126

Ruben Ndihokubwayo & Theo Haupt

Origin – cause matrix: a practical 
approach for identification of waste 
associated with variation orders 

Peer reviewed

Abstract
This article has a two-fold aim, namely of reviewing the literature pertaining to 
waste associated with variation orders and providing a tool for identification of 
waste zones arising from a variation order. Literature was reviewed about the 
administration and waste associated with variation orders. Two case studies for 
the purpose of the study consisted of completed apartment complexes in Cape 
Town. Variation orders on the respective projects were grouped by number and 
value in an origin-cause table. The literature review confirmed the likelihood of 
waste of resources following the occurrence of variation orders. Arguably, the 
excessive occurrence of variation orders was among factors that contributed 
to overall higher construction delivery costs and time overruns. By auditing each 
variation order in terms of the value, origin agent and the cause, it was possi-
ble to identify some project aspects that yielded waste of resources. Typically, 
these were the cost of errors originating from the consultant and the client. The 
origin-cause matrix could be a tool to provide a breakdown of the probable 
magnitude of waste associated with variation orders. The study was confined 
to a limited number of apartment-type construction projects to provide insight 
into the potential impact of variation orders on project performance. The ori-
gin-cause matrix could be a practical tool used to track construction project 
activities that yield waste. The topic discusses issues that have not been widely 
covered by previous research studies. The origin-cause matrix was designed as 
a tool for identification of waste based on a theory of waste formation.

Keywords:  Causes, non value-adding, origin agents, variation orders, waste

Mr Ruben Ndihokubwayo, Junior Researcher, Southern Africa Built Environment 
Research Center (SABERC), Department of Built Environment, Faculty of Engi-
neering, Cape Peninsula University of Technology, P O Box 1906, Bellville, South 
Africa, 7535. Tel.: 021-9596317/6637, Mobile: 0737215859, E-mail: <ndihokub-
wayor@cput.ac.za>

Prof. Theo Haupt, Research Coordinator, Southern Africa Built Environment 
Research Center (SABERC), Department of Built Environment, Faculty of Engi-
neering, Cape Peninsula University of Technology, P O Box 1906, Bellville, South 
Africa, 7535. Tel.: 021-9596845/6637, Mobile: 0824929680, E-mail: <hauptt@cput.
ac.za>

Oorsigartikels • Review articles



Ndihokubwayo & Haupt • Origin — cause matrix: identification of 
waste associated with variation orders

127

Abstrak 
Hierdie artikel het ’n tweeledige doel, naamlik ’n literatuuroorsig oor afval wat 
geassosieer word met wysigingsopdragte, asook die verskaffing van ’n instru-
ment vir die identifisering van afval sones wat onstaan as gevolg van wysig-
ingsopdragte. ‘n Literatuurstudie oor die administrasie van afval as gevolg van 
wysigingsopdragte is gedoen. Twee gevallestudies oor voltooide woonstel-
blokke in Kaapstad is vir die doel van die studie gebruik. Wysigingsopdragte vir 
die onderskeie projekte is groepeer deur nommers en waarde in ’n ontstaan-
oorsprong matriks saam te voeg. Die literatuuroorsig bevestig die waarsky-
nlikheid dat afval van hulpbronne onstaan as gevolg van die voorkoms van 
wysingsopdragte. Argumentsonthalwe, die oortollige voorkoms van wysigings-
opdragte was onder faktore wat bygedra het tot ’n oorhoofse konstruksie 
afleweringskoste asook tydoorskryding. Deur elke wysigingsopdrag te oudit in 
terme van waarde, oorsprong-agent en die oorsprong daarvan, was dit moont-
lik om sommige projek-aspekte te identifiseer wat vermorsing van hulpbronne 
oplewer. Tipies, was hierdie aspekte die koste van foute voortspruitend uit die 
konsultant en kliënt.  Die ontstaan-oorsprong matriks kan ’n instrument wees 
om ’n afbreking van die moontlike grootte van afval geassosieer met wysiging-
sopdragte te verskaf. Die studie is beperk tot ’n aantal woonsteltipe konstruksie 
projekte om insig te verskaf in die potensiële impak van wysigingsopdragte op 
projek-aanbieding. Die ontstaan-oorsprong matriks kan as ’n praktiese instru-
ment gebruik word om konstruksieprojekte aktiwiteite te volg wat afval oplewer. 
Die onderwerp bespreek gevalle wat nie wyd gedek is deur vorige navorsing 
nie. Die ontstaan-oorsprong matriks is ontwerp as ’n instrument vir die identifika-
sie van afval gebaseer op ’n teorie van afvalvorming.

Sleutelwoorde: Oorsake, nie-waardetoevoeging, oorsprong-agente, wysigings-
orders, afval

1. Introduction

A construction contract is a business agreement that is subject to 
variability. Contractual clauses relating to changes allow parties 
involved in the contract to freely initiate variation orders within the 
ambit of the scope of the works without alteration of the original 
contract. Variation orders involve additions, omissions, alterations 
and substitutions in terms of quality, quantity and schedule of works. 
Without contractual clauses, the building contractor would have 
to agree to erect without any change the building shown on the 
drawings and represented in the bills of quantities for a contract 
sum. Ssegawa et al. (2002) argued that the spirit in which variation 
orders are permitted allows the contract to proceed without com-
piling another contract to cater for the changes. Most contracts 
make provision for possible variations given the nature of building 
construction (Finsen, 2005; Wainwright & Wood, 1983). A degree of 
change should be expected since it is difficult for clients to visualise 
the end product they procure (Love, 2002). Unforeseen conditions1 

1 Such as for example adverse ground conditions affecting foundations  which 
become apparent only during excavation.



Acta Structilia 2008: 15(2)

128

may arise which require measures that have not been provided for 
in the contract (Finsen, 2005). 

However, the disadvantage of the variation clause is that architects 
tend not to crystallise their intentions on paper before the contract 
is signed because they know the variation clause will permit them to 
finalise their intentions during the term of the contract (Wainwright 
& Wood, 1983). An unfortunate aspect of the variation clause is that 
it tends to encourage clients to change their minds and embark 
on building projects without having properly thought through their 
project requirements (Finsen, 2005). Traditionally, the clients’ prima 
perceived requirements include functionality, durability and opti-
mality. In order to achieve these requirements, clients appoint 
consultant-teams to advise them on design and optimum use of 
resources. On the other hand, contractors concern themselves pre-
dominantly with construction input costs and their reduction. Little 
recognition is given to the fact that the clients or their agents may 
be sources of higher construction costs. Clients and consultants typi-
cally forget that issuing numerous variation orders result in higher 
construction costs. For example, a client who targets a completion 
date may want works to start on site while the design is still at a 
sketchy stage. In some cases, the construction works may overlap 
the design where the contractor will have to wait for the detailed 
design. As a result, some works are put on hold and others are sub-
ject to abortion or demolition. Arguably, the costs for aborted works 
are wastage of resources and are typically transferred to the client. 
They contribute to higher construction delivery costs. The construc-
tion industry does not grasp that the reduction of the occurrence 
of variation orders may optimally lower construction delivery costs. 
Ibbs (1997) concluded that the greater the amount of change the 
greater the negative impact on both productivity and cost.

2. Categorisation of site instructions

Variation orders are often issued in the form of site or contract instruc-
tions. Consequently, variation orders have rightly or wrongly been 
loosely referred to as site or architect’s instructions. It is unclear from 
the work of various authors and standard forms of contract what 
instructions should be regarded as variation orders or not. Accord-
ing to Uff (2005) disputes often arise as to whether an instruction 
actually constitutes a variation order because the contract is silent 
on a definition of what may constitute a variation. Ssegawa et al. 
(2002) contend that there is no single definition of what a variation 
is. Not all architect’s instructions constitute variation orders such as 



Ndihokubwayo & Haupt • Origin — cause matrix: identification of 
waste associated with variation orders

129

for example, an instruction to remove defective work (Wainwright 
& Wood, 1983; FIDIC, 1999).  The JBCC2 (2005) defines a contract 
instruction as a written instruction signed and issued by or under the 
authority of the principal agent to the contractor. The FIDIC3 (1999) 
general conditions clause 3.3 stipulates that the engineer may issue 
to the contractor instructions and additional or modified drawings 
which may be necessary for the execution of the works and the 
remedying of any defects, all in accordance with the contract. But, 
not all instructions vary the contractual arrangements or the way 
the works are being undertaken. Consequently, some contract 
instructions may be considered as variation orders while others may 
not. It is useful to categorise site instructions on the basis of whether 
they are variation orders or not. With reference to clause 17 (JBCC, 
2005) of the Principal Building Agreement, Finsen (2005) derived five 
categories of contract instructions including:

Instruction to vary the design, quality or quantity of works, for • 
example to carry out an additional work. This is a variation 
order.

Instruction to resolve discrepancies between contract • 
documents, for example to rectify errors. This is a variation 
order.

Instruction to reiterate or enforce contractual provisions, for • 
example to remove from site goods that do not conform to 
original specifications: this is not a variation order. It becomes 
a variation order if incidental to instruction in terms of 
categories 1 and 2.

Instruction to deal with monetary allowance, for example to • 
indicate how to spend money budgeted under prime cost: 
this is not a variation order. It becomes a variation order if 
incidental to instruction in terms of categories 1 and 2.

Instruction to protect the client’s interest, for example to • 
remove from site camp a worker that constitutes a nuisance. 
This is not a variation order at all.

2 The Joint Building Contracts Committee 
3 FIDIC is a French acronym that stands for Fédération Internationale des Ingénieurs-

Conseils interpreted in English as International Federation of Consulting Engineers



Acta Structilia 2008: 15(2)

130

3. Nature of variation orders

The nature of variation orders can be determined by referring to 
both the reasons for their occurrence and subsequent effects. Arain 
& Pheng (2005) distinguished two types of variation orders, namely 
beneficial and detrimental variation orders.

3.1 Beneficial variation orders

A beneficial variation order is one issued to improve the quality 
standard, reduce cost, schedule, or degree of difficulty in a project 
(Arain & Pheng, 2005). It is a variation order initiated for value anal-
ysis purposes to realise a balance between the cost, functionality 
and durability aspects of a project to the satisfaction of the client. 
A beneficial variation order eliminates unnecessary costs from a 
project; and as a result, it optimises the client’s benefits against the 
resource input by eliminating unnecessary costs. However, it should 
be noted that regardless of how beneficial a variation order might 
be, non value-adding costs are likely to accrue as a result. For exam-
ple, a variation order to solve the discrepancies between contract 
documents involves the abortion of works that have already been 
executed. Cost for aborted works should not have been incurred if 
discrepancies were not found between contract documents.

3.2 Detrimental variation orders

A detrimental variation order is one that negatively impacts the cli-
ent’s value or project performance (Arain & Pheng, 2005). Arguably, 
a detrimental variation order compromises the client’s value system.  
A client who is experiencing financial problems may require the sub-
stitution of quality standard expensive materials to sub-standard 
cheap materials. For example, on a construction project situated in 
a salty environment, steel window frames result in steel oxidation if 
selected in lieu of timber or aluminium frames.

4. Waste associated with variation orders

4.1 Concept of waste vis-à-vis variability

The paradigm of waste as used in construction has various mean-
ings depending on one’s point of view. Very often, waste has been 
referred to as physical losses of material occurring during the con-
struction process. According to Formoso et al. (1999) most studies on 
waste are based on the conversion model where material losses are 
considered to be synonymous to waste. Waste is defined as: 



Ndihokubwayo & Haupt • Origin — cause matrix: identification of 
waste associated with variation orders

131

any inefficiency that results in the use of equipment, materi-
als, labour, or capital in larger quantity than those considered 
as necessary in the production of the building. (Formoso et 
al.,1999: p. 325)

However, it should be understood that the contractor recognises 
allowable waste as the percentage for losses of material allocated 
to bill rate components by the estimator at tender stage and it varies 
from one material to another. Unfortunately the existing estimating 
and contract valuation techniques do not provide a clear break-
down of losses of materials resulting from variation orders. For exam-
ple, cement that hardens in the stores following a variation order 
to suspend works is not allocated to the variation order account. 
Waste of materials resulting from the occurrence of variation orders 
may, for example, emanate from the following circumstances: 

Compensating waste arising when material ordered for one • 
specific purpose is used for another. For example, facing bricks 
ordered for external wall erection may be used for internal 
plastered walls when there is a shortage of common bricks.

Waste due to the uneconomic use of plant arising when the • 
plant lies idle on site as a result of a variation order. Saukkoriipi & 
Josephson (2006) estimated the waste for non-productive use 
of resources at more than 10% of a project’s production cost.

Waste of materials due to incorrect decisions, indecision or • 
inconsistent inspection of works by the project consultant.

Waste of materials after demolition of a portion of work caused • 
by the variation order to change a trade. For example waste 
for breaking down a wall to accommodate a new door.

Waste due to the wrong use of material or waste stemming • 
from materials wrongly specified.

Other authors have defined waste as being not only physical losses 
of materials. Al-Hakim (2005) defined waste as anything that adds 
no value to producing the required services. The understanding 
of waste would require an explanation of what value-adding and 
non value-adding activities are. An activity is value-adding if it is 
judged to contribute to customer value or satisfy an organisational 
need (Tsai, 1998). From the perspective of the client, Saukkoriipi 
(2005) defined non-value adding activities as those which absorb 
resources without adding value to the customer. The value consists 
of two components, namely production performance and freedom 
from defects (Koskela, 1992). The production of services requires 
resources and flow of activities over a certain portion of time. 



Acta Structilia 2008: 15(2)

132

According to Koskela (1992), the 4philosophy of production consists 
of both conversion and flows. Since only conversions add value, the 
improvement of flow activities should primarily be focused on reduc-
ing or eliminating them, whereas conversion activities have to be 
made more efficient. Therefore, waste reduction is enhanced by 
avoiding flow variability. In construction terms this refers to avoiding 
excessive occurrence of variation orders.

4.2 Identification of the origin agent, causes and cost of 
variation orders

While most construction industry stakeholders are arguably inter-
ested in the reduction of overall production costs, they are not 
always aware of the extent of non-value adding activities on con-
struction projects (Saukkoriipi, 2005). Consequently, there is a lack of 
knowledge about non value-adding costs associated with variation 
orders. The realistic quantification of such costs is problematic due 
to lack of appropriate techniques for their measurement. In com-
mon practice, non value-adding costs arising from variation orders 
that are typically transferred to the client are underestimated. For 
example, one may be able to calculate the costs of aborted works, 
but non value-adding costs arising from non-productive time, rede-
sign and overheads are not attributed to such an activity. Very 
often these costs are unknowingly transferred under the account of 
contingencies. 

It is necessary to uncover non value-adding activities arising from 
variation orders in order to take proactive measures to reduce them. 
The reason for variation orders and the magnitude of the associated 
non value-adding costs should be known. A clearer understanding 
of variation orders and subsequent waste might be possible if they 
are categorised by their origin and identification of possible waste 
zones. Koskela (2000) suggested a framework of the formation for 
waste and value loss that takes into account the following, namely:

Waste and value loss;• 

Factors causing loss; and• 

Root causes.• 

Every time a task is divided into two subtasks executed by differ-
ent specialists, non value-adding activities increase, such as, for 

4 Philosophy of production refers to an evolving set of methodologies  techniques 
and tools  the genesis of which was in the Japanese JIT (Just In Time) and TQC (Total 
Quality Costs) effort in car manufacturing (Koskela  1992)



Ndihokubwayo & Haupt • Origin — cause matrix: identification of 
waste associated with variation orders

133

example, inspecting, moving and waiting (Koskela, 2000). Similarly, 
when a variation order is issued, numerous non value-adding activi-
ties/costs are likely to arise. These include travelling and commu-
nication expenses; idle plant and labour during the waiting time, 
demolitions, time taken by the designer to understand the required 
change and redesign; cost and time for litigation in case the misun-
derstanding arises between the contractor and the client or his/her 
consultant. These represent a waste of resources and are typically 
paid for by the client. In addition, a delay of the consultant to issue 
an appropriate instruction may result in remedial works. Acharya 
et al. (2006) suggested that consultants should aim at getting an 
understanding of the overall scope and goals of the project, make 
sure they understand deliverables and offer specific suggestions 
when they makes sense; and do all relatively quickly without having 
negative effect on productivity. Furthermore, a lack of judgment 
and experience of the designer contributes to errors and omissions 
in the design. However, factors influencing the occurrence of varia-
tion orders and their adverse impact on project performance vary 
from one project to another. Factors include the nature of works, 
the complexity of the project, procurement method and complete-
ness of design before the works commence on site. Studies revealed 
a significant reduction in both cost increase and time delay as a 
result of a complete design before commencement of works on 
site; hence, the prevention of the likelihood occurrence of variation 
orders (Koushki et al., 2005). 

Variation orders can be avoided if their origin and causes were 
clearly known (Mohamed, 2001). The identification of the originat-
ing root involves identification of the initiator of a variation order. 
Arain & Pheng (2006) identified four origin agents of variation orders. 
These included ‘client’, ‘consultant’, ‘contractor’ and ‘others’. It is 
also important to know what could be the reason for a variation 
order to be issued. A classification of categories/types rework (Love 
& Sohal, 2003) revealed the following causes or the circumstances 
under which variation orders could be initiated, namely:

Design changes which arise from the client/consultant, • 
contractor, occupier and supplier/manufacturer or change 
initiated for improvement purpose.

Design errors which are mistakes made in the design.• 

Design omissions which arise when an item or component is • 
omitted from the design.



Acta Structilia 2008: 15(2)

134

Construction changes which are initiated to improve • 
constructability or due to site conditions. Change may be 
made by the client, the consultant or the occupier after some 
work has been performed on site. Change may be made if 
the process or product needs` to be altered/rectified or if 
there is a need to improve quality. 

Construction errors which are the result of erroneous • 
construction methods procedures.

Construction omission which are those activities that occur • 
due to omission of some activities during the construction.

Damage caused by accident or inclement weather.• 

5. Scope of the study

The study is being undertaken in South Africa that is currently expe-
riencing an unprecedented construction boom. While existing infra-
structure and buildings are upgraded the backlog in housing and 
infrastructure delivery, the deficit of skills, the high construction deliv-
ery costs and quality standards related problems are current chal-
lenges faced by the construction industry. There is growing concern 
about rising construction delivery costs. Recently, studies have been 
done in Sweden to investigate the existence of non value-adding 
(waste) activities in all phases of construction that resultantly give rise 
to increases in construction costs. The study reported in this article is 
similar given that it seeks to uncover waste within various activities/
practice in construction projects. The study is confined to variation 
orders, an area that has not been widely researched.

6. Methodology

In order to identify waste formation zones, the framework suggested 
under the literature review was considered. Each variation order was 
audited in terms of three parameters, namely value of the loss, root 
causes and factors causing loss. This was made possible by design-
ing an origin-causes matrix as illustrated in Table 1. Row A, B, C, etc. 
contain the costs of variation orders as per origin agent and column 
1, 2, 3, etc. contain the costs of variation orders as per causes. The 
shaded areas represent the variation orders that are prone to waste. 
For example, by assuming that column 2 represents construction 
error and column 5 represents damage, the magnitude of waste is 
then calculated as follows: (A;2) + (C;2) + (C;5). 



Ndihokubwayo & Haupt • Origin — cause matrix: identification of 
waste associated with variation orders

135

Table 1:  Illustration of waste zones of variation orders 

(Origin - cause)
Causes

Total
1 2 3 4 5 …

Origin 
agents

A Xx Xx Xx XX

B xx Xx XX

C xx Xx Xx XX

… xx Xx XX

Total XX XX XX XX XX XX

7. Findings and discussions

7.1 Projects particulars

Primary data was obtained from a reputable cost consultant com-
pany in South Africa. A comparative analysis of cost of variation 
orders was done on two completed apartment complexes; a residen-
tial apartment hereby known as project A and shopping apartment 
hereby known as project B. Records including short descriptions, mon-
etary values, the initiator and reasons for the variation were captured 
from the variation order files. The occurrence of variation orders were 
first grouped by number and secondly by value. Variation orders were 
recorded in a table according to the four origin agents and seven 
causes of variations identified from the literature. The origin agents 
included the ‘client’, the ‘consultant’, the ‘contractor’ and ‘oth-
ers’. In this context, ‘client’ included the development initiator and 
occupiers/tenants who financed the projects. ‘Consultant’ included 
the whole professional team that represented the client. ‘Contrac-
tor’ included the main contractor and his subcontractors. ‘Others’ 
included weather conditions, state regulations or any other condi-
tions beyond control of either party to the contract. The seven causes 
included design change, design error, design omission, construction 
change, construction error, construction omission and damage. Addi-
tional preliminaries costs were added as an eighth column. 

The tender sum for project A was R28,315,000 and the original 
planned works duration was 9 months. The tender sum for project 
B was R61,617,996 and the original planned works duration was 11 
months. In total, 75 and 118 variation orders occurred on respec-
tive projects A and B. On project A, there were numerous additional 
works associated with the continuously revised electrical works. The 
reinforcement for concrete slabs changed from post-tensioned 
to conventional rebar. As the contractor could not finish on agreed 



Acta Structilia 2008: 15(2)

136

time, the extension of time of 25 days was granted. Unfortunately, due 
to a further failure to complete works during the revised completion 
period, the contractor was charged a penalty of R13,000 per day total-
ling R923,000 in 71 days above the extended period. Penalty charge 
amount was 3% of the contract sum and the actual completion period 
was 12 months with an escalation of 33% above the original time 
schedule. While there could be other factors that contributed to time 
escalation, it is argued that numerous changes to electrical works con-
tributed to delays where the contractor might have failed to justify at 
which extend his productivity and progress were effected. On project 
B, the contractor was granted an extension of time of 26 days which is 
a time overrun of 9% over the planned works duration. No penalty was 
charged to the contractor and the consultant’s records did not show 
in detail the reason behind such an extension. 

Figure 1: Origin agents of variation orders

7.1.1 Variation order occurrence

Figure 2: Causes of variation orders

0%
10%
20%
30%
40%
50%
60%
70%
80%
90%

13%
23%

80%
69%

0% 1%
8%7%

A. Client B. Consultant C. Contractor D. Others

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Project A Project B

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20%

40%

60%

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1. 
Design 

change

2. 
Design 
error

3. 
Design 

omission

4. 
Constr. 

change

5. 
Constr. 
error

6. 
Constr. 

omission

7. 
Damage

8. 
Add. 
P&Cs

Project A Project B



Ndihokubwayo & Haupt • Origin — cause matrix: identification of 
waste associated with variation orders

137

Figure 1 shows the percentage of the value of origin agents of vari-
ation orders. For example, on both projects A and B, the consult-
ant was the most predominant origin agent who produced 80% 
(R1,658,589) and 69% (R1,404,500) of the net total sum of variation 
orders. Figure 2 shows the percentage of the value of causes of vari-
ation orders. On both projects A and B, the design change was the 
most predominant cause of variation orders that amounted to 86% 
(R1,784,634) and 67% (R1,363,394) of the net total sum of variation 
orders.  The value of errors and damage is provided for both respec-
tive projects are clearly shown. Unfortunately, the chart does not 
reveal the exact originating agent. Therefore, this will be possible 
by means of tables that clearly show at the same time parame-
ters including monetary value, origin agent and causes of variation 
orders. 

7.2 Identification of waste zones

Table 2 and 3 record the variation orders that occurred on projects A 
and B. The origin-cause matrix clearly shows the number and value 
corresponding at each couple origin-cause. It was possible to iden-
tify variation orders that were likely to generate waste. On project 
A, the cost of the design errors resulting from the consultant (B;2) 
was 4% (R83,360) of the net total sum. These were costs for remedial 
works to imported joinery as a result of inefficiency in design co-ordi-
nation and repair that was done on electrical cables and conduits 
damaged. It is argued that costs for demolition of erected works 
due to design error constitute waste of resources. The construction 
cost for construction error resulting from the contractor (C;5) was 
0.18% (R3,738). Instruction was issued to repair damage done by the 
contractor (C;7) to neighbouring building during demolition works; 
but the works were not yet executed and subsequent cost was not 
provided. On project B, the cost of design errors resulting from the 
consultant (B;2) was 4% (R82,135) of the net total sum of variation 
orders and the cost resulting from the construction error of the con-
tractor (C;5) was 1% (R12,395). The combination of the cost of errors 
originating from the consultant and the contractor amounted to 5% 
(R94,530) of the net total sum of variation orders. It was revealed 
that the consultant and the contractor had generated situations 
that yielded waste. No waste arose from unspecified ‘others’. The 
question is to know who pays for such costs. In most cases, these 
are transferred to the account of the client and as a consequence, 
construction delivery cost increased. 



Acta Structilia 2008: 15(2)

138

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Acta Structilia 2008: 15(2)

140

8. Conclusions

The review of the literature revealed that variation orders were likely 
to occur on construction projects since these are permitted under 
contractual agreements. Variation orders cannot be avoided com-
pletely since construction works involve complex operations that 
cannot be accurately determined in advance. It was argued that 
whenever a variation order is issued unnecessary costs could likely 
occur. These constituted waste of resources and as a result they 
contributed to higher construction delivery costs.  

A comparative study was done on two apartment complexes. A total 
number of 75 and 118 variation orders averaging 8% (R2,076,600) and 
4% (R2,032,919) of the contract sum (R28,315,000 and R61,617,996) 
occurred on respective projects A and B. It is argued that numerous 
variation orders on both projects contributed to time overruns and 
had potentially contributed to waste. Both projects A and B incurred 
delays and time for completion escalated at 33% and 9% over the 
original completion time. On project A, a contractor was charge a 
penalty of 3% (R923,000) of the original contract sum. Arguably, the 
numerous variation orders contributed to delays where the contrac-
tor might have failed to properly justify at which extent his produc-
tivity and progress were affected. However, there might be other 
factors beyond the scope of this study that contributed to delays. 

By auditing each variation order in terms of the value, origin agent 
and the cause, it was possible to identify that variation orders were 
likely to generate waste. On project A, the cost of the error origi-
nating from the consultant and the client was 4% (R87,098) of the 
total net sum (R2,076,600). On project B, the combination of the cost 
of error originating from the consultant and the contractor was 5% 
(R94,530) of the net total sum of variation orders (R2,032,919). The 
origin-cause matrix proved to be an efficient tool that provided a 
breakdown of uncovering the probable magnitude of waste associ-
ated with variation orders.

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