Viewpoint 

Perceived Benefits of Adopting Standard – Based 
Pricing Mechanism for Mechanical and Electrical 
Services Installations 

Ganiyu Amuda Yusuf and Sarajul Fikri Mohamed, (Universiti Teknologi Malaysia, 
Malaysia) 

 
 
 

Abstract  
Cost is an important measure of project success and clients will expect a reliable forecast at the 
early stage of construction projects to inform their business decision. This study was undertaken 
to investigate the current practices in managing cost of mechanical and electrical (M&E) 
services in buildings. The perceptions of practitioners on the benefits of adopting Standard – 
Based Pricing Mechanism for M&E services as used for building fabrics and finishes was 
ascertained. The methodology adopted for the study was semi – structure interview and 
questionnaire survey. Inferential statistics technique was used to analyse the data collected. The 
results revealed that, M&E services tender documents are often based on lump sum contract. 
Practitioners are of the opinion that the adoption of Standard – Based Pricing Mechanism 
(SBPM) could enhance the quality of M&E services price forecasts; ensure active post contract 
cost monitoring and control; encourage collaborative working relationship; enhance efficient 
whole life cycle cost management; improve risk management and facilitate an efficient tendering 
process. The study suggested the development of local Standard Method of Measurement for 
M&E services and proposed strategies to facilitate the adoption of SBPM as basis for 
forecasting contract price of mechanical and electrical services in buildings. 
 
Keywords: Building fabrics, Forecast, Mechanical and Electrical services, Standard Method of 
Measurement, Standard-Based Pricing Mechanism 

 

Introduction 
The measurement of project success is subjective, but there seems to be a general agreement 
among researchers that a project is deemed successful if it meets clients’ value criteria of time, 
cost and quality. Therefore, the principal activity of quantity surveyors at the early stage of 
construction projects is to establish the probable cost of such project and advice the client on 
cost – quality criteria (Bowen & Edwards, 1996). However, the price determined at this early 
stage of construction projects forms the basis of the contract sum and is the amount established 
for the project which is not expected to be exceeded (Flanagan & Tate, 1997). Therefore, the 
forecast should incorporate both foreseen and unforeseen costs needed for the achievement of 
clients’ value criteria, (Flanagan & Tate, 1997; Ling & Boo, 2001). The value of the cost advice 
given by the quantity surveyor at this stage is the reliability of the cost estimates (Swaffield & 
Pasquire, Improving Early Cost Advice for Mechanical and Electrical Services RICS Foundation 
Research Papers; 3 No.15, 2000), as this will provide real opportunities to add value to clients’ 
business decisions and, the client will expect nothing but a reliable assessment of anticipated 
project value which will aid strategic decision making (Fortune & Cox, 2005). 
 
Effective cost management of M&E services in buildings is highly desirable by industry 
stakeholders because of its significance and increasing complexity in modern buildings, which 
have tremendously impacted its relative cost to the total cost of building projects (Davis 
Langdon, 2010). However, cost advice on this element of buildings has historically been 
neglected by quantity surveyors because it was regarded as a specialist element, therefore, 



 

Australasian Journal of Construction Economics and Building 

Amuda Yusuf, G and Mohamed, S F (2014) ‘Perceived benefits of adopting standard – Based pricing mechanism for 
mechanical and electrical services installations’, Australasian Journal of Construction Economics and Building, 14 (2) 104-
119  

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quantity surveyors only manage cost of building fabrics and finishes while engineers manage 
cost of M&E services (McCaffrey, 2011). There has been increasing demand for specialist 
quantity surveyors to take charge of the cost management of M&E services as a result of its 
increasing complexity and cost sensitivity (Rawlison, Nugent, & Dedman, 2007). Industry 
stakeholders in the Malaysian Construction Industry have expressed concern on the cost 
management of M&E services as practitioners often used the traditional approach and there is 
no uniformity in the methods adopted in preparing BoQ for building services (CIDB, 2009; 
Amuda Yusuf, Mohamed, & Remeli, 2013a). This approach has been observed to be 
unsatisfactory and can lead to an unbalanced contract, as the BoQ may not be comprehensive 
enough so that the contractor must re-check for any omitted items, requiring more time and 
resources to carry out detail measurement (Flanagan & Tate, 1997; Molloy, 2007; Potts K. , 
2008).  
 
It is established that there has been no empirically based work reported that considered the 
adoption of detail rules of SMM for forecasting price of M&E services in the context of Malaysian 
Construction Industry. Therefore, this study is set out to investigate current budget estimating 
practices and determine the potential benefits of adopting the rules of SMM in forecasting M&E 
services contract price. The study is divided into six sections with the introduction, followed by 
review of relevant literature on traditional building price forecasting process and the problems 
associated with M&E services price estimating as well as the importance of SBPM. The method 
adopted for this research is described in section three while section four is data analysis and 
discussion of results. Sections five and six comprises of strategies to encourage practitioners to 
adopt SBPM for M&E services and conclusions respectively. 
 

Literature Review 
Forecasting Contract Price of Building Fabrics, Finishes and M&E Services 
Measurement is central to the financial management of construction projects and it involves the 
Quantity Surveyors in measuring different types of work as shown on the drawings produced by 
the architect or engineer (Oforeh E. , 2008). The quantities are prepared in line with the rules of 
accepted SMM and the tender document prepared is referred to as BoQ. The completed BoQ is 
normally forwarded along with other documents for the contractor to price (Hore, Kehoe, 
Macmullan., & Penton, 1997). The bill items measure the quantity in suitable physical units, 
such as cubic meters, enumeration and linear meters in line with detailed rules of the Standard 
Method of Measurement in use in the locality. The completed BoQ is normally forwarded along 
with other documents for the contractors to price. This process is referred to as Standard-Based 
Pricing Mechanism (SBPM) in the context of this study. However, this approach is only adopted 
for building fabrics and finishes by quantity surveyors. While prime costs sums are allowed for 
specialist works  because they are not designed by the architect such as lifts, heating systems, 
air-conditioning systems and electricity supply systems; whereas provisional sums are allowed 
for works which cannot be adequately defined and quantified at the time of preparing tender 
documents such as substructure (Murray, 1997). However, all works covered by prime cost sum 
and provisional sums are appropriately adjusted at post contract stage when more design 
information are available.  
 
The resulting estimate from this exercise usually forms the basis for price indices, compiled and 
used as historical cost data for future projects of similar characteristics either by individual 
organizations (cost data bank) or regulatory bodies like the Building Cost Information Service 
(BCIS). However, except for plumbing work, all mechanical and electrical service items 
including comfort cooling, heating systems, lighting, electrical supply systems, lifts, and fire 
detection systems are not measured in the index because mechanical and electrical services 



 

Australasian Journal of Construction Economics and Building 

Amuda Yusuf, G and Mohamed, S F (2014) ‘Perceived benefits of adopting standard – Based pricing mechanism for 
mechanical and electrical services installations’, Australasian Journal of Construction Economics and Building, 14 (2) 104-
119  

106 

are usually included as lump sums in BoQ. The lump sums allowed in the BoQs for M&E 
services are often determined by consultants based on the gross floor area from previous 
building projects (Swaffield & Pasquire, 1996) single purpose deterministic estimate (Mok, 
Tummala, & Leung, 1997) statistical and historical cost data (Nanayakkahara & Fitzsimmons, 
1999), building forms and functions (Swaffield & Pasquire, Examination of Relationships 
Between Building Forms and Function and the cost of Mechanical and Electrical Services., 
1999). The resultant estimates and cost plans used were not often based on projects with M&E 
services of similar performance and aesthetic standards, as this information may not be 
identifiable from historic information (Swaffield & Pasquire, Improving Early Cost Advice for 
Mechanical and Electrical Services RICS Foundation Research Papers; 3 No.15, 2000). The 
problems with this method of forecasting cost of M&E services are well researched. Swaffield & 
Pasquire (1996) examined the method used for the production of budget estimate for M&E 
services by assessing the ease of use and appropriateness of historic cost data for engineering 
services. They found that the current method of budget estimating for building structure and 
fabric is not appropriate for M&E services and there is need for a better understanding of the 
factors that affect the cost of engineering services. 
 
Similarly, Mok et.al (1997) studied early–price estimation practices in Hong Kong and described 
the method used by building services engineers as single–figure deterministic estimate. They go 
on to state that the approach is illogical, cost ineffective and reactionary in nature and therefore 
inadequate for M&E services project. Mok et.al (1997) proposed risk management processes as 
a logical and consistent approach of identifying and making appropriate allowances for risk 
factors in M&E services cost estimation process. However, the study did not provide information 
about specific practices and how the process could be applied to effectively manage cost of 
M&E services in building projects. According to James (Fortune & Lees, 1999), single price rate 
approximate estimating could only be applied to determine the early price of only the building 
fabrics and finishes, they are not suitable for site works, special foundations and building 
services. He further stated that, the cost of building services are rarely constant between one 
project and another and is therefore a matter which requires separate attention when preparing 
budget estimate. 
 
In a seminal work by Nanayakkahara & Fitzsimmons (1999), they developed cost benchmark for 
buildings services in United Kingdom and examined some of the methods used in forecasting 
contract price of M&E services and stated that the historical and statistical cost information 
generally used for M&E services cost estimate lacks quality and consistency as costs are 
normally averages for similar installations but derived from projects with different attributes; the 
cost information available from tenders is generally related to the type of product rather than its 
quality and effectiveness of the management process responsible for developing it; published 
cost information does not normally identify the costs of project organization and administration, 
the design process and project management and their impact on construction cost and therefore 
not suitable for predicting cost of M&E services.  
 
McCaffrey, (2011)outlines the role of the mechanical and electrical services quantity surveyors 
and observed that, the traditional practices where quantity surveyors are only responsible for 
the building structure and finishes and the consulting M&E engineers control cost of M&E 
services failed because M&E costs fall through the gap and are not properly managed. It has 
been observed that the traditional practices by quantity surveyors were partly because there 
was an interface problem between the knowledge base and skill of quantity surveyors and the 
technologies associated with M&E services (Swaffield & Pasquire, Improving Early Cost Advice 
for Mechanical and Electrical Services RICS Foundation Research Papers; 3 No.15, 2000). 



 

Australasian Journal of Construction Economics and Building 

Amuda Yusuf, G and Mohamed, S F (2014) ‘Perceived benefits of adopting standard – Based pricing mechanism for 
mechanical and electrical services installations’, Australasian Journal of Construction Economics and Building, 14 (2) 104-
119  

107 

Furthermore, Swaffield & Pasquire (2000) proposed a method of analysing the quality of M&E 
services in a way that could be understood by quantity surveyors. They suggested that if the 
method is adopted it would bridge the gap between quantity surveyors’ knowledge and M&E 
services technology, enable more detailed analysis of M&E service costs, facilitate the collection 
of more appropriate historic cost information and enable quantity surveyors to make better use 
of M&E services information. However, the method proposed by Swaffield & Pasquire (2000) 
could not be applied to test its reliability because the tender documents collected and analyzed 
were prepared by specialist contractors and are not prepared based on a uniform method hence 
they could not reconcile the information contained in the various documents for the purpose of 
further analysis. 
 

Standard – Based Pricing Mechanism (SBPM) 
The major cost decisions on construction project are made at the early stages of design 
development when little information is available for computing estimates. However, more 
information are made available as design progresses which could lead to more reliable 
estimate, but the highly important decision made based on unreliable estimates are often 
difficult to reverse (Skitmore & Thomas Ng, 2003). Fortune (Fortune & Lees, 1999) stated that 
enhancing the quality of building project price forecasts will increase the level of clients’ 
satisfaction with the services provided by design team professionals. Fortune (Fortune & Cox, 
2005) pointed out that practitioners often evaluated forecasting models on single criterion of the 
perceived level of model output accuracy. They comment that accuracy cannot be considered 
as the sole criterion of forecasting model selection process as it was not necessarily only the 
product of the model that needed to be evaluated. According to Fortune (Fortune & Lees, 1999), 
the quality of building price forecast is also affected by both the technical formulation of the price 
forecast itself and the human processes involved with the interpretation and transmission of the 
price forecast to clients.  
 
Therefore, to improve the quality of price forecast advice given by cost consultants, it is 
essential to consider enhancement of the process itself. In order to improve the process of 
producing building project price forecast given at the early stages of design development, 
(Skitmore M. , 1991) suggested the developing of entirely new estimating techniques or using 
detailed estimating techniques (e.g. BoQ) in the earlier design stages. Quantity based methods 
of pre –contract price determination may have to serve until better methods are available, but 
they should be used with all possible skill and judgment. Although, quantity based costing 
method may not be suitable for design advise but the method remain the most reliable tools 
available because it is more suitable for forecasting the cost of a whole design. Olatunji et.al 
(2010) argued that, until electronically generated design drawings can create consistent 
information suitable to be priced by contractors, the skill of quantification measurement from 
drawings will remain important. In fact, the measurement of BoQ for M&E services is increasing 
due to the rising and significant proportion of building cost that can be represented by these 
services. 
 

Research Methodology 
The study started with a review of relevant literature which includes materials from textbooks, 
journals, magazines, government and government agencies reports, conference proceedings 
and web trawl. The objective of the literature review was to develop an overall framework for the 
research study and to prepare for the questionnaire survey. This was followed by a study of 
secondary data and interview of practitioners in the industry.  
 



 

Australasian Journal of Construction Economics and Building 

Amuda Yusuf, G and Mohamed, S F (2014) ‘Perceived benefits of adopting standard – Based pricing mechanism for 
mechanical and electrical services installations’, Australasian Journal of Construction Economics and Building, 14 (2) 104-
119  

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The study was conducted in two stages. The first stage was conducted through analysis of 
secondary data. Data were obtained from past bills of quantities of M&E services projects in 
Southern Peninsular Malaysia and semi structured interview of practitioners involved on the 
project was conducted (this part of the study is not reported in this paper). The second stage of 
the study was conducted using the quantitative method through a questionnaire survey in order 
to get information from a larger population, as the goal of built environment research is the 
development of theory through explanatory rather than creation of generalizations (Fellows & 
Liu, 2008). Therefore, a qualitative method could be integrated with a quantitative approach to 
achieve results on the issues being examined, the people to be studied, and the changes that 
are needed (Amaratunga, Baldry, Sarshar, & Newton, 2002).  
 
It is considered that, qualitative approach is appropriate to investigate the current method of 
measuring M&E services by examining practitioners in the industry and review of related 
contract documents through document review and semi-structured interview. Quantitative 
strategy assisted in getting more information from industry wide practitioners about their views, 
on the current practices and the potentials of adopting SBPM. This was achieved through 
structured questionnaire survey. In addition, qualitative methods were adopted to give general 
explanations of the survey results and their relationships with the research aims and objectives. 
This is in line with the claim that mixed method approach can compensate for the strength and 
weaknesses inherent in each of the methods (Amaratunga, Baldry, Sarshar, & Newton, 2002). 
 

Questionnaire Survey 
The survey questionnaire was designed by incorporating the benefits of SBPM as identified 
from literature. A total of 14 perceived benefits of SBPM identified in literature formed the basis 
of the survey. A pilot study was conducted among the industry experts and this assisted in 
enhancing the quality and appropriateness of questions posed. The targeted practitioners are 
Architects, Quantity surveyors, Electrical and Mechanical engineers and Structural engineers 
working in clients, consultancy, contracting and multidisciplinary types of organizations. A total 
of 375 questionnaires were distributed by means of both postal and e-mail. Follow –up 
communication through email, telephone and visits to the respondents’ offices lead to the return 
of 167 questionnaires which represents about 45 per cent of questionnaire sent out. 4 of the 
questions were not properly filled therefore could not be analysed. Therefore analysis of result 
was based on 163 valid questionnaire returned. Respondent were requested to rate their 
responses on a 5 points Likert scale from 1 = strongly disagree, 2 = disagree, 3 = moderately 
agree, 4 = agree and 5 = strongly agree. 
 

Data Analysis and Discussions 
Profile of Respondent 
All respondents are well experienced and are professionals in the construction industry. Only 9 
per cent of the respondents have experience ranging between 6 to 10 years, the remaining 91 
per cent have experience between 11 to 20 years and above. Therefore, their opinions to 
survey questions are considered reliable and appropriate for this study. 
 

Documents used for M&E Services Tender 
Respondents were requested to select from a list of three options, the type of documents used 
to invite bid for M&E services contract. Only 21 per cent indicated the use of detail bill of 
quantities, 66 per cent selected Lump sum and the remaining 13 per cent indicated that 
drawings and schedule of rates are used. This result showed that M&E services tenders are 
often invited based on lump sum tender documents. The result is in line with the findings in the 
secondary data reviewed during the first phase of this research. However, it is worth mentioning 



 

Australasian Journal of Construction Economics and Building 

Amuda Yusuf, G and Mohamed, S F (2014) ‘Perceived benefits of adopting standard – Based pricing mechanism for 
mechanical and electrical services installations’, Australasian Journal of Construction Economics and Building, 14 (2) 104-
119  

109 

that, what is referred to as detail BoQ is an equivalent of approximate quantities used at the 
preliminary stage of the building projects where three to four items are combined and described 
together without reference to any standard documents. For example, underground cables were 
only described, without reference to excavation, nature of ground to be excavated, the kind of 
backfilling materials and specification of underground cable protection. Another example is 
where cables are to be drawn in trunking and cables trays, only cables are usually properly 
specified. The type of materials for cable trays and trunking, necessary support required, 
receiving backgrounds and accessories are often neglected for contractors to decide, moreover, 
these items could be made from materials of different quality and prices (e.g cast iron, 
galvanized steel etc). In addition, preamble section of the BoQ often contain provisions such as  
 

the sub – contractor shall provide all materials fittings or perform any work necessary for 
the proper installation of the work … even though such materials or work may not be 
explicitly mentioned in the specification or shown in the drawings… 

 
According to Rawlinson & Dedman (2010) this type of provisions will safeguard the employer 
from being held accountable to the contractor for any inaccuracies in tender documents. 
However, Molloy (2007) opined that such provisions are “short – sighted in the extreme and 
serve only to destroy the primary functions of BoQ”. Molloy further argued that if the engineer 
does not know for certain what is allowed for in each rate, how can he use those rates for the 
valuation of variations? Similarly, if one of the “deemed included” item is omitted how can such 
omission be valued?  
 

Estimating Method used for M&E Services 
The most popular estimating method used during the design phase was found to be superficial 
area method (72 per cent), this is followed by unit method (10 per cent) and approximates 
quantities (7), the least used method is standard – based detail measurement (5 per cent) 
followed by elemental method (6 per cent). This results shows that detail measurement in line 
with standard method of measurement were not adopted in preparing M&E services pre-
contract budget estimate. During the follow up interview, some of the respondents comment that 
differences in the initial contract sum and final account figure is the most difficult problem on 
M&E services contract, while some stated that ‘we always have problems with consultants in 
measurement of actual cable length used on site’. Another problem is with main contractor and 
subcontractor relationships: ‘sometimes “main con” will ask us to make good all works disturbed 
during installation of cables and conduit pipes’ 
On the reasons why details rules of SMM were not adopted for M&E services BoQ Quantity 
Surveyors said that they only allow prime cost sums for M&E services work and detailed 
breakdowns are done by M&E services engineers or contractors based on performance 
specifications. They also stated that they don’t have good knowledge of M&E services; therefore 
it is difficult for them to provide standard – based quantity as done for building fabrics and 
finishes. A large proportion of quantity surveyors argued that, M&E services design are often not 
ready for quantification at tender stage and design consultants mostly give out performance 
specifications to contractors for tendering purposes, therefore, contractors always use their own 
method to arrive at tender price. Some of the consultant services engineers stated that they are 
not aware of any SMM, while majority are of the opinion that they don’t have knowledge of how 
to use SMM that only quantity surveyors were trained on how to use SMM.  
 

Practitioners Perceptions of the Adoption of Standard–Based Pricing Mechanism 
On the practitioners’ perception about the proposition that ‘adoption of SBPM for M&E services 
could lead to a better cost management of M & E services projects in the industry. Respondents 



 

Australasian Journal of Construction Economics and Building 

Amuda Yusuf, G and Mohamed, S F (2014) ‘Perceived benefits of adopting standard – Based pricing mechanism for 
mechanical and electrical services installations’, Australasian Journal of Construction Economics and Building, 14 (2) 104-
119  

110 

were requested to indicate their level of agreement on Likert scale 1 to 5, where 1 = strongly 
disagree and 5 is strongly agree. The result shows that adoption of SBPM could lead to a better 
cost management of M&E services contract. As can be seen on Table 1, 77 per cent of the 
practitioners agreed, 19 per cent disagreed while 4 per cent were undecided. A cursory look at 
the table also revealed that the large percentage of practitioners that disagreed are mechanical 
and electrical services engineers as 30 per cent mechanical and 32 per cent electrical 
engineers that responded disagreed that SBPM would provide good basis for managing cost of 
M&E services in buildings. 

Table 1 Practitioners’ Perception on the Adoption of SBPM for M&E Services 

 

Benefits of Adopting SBPM for Mechanical and Electrical Services 
The objective of this section is to determine the level of importance attached to each of the 
benefits. Therefore, respondents were requested to rate their level of agreement as indicated in 
the previous sections. This standpoint was verified at a significance level of 5 per cent and 162 
degree of freedom (n= 163-1) using a one–way t-test statistics, the critical rating was set at 3 
because on the rating scale adopted 3 are neutral. Therefore, SBPM benefits-rating below 3 are 
not significant (De Silva, Dulaimi, Ling, & Ofori, 2004) 
 
The result of the t–test statistics is shown on Table 2, the mean score of each benefit of SBPM 
from the perspective of the practitioners were calculated and ranked according to the magnitude 
of their mean score. The five most important factors in order of importance includes SBPM 
minimize measurement related disputes; provide good basis for valuing variations; provide good 
basis for assessing interim valuation; reduces tendency of misinterpretation of specifications 
and, improve accuracy of initial budget estimate. However on the tendency of SBPM reducing 
the time and cost of tender, with a mean score of 2.98, and p–value > 0.05 at 162 degree of 
freedom. It is therefore reasonable to state that, from the perspective of the practitioners, this 
factor is insignificant and does not constitute benefit of SBPM. It is important to state that the 
remaining 13 benefits of SBPM are statistically significant (p < 0.05).  
 

Statistical Validity and Results 
The correlation matrix shows how each of the 14 items is associated with each of the 13 others 
and the SBPM benefits provided a ‘determinant’ value of 0.099. The underline assumption is 
that, the determinant should be more than 0.00001 and the value here is 0.099 from which it 
can be assumed that the matrix does not suffer from collinearity. Moreover, the Kaiser –Meyer –
Olkin (KMO) and Bartlett’s test results measures the sampling adequacy which should be 
greater than 0.5 for a satisfactory factor analysis to continue. The KMO statistics ranges from 0 

Discipline 
Strongly 
disagree 

Disagree 
Moderately 

agree 
Agree 

Strongly 
agree 

Total 
responses 

Quantity 
Surveyors 

5 per cent 5 per cent 0 per cent 
15 per 
cent 

74 per cent 100 per cent 

Mechanical 
Engineers 

15 per 
cent 

15 per 
cent 

0 per cent 
46 per 
cent 

23 per cent 100 per cent 

Electrical 
Engineers 

14 per 
cent 

16 per 
cent 

2 per cent 
18 per 
cent 

50 per cent 100 per cent 

Civil Engineers 
 

15 per 
cent 

6 per cent 3 per cent 
27 per 
cent 

50 per cent 100 per cent 

Architects 
 

4 per cent 
12 per 
cent 

4 per cent 
27 per 
cent 

54 per cent 100 per cent 

Others 
 

0 per cent 0 per cent 0 per cent 
50 per 
cent 

50 per cent 100 per cent 



 

Australasian Journal of Construction Economics and Building 

Amuda Yusuf, G and Mohamed, S F (2014) ‘Perceived benefits of adopting standard – Based pricing mechanism for 
mechanical and electrical services installations’, Australasian Journal of Construction Economics and Building, 14 (2) 104-
119  

111 

to 1. A value of 0 implies that the sum of partial correlations is large relative to the sum of 
correlations, therefore factor analysis will be inappropriate, on the other hand, a value close to 1 
implies that patterns of correlations are relatively compact and factor analysis would yield 
distinct and reliable individual factors (Gravetter & Wallnau, 2007) The KMO value is 0.712 
which indicate a good degree of common variance and is above the acceptable threshold of 0.5, 
similarly, the Bartlett’s test of sphericity is significant at 459.92 compared with associated 
significance level ,and the associated probability is less than 0.05 (p-value = 0 .000), meaning 
that the correlation matrix is not an identity matrix. The results of the analysis revealed that the 
coefficients of correlation between pairs of the variables were small when the effects of other 
variables were eliminated (Gravetter & Wallnau, 2007). Therefore, the data collected were 
adequate for factor analysis and appropriate for the factors extraction. 
 

Benefits SBPM t-value Mean 
P-

value 
Std. 

Deviation 
Rank 

Minimize measurement related disputes 
 

24.355 4.5460 0.000 .81044 1 

Provide good basis for valuing variations 
 

20.402 4.4785 0.000 .92521 2 

provide good basis for assessing interim valuation 
 

17.652 4.4049 0.000 1.01615 3 

Reduces tendency of misinterpretation of 
specifications 

17.985 4.3742 0.000 .97554 4 

Improve accuracy of initial budget estimate 
 

15.769 4.3129 0.000 1.06297 5 

Avoid the need for contractors to measure M&E 
work  

19.205 4.2761 0.000 .84830 6 

Provide reliable database for future cost planning 
 

14.936 4.2086 0.000 1.03312 7 

Assist contractors in ordering and preparing labor 
schedule 

13.582 4.0859 0.000 1.02076 8 

coding system allow ease of automation of 
estimating process 

10.016 3.9198 0.000 1.16884 9 

Ensure reflection of local practices and procedure 
 

8.153 3.8160 0.000 1.27773 10 

Ensure that design is completed prior to tender 
 

7.941 3.6503 0.000 1.04547 11 

Enhance risk management 
 

5.136 3.5276 0.000 1.31145 12 

Assist in asset management 
 

2.362 3.2331 0.000 1.25988 13 

Reduce time and cost of tender 
 

-.208 2.9816 0.836 1.13024 14 

a
n = 163; df = 162 at 95 per cent confidence level. Items are rated on 5 –pints likert scale (1-strongly 

disagree, 3 = neutral and 5 = strongly agree) 

Table 2 Practitioners Perception of the Benefits of SBPM 

 
The main purpose of factor analysis is to statistically reduce the number of factors on which the 
variables under investigation have high loadings, so as to make the interpretation of the analysis 
easier (Proverbs, Holt, & Olomolaiye, 1999). The extracted factors were subjected to principal 
component analysis and varimax with Kaiser Normalization rotation. The result shows that the 
14 factors identified produced a six–factor solution along with their eigenvalues greater than 1. 
The cumulative percentage of variance explained accounted for 66.53 and the  per cent of 



 

Australasian Journal of Construction Economics and Building 

Amuda Yusuf, G and Mohamed, S F (2014) ‘Perceived benefits of adopting standard – Based pricing mechanism for 
mechanical and electrical services installations’, Australasian Journal of Construction Economics and Building, 14 (2) 104-
119  

112 

variance attributable to each factor are shown on Table 2. However, the loadings of the fourteen 
variables on six factors extracted were subjectively classified under six categories on Table 3. 
The criteria for group classification were that variables with a loading value higher than 0.50 in 
one component belong to that component (Awakul & Ogunlana, 2002). The higher the absolute 
value of the loading, the more the factor contribute to the variable, the gap on the table 
represent loadings that are less than 0.5 because loadings less than 0.5 were suppressed. The 
first three grouped factors accounted for 14.024 per cent, 11.726 per cent and 11.411 per cent 
respectively. All the remaining factors after the sixth factor are not significant and were not 
reflected in the results.  
 
Furthermore, Figure 1 is the scree plot graph of the Eigen values against the factor number. The 
loadings of the 14 factors were higher than 0.50. It is generally assumed that the higher the 
absolute value of the individual factor loading, the more a particular individual factor contributes 
to its group components (Proverbs, Holt, & Olomolaiye, 1999). A cursory look at the figure 
shows that from the sixth factor, the successive factor is accounting for smaller and smaller 
amounts of the total variance. This is a further proof that six – factor group is sufficient for the 
components. 

Figure 1 Scree Plot Graph of Eigen Values 

 
Discussion of Factor Analysis 
Factor 1: SBPM Enhance quality and reliability of Price Forecast 
This factor account for 14.02 per cent of the variance and comprises of four benefits of SBPM; 
minimize measurement related disputes, ensure reflection of local practices and procedures, 
improve accuracy of initial budget estimate and reduces tendency of misinterpretation of 
specifications. The loading of these four benefits are 76 per cent, 65 per cent, 59 per cent and 
56 per cent respectively. The correlation matrix showed significant statistical relationship 
between the four benefits. The association between the four benefits as shown in the correlation 
matrix (Table 3). All the four benefits in this group share common features which is their impact 
on the quality and reliability of early contract price estimate, and hence factor 1 was labelled 
enhance quality of price forecast.  
 



 

Australasian Journal of Construction Economics and Building 

Amuda Yusuf, G and Mohamed, S F (2014) ‘Perceived benefits of adopting standard – Based pricing mechanism for 
mechanical and electrical services installations’, Australasian Journal of Construction Economics and Building, 14 (2) 104-
119  

113 

Standard–Based quantity provides a more sensitive and balanced description of the value of 
work in a contract. Therefore, all necessary works required for the installations of M&E services 
components are properly quantified in line with the accepted SMM at the pre-contract stage for 
contractors to submit bids. The resulting document will serve as a basis upon which the entire 
work will be executed and paid for, therefore contractors would be able to determine the amount 
due upon execution of a particular section(s) of the work. This will reduce the tendency of 
measurement disputes. SBPM would also reduce the possibility of misinterpretation of 
specifications because; SMM usually reflects local practices, statutory requirements to be 
complied with, acceptable materials as well as quality of workmanship required. This is because 
the value attached to a particular item of work by tendering contractor is a function of 
information provided which serves as basis for determining the rate to be inserted against each 
item of work (Oforeh E. , 2008). However, if there are ambiguities in the description regarding 
the exact M&E services components, the tendering contractors will price based on their 
understanding of the specification leading to disputes at the post–contract stage. On the other 
hand, a clearly defined components will lead to effective communication from the cost 
consultant to the tenderers resulting into a more accurate and reliable estimate.  
 
Factor 2: Ensure active post contract cost monitoring and control 
This factor account for 11.73 per cent of the variance and comprises of two benefits of SBPM. It 
provides good basis for assessing interim valuation and assist contractors in ordering and 
preparing labour schedule. The loading of these two factors are 74 per cent and 58 per cent 
respectively. Similarly, the correlation matrix in Table 3 shows that there is a strong association 
between the two benefits loaded under this factor. This benefit of SBPM was labelled ‘ensure 
active post contract cost monitoring and control’. Each of these factors helps the project team 
and specifically the cost consultants and the contractor to be involved in active monitoring and 
control. SBPM facilitate the production of periodic interim valuation for payment to contractor, 
prepare earn value analysis, and assist in reporting the financial position of M&E services 
project since all the cost significant items have been clearly identified and priced at pre – 
contract stage of the building project. Similarly, it would serve as basis for developing reliable 
work breakdown structure (WBS) by the contractor. This WBS could assist the contractor in 
material ordering, preparation of labour schedule; cash flow forecast and cost value 
reconciliations as well as a reliable programme.  
 
Factor 3: Encourage collaborative working relationship 
Factor 3 comprises of SBPM ensure that design is completed prior to tender (71 per cent 
loading) and that the coding system would allow ease of automation of the price estimating 
process (70 per cent loading), and has been labelled ‘encourage collaborative working 
relationship’ and account for 11.4 per cent of the variance in the selection factors. The 
measurement process will provide a check against the original design because at the early 
stage of building projects SBPM relies on detail design information from design consultants to 
prepare price forecasts. When design information are not clearly presented, the quantity 
surveyors usually issue queries to design consultants for clarification of omitted and ambiguous 
design information thereby facilitating dialogue between the quantity surveyor and M&E design 
consultants and ensure collaborative working relationships with other team members, leading to 
clearly defined clients requirements and reasonably completed design as well as a correctly 
described and accurately measured BoQ. In addition, it will also help in establishing relationship 
between the cost of M&E services and the quality of its components. Similarly, the coding 
system in SMM facilitates automation of the taking–off process, and hence making feasible the 
application of information and communication technology like auto–quantity generation from 
auto-CAD and other computer applications. In addition, Building Information Modelling (BIM) 



 

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measurement and its links with estimating require the need to filter BIM data so that they comply 
with the rules prescribed in relevant SMM (Olatunji, Sher, Gu, & Ogunsemi, 2010).  
 

Variables 
Factor 
loading 

Eigen 
value 

Percentage 
of variance 
explained 

Cumulative 
percentage 
of variance 
explained 

Factor 1: Enhance quality of Price Forecast 

i. Minimize measurement related disputes 0.763 2.338 14.024 14.024 

ii. Ensure reflection of local practices and 
procedure 

0.653    

iii. Improve accuracy of the initial budget 
estimate 

0.588    

iv. Reduces tendency of misinterpretation of 
specifications 

0.562    

Factor 2: Ensure active post contract cost monitoring and control 

i. provide a good basis for assessing interim 
valuation 

0.740 1.697 11.726 25.750 

ii. Assist contractors in ordering and preparing 
labour schedule 

0.584    

Factor 3: Encourage collaborative working relationship 

i. Ensure that design is completed prior to 
tender 

0.708 1.587 11.411 37.160 

ii. The coding system allow ease of 
automation of estimating process 

0.700    

Factor 4: Enhance efficient whole life cycle management of completed projects 

i. Assist in asset management 0.842 1.332 10.369 47.530 

Factor 5: Enhance risk and change order management 

i. Provide good basis for valuing variations 0.761 1.250 9.861 57.390 

ii. Enhance risk management 0.618    

iii. Provide reliable database for future cost 
planning 

0.560    

Factor 6: Facilitate efficient tendering process 

i. Reduce time and cost of tender 0.830 1.111 9.141 66.532 

ii. Avoid the need for contractors to measure 
M&E services work themselves 

0.536    

Table 3 Principal factor extraction and Varimax Rotation of 14 Benefits of SBPM 

 
Factor 4: Enhance efficient whole life cycle cost management 
This factor consists of assist in asset management with a factor loading of 84 per cent and 
accounts for 10.4 per cent of the variance in the selection factors. M&E services in buildings are 
becoming more complex and the capital cost of the various systems and components could be 



 

Australasian Journal of Construction Economics and Building 

Amuda Yusuf, G and Mohamed, S F (2014) ‘Perceived benefits of adopting standard – Based pricing mechanism for 
mechanical and electrical services installations’, Australasian Journal of Construction Economics and Building, 14 (2) 104-
119  

115 

less than half of the whole life cycle cost. Therefore, the adequacy of information in the tender 
will ensure that the contractor quote for exact and durable materials and components which will 
impact maintenance cost. In addition, SBPM will assist in setting up a life cycle data bank on 
M&E services components and equipment which will assist in projecting maintenance costs. 
This will ensure that sufficient information about the performance and aesthetic standard of 
M&E services on completed projects are known, thus, making it possible to reliably predict 
equipment life span. 
 
Factor 5: Enhance risk and change order management 
This factor was labelled enhance risk and change order management, and it accounts for 9.9 
per cent of the variance in the selection factors. This group comprises of SBPM and provides a 
good basis for valuing variations; enhance risk management and provide a reliable data base 
for future cost planning with loading factor values of 76 per cent, 62 per cent and 56 per cent 
respectively. The use of SBPM results in the pricing risk being retained by the client as far as 
quantities are concerned leading to more competitive prices being obtained as risk is more 
evenly distributed with the client taking a greater burden. In this case the contractors’ risk is 
reduced to the tender price and not the extent of work. However, if the contractor is allow to 
measure the work, the risk for the extent of the work rests with the contractor and there is no 
assured consistency in the measurement process thereby increasing the likelihood of post 
contract variation. 
  
Factor 6: Facilitate efficient tendering process 
Factor 6 accounted for 9 per cent of the variance and comprises two factors; SBPM reduce time 
and cost of tender (83 per cent loading) and avoid the need for contractors to measure M&E 
services work themselves (54 per cent loading).The aims of the tendering procedure are to 
assess the skills of the contractor; to translate to the contractor through the tender 
documentation all the project information, including the client’s objectives, required to form the 
contract; and to obtain a competitive quote (RICS, 2000). The availability of standard–based 
quantity will increase the efficiency in obtaining competitive tenders from subcontractors on 
M&E services, ensuring that estimators are able to price SMM bill more accurately than one 
which is not prepared to any particular method of measurement, and prices obtained from 
specialist subcontractors will be more accurate if SMM rules apply (Potts K. , 2004). 
  

Adoption of Standard–Based Pricing Mechanism 
To ensure successful adoption of Standard–Based Pricing Mechanism it is essential to consider 
the following: 
 

i. Education and Training of Professionals 
Total cost management of buildings should be the responsibility of quantity surveyors but they 
still do not have adequate knowledge of M&E services technology, therefore, there is need for 
capacity building, for quantity surveyors to develop a better understanding of the technology of 
mechanical and electrical services so as to improve the quality of price advice given to clients.  
 

ii. Development of Standard Method of Measurement 
Development of a generally accepted Standard Method of Measurement for M&E services that 
will reflect the local practices and procedures is essential to serve as a basis for predicting the 
probable cost of building services. In addition, relevant industry stakeholders should be 
identified and a strategy to manage them developed so as to agree on the best classification 
method for SMM for Mechanical and Electrical services. 
 



 

Australasian Journal of Construction Economics and Building 

Amuda Yusuf, G and Mohamed, S F (2014) ‘Perceived benefits of adopting standard – Based pricing mechanism for 
mechanical and electrical services installations’, Australasian Journal of Construction Economics and Building, 14 (2) 104-
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116 

iii. Early involvement of design and specialist consultants and contractors 
Early involvement of M&E services design consultants is essential. Industry stakeholders should 
also be encouraged to develop strategy to involve major downstream supply chain at the 
inception of M&E services project to reduce the risk of incomplete design information that could 
prevent the use of SBPM. 
 

iv. Application of Value Engineering 
Industry stakeholders should also consider the application of Value engineering at the early 
stage of M&E services project. This would assist in equipment selection based on function and 
whole life cycle costs thereby ensuring that clients achieve absolute value for money. In 
addition, it will ensure collaborative working relationship between quantity surveyors and M&E 
consultants engineer leading to a better understanding of M&E services components by quantity 
surveyors and more reliable price forecast. 
 
The importance of this study is that, it has specifically identified current practices used for 
determining and controlling cost of M&E services and highlighted its impact on the overall 
procurement and cost of buildings. The potential benefits of adopting a Standard–Based Pricing 
Mechanism for M&E services was also ascetained from the perspectives of industry 
practitioners and strategies to encourage stakeholders to adopt SBPM was sugested. However, 
the limitations of this study is that, it does not indicate how to develop a Standard Method of 
Measurement to serve as basis for adopting SBPM for M&E services price forecast. Therefore, 
future studies should focus on investigating the essential features of SMM for M&E services and 
come up with framework to develop and encourage stakeholders to adopt it as basis for 
preparing M&En services price forecast. 
 

Conclusion 
The adoption of SBPM for M&E services has the potentials of enhancing the procurement and 
cost management of M&E services, provides home ground advantage for indigenous industry 
practitioners and creates a transparent contractual atmosphere for the participation of 
international contracting organizations and interest groups at the liberalisation of the services 
sector in the country. Practitioners perceived that the use of SBPM will increase the time 
required to prepare tender documents as designs will have to be reasonably completed before 
detail measurements could be undertaken. Contractors are of the opinion that they have a 
better method of estimating the tender price of M&E services as the documents prepared by 
consultants are often inadequate for pricing items of M&E services. Nevertheless, a systematic 
structure of Standard–Based BoQ items would lead to a more uniform and adequate 
descriptions in tender documents, leading to a more reliable M&E services tender that could be 
used as basis for historic cost information and provide better value for clients money.  
 

References 
Amaratunga, D., Baldry, D., Sarshar, M. and Newton, R. (2002) Quantitative and Qualitative 
Research in the Built Environment: Application of “mixed” Research Approach. Work Study, 51 
(1), pp. 17-31. 

Amuda Yusuf, G., Mohamed, S. F. and Remeli, S. (2013) Factors Inhibiting the Adoption of a 
Uniform Pricing Mechanism for Building Services. International Journal of Engineering Business 
Management, 5 (3), pp. 1-10. 

Ashworth, A. & Hogg, K. (2007) Willis's Practice and Procedure for the Quantity Surveyor. 12 
éd. Oxford: Blackwell. 



 

Australasian Journal of Construction Economics and Building 

Amuda Yusuf, G and Mohamed, S F (2014) ‘Perceived benefits of adopting standard – Based pricing mechanism for 
mechanical and electrical services installations’, Australasian Journal of Construction Economics and Building, 14 (2) 104-
119  

117 

Awakul, P. & Ogunlana, S. (2002) The Effect of Attitudinal Differences on Interface Conflicts in 
Large Scale Construction Projects: a Case Study. 20 (4), pp. 365 – 377.. 

Bowen, P. A. & Edwards, P. J. (1996) Interpersonal Communication in Cost Planning During the 
Building Design Phase. Construction Management and Economics, pp. 395 - 404. 

CIDB (2009) Annual Report: Strategic Thrust 2 - Strethen the Construction Industry Image, 
Kuala Lumpur: Construction Industry Development Board. 

Davis Langdon (2010) Building Services - Company Profile 2010. [En ligne]  
Available at: 
http://www.davislangdon.com/upload/DLA%20Brochures/Building%20Services%20-
%20Company%20Profile%202010.pdf 
[Accès le 18th August 2011]. 

De Silva, N., Dulaimi, M., Ling, F. & Ofori, G. (2004) Improving the Maintainability of Buildings in 
Singapore. Building and Environment, Volume 39, pp. 1243 -1251. 

Dell'lsola, M. (2002) Architect's Essentials of Cost Management. New York: John Wiley & Sons. 

Dent, C. (1980) Construction Measurement in Accordance with SMM6: Volume 1 Elementary 
Substructure and Superstructures. Second Edition éd. London: Granada. 

Dulaimi, M. & Hwa, T. (2003) Developing World Class Construction Companies in Singapore. 
Construction Management and Economics, Volume 19, pp. 591 - 599. 

Dulami, M., Ling, F. & Bajracharya, A. (2003) Dulami, M.F., Ling, F.Y.Organisational motivation 
and interorganisational interaction in construction innovation in Singapore. Construction 
Management and Economics, Volume 21, pp. 307 - 318. 

Entrusty (2011) Construction Contract and Management Issues: Ground Conditions - Mysteries 
Unravelled. Master Builder Journal, Volume 3, pp. 72 - 82. 

Fellows, R. & Liu, A. (2008) Research Methods for Construction. 3rd éd. Chichester: Wiley 
Blackwell. 

Flanagan, R. & Tate, B. (1997) Cost Control in Building Design. Oxford: Blackwell Science. 

Fortune, C. & Cox, O. (2005). Current practices in building project contract price forecasting in 
the UK. Engineering,Construction and Architectural Management, 12 (5), pp. 446 - 457. 

Fortune, C. & Lees, M., (1999) The Relative Perfomance of New and Traditional Cost Models in 
Strategic Advice. Dans: M. Skitmore & V. Marston, éds. Cost Modeling. London: E & FN Spon, 
pp. 93-153. 

Fussell, W. (1971) The Measurement of Engineering Services.. London: E&F.N. Spon Ltd.. 

Gravetter, F. & Wallnau, L. (2007) Statistics for the Behavioral Sciences. Seventh Edition éd. 
Belmont: Thomson Wadsworth. 

Gura, J. (1984) Role of the Building Services Engineering Consultants. IEEE Proceedings, 
131(6). 

Hacket, M., Robinson, L. & Statham, G. (2007) The Aqua Group Guide to 
Procurement,Tendering and Contract Administration. Oxford: Blackwell. 

Hore, V., Kehoe, J., Macmullan., R. & Penton, M. (1997) Construction 1: Management, Finance, 
Measurement for Construction and Built Environment Programmes. Hong Kong: Macmillan. 

Ling, Y. & Boo, J. (2001) Improving the Accuracy of Approximate Estimates of Building 
Projects,. Improving the Accuracy of Approximate Estimates of Building Projects, Building 
Research and Information,, pp. 312 - 318. 



 

Australasian Journal of Construction Economics and Building 

Amuda Yusuf, G and Mohamed, S F (2014) ‘Perceived benefits of adopting standard – Based pricing mechanism for 
mechanical and electrical services installations’, Australasian Journal of Construction Economics and Building, 14 (2) 104-
119  

118 

Mathew, O. & Howell, G. (2005) Integrated Project Delivery: An Example of Relational 
Contracting. Lean Construction Journal, 2 (1), pp. 46 - 61. 

McCaffrey, J. (2011) What is an M&E QS. Royal Institution of Chattered Surveyors Students 
Construction Journal, pp. 22 - 23. 

Michie, A. (1981) Integration and Co- ordination of Building Services and its Relationship with 
Project Management. Building Services Engineering Research and Technology, 2 (15 - 26). 

Mok, C., Tummala, V. & Leung, H. (1997) Practices, barriers and benefits of risk management 
process in building services cost estimating. Construction Management and Economics, pp. 161 
-175. 

Molloy, J. (2007) Civil Engineering Measurement Claims in Hong Kong,. [En ligne]  
Available at: http://www.fig.net/pub/fig2007/papers/ts_3g/ts03g_02_molloy_1664.pdf  
[Accès le 28 August 2011]. 

Murray, G. ( 1997) Measurement of Building Services. London: Macmillan. 

Nanayakkahara, R. & Fitzsimmons, J. (1999) Cost Benchmarks for the Installation of Building 
Services: Part1 – The Benchmarking Process AG 20 -1/99. BSRIA., London: BSRIA. 

Nani, G. E. & Adjei-Kumi, J. (2008) Customisation and Desirable Characteristics of Standard 
Method for Building Works in Ghana. Australia Journal of Construction Economic and Building, 
Vol 8, no 2. 

Odeyinka, H., Kelly, S. & Perera, S. (2009) An evaluation of the budgetary reliability of bills of 
quantities in building procurement. Cape Town, University of Capetown, pp. 435-446. 

Oforeh, E. (2008) Installation and Electrical Works in Buildings. Second Edition éd. Lagos: 
Cosines. 

Oforeh, E. & Alufohai, A. (1998) Management Estimating and Budgeting for Electricasl 
Installations. First Edition éd. Lagos: Cosines (Nig) Ltd. 

Olatunji, O., Sher, W., Gu, N. & Ogunsemi, D. (2010) Building Information Modelling Processes: 
Benefits for Construction Industry. Salford, CIB, pp. 137 - 151. 

Potts, K. (2004) Quantity Surveying Tools and Techniques - A Review of Client And Contractor 
Requirements. Leeds Metropolitant University, RICS Research Foundation. 

Potts, K. (2008) Construction Cost Management: Learning from Case Studies. London: Taylor 
and Francis. 

Proverbs, D., Holt, G. & Olomolaiye, P. (1999) Factor Influencing the Choice of Concrete Supply 
Methods. Building Research and Information, 25 (3), pp. 176-184. 

Rawlinson, S. & Dedman, A. (2010) Specialist Costs: M&E Services. Davis Langdon Building 
Magazine. 2010; available at http://www.davislangdon.com/. [En ligne]  
Available at: /EME/Research/ResearchFinder/Specialist-Costs/Specialist-Costs---ME-services-
2010/; [Accès le 25 August 2011]. 

Rawlison, S., Nugent, B. & Dedman, A. (2007) Procurement of Building Services. [En ligne]  
Available at: http://www.davislangdon.com/Global/Search/?q=building+services+procurement 

RICS (2000) RICS Guidance Note: Building Services Procurement. London: RICS. 

Seeley, I. (1989) Advanced Building Measurement. 2nd éd. London: Macmillan. 

Seeley, I. (1996) Building Economics:Appraisal and Control of Building Design Cost and 
Efficiency. 4th éd. England: MacMillan. 



 

Australasian Journal of Construction Economics and Building 

Amuda Yusuf, G and Mohamed, S F (2014) ‘Perceived benefits of adopting standard – Based pricing mechanism for 
mechanical and electrical services installations’, Australasian Journal of Construction Economics and Building, 14 (2) 104-
119  

119 

Seeley, I. & Winfield, R. (1998) Building Quantities Explained. London: MacMillan. 

Skitmore, M. (1991) Which Estimating Technique?. Dans: P. Venmore-Rowland, P. Brandon & 
T. Mole, éds. Proceedings of the First National RICS Research Conference. London: Taylor 
&Francis. 

Skitmore, R. & Thomas Ng, S. (2003) Forecast Models for Actual Construction Times and Cost. 
Building and Environment, Volume 38, pp. 1075 - 1083. 

Swaffield, L. & Pasquire, C. (1996) A Crtique of Mechanica and Electrical Services Cost 
Planning: Existing Methods and Published Information.. Financial Management of Property and 
Construction, 1 (3), pp. 23 - 41. 

Swaffield, L. & Pasquire, C. (1999) Examination of Relationships Between Building Forms and 
Function and the cost of Mechanical and Electrical Services.. Construction Management and 
Economics, Volume 17, pp. 483 - 492. 

Swaffield, L. & Pasquire, C. (2000) Improving Early Cost Advice for Mechanical and Electrical 
Services RICS Foundation Research Papers; 3 No.15, London: RICS.