24: There were no incidences of disagreements resulting from industrial relations prevailing at the time of project implementation. SV25: The physical and ecological conditions surrounding the project were favourable to project execution. SV26:There were very few internal procurement challenges SV27: The client’s decisions were timely and objective. SV28: Right equipments were available in the construction site of this project. SV29: The project faced stringent insurance and warranty contractual requirements. SV30: Working capital was adequate.
ESV3: Effect of the Governance policy. ESV4: Favourable physical and ecological conditions. ESV5: Effect of Macro- economic conditions. ESV6: No incidences industrial unrests.
affected by the surrounding weather ESV3: Effect of the Governance policy
Supply chain related factor (3)
LSV1:Few internal procurement challenges LSV2: Right equipments were available. LSV3: Effect of stringent insurance/warranty rules.
Supply chain related factor (3)
LSV1: Few internal procurement challenges LV2: Right equipments were available LSV3: Effect of stringent insurance/warranty rules
Consultant related factor (3)
SSV1: No variations were incorporated. SSV2: Adequate designs/specifications and documentations. SSV3: Adequate consultant committed to project.
Consultant related factor (2)
SSV1: No variations were incorporated SSV2: Adequate designs/specifications and documentation
Contractor related factor (3)
RSV1: Site Managers possessed requisite skills. RSV2: Contractor had adequate technical skills. RSV3: Contractor used latest construction methods.
Contractor related factor (2)
RSV1: Site Managers possessed requisite skills RSV2: Contractor had adequate technical skills.
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Testing of the first order measurement model and the second order measurement
model (that includes mediation of external environment related factor) through
appropriate test statistics indicate that both models are acceptable. In the first order
model, some constructs are found to be positively correlated while others are
negatively correlated. For instance, project related construct has positive correlation
with client related construct and negative correlation with environment construct. This
probably indicates that the positive influence of project related factor is accompanied
by the positive influence on client related factor and vice-versa. However, the
influence of project related factor on environment is negative.
The first order model further shows that the project related construct possesses the
maximum explanatory power followed by consultant related construct while the
environment related construct has the minimum explanatory power. Further project
related construct is also has the highest reliability. Similarly the remaining five
constructs were also found to posses adequate scale reliability. This indicates that the
measurement items across all constructs may be considered as valid and reliable
which may be successfully utilized by the project managers for evaluating CSFs of
construction projects.
The second order construct and its relationships with the first order constructs enables
project managers to view the project success at a higher level. Due to this, the model
could reveal patterns of relationships among the constructs which are otherwise not
visible in the first order model. The second order model shows that all the six CSFs
are important in determining the success of CDF construction projects, as shown
through the standardised second order loadings. The external environmental related
factor possess the most influence on project success followed by project related factor
while supply chain related factor has the least influence.
8.1.4 Summary findings regarding the Performance Evaluation Framework
A SEM was developed to evaluate the impact of CSFs on project success. Further, it
was hypothesised that project success is positively associated with overall project
performance which is again expressed in terms of time, cost, quality, safety, site
disputes and environmental impact. The reliability of the twelve constructs and of the
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model was found satisfactory. The GOF indices of the structural model were also
found quite satisfactory. However, not all the path coefficients were significant.
The influence of CSFs on project success
The results indicate that all the CSFs are appropriate success factors for CDF
construction projects since they have high factor loadings that are significant
at 5%. Based on the loadings of these CSFs on project success, it can be stated
that the most important CSF is project-related factor, followed by consultant-
related factor, client-related factor, contractor-related factor, supply chain-
related factor and external environment-related factor in descending order of
importance.
The results of the SEM model also suggest that mediation of external
environment related factor into the relationships between project success and
each of the CSFs is not fully supported.
The association between project success and overall project performance
Given that all the CSFs were found to influence the success of CDF
construction projects, the main challenge facing these projects is still
construction management which is undertaken by the client, consultants and
contractors. The success of construction management is reflected through
overall project performance. The association of project success and overall
project performance was found to be significant and positive indicating that
the two concepts are related in the assessment of project performance.
The relationship between overall project performance and KPIs
Results of SEM indicate that “cost” is the predominant indicator of overall
project performance followed by “quality”, “time” and “site disputes” in that
order. Three of these indicators cost, time and quality are well represented in
the literature on the “iron triangle” and have not been contradicted in the
current study. “Site disputes” being a contemporary measure of performance,
is an addition to the iron triangle emerging from the current study which seeks
to ensure harmony at the construction site (David, 2009; Tabish & Jha, 2011).
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The remaining two performance indicators, safety and environmental impact
were not significant. The reason for this insignificant relationship of safety
with overall project performance seems to be its intangibility. Further, the
outcome of environmental impact of a project becomes evident long after the
construction process is completed. Because of this, it may not occur to the
project stakeholders that a project may have some adverse environmental
impact.
Whereas cost and time performances were positively related to overall project
performance, quality and site disputes performance were negatively related.
8.2 Managerial implications of the findings
The findings of the current study have several implications to the managers and
stakeholders involved in the implementation of public sector construction projects.
Below is a brief description of these implications.
The findings of the study on project characteristics and respondents’
demographic profile imply that some of the project procurement approaches
are more cost effective than others.
The findings of KPIs imply that public sector construction projects can be
evaluated on the basis of six KPIs namely cost, time, quality, site disputes,
safety and environmental impact. The positive and negative relationships
among the KPIs give important insights to the managers to the fact that when
performance on one KPI improves, the performance on the other KPIs might
improve or deteriorate.
The final findings of KPIs also imply that while measuring performance of
public construction projects, project cost is the most important performance
indicator, followed by time, quality and site disputes.
Findings reveal that cost and time performance are positively related to overall
project performance whereas quality and site disputes are negatively related to
overall project performance. This implies that improvement in cost and time
performance will improve overall project performance whereas insistence on
quality and site dispute resolution could undermine overall project
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performance. Therefore project stakeholders consider pursuance of quality as
an effort that requires additional cost and time thereby impacting negatively
on overall project performance.
Further, the findings also imply that while implementing public sector
construction projects, there are six CSFs that influence the success of public
sector construction projects. Project success can therefore, be evaluated on the
basis of each individual success variables which may be used as a check list to
pinpoint areas of weaknesses which may need to be corrected in case of
unsatisfactory performance on a particular item.
Project related factor is relatively more important on success of public sector
construction projects implying that project characteristics are likely to have
significant impact on the project than the remaining factors. Therefore, the
findings provide insights to the managers in terms of how to monitor the
progress of public construction projects based on CSFs.
Further, the inter-correlations amongst three pairs of CSFs imply that project
stakeholders should take a holistic view of CSFs while determining their
influence on project success as one CSF is likely to be associated with another
CSFs
Similarly, the findings imply that project success and overall project
performance are distinct components of a performance evaluation framework.
They are however associated although each is captured through different
constructs.
8.3 Recommendations
The project stakeholders can use this performance evaluation framework to clarify
their understanding of performance of public sector construction projects during
construction and be able to take corrective action in order to improve overall
performance. It is therefore, recommended that project stakeholders should
Consider using those project procurement approaches which are cost effective
in order to avoid cost overrun on the projects.
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Understand the needs of the community through proper involvement of the
representatives of the community and other stakeholders and accordingly
select suitable projects which would cater to their needs.
Understand the urgency of evaluating public sector construction projects on
multi-dimensional performance measures incorporating economic, social and
environmental aspects. Develop appropriate operational metrics to reflect the
three broad dimensions of performance of public sector construction projects.
Develop a holistic performance evaluation framework of public sector
construction projects consisting of the six KPIs with the help of 17 observable
performance related variables.
Allocate considerable amount of resources into the issues relating to project
time, cost, quality and site disputes of public construction projects. This is
because cost, time, quality and site disputes were relatively more important.
On the basis of KPIs, identify the CSFs that are appropriate for attainment of
success on the various KPIs and consider monitoring the progress of public
sector construction projects on the basis of CSFs.
Put more emphasis on project characteristics as they ranked higher in
importance among the CSFs influencing project success. However, the
contractors play an important role in the day-to-day management of the
construction activity. Thus even though the other factors were not ranked as
high as the project related factor, the managers should allocate sufficient
resources to the remaining factors as well which would enable them to
achieve satisfactory success on these CSFs for public sector construction
projects.
Distinguish between successful project implementation and overall project
performance and utilize the framework developed to compare success of
different types of construction projects on different CSFs. Similarly, project
managers could compare overall project performance of different projects
based on specific performance indicators.
8.4 Limitations of the study
The current study suffers from the following limitations
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The responses to the questionnaire were based on perceptions of respondents
regarding the performance measurement variables and project success
variables. However, the frame of mind of the respondents may differ, and
hence, the responses provided are fraught with some element of subjectivity.
Secondly, the study was based on the perceptions of clients, consultants and
contractors but left out the community which actually benefits from the public
sector construction projects and for whom the projects are expected to be
relevant. The study did not consider community satisfaction with project
implemented though this is one of the desired outcomes of public construction
projects.
Further, there could be direct interactions between CSFs and the various KPIs.
The scope of the current study could not allow the researcher to examine such
direct relationships.
Similarly, the data for the development of the measurement instrument was
gathered in one province in Kenya. The prevailing circumstances in Western
province, Kenya could be different from the circumstances in other provinces
in Kenya and other developing countries.
Further these projects are characterized by the involvement of many
stakeholders with varying interests, numerous bureaucratic hassles and of
course, varying political interests, which facilitates corruption. Corruption
which includes bribery, embezzlement, kickbacks and fraud in construction
projects undermines the delivery of infrastructure services. These practices can
lead to increases in cost, extension of time and poor quality of constructed
facilities. The element of corruption has not been included in the present
study.
8.5 Directions for Future Research
This section recommends some potentially useful future research that can address
some of the limitations of this study.
Researchers could undertake a study in performance evaluation from the
perspectives of the community which constitutes the actual beneficiaries of the
173
projects. In such a study, the level of community satisfaction with the projects
implemented can be addressed.
Further future studies can attempt to identify the direct relationship between
the CSFs and KPIs through empirical studies. Also, future studies may
examine moderating factors that may have an effect on the relationship
between CSFs and project success.
Future researchers could advance the current construction project performance
evaluation scale and test its applicability within the context of other
constituencies in different regions in Kenya and those projects in other
developing countries. There is, therefore, an important need to undergo cross-
cultural validation of the instrument using data gathered from other provinces
of Kenya and other developing countries as well in order to enhance the
generalization of items.
Finally, a study incorporating the effect of corruption in performance
evaluation of public sector construction projects is of great importance. This is
because the intended objectives of public sector construction projects can be
properly realised in a corruption free environment. It is a well known fact that
these kinds of projects are severely affected by the scams prevalent in many
countries.
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