The author wants to proof with qualitative data that projects managed using BIM achieve better outcomes than comparable ones not using them. Factors influencing the success of projects are usually more qualitative than quantitative (Fortune and White, 2006) and that social forces have a great effect on the implementation of new technologies (Williams and Edge, 1996) and on the success of projects with complex inter-organisational structures (Maurer, 2010 and Kadefors, 2004).
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MT - Using BIM as a PM Tool: 2.4 Chapter Summary
The literature review shows a clear tendency towards major project complexity (Chan et al., 2004; Williams, 2002; Alshawi and Ingirige, 2003). It also shows a linkage between complex projects and the existence of inter-organizational associations to accomplish these projects (Maurer, 2010).A second linkage has been drawn between inter-organizational associations and the need for “better integration, cooperation, and coordination of construction project teams” (Cicmil & Marshall 2005, cited in Maunula, 2008).
The unprecedented level of communication, collaboration and efficiency that BIM allows (Lee, 2008) seems to draw the last linkage on this chain: we have more complex projects that require inter-organizational associations; these associations require better coordination and cooperation; BIM promises to allow this increased coordination and collaboration. Ignoring BIM from the Project Management point of view seems to the author as a big mistake.
Lastly, we have seen how the industry requires a shift from a document based approach to communicating information to what many have chosen to name as Project Integrated Databases. The scholarly literature and statements from BIM supporting bodies suggest that BIM could help on this shift from documents to PIDs, for its nature is the “creation and maintenance of an integrated collaborative database of multi-dimensional information”, as we have seen in the definition of BIM on Chapter 1.
We have also seen a list of 10 potential benefits that PMs can get by implementing BIM in the projects (Table 2.1). BIM can thus be the catalyst that will enable Project Managers to reengineer the processes to better integrate the different stakeholders involved in modern construction projects.
There are and there will be challenges to the acceptance and implementation of BIM. Some of them are inherent to the new associations between stakeholders needed. The correct implementation of BIM requires “understanding and developing inter-organizational work practices” (Harty, 2005, cited in Maunula, 2008). This requirement for the implementation of BIM could be the catalyst for an overall shift towards better, more collaborative processes that could improve drastically the results and the productivity of the companies working on the AEC Industry.
The intention of this dissertation is thus to analyze the benefits of BIM as a Project Management tool and to explore in which ways and to what extent BIM will help the implementation of better processes to successfully deliver complex construction projects and which are the main challenges ahead. The methodology to achieve these goals will be explained on the following chapter.
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The unprecedented level of communication, collaboration and efficiency that BIM allows (Lee, 2008) seems to draw the last linkage on this chain: we have more complex projects that require inter-organizational associations; these associations require better coordination and cooperation; BIM promises to allow this increased coordination and collaboration. Ignoring BIM from the Project Management point of view seems to the author as a big mistake.
Lastly, we have seen how the industry requires a shift from a document based approach to communicating information to what many have chosen to name as Project Integrated Databases. The scholarly literature and statements from BIM supporting bodies suggest that BIM could help on this shift from documents to PIDs, for its nature is the “creation and maintenance of an integrated collaborative database of multi-dimensional information”, as we have seen in the definition of BIM on Chapter 1.
We have also seen a list of 10 potential benefits that PMs can get by implementing BIM in the projects (Table 2.1). BIM can thus be the catalyst that will enable Project Managers to reengineer the processes to better integrate the different stakeholders involved in modern construction projects.
There are and there will be challenges to the acceptance and implementation of BIM. Some of them are inherent to the new associations between stakeholders needed. The correct implementation of BIM requires “understanding and developing inter-organizational work practices” (Harty, 2005, cited in Maunula, 2008). This requirement for the implementation of BIM could be the catalyst for an overall shift towards better, more collaborative processes that could improve drastically the results and the productivity of the companies working on the AEC Industry.
The intention of this dissertation is thus to analyze the benefits of BIM as a Project Management tool and to explore in which ways and to what extent BIM will help the implementation of better processes to successfully deliver complex construction projects and which are the main challenges ahead. The methodology to achieve these goals will be explained on the following chapter.
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End of Support for Windows XP
If you are of that 7,33% still on windows XP consider upgrading. Support ends on April 8, 2014
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Clash Detection Using Autodesk Navisworks Manage
Testing the Clash Detection Feature of Navisworks Manage to compare it to other platforms.
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BIM,
Clash Detection,
Navisworks
Clash Detection Using Tekla BIM Sight
Testing the Clash Detection Feature of Tekla BIM Sight to compare it to other platforms.
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BIM,
Clash Detection,
Tekla BIMsigth
MT - Using BIM as a PM Tool: 2.3.2– BIM: more than just another IOIS
The AEC Industry is based on the collaboration of several parties during the project life-cycle, and the success of projects depends on exchanging information between stakeholders on a timely manner. IOIS aim to increase the sharing of information between partners. Some years back, researchers promised that IOIS would be used “to enhance construction project documentation and control and to revolutionize the way in which a construction project team conducts business” (Nitithamyong and Skibniewski, 2004: p. 492).
Despite the benefits brought by the extensive use of IOIS, these systems are still lacking on the aspect of integration. The author has the experience of working with some of this IOIS (shared FTP portals in USA and document management systems in Germany and Spain) and they all seem to be mostly used just as online repositories of documents that all stakeholders can access. Without disregarding what the existing IOIS have accomplished – reduction of email based communication, safe storage of documents, improved communication, etc - it seems that another shift in the way things are done is needed.
BIM could be the key approach to adopt to ensure this integration and shift from the document paradigm to the Integrated Database paradigm happens. On this line of thought, the International Alliance for Interoperability [IAI] has been developing since 1995 a standard for sharing building and construction industry data. This standard has been named Industry Foundation Classes [IFC] and it follows on the work done with STEP for Product Models. Although IAI’s mission is to “support open BIM through the life cycle” (IAI, 2010a), their holistic approach to BIM encompasses many other aspects of the project delivery process. Their Information Delivery Manual [IDM] (IAI, 2010b) considers, in addition to the IFC] standards, a methodology to support the implementation of BIM, addressing the business processes and information exchange requirements.
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Despite the benefits brought by the extensive use of IOIS, these systems are still lacking on the aspect of integration. The author has the experience of working with some of this IOIS (shared FTP portals in USA and document management systems in Germany and Spain) and they all seem to be mostly used just as online repositories of documents that all stakeholders can access. Without disregarding what the existing IOIS have accomplished – reduction of email based communication, safe storage of documents, improved communication, etc - it seems that another shift in the way things are done is needed.
BIM could be the key approach to adopt to ensure this integration and shift from the document paradigm to the Integrated Database paradigm happens. On this line of thought, the International Alliance for Interoperability [IAI] has been developing since 1995 a standard for sharing building and construction industry data. This standard has been named Industry Foundation Classes [IFC] and it follows on the work done with STEP for Product Models. Although IAI’s mission is to “support open BIM through the life cycle” (IAI, 2010a), their holistic approach to BIM encompasses many other aspects of the project delivery process. Their Information Delivery Manual [IDM] (IAI, 2010b) considers, in addition to the IFC] standards, a methodology to support the implementation of BIM, addressing the business processes and information exchange requirements.
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MT - Using BIM as a PM Tool: 2.3.1– From documents to Project Integrated Databases
As we have seen, there is a need for better integration of project teams (Manaula 2008), one way to achieve this integration is by the proper use of Inter-Organizational Information Systems [IOIS] (Ibid.).
“The construction and facilities industry has historically used a document-based way of working, through drawings and reports, and has communicated through ‘unstructured’ text such as letters and emails” (BSI, 2010, p. 2).
A document based way of working means that through the project life cycle there is an “unstructured stream of text or graphic entities” (BSI, 2010, p. 2). This unstructured stream is a challenge for better integrated practices. The information exchanged at the document level is generally “fuzzy, unformatted or difficult to interpret” (Ajam et. al. 2010: p. 763).
A key aspect is to understand what means “proper use” of the IOIS mentioned in the beginning of this section. Ajam et al. (2010) argue that the proper use is that of going from document sharing practices to share information at the object or element level. The proper use of these IOIS is thus the one that allows the much needed integration of project teams and the switch from the mentioned unstructured stream of entities to an integrated and interrelated use of information, what has been named by several authors as the Project Integrated Database [PID] paradigm.
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Figure 2.3 Use of e-business solutions in the EU industries
(adapted from e-business Watch, 2006)
(adapted from e-business Watch, 2006)
“The construction and facilities industry has historically used a document-based way of working, through drawings and reports, and has communicated through ‘unstructured’ text such as letters and emails” (BSI, 2010, p. 2).
A document based way of working means that through the project life cycle there is an “unstructured stream of text or graphic entities” (BSI, 2010, p. 2). This unstructured stream is a challenge for better integrated practices. The information exchanged at the document level is generally “fuzzy, unformatted or difficult to interpret” (Ajam et. al. 2010: p. 763).
A key aspect is to understand what means “proper use” of the IOIS mentioned in the beginning of this section. Ajam et al. (2010) argue that the proper use is that of going from document sharing practices to share information at the object or element level. The proper use of these IOIS is thus the one that allows the much needed integration of project teams and the switch from the mentioned unstructured stream of entities to an integrated and interrelated use of information, what has been named by several authors as the Project Integrated Database [PID] paradigm.
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MT - Using BIM as a PM Tool: 2.3 – BIM and Information Management
The process on how information is exchanged is thus seen as a key aspect for successful implementation of BIM. This exchange of information is mostly done through ICT. A study shows that the construction industry has had a much lower integration of ICT and e-business processes than other industries in the European Union [EU] (e-Business Watch, 2006) ICT and e-business are generally used much less than in the other industries, as it can be seen on figure 2.3. In countries like Spain, according to the study by Bayo-Moriones and Lera-López (2007), the Building Industry is “behind the rest of sectors in the adoption rate of several ICT” (Ibid. P. 363).
The low rate of adoption of ICT compared to other industries is a challenge for the implementation of better ICT processes like BIM. Nevertheless, a bigger problem for this implementation might be the way the construction industry has traditionally worked. We will see on the following subsection how the change needed embraces the overall approach towards ICT and not just a shift from CAD to BIM.
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The low rate of adoption of ICT compared to other industries is a challenge for the implementation of better ICT processes like BIM. Nevertheless, a bigger problem for this implementation might be the way the construction industry has traditionally worked. We will see on the following subsection how the change needed embraces the overall approach towards ICT and not just a shift from CAD to BIM.
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ICT,
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MT - Using BIM as a PM Tool: 2.2.2 The BIM Potential
When people work together on a project, communicating specific characteristics of the project amongst the different parties involved requires documentation of these characteristics (Lee, 2008). Traditionally, this documentation was done on a paper or document basis (BSI, 2010). BIM takes the traditional paper-based tools of construction projects, puts them on a virtual environment and allows a level of efficiency, communication and collaboration that exceeds those of traditional construction processes (Lee, 2008).
Moreover “the coordination of complex project systems is perhaps the most popular application of BIM at this time. It is an ideal process to develop collaboration techniques and a commitment protocol among the team members.” (Grilo and Jardim-Goncalves, 2010 : p. 524).
BIM can be of great use on all stages of the project life-cycle. It has many dimensions: it can be used by the owner to understand project needs; by the design team to analyze, design and develop the project; by the contractor to manage the construction of the project and by the facility manager [FM] during operation and decommissioning phases (Grilo and Jardim-Goncalves, 2010).
Aouad et al. (2006) defined this multidimensional capacity of BIM as nD modelling, for it allows adding an almost infinite number of dimensions to the Building Model. This “n” dimensions can be seen in Figure 2.2 that shows what BSI (2010) understands as a complete BIM.
Project Management has a wide scope of services or dimensions; most of them, like managing Quality, Time, Risks, Procurement and Integrations (PMI, 2004) are dimensions that can be integrated into a BIM, as seen in Figure 2.2.. Although most BIM projects do not yet use BIM for all dimensions (BSI, 2010), it is on this nD understanding of BIM that the author is interested, for it is the approach that makes BIM a relevant tool for Project Managers.
As we have seen, very few PM scholars have studied BIM from the PM point of view. Other than on scientific Journals, an article from Allison (2010) is maybe the one that addresses the BIM potential as a PM Tool more directly. Allison describes “10 reasons why project manager should champion 5D BIM” (Table 2.1). 5D BIM is traditionally understood as BIM that includes, besides the 3D model, Scheduling information (the 4th D) and information for estimating the project from the model (the 5th D). Although the article is from an employee of a BIM software vendor, and the potential of BIM for PM might be slightly exaggerated, the list of advantages for PM practitioners is worth considering. These advantages are compiled in Table 2.1, and should be seen as potential ways in which BIM can benefit Project Managers.
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Moreover “the coordination of complex project systems is perhaps the most popular application of BIM at this time. It is an ideal process to develop collaboration techniques and a commitment protocol among the team members.” (Grilo and Jardim-Goncalves, 2010 : p. 524).
BIM can be of great use on all stages of the project life-cycle. It has many dimensions: it can be used by the owner to understand project needs; by the design team to analyze, design and develop the project; by the contractor to manage the construction of the project and by the facility manager [FM] during operation and decommissioning phases (Grilo and Jardim-Goncalves, 2010).
Aouad et al. (2006) defined this multidimensional capacity of BIM as nD modelling, for it allows adding an almost infinite number of dimensions to the Building Model. This “n” dimensions can be seen in Figure 2.2 that shows what BSI (2010) understands as a complete BIM.
Project Management has a wide scope of services or dimensions; most of them, like managing Quality, Time, Risks, Procurement and Integrations (PMI, 2004) are dimensions that can be integrated into a BIM, as seen in Figure 2.2.. Although most BIM projects do not yet use BIM for all dimensions (BSI, 2010), it is on this nD understanding of BIM that the author is interested, for it is the approach that makes BIM a relevant tool for Project Managers.
As we have seen, very few PM scholars have studied BIM from the PM point of view. Other than on scientific Journals, an article from Allison (2010) is maybe the one that addresses the BIM potential as a PM Tool more directly. Allison describes “10 reasons why project manager should champion 5D BIM” (Table 2.1). 5D BIM is traditionally understood as BIM that includes, besides the 3D model, Scheduling information (the 4th D) and information for estimating the project from the model (the 5th D). Although the article is from an employee of a BIM software vendor, and the potential of BIM for PM might be slightly exaggerated, the list of advantages for PM practitioners is worth considering. These advantages are compiled in Table 2.1, and should be seen as potential ways in which BIM can benefit Project Managers.
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Labels:
BIM,
Master Thesis,
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MT - Using BIM as a PM Tool: 2.2.1 The BIM Background
“Traditional representation methods used by architects and engineers for hundreds of years, such as scale drawings, renderings, and three dimensional scale models, contain only a small part of the information needed to interpret and assess the quality of the design” (Khemlani et al., 1998).
The first Computer Aided Design [CAD] application was invented in 1963 by Ivan Sutherland (Broquetas, 2010a). Widespread adoption of this new technology in the AEC industry did not happen in a few years, it took decades, and when it happened the Adoption of CAD software in AEC firms was progressive, and it is nowadays widely spread in virtually all architectural firms (Broquetas, 2010b). Some resisted the adoption of the CAD systems, and others have argued that CAD poses some challenges to creative design (Lawson, 2002). Nevertheless, in 2009, the result of a study and poll amongst AEC industry leaders, showed CAD as the greatest advance in construction history (Architect’s Journal, 2009).
Despite the relevance taken by CAD in the AEC industry, Khemnlani et al. (1998) argued that CAD simply imported the traditional representation methods used for hundreds of years by architects and engineers into the computer environment, and with that, the informational deficiencies that these methods imply were incorporated into the new way of designing and documenting projects. They foresaw the need for a more intelligent way of documenting projects that “will embody some of the knowledge added to the interpretation of drawings by the human observers” (Khemnlani et al., 1998 : p. 50).
While the AEC industry was slowly adopting CAD, the product development and manufacturing industry [PDM] adopted it much faster and the use in this industry rapidly evolved into a modelling process (Lee, 2008). This modelling approach raised the need for the PDM industry to develop practices of better integration of multidisciplinary teams. Due to this need, “since 1984 the International Organization for Standardization (ISO) has been working on the development of a comprehensive standard for the electronic exchange of product data between computer-based product life-cycle systems” (Pratt, 2001 : p. 102). This standard is named STandard for the Exchange of Product model data [STEP] and is included in the ISO 10303: Automation systems and integration, Product data representation and exchange (Ibid.) and its goal is to “develop common representations of complex products for communicating information between CAD and other design applications” (Eastman and Siabiris, 1995 : p. 284)
In the AEC Industry, the idea of integrated product models for buildings, or Building Product Models [BPM] has been around for many years with one of its pioneers being Charles Eastman (Eastman and Siabiris, 1995; Eastman, 1999) who has used the term since the late 70s of the 20th century. The integrated approach was for the first time named Building Information Modelling [BIM] by Autodesk employee Phil Bernstein (Wikipedia, 2010) although many argue that the term is essentially the same as BPM (Yessios, 2004), so Eastman should be given the “father of BIM” title.
The concept of BIM is thus not so new, but thanks to the computational speed and memory available today (Yessios, 2004) and the strong push from software vendors (Holzer, 2007) the interest in BIM has raised very importantly in recent years both in scholarly circles (Figure 1.3) as well as in the general public (Figure 1.4).
BIM is, as it will be seen in the following section, a set of tools and processes with the potential to change the AEC Industry in the same way the modelling approach changed the manufacturing sector. Both technological requirements and commercial interests are also aligned to allow widespread implementation of BIM. With this alignment of factors, the author of this dissertation sees no better time to analyze its potential benefits for the AEC Industry.
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The first Computer Aided Design [CAD] application was invented in 1963 by Ivan Sutherland (Broquetas, 2010a). Widespread adoption of this new technology in the AEC industry did not happen in a few years, it took decades, and when it happened the Adoption of CAD software in AEC firms was progressive, and it is nowadays widely spread in virtually all architectural firms (Broquetas, 2010b). Some resisted the adoption of the CAD systems, and others have argued that CAD poses some challenges to creative design (Lawson, 2002). Nevertheless, in 2009, the result of a study and poll amongst AEC industry leaders, showed CAD as the greatest advance in construction history (Architect’s Journal, 2009).
Despite the relevance taken by CAD in the AEC industry, Khemnlani et al. (1998) argued that CAD simply imported the traditional representation methods used for hundreds of years by architects and engineers into the computer environment, and with that, the informational deficiencies that these methods imply were incorporated into the new way of designing and documenting projects. They foresaw the need for a more intelligent way of documenting projects that “will embody some of the knowledge added to the interpretation of drawings by the human observers” (Khemnlani et al., 1998 : p. 50).
While the AEC industry was slowly adopting CAD, the product development and manufacturing industry [PDM] adopted it much faster and the use in this industry rapidly evolved into a modelling process (Lee, 2008). This modelling approach raised the need for the PDM industry to develop practices of better integration of multidisciplinary teams. Due to this need, “since 1984 the International Organization for Standardization (ISO) has been working on the development of a comprehensive standard for the electronic exchange of product data between computer-based product life-cycle systems” (Pratt, 2001 : p. 102). This standard is named STandard for the Exchange of Product model data [STEP] and is included in the ISO 10303: Automation systems and integration, Product data representation and exchange (Ibid.) and its goal is to “develop common representations of complex products for communicating information between CAD and other design applications” (Eastman and Siabiris, 1995 : p. 284)
In the AEC Industry, the idea of integrated product models for buildings, or Building Product Models [BPM] has been around for many years with one of its pioneers being Charles Eastman (Eastman and Siabiris, 1995; Eastman, 1999) who has used the term since the late 70s of the 20th century. The integrated approach was for the first time named Building Information Modelling [BIM] by Autodesk employee Phil Bernstein (Wikipedia, 2010) although many argue that the term is essentially the same as BPM (Yessios, 2004), so Eastman should be given the “father of BIM” title.
The concept of BIM is thus not so new, but thanks to the computational speed and memory available today (Yessios, 2004) and the strong push from software vendors (Holzer, 2007) the interest in BIM has raised very importantly in recent years both in scholarly circles (Figure 1.3) as well as in the general public (Figure 1.4).
BIM is, as it will be seen in the following section, a set of tools and processes with the potential to change the AEC Industry in the same way the modelling approach changed the manufacturing sector. Both technological requirements and commercial interests are also aligned to allow widespread implementation of BIM. With this alignment of factors, the author of this dissertation sees no better time to analyze its potential benefits for the AEC Industry.
Show me more...
Labels:
BIM,
Master Thesis,
Project Management
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