Australasian Journal of  Construction Economics and Building 2014. © 2014 Oluwole Alfred Olatunji and Willy Sher. This is an 
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Citation: Olatunji O.A. & Sher W. 2014 ‘Perspectives on modelling BIM-enabled estimating practices’, Australasian Journal of 
Construction Economics and Building, 14 (4), 32-53. http://dx.doi.org/10.5130/ajceb.v14i4.32 
 

 

Perspectives on Modelling BIM-enabled 
Estimating Practices 
Oluwole Alfred Olatunji (Curtin University of Technology, Australia) 

Willy Sher (University of Newcastle, Australia) 

Abstract 
BIM-enabled estimating processes do not replace or provide a substitute for the traditional 
approaches used in the architecture, engineering and construction industries. This paper 
explores the impact of BIM on these traditional processes.  It identifies differences between 
the approaches used with BIM and other conventional methods, and between the various 
construction professionals that prepare estimates. We interviewed 17 construction 
professionals from client organizations, contracting organizations, consulting practices and 
specialist-project firms. Our analyses highlight several logical relationships between 
estimating processes and BIM attributes. Estimators need to respond to the challenges BIM 
poses to traditional estimating practices. BIM-enabled estimating circumvents long-
established conventions and traditional approaches, and focuses on data management.  
Consideration needs to be given to the model data required for estimating, to the means by 
which these data may be harnessed when exported, to the means by which the integrity of 
model data are protected, to the creation and management of tools that work effectively and 
efficiently in multi-disciplinary settings, and to approaches that narrow the gap between 
virtual reality and actual reality.  Areas for future research are also identified in the paper. 
Keywords:  BIM, BIM-enabled estimating, estimating, tendering 

Background  
Building information modelling (BIM) has had a critical impact on estimating practice in 
recent years. It is considered as revolutionary, relying on parametric and integrative 
capabilities to service multidisciplinary needs. Several different philosophical perspectives 
have emerged. Aranda-Mena et al. (2008) and Gu et al. (2007) argue that BIM is a precursor 
to revolutionary changes in prevailing professional practices and theories. Succar (2009) 
notes that BIM introduces new methodologies and provides the basis for new policies about 
how disciplines interact, collaboratively and cooperatively, in modern construction project 
delivery systems. Others have identified relationships between BIM and estimating 
processes, and how well construction projects perform.  In this context: 

• BIM databases are seen to facilitate objectivity as project teams collaborate and 
integrate data and processes across multiple disciplinary boundaries (Gujarathi & Ma 
2011). 

• BIM offers project teams opportunities to communicate and collaborate in ways that 
are richer than in conventional processes (Aranda-Mena et al. 2009; Huang et al. 
2009). Where communication and collaboration are compromised, Acharya, Lee and 
Im (2006) and Velasquez, Lara and Nof (2008) have shown that project performance 
suffers as a result of conflicts, errors and avoidable complications in the design and 
construction stages.  These shortcomings may linger throughout facilities’ operations. 

https://creativecommons.org/licenses/by/4.0/


Australasian Journal of Construction Economics and Building 

 

33 

• BIM improves the accuracy of estimates as well as of designs (Eastman et al. 2011).   

• BIM does not address all the challenges experienced by those designing, 
constructing, maintaining and deconstructing buildings.  Amor and Faraj (2001) and 
Amor, Jiang and Chen (2007) argue that it is technically impossible for BIM data to 
be structured to simultaneously satisfy the requirements of these disciplines. 

• BIM enables disciplines to adapt and manipulate data according to their own 
requirements. Studies by Sattenini, Azhar and Thuston (2011) and Sattenini and 
Bradford (2011) indicate that BIM solutions vary from discipline to discipline and 
depend on the task at hand. This suggests that it is the prerogative of each discipline 
to explore how best to manage their BIM-specific solutions. 

• In the context of estimating, a common simplistic view is that BIM data enable 
accurate estimates to be prepared (Eastman et al. 2011). However others argue that 
automatic estimating solutions may be based on the export of BIM metadata (Yum et 
al. 2008; McCuen 2009; Sabol 2008; Zhiliang et al. 2011).  

These observations indicate the breadth of estimating-related applications that BIM impacts 
upon.  BIM offers solutions to the numerous problems that beset traditional construction 
project management processes. This is not to say that BIM provides a silver bullet for all the 
challenges identified. The limitations of some of these solutions are indicated by the authors 
concerned. 

Additionally, Holzer (2007) argues that estimating with BIM requires more than the adoption 
of model data by non-design professionals. Dean and McClendon (2007), Love, Edwards 
and Han (2011) and Tiwari et al. (2009) agree, arguing that it is not yet possible to automate 
estimating simply by exporting BIM data to other applications. Furthermore, BIM-enabled 
automated estimating is unlikely to entirely replace conventional estimating practices. 
Olatunji, Sher and Gu (2010) argue that BIM is likely to transform these traditional practices. 
They highlight the contribution that BIM can make in quantifying the materials and other 
construction elements of which buildings are comprised.  They foresee an emerging reliance 
on BIM applications to generate such quantities, but argue that estimators still need to vet 
BIM-generated quantities.  Furthermore, they predict estimators’ responsibilities for costing 
and resourcing will continue. Despite the time BIM applications save in quantification, 
reliable estimates require some model reconstruction, design analysis and adaption to 
address the peculiarities of individual construction projects.  

A significant challenge relates to the manner in which BIM data are structured. Amor, Jiang 
and Chen (2007) and Pučko, Šuman and Klanšek (2014) observe that these data are 
generally not organised in ways that meet estimators’ requirements. Tiwari et al. (2009) and 
Olatunji and Sher (2010) suggest that overcoming this challenge is time-consuming; 
although others have pointed out that BIM-estimating improves estimators’ productivity (Kim 
et al. 2009). Nevertheless there is debate about whether perceived productivity 
improvements are a substitute for accuracy, feasibility and thoroughness (Ogunlana & 
Thorpe 1991). 

Estimators have long been reluctant to embrace automated estimating solutions (Best et al. 
1996; Brook 2004; Lowe & Skitmore 1994; Ogunlana & Thorpe 1991; Sher 1996). According 
to Hardie et al. (2005), this trend persists notwithstanding the proliferation of computer-aided 
estimating solutions that have evolved over the years. Cartlidge (2010) notes that there is 
general acceptance amongst construction professionals that estimators’ skills cannot 
currently be subsumed by BIM-enabled systems.  However, we argue that estimators should 
not be complacent about the changes BIM-enabled applications foreshadow. The pace at 
which these applications have developed over the past decade has accelerated and it is 
likely that that they will continue to evolve in increasingly sophisticated ways. Whilst BIM-
enabled estimating processes neither substitute nor replace traditional estimating 
approaches, it is important to distinguish between BIM estimating and conventional 



Australasian Journal of Construction Economics and Building 

 

34 

estimating. This paper explores how an analysis of BIM-enabled estimating activities can 
contribute to the development of contemporary theories and new directions. In turn, these 
facilitate comparisons with other design regimes. The following section describes the 
relationships between estimating processes and BIM attributes. It reviews literature about 
BIM-enabled estimating and explores the contributions of estimating activities and processes 
to construction businesses, and how BIM impacts upon them. 

Different Forms of Estimating 
There are various forms of construction estimating and these align with stakeholders’ 
perspectives and priorities. Olatunji (2012) distinguishes between estimators who work in 
client organizations, contracting organizations, consulting practices and those who work in 
specialist project organizations. The approaches they adopt result in subtly different 
practices and procedures. Some of the nuances between these approaches are discussed 
below. 

Construction contractors distinguish between their costs (their estimate) and the amount of 
money they are prepared to sell their work for. In cost accounting terms this is called their 
price (or tender amount) and includes sums of money that allow for site and general 
overhead expenses, risk allowances, contingencies and profit. Contractors prepare their 
estimates using various approaches. Some are based on predicting costs from first 
principles (including unit rate, operational rate and spot rate estimating), (Akintoye & 
Fitzgerald 2000; Ashworth 2010; Ashworth & Hogg 2007; Brook 2008; Gerrard 2000; Harris 
et al, 2006; Skitmore & Wilcock 1994). Other approaches service the tenders prepared by 
sub-contractors for discrete work packages. Tendering (the conversion of an estimate into a 
profitable offer to complete a construction project) is far less well documented because 
contractors are loath to publicise details about commercially sensitive aspects of their 
businesses.   

Clients require budgets from the very early stages of a construction project. Whilst these 
budgets may be prepared in-house or out-sourced, they are generally based on data from 
past projects. Frequently, these data relate to projects that were constructed in different 
conditions and circumstances to the current project. They reflect the approach adopted by a 
specific contractor, using their particular construction methods and overheads structure. 
Clients select suitable historic tender data and modify these according to current economic 
conditions and the peculiarities of the project in question. Some large clients and providers 
of estimating services collect their own data. These are sometimes supplemented by 
reference to published cost data (RICS 2014) and by market surveys. This pragmatic 
approach has become widespread amongst clients.   

There is considerable potential for BIM to impact on the estimating practices of clients, their 
representatives and the professional consultants they employ, as well as on contractors, 
sub-contractors and suppliers. However, the term estimating has different meanings for 
clients, the professional teams they engage and the contractors who are called upon to 
complete the works on site. A client’s view of a construction estimate is that of a contractor’s 
tender, whereas for a contractor, an estimate and a tender are mutually dependent on each 
other. This is particularly relevant to discussions about BIM-enabled estimating because the 
variety of discipline specific interpretations inevitably leads to confusion. We have not 
distinguished between the estimating practices and procedure of clients and contractors in 
this paper because of the generic nature of our discussions. Readers are however alerted to 
these differences and the subtleties involved. 

Review of Related Studies 
BIM-enabled estimating is described as an automatic process that involves adopting and/or 
adapting data, exporting these and then associating them with costs based on past projects. 
Automation is not new to estimating processes: Skitmore (1990), Smith and Skitmore (1991), 



Australasian Journal of Construction Economics and Building 

 

35 

Best et al (1996) and Sher (1996) describe computer-aided estimating processes that 
existed before BIM. Many estimators use dedicated estimating software for BIM-related 
estimating tasks. However, sophisticated BIM processes and procedures do not necessarily 
result in accurate estimates (Olatunji 2014). Nonetheless, much can be learnt from the 
computer-aided estimating methods used prior to BIM and those that are BIM-enabled. 
These may be reviewed through the following lenses: 

• Has anything changed? 

• BIM capabilities and the quality of construction estimates: does parametricism make 
any difference? 

• Process modelling: a critique of options 

Computer - aided Estimating: Has Anything Changed? 
The computer-aided estimating applications available before the advent of BIM generally 
replicated conventional estimating processes. For example, Best et al. (1996) reported that 
estimators have always used different software applications for different estimating activities 
– for quantification, resource planning, calculating costs, document management, risk 
analysis and contract management. As conventional CAD became popular, Geiger and Dilts 
(1996) suggested that estimators could exploit CAD data. These authors described the 
process of estimating with CAD as a quasi-integrated approach upon which subsequent 
computer-aided estimating approaches could be built. 

Following Geiger and Dilts’ (1996) work, several studies indicate increasing interest in 
integrated solutions for estimating. For example Gujarathi and Ma (2011), Pratt (2011), 
Peterson and Dagostino (2010) and Pučko, Šuman and Klanšek (2014) have all shown that 
quantification processes can be integrated with CAD and that the outcomes can be linked to 
cost databases. Various authors including Sher (1991) and Underwood and Alshawi (1997), 
have documented the development of computer-aided systems for integrating interim 
valuations and pre-contract estimates.  These integrated processes are subtly different to 
the manual processes described by Ashworth (2010), Brook (2008), Collier (1974), Gerrard 
(2000), Harris et al. (2006) and Skitmore and Wilcock (1994). According to these authors, 
conventional manual quantification activities are fragmented and include taking-off, 
abstracting, working-up and drafting of bills of quantities. Each of these activities requires 
different resources and actions. When these activities are integrated, outcomes become 
streamlined. BIM-enabled estimating draws on the integration of design, measurement and 
estimating activities. Whilst many estimating applications have evolved to exploit BIM data, 
opinions about BIM-enabled estimating processes differ. Recent research suggests that 
BIM-enabled applications require approaches and skills that differ from conventional 
estimating methods. For example Dean and McClendon (2007) observe that estimators use 
fragmented tools to estimate with BIM, whilst Bailey (2010), McCuen (2009), Sabol (2008), 
Samphaongoen (2010), Yum et al. (2008), Zhiliang et al. (2011), Lawrence et al. (2014) and 
Pučko, Šuman and Klanšek (2014) all propose different BIM estimating methods. 

It is informative to distinguish between these approaches and to appreciate the underlying 
differences (see Figure 1). In conventional estimating processes estimators regularly refer to 
the different rules and practices that govern measurement and estimating. Variants of these 
documents, including Standard Methods of Measurement (SMM) exist in different contexts 
(there are SMMs for building, civil works and for heavy engineering works) and geographic 
locations (including UK, Australia and South Africa). Whilst similar elements exist in different 
contexts, each SMM may provide different measurement rules. Ambiguities arise if 
components are ill-defined or not described in SMMs. Best practice guidelines (e.g. the 
CIOB’s Guide to Estimating Practice) recommend that estimates are developed according to 
structured processes upon which cost and resource estimates are based (Seeley & Murray 
2001; Seeley & Winfield 1998). 



Australasian Journal of Construction Economics and Building 

 

36 

 

 

Measurement rules,  quantification 
templates, data files, project 
drawings 

Digitizers, word processors, e-
storage 

 

In traditional estimating processes, estimators rely on measurement 
rules, which require strict interpretation irrespective of project situations. 
Even when digitizers are used, estimating processes have remained 
largely unchanged. 

 

  

  Estimating with CAD data - adapted from Dean & McClendon (2007) 
 

Using CAD data, estimating processes and methods have remained 
largely unchanged. Noticeable additions include automated data 
extraction from CAD files, development of rule libraries into 
quantification applications and integration of resource and cost 
databases with quantification data. 

 

Integration in BIM/Parametric CAD regimes (Adapted from www.buildingsmart.org) 

In BIM/parametric CAD regimes, context-specific data can be exported to different estimating 
applications or have cost data contained within a model. While other design regimes may be 
fragmented, BIM is able to integrate data across the different stages of a project’s lifecycle. 

Figure 1: A taxonomy of estimating systems in different design data structures  



Australasian Journal of Construction Economics and Building 

 

37 

Over the years quantification practices have evolved to exploit the opportunities presented 
by digital technologies. For example, there are applications that allow measurements to be 
generated directly from CAD files and others that allow digital scaling of hardcopy drawings. 
Moreover, when combined with relevant parametric performance data, estimators can 
quantify and cost construction drawings appreciably faster than when conventional 
processes are used (Sher 1982). Notwithstanding these advantages, some estimators prefer 
to measure manually from drawings. They are hesitant to change and prefer approaches 
that they consider to be tried and trusted. Although BIM builds on conventional 2D CAD, the 
estimating processes used in 2D CAD and BIM are different. Generally, estimating with 2D 
CAD replicates traditional processes, whilst BIM-enabled estimating provides additional 
deliverables. BIM data can be used to prepare estimates without substantial alteration 
(Tiwari et al. 2009; Yum et al. 2008).  

Simulations can be developed with BIM data to show the sequence and duration of 
construction operations. It is also possible to visualize different construction sequences 
(Vozzola et al. 2009; Huang et al 2009). Sundry documents can be attached to BIM data 
(including technical notes, instruction manuals and operational manuals). These ancillary 
details or hyper-models may be stored in BIM databases and used, for example, to 
accumulate and record the lifecycle costs of a construction project (Olatunji 2012). BIM-
enabled estimating thus provides benefits that extend beyond design and construction. 
Recognising these benefits, some construction businesses have chosen to focus on BIM 
projects (Abdelkarim 2010). 

BIM Capabilities and the Quality of Construction Estimates: Does Parametricism Make 
any Difference? 
The main difference between 2D CAD and BIM is the ability of the latter to be altered when 
selected parameters are changed. According to Ji et al. (2011, p.1), “geometric 
representation… is restricted to explicit, extrusion and Constructive Solid Geometry (CSG) 
approaches”. Hubers (2010, p.3) notes that “the advantage of parametric software is that if 
the virtual 3D model is set-up appropriately, changes in the parameters [will] generate within 
minutes[,] complete correct models and consequent bill of quantities and 2D sections (…) it 
[is] possible to adjust designs until the last minute”. 

Parametric design models are assembled from digital data that are linked by user-defined 
parameters. When one parameter is changed, the resulting impact is reflected automatically 
in all connected components. This means that the underlying data, which estimators rely on 
for quantification, represent the entire design model at a point in time. If measurements are 
exported as designs evolve, successive records can be harvested to show how costs have 
changed over time. Quantification data can thus be exported in forms that facilitate 
estimating and resourcing. Hubers (2010) refers to these data as bills of quantities. In his 
view, and contrary to other researchers (e.g. Amor et al. 2007), parametric BIM data are 
sufficiently well-structured to meet the requirements of estimators, including interpreting 
standard methods of measurement and commercial considerations that accompany 
estimating calculations (e.g. Ashley & Teicholz 1977). In addition to Hubers’ views, other 
researchers suggest alternative ways of developing estimates based on parametric data as 
described below. 

BIM Estimating Process Modelling: a Critique of Options  
Despite numerous case studies on BIM-enabled estimating (Broekmaat 2008; Dean & 
McClendon 2007; Goldberg 2007; McCuen 2009; Zhiliang et al. 2011) there is little specific 
guidance about the use of these applications. Our study has identified the following four 
types of BIM-enabled estimating.   

• The IFC export approach: BIM data need to be exported to dedicated estimating 
software applications. These data need to be structured in an application-



Australasian Journal of Construction Economics and Building 

 

38 

independent format such as Industry Foundation Classes (IFC), exported to a 
spreadsheet and filtered to support specific reporting structures. Figure 2 shows a 
model for a multi-storey building as well as data to be exported to a spreadsheet. 
Rather than manipulating model data, this approach allows estimators from different 
domains to moderate the model data as they see fit. 

In a case study reported by Ma, Wei and Zhang (2013) algorithms were created to 
export and filter IFC data to align with project specifications and other constraints. 
The results of this study indicate that BIM data need to be moderated to align with 
the specifications and the form of contract used. Zhiliang et al. (2011) conducted a 
similar study to Ma et al. (2013): they were able to translate IFC data directly into bills 
of quantities. However, it is unclear from these studies whether estimates can be 
reliably generated on the basis of BIM data. Each construction project is unique and 
generalised data need to be manipulated to cater for site specific constraints. The 
methods by which one-off element descriptions are catered for is presently not well 
documented. In addition, the process of transferring data between software 
applications is frequently problematic (Ji et al. 2011) as some IFC translators may not 
cater for unstandardized or unlinked components of models.    
 

 

Figure 2: IFCs and model element data 
 

• The model ‘as-is’ costing approach: Yum et al. (2008) proposed a procedure in 
which cost data were built directly into a design model. Using this approach BIM data 
store both cost and time components.  Figure 3 shows how costs for doors are 
included in a model.  Using this approach, every component is identified and costed 
without being exported to or manipulated in other applications. This approach can 
also be extended to generate forecasts of cash flow and timing. 

Estimators’ skills and abilities in this area are evolving. Issues relating to the reliability 
of model data for estimating purposes continue to raise concerns. For example, an 
element (e.g. a floor) needs to be modelled differently depending on whether it is flat 
or sloping. From an estimator’s perspective different areas such as these require 



Australasian Journal of Construction Economics and Building 

 

39 

different resources, which in turn generate different costs. However, from a design 
perspective, such additional modelling is not commonplace. It follows that elements 
used for estimating purposes are unique (Olatunji, Sher & Gu 2010).  

 

Figure 3: Embedding costs into models. 
 

Based on the challenges described above, estimators would benefit from acquiring 
skills and abilities to interrogate and modify 3D objects. However there are few 
incentives for them to do this. They are discouraged, in part, by the lack of 
opportunities they have to influence the manner in which designers assemble 3D 
objects, and by the effort required to acquire such skills and abilities. In addition, 
dedicated model translators have been developed to convert BIM data into formats 
such as bills of quantities that are widely used by estimators (Pučko, Šuman & 
Klanšek 2014). Where such translators are available, estimators see little benefit in 
developing the aforementioned skills and abilities.    

An additional constraint is the one-off nature of this estimating approach.  Each 
object needs to be uniquely resourced and costed and this contrasts with the 
structure of many computer-aided estimating applications. These facilitate the re-use 
of element specific resource data (and allow them to be adapted to the requirements 
of specific projects). 

In summary, estimators are not designers and have few opportunities to influence the 
ways in which object data are assembled. This leads them to adopt pragmatic 
approaches to harvest the data prepared by others. An inevitable consequence of 
this is that they need to manipulate these data so that their needs are met. 

• The model moderation costing approach: Estimators seldom adopt model data 
without review (Tiwari et al. 2009). This frequently leads to a restructuring of the data 
to reflect the estimating approaches adopted (e.g. construction processes, work 
zones, trades, project elements) (Amor, Jiang & Chen 2007). Different estimators use 
different approaches to moderate models according to Olatunji (2012). Tools like 
Navisworks enable models that are generated in different applications to be merged. 



Australasian Journal of Construction Economics and Building 

 

40 

These tools facilitate design analyses, reviews, clash and interference detection and 
the ability to interact with the functional attributes of each element. Some of these 
tools also allow users to modify models without compromising their geometrical 
integrity. For instance, a large concrete slab, authored as a single element, can be 
divided into pours (see Figure 4 – note the light green area in the slab model). As 
such, all model elements can be broken down according to how they will be 
resourced and executed. These data can then be exported into dedicated 
applications for further estimate-related processes and analyses. However, this 
approach has some limitations. Integrative platforms generally limit the extent to 
which those who have not authored data are able to make modifications. Where 
modelled data are ambiguous, multiple disciplines may need to be involved to reach 
a resolution. However, clients can be exploited where such interactions are not 
possible (e.g. where a contractor shares a fragmented relationship with a project 
team, especially during bidding (Ashley & Teicholz 1977).  

 

Figure 4: A slab model showing pour ‘cut’ (in light green) 
 

• The process simulation costing approach: Estimates can also be based on 
simulations of the sequence of construction operations. Huang et al. (2009), Chou 
(2011), König, Beißert and Bargstädt (2007), Vozzola, Cangialosi & Lo Turco (2009) 
and Yan (2008) have all experimented with this approach, but their conclusions vary. 
The overarching principle is that different construction scenarios may be simulated 
from a given design model but, in some of the aforementioned cases, the simulation 
tools used were not able to reflect resources appropriately. Furthermore, it is 
complex to incorporate risks into the process models and subsequent simulations. 
Although these process models are helpful for estimating purposes, it is noteworthy 
that they are not yet accepted as contract documents (Olatunji 2014). Contractors 
are those responsible for selecting construction methods and are therefore best 
placed to develop such virtual reality models. Consequently, the simulations 
prepared by other parties should be considered as indicative or advisory. 

These approaches indicate that the challenges of estimating in BIM-enabled environments 
have evolved in a variety of ways. BIM-enabled estimating necessitates the management of 
data. It involves a consideration of what model data to export, how to work with these data, 
how to protect the integrity of the data, how to create and manage tools that work effectively 
in multi-disciplinary settings, and how to represent construction processes authentically in 
digital simulations. However there is currently little empirical evidence about these 
approaches. The goal of the investigation reported in this paper is to explore BIM-enabled 



Australasian Journal of Construction Economics and Building 

 

41 

estimating activities and their relative importance from the perspectives of estimators in each 
of the practice domains noted above.   

Research Method 
As described above, estimating may be ontologically stratified into different practice domains 
(Olatunji 2012). These are informative because they facilitate an understanding and 
appreciation of the imperatives faced by different construction professionals. Whilst the 
concept of predicting costs from digital data is attractive, there are significant challenges 
associated with this seemingly mechanical task. Extracting the quantities of building 
elements from digital models is only part of the challenge that estimators face, as data needs 
to be arranged in useful and usable ways. Once this has occurred, monetary amounts need 
to be associated with these quantities. The construction professionals responsible for 
calculating costs (estimates) and sales (tender) amounts do so in markedly different ways. In 
addition, and within the same practice domain, some estimators are likely to be more 
experienced and successful than others. Skitmore and Wilcock (1994) have shown that 
variability in estimating processes and outcomes is common in construction businesses. 

This study has been designed to explore how estimators in different practice domains have 
embraced BIM estimating processes. We selected an equal number of firms to represent 
four practice domains. For the sake of simplicity and to facilitate triangulation of data, two 
firms (eight in all) were recruited to represent all the domains. Each firm nominated 
participants to contribute to focus group discussions and individual interviews both of which 
used semi-structured prompts. Seventeen participants took part in five focus group 
discussions and four interview sessions. Eighty eight per cent had worked as quantity 
surveyors and construction estimators for an average of over 22 years. They had worked in 
more than ten countries including Australia, United Kingdom, Singapore, Malaysia, Vietnam, 
Fiji and Brunei. Where participants were not estimators, they had worked in project 
management roles with estimators, and were conversant with BIM and BIM-enabled 
estimating applications. Participants had professional backgrounds in architecture, 
construction estimating, software engineering and quantity surveying. The University of 
Newcastle’s ethics committee approved these investigations (Approval number H-2009-
0275). The entirety of these investigations is reported elsewhere (Olatunji 2012). Participants 
were asked to explain or demonstrate how they estimated and planned in BIM-enabled 
environments. Their responses are discussed below. 

Outcomes 
Responses from these interviews were classified in the following five categories: 

• Project conceptualization and design planning 

• 3D visualization and virtual reality 

• Automated estimating, hyper-modeling and tendering 

• Contractor selection through virtual models and estimating during construction 

• Post-construction estimating and using estimate data for facilities management  

It is informative to consider these categories in the context of the RIBA Plan of Work stages 
(RIBA 2013) (Table 1).  It will be noted that the categories identified from the interview data 
straddle the RIBA stages. This arguably highlights the need for protocols that explicitly 
encompass BIM-enabled practices. Nevertheless Table 1 highlights where BIM-enabled 
estimating practices align with the RIBA stages of construction and these are described and 
discussed below. 

 
 



Australasian Journal of Construction Economics and Building 

 

42 

Table 1: Research stages mapped against the RIBA Plan of Work (RIBA, 2013) 

Strategic 
Definition 

Preparation 
and Brief 

Concept 
Design 

Developed 
Design 

Technical 
Design 

Construction Handover and 
Close Out 

In Use 

Stage 1      

 Stage 2   

   Stage 3   

     Stage 4   

      Stage 5 

 

Stage 1: Project Conceptualisation and Design Planning 
Participants saw BIM-enabled estimating starting with understanding clients’ requirements in 
line with their project goals.  The challenges experienced by some estimators at this stage 
are highlighted in the following quote: 

‘Many clients can’t read plans. They might think that they can. A lot of architects can’t 
read plans very well either. The main benefit of 3D BIM is that clients understand the 
building better which gives them more realistic expectations of what they’re getting’ 

Clients need to communicate their requirements to those they have appointed. However, the 
difficulties of appreciating three-dimensional spaces are apparent in the quote above. In 
addition, each project team-partner needs to align their understandings with those of others.   

Some of the activities that occur during this stage are reflected in the quote below: 

‘….if you just get the raw dump of data from a 3D file with everything inside, that 
information is useless. Quantities have to be organised in what we call a cost plan 
situation, a format that makes sense. The cost of a building can be dissected into 
elemental areas to be analysed…’ 

Bearing in mind the multiple different uses to which they are put, BIM data need to be 
manipulated before they are useful to estimators. The participants noted that models had to 
be reconstructed into elements that made sense before they could commence estimating. 
This involves reorganising the data so they depict a particular style of reporting (e.g. 
construction trade, section, element, zone or process). If, for whatever reason, estimators do 
not wish to reorganise their data, they can resort to condensed costing (explained in Stages 
4 and 5). However, if estimates are to reflect all the activities involved in the construction 
process, some remodelling is required. This can occur, for example, where temporary works 
such as scaffolding and/or falsework are required. These items are integral to many 
construction operations and are removed once their temporary purpose has been 
accomplished.  Designers generally do not represent these items in their models.   

Estimators need to be able to visualize project elements and analyse how these elements 
interact. They need to be able to visualise construction processes and other project 
components. These aspects were emphasized by a participant who noted that estimators 
want to be  

‘…able to quickly look at different morphing of the building shape and configuration so 
that we can immediately give the architect and the rest of the design team some 
indication as to how it’s affecting the budget.’ 

In this quote, underlining has been used to emphasize the fact that estimates should reflect 
the intended construction processes. This implies that estimates need to be appropriately 
resourced and accurately modelled. Many of the participants reconstructed their model data 
to reflect cash flow targets, cost plans and how they intended to structure their tenders.  



Australasian Journal of Construction Economics and Building 

 

43 

In summary, the estimating activities in this stage include:  

• Interaction with the client and the project team. 

• Model reconstruction to reflect the construction approach on which the estimate is 
based.  

• Appreciation of the complexities of design components to enable costings to be 
calculated as accurately as possible. 

• Design analyses, including clash detection, interference and value analyses of model 
elements.  

• Resource planning and estimating for each building element. 

• Export of data for ancillary uses. 

Understandably, participants in the different practice domains attached varying degrees of 
importance to these tasks. For example, those in client-related organizations tended to focus 
on representing their clients’ requirements and paid little attention to how the project was to 
be constructed. In contrast, understanding the constraints of a particular project from build-
ability and constructability perspectives was of prime interest to those representing 
contracting organizations. In this context it is interesting to contrast the priorities of 
construction professionals. Those in consulting practices discharged their services as 
umpires acting between their clients and contractors or by addressing the needs of the 
parties who employed them. The estimators in specialist project organizations were 
generally interested in the long-term goals of their projects. As this involved minimizing long-
term risks, they often concentrated on design analyses that enhanced both product and 
construction process models. 

Stage 2 – 3D Visualisation and Virtual Reality 
Participants in client organizations observed that estimating using virtual reality (VR) starts 
with scenario simulation and uses active agents as described below: 

‘Virtual walk-throughs ties in with the client being aware. Adobe has in their free 
reader, the ability to view 3D files which can be spun around. They can also be cut in a 
section and that section line can be adjusted in any plane and moved along. Clients 
love it. It means they can understand something. It’s simple for them to use. They don’t 
need proprietary software and it’s quick. Designers can send them a plan. They can 
see where their office is and they can walk through that with no hassles at all’. 

Based on the interviews, the estimating variables relating to 3D visualization and VR may be 
summarised as: 

• Facilities use scenario simulation, using active agents to demonstrate clients’ 
requirements so that informed choices can be made about priorities during design 
and procurement. 

• Construction scenario simulations which show how construction activities are 
sequenced. This approach may be used as a basis for bid competition on large and 
highly risky projects. This is closely related to the construction contexts already 
established in Stage 1. 

• Cost control: Design and project costs based on simulated models can be 
controlled according to targets. While clients usually focus on controlling the total 
cost of projects, from a contractor’s perspective, production cost control is a priority. 
For integrated project delivery (IPD) projects the focus is on the long-term value of a 
project in preventing wastage, avoiding risks and promoting community engagement. 
In summary, different stakeholders have different perspectives on cost control at this 
stage (and use different tools to achieve their desired outcomes). Clients may focus 



Australasian Journal of Construction Economics and Building 

 

44 

on cost reduction, while contractors and IPD stakeholders focus on making a profit 
and providing value for money respectively.   

• Model-based value engineering: based on scenarios of a facility’s use and 
construction, these facilitate the integrated use of knowledge to inform decisions on 
value-adding designs and procurement alternatives. 

• 4D, 5D, VR and hyper-modeling: 4D involves attaching a timescale to a 3D model.  
5D is based on 4D plus an overlay of costs. VR involves simulating the use of a 
facility or its construction. Hyper-models are formed when non-geometric data are 
linked to a model. These documents include technical notes (for example, handling 
instructions about components and notes about risks).  

• Finalizing project models for estimating and tendering: Modelers seldom 
construct models specifically for estimators. Consequently, estimators have had to 
adopt different design models and then deconstruct and reconstruct them to generate 
models that support the outcomes they require.  

Participants had differing views about the importance of these activities. For example, 
participants in client organizations had a good understanding of hyper-modelling but made 
little use of these facilities (and were still able to prepare reliable estimates without them). 
Moreover, as clients generally do not specify a particular construction approach, participants 
representing clients did not ascribe high importance to construction scenario simulations.  
Instead, they focussed on use scenario simulations, although it was observed that they were 
able to complete their estimating processes reliably without committing much effort to these 
activities. It is interesting to contrast these views with those of participants in contracting 
organizations. Unless contractors’ estimators are involved in model development, they focus 
on devising construction methods during pre-contract estimating. 3D visualization and VR 
was seen to provide contractors with a competitive edge and participants in contracting 
organizations viewed this activity as most important. As consulting practices serve the goals 
of their employers, participants in this domain viewed these activities in a similar way to 
clients’ representatives. Although estimating using model objects was not found to be 
widespread, all the activities that occur were considered to be crucial to developing reliable 
estimates. Participants in specialist-project organizations also ranked all of these activities 
as very important. 

Stage 3: Estimating and Tendering 
All participants agreed that traditional estimating practices prevail. They are largely paper-
based, and make minimal use of CAD. This applies whether or not data are sourced from 
CAD models. Participants identified the following four approaches: 

(a) Data are exported to spreadsheets and then adjusted and re-arranged to prepare 
estimates of cost, time and tender price. 

(b) Using applications such as Navisworks and VICO to remodel project model data, 
work items can be exported or interrogated in a variety of ways (based on location, 
time-lining, trades, sections or elements of buildings). 

(c) Using translator applications such as CostX, models’ descriptive data can be 
exported automatically into bills of quantities templates.  

(d) Using simulation applications such as Synchro, it is possible to extract process 
representations according to estimators’ preferences.  

There was limited agreement about what should be presented in virtual process 
representations (d). Are these representations unique to BIM estimating or a continuation of 
activity-based construction (ABC) estimating? The following comment provides an answer to 
this question: 



Australasian Journal of Construction Economics and Building 

 

45 

‘You push a button and quantities are generated. …if [drawings are] in 2D it is not as 
easy to visualise if you do it in 3D, but even better if you’ve got BIM. You can virtually 
measure all the elements… You can pick up all the dimensions rather than measuring 
it.  If you've got a wall, you don’t have to measure it. If you want internal walls, external 
walls and everything else it would still be a lot simpler if we have got BIM information... 
It would be a lot simpler to measure and once it's measured, you know it's accurate 
because it’s been produced using BIM functions. So we spent less time measuring, 
more time evaluating and helping to formulate the way the project should be going. 
The counter argument to the [one button] is that when you are stepping through the 
measurement process, you are coming to understand the building … If you are just 
presented with a file and you press a button and all these quantities come out, you are 
no wiser than five minutes previously…’ 

The tasks at this stage were seen to include: 

• Automatic export of BIM data in a format that can be imported into computer-aided 
estimating (CAE) systems. 

• Moderation of model data e.g. timeline simulations and evaluated risk assessments 
(ERA) with a focus on specific project components which may be arranged as line 
items, elements, zones, locations, sections, interim report stages and finance 
engineering. 

• Construction process hyper-modeling, including parametric resourcing and costing by 
ERA, and by focusing on prevalent market conditions in relation to customized 
construction method designs.  

• Application of base costs for conceptual budgeting, including provisional estimating 
and market surveys. 

• Conversion of estimates into tenders. 

• Tender documentation, including augmented packaging and submission. 

 

BIM-enabled estimating allows quantification data be exported to CAE platforms. 
Participants saw this activity as crucial. However, different practice domains used these data 
in different ways and these necessitate specific export protocols. Whilst estimators 
representing clients used translators that ensured that BIM data were costed as they appear 
in the model, contractors’ estimators required more flexible solutions. These estimators need 
to predict the costs of successive construction operations and implicit in this is a 
consideration of specific items of plant and equipment and/or other resources. Quantification 
data therefore needed to be manipulated to align with the construction processes (rather 
than the model). This did not preclude clients’ estimators from augmenting model data for 
their estimating activities (including conducting risk analyses, cost analyses related to 
different construction methods and predicting project cash flows). 

Participants also appreciated the efficacy of process hyper-models to support estimates, as 
visualisations were considered to be more informative than texts. Whilst clients’ estimators 
may focus on product data models, participants agreed that process hyper-models provided 
contractors with a competitive edge. Participants representing clients were receptive to 
visualizations of their project at time of tender. The following are the different ways this might 
occur 

• Clients’ estimators could simulate the costs of major project elements using short 
video clips, or show project development processes in their entirety. These clips 
could be used to stimulate discussion about alternatives and/or as a means of 
reviewing progress.  



Australasian Journal of Construction Economics and Building 

 

46 

• Contractors’ estimators could create process hyper-models as short video clips and 
supply these with their tender documentation. These could be further developed after 
contract award in collaboration with clients and updated as the project progresses. 

• Consultant practices could create similar video clips to help their clients visualize the 
cost implications of their decisions. These were seen to be useful in helping reconcile 
clients’ requirements with the provisions made by contractors. 

• Most specialist project organizations would prefer to have both their preliminary and 
detailed process models developed in collaboration with their main contractors from 
the start. Updating could be conducted collaboratively and/or cooperatively. 

In summary, clients’ estimators viewed the automatic importing of BIM product data to their 
applications as highly important. Estimators from other domains need to manipulate BIM 
data before using these in their CAE applications. They saw value in hyper-modelling and 
model reconstruction. Moreover, while clients’ estimators considered auto-pricing based on 
past project data as highly important, other domains favoured costing by ERA, prevalent 
market conditions and customized operational process benchmarks.  

Stage 4: Contractor Selection Based on Virtual Models and Estimating  
Approaches for selecting contractors have remained unchanged for decades (Aje 2012). 
These involve checking for errors and discrepancies in bids. Most importantly, they rely on 
price and descriptive data in contractors’ submissions to judge whether the clients’ terms 
and conditions have been met. Participants felt that BIM assists this activity as follows:  

‘Many clients can’t read plans… The main benefit of 3D BIM is that clients understand 
the building better which gives them more realistic expectations of what they’re 
getting.’ 

Thus, instead of traditional paper-based estimate submissions, BIM makes it possible to use 
virtual construction process models to help clients visualize and analyse proposed 
construction methods.  

‘…So the idea is via an iterative process or via looking at and changing and varying 
the material structure of the building and also varying the operational energy 
considerations involved with operating the building. We can compare it to other 
buildings and also then we can make judgements as to how the construction will go.’ 

As noted above, estimators use different approaches to explore and exploit BIM data. On the 
other hand, clients need to specify the approach they require to be incorporated in their bids. 
Contractors commented that they supplemented their traditional bids with BIM-enabled 
digital resources and incorporated these into their contract documents in the following ways: 

• Object pricing: Cost data can be included in an object as: the predicted costs of an 
object, notes on negotiations where applicable, actual construction costs, notes on 
procurement specifications, guides and embellishments and notes on amendments 
and change decisions. 

• Object pricing of process hyper-models: In contrast to the above, where prices 
are embedded in models, hyper-models allow for the inclusion of resources and 
durations.  

All participants agreed that augmenting tender submissions with BIM-enabled process 
models was valuable; 68% of participants had won large projects using this approach, or had 
participated in bids where BIM was used. In all these cases, the contractors spent ‘obvious’ 
additional costs on bid documentation. However there was no significant change to clients’ 
tender costs. Participants also noted a 65% saving of the time they would have spent on 
quantity calculations when data were exported directly to their preferred CAE application. 



Australasian Journal of Construction Economics and Building 

 

47 

However the time spent developing hyper-models to support bids was difficult to assess and 
was seen to be dependent on the competence of the operator and on the application used. 

Across all business models, participants indicated that the accuracy of their estimates did 
not change significantly when their estimates were based on BIM data. However, quantity 
measurement was faster, more reliable and more accurate than with 2D CAD. Thus, while 
participants could not quantify the extent to which BIM reduced costs, they argued that 
clients benefitted from the openness, control, project value and knowledge-based decisions 
that BIM facilitated. These intangible cost savings resulted from improved communication 
that was facilitated by BIM. 

Participants were asked how BIM affected their tender analyses and selection of contractors. 
The consensus view was that BIM supported e-tendering but whether this was adopted or 
not, tender analyses and contractor selection were relatively unchanged from conventional 
practice; contract prices and contractors’ values were seen as the main determining factors. 
In addition, participants commented on the contribution BIM made to tender analysis in 
terms of: automation (e.g. auto-reporting), error detection (e.g. omissions in model or item 
pricing, erroneous pricing and violation of bidding rules), and data management (e.g. 
whether data were transmittable, re-usable or error-proof). In all cases, BIM was seen to 
have had little impact on these issues. Although visualization helps decision-making, BIM 
had not replaced human judgment in selecting contractors. This involved reviewing bids and 
determining whether contractors were able to support BIM during construction.  

Based on the above, BIM-enabled estimating activities at this stage include: 

• Preparation of virtual representations of construction processes and alternatives  

• Analyses of tenders based on visual, quantitative and qualitative data. BIM enables 
analyses of tender prices in tandem with life-cycle costs and values. 

• Moderation/integration of work-process models to integrate client’s models with those 
of contractors (e.g. to provide feedback on proposals, negotiations or to coordinate 
understanding).  

• Organization of software applications to integrate on-site and offsite systems for cost 
management and project supervision purposes.  

• Object-based communication (and analyses) of project finance matters. These 
replace text-based interim valuations, final accounts and accounts’ reconciliations. 

• Parametric documentation of a project’s financial data, including embedding project 
models with valuations or actual project data, and reconciliation of a project’s 
financial data. 

Participants in clients’ organizations viewed the use of virtual models for bidding and 
reporting as fairly important. Participants in contracting organizations observed that virtual 
representations helped them communicate the merits of their solutions. In addition, these 
also provided clients with opportunities to visualize and understand the choices they made.  
These participants noted that using BIM for tendering was a priority for some contractors, 
and that positive benefits had accrued from these activities. 

While participants in clients’ organizations viewed the integration of clients’ and contractors’ 
process models as important but not compulsory, estimators in contracting organizations 
preferred to interpret their clients’ requirements in line with the strategies they chose. 
Representatives from consulting practices and specialist-project organizations supported the 
use of virtual representations and reporting. Although estimators in consulting practices 
identified some challenges (e.g. the lack of practice frameworks and the motivation of their 
clients), participants in specialist-project organizations thought that BIM adoption was self-
driven and its value was all encompassing.  



Australasian Journal of Construction Economics and Building 

 

48 

Stage 5: Post-construction Cost Management and Facilities Management  
Unlike traditional practices where design, construction and facilities management data are 
fragmented, BIM enables these data to be integrated. Although some participants did not 
have extensive experience of facilities management, the information provided by others, 
especially those in specialist-project firms, was informative. Based on construction cost data, 
estimators still need to make decisions on taxation, depreciation of construction (and 
constructed) facilities, monitoring the cost implications of project performance and updating 
model data (as lifecycle phenomena) for maintenance works. The following quote is from a 
participant in a specialist-project organization: 

‘We operate a complete system; it allows us to do anything from early conceptual 
estimates through to full bills of quantities, through to progress claims, variations, 
financial reporting, tax depreciation, cash flows; we can all run it through this system 
and it all links together so you can carry a job basically all the way through from 
concepts through to basically tax and operational life cycle costings...’ 

Following earlier comments from participants in client organizations about database 
management, and in line with the quote above, it is evident that post-construction models 
contain cost information pertaining to when a project is handed over. When this is extended 
to facilities operations, the data can be used for lifecycle costing purposes. In addition, they 
can be used to update asset inventories and as auto-alerts when items require replacement 
or maintenance.   

Based on participants’ observations, the BIM-enabled estimating processes that support 
facilities management include integration of model data into asset inventories, the use of 
these inventories to track assets, providing management with intelligence for future 
procurement opportunities, consistently updated cost data in lifecycle product models and 
value analyses of space usage to inform future projects. 

Applications of Study Findings  
Participants viewed Stage 4: Contractor selection based on virtual models and estimating as 
the most value-adding stage leading to successful BIM estimating. Stage 3: Automated 
estimating and hyper modelling was ranked next, followed by Stage 2: 3D Visualization and 
virtual reality. The reasons for this can be ascribed to: 

• New and unfamiliar skills being required to use VR. VR is not included in most 
professional and academic curricula and is not a mandatory requirement for most 
tenders. 

• VR is a simulation tool. As such, what is shown on screen might not be what actually 
occurs. Thus, the correlation between VR and accurate estimates is debatable. Data 
from VR are neither exportable nor do they make estimating activities faster or more 
accurate. 

Overall, participants viewed model decoupling, visualization and application of base costs as 
the most significant activities, while hyper-modelling, construction simulation and 
establishment of a basis for asset tracking were viewed as the least important. There are 
clear inferences to draw from this: 

• Estimators found it difficult to manipulate BIM data to support their estimates. 
• Visualization helps designers clarify their thoughts, reducing the need for guesswork 

due to uncertain design information. 
• Estimators rely on historical data and these are contingent on the previous two 

points. 
• Like VR, hyper-modelling requires new skills. Clients rarely require hyper-models and 

there is therefore little incentive for estimators to use these tools. 



Australasian Journal of Construction Economics and Building 

 

49 

• Currently, BIM-enabled asset tracking is also rarely called for and the incentives for 
this activity are weak.    

Conclusion 
This study has shown that BIM data may be used to assist with estimating. Quantification 
data need to be exported, (re)structured and moderated with care. This requires estimators 
to consider different risk areas and to accommodate these in their presentations to clients. 
However stakeholders find it difficult to visualize the factors that have cost consequences.  
BIM process hyper-models provide such opportunities by facilitating the integration of 
contributing disciplines’ views, thereby creating a common understanding of costs.  

There are additional challenges that estimators face. As with conventional processes, 
comprehensive guides are required to inform practitioners how to develop and use these 
models. Rather than applying conventional rules and techniques (which were implemented 
to ensure the integrity of quantification data and estimating outcomes) the current challenge 
is how to manage and integrate data. Importantly, BIM facilitates integration and has the 
potential to enable the views of different practice domains to converge. However, this is 
outside the scope of this study. It is recommended that further investigations focus on: 

• Developing practice guides for process modelling, and the standards for integrating 
these across different applications and disciplines. 

• Communicating the benefits of BIM-enabled estimating to clients so that they more 
fully understand the professional services provided to them. BIM-enabled services 
warrant new approaches for valuing the professional services offered by estimators. 

• Process models require activities to have logical connections between themselves 
and the prescribed outcomes. This area requires further empirical analysis. 

 

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	Perspectives on Modelling BIM-enabled Estimating Practices
	Abstract
	Background
	Different Forms of Estimating

	Review of Related Studies
	Computer - aided Estimating: Has Anything Changed?
	BIM Capabilities and the Quality of Construction Estimates: Does Parametricism Make any Difference?
	BIM Estimating Process Modelling: a Critique of Options

	Research Method
	Outcomes
	Stage 1: Project Conceptualisation and Design Planning
	Stage 2 – 3D Visualisation and Virtual Reality
	Stage 3: Estimating and Tendering
	Stage 4: Contractor Selection Based on Virtual Models and Estimating
	Stage 5: Post-construction Cost Management and Facilities Management
	Applications of Study Findings

	Conclusion
	References