Building information modeling





Building information modeling (BIM) is a process involving the generation and management of digital representations of physical and functional characteristics of places. Building information models (BIMs) are files (often but not always in proprietary formats and containing proprietary data) which can be extracted, exchanged or networked to support decision-making regarding a building or other built asset. Current BIM software is used by individuals, businesses and government agencies who plan, design, construct, operate and maintain diverse physical infrastructures, such as water, refuse, electricity, gas, communication utilities, roads, railways, bridges, ports and tunnels.




Contents






  • 1 BIM origins and elements


  • 2 Definition


  • 3 BIM throughout the project life-cycle


    • 3.1 Management of building information models


    • 3.2 BIM in construction management


    • 3.3 BIM in facility operation


    • 3.4 BIM in land administration and cadastre




  • 4 BIM software


    • 4.1 Non-proprietary or openBIM standards




  • 5 International BIM developments


    • 5.1 Asia


      • 5.1.1 Hong Kong


      • 5.1.2 India


      • 5.1.3 Iran


      • 5.1.4 Malaysia


      • 5.1.5 Singapore


      • 5.1.6 South Korea


      • 5.1.7 United Arab Emirates




    • 5.2 Europe


      • 5.2.1 Austria


      • 5.2.2 Czech Republic


      • 5.2.3 Estonia


      • 5.2.4 France


      • 5.2.5 Germany


      • 5.2.6 Ireland


      • 5.2.7 Italy


      • 5.2.8 Lithuania


      • 5.2.9 The Netherlands


      • 5.2.10 Norway


      • 5.2.11 Poland


      • 5.2.12 Portugal


      • 5.2.13 Russia


      • 5.2.14 Slovakia


      • 5.2.15 Spain


      • 5.2.16 Switzerland


      • 5.2.17 United Kingdom




    • 5.3 North America


      • 5.3.1 Canada


      • 5.3.2 United States of America




    • 5.4 Africa


      • 5.4.1 Nigeria


      • 5.4.2 South Africa




    • 5.5 Oceania


      • 5.5.1 Australia


      • 5.5.2 New Zealand






  • 6 Anticipated future potential


    • 6.1 BIM-GIS integration


    • 6.2 Building information science




  • 7 See also


  • 8 References


  • 9 Further reading





BIM origins and elements


The concept of BIM has existed since the 1970s.[1][2][3]


The term 'building model' (in the sense of BIM as used today) was first used in papers in the mid-1980s: in a 1985 paper by Simon Ruffle eventually published in 1986,[4] and later in a 1986 paper by Robert Aish[5] - then at GMW Computers Ltd, developer of RUCAPS software - referring to the software's use at London's Heathrow Airport.[6] The term 'Building Information Model' first appeared in a 1992 paper by G.A. van Nederveen and F. P. Tolman.[7]


However, the terms 'Building Information Model' and 'Building Information Modeling' (including the acronym "BIM") did not become popularly used until some 10 years later. In 2002, Autodesk released a white paper entitled "Building Information Modeling,"[8] and other software vendors also started to assert their involvement in the field.[9] By hosting contributions from Autodesk, Bentley Systems and Graphisoft, plus other industry observers, in 2003,[10] Jerry Laiserin helped popularize and standardize the term as a common name for the digital representation of the building process.[11] Facilitating exchange and interoperability of information in digital format had previously been offered under differing terminology by Graphisoft as "Virtual Building", Bentley Systems as "Integrated Project Models", and by Autodesk or Vectorworks as "Building Information Modeling".


The pioneering role of applications such as RUCAPS, Sonata and Reflex has been recognized by Laiserin[12] as well as the UK's Royal Academy of Engineering.[13]


As Graphisoft had been developing such solutions for longer than its competitors, Laiserin regarded its ArchiCAD application as then "one of the most mature BIM solutions on the market."[14] Following its launch in 1987, ArchiCAD became regarded by some as the first implementation of BIM,[15][16] as it was the first CAD product on a personal computer able to create both 2D and 3D geometry, as well as the first commercial BIM product for personal computers.[15][17][18]



Definition


The US National Building Information Model Standard Project Committee has the following definition:



Building Information Modeling (BIM) is a digital representation of physical and functional characteristics of a facility. A BIM is a shared knowledge resource for information about a facility forming a reliable basis for decisions during its life-cycle; defined as existing from earliest conception to demolition.[19]

Traditional building design was largely reliant upon two-dimensional technical drawings (plans, elevations, sections, etc.). Building information modeling extends this beyond 3D, augmenting the three primary spatial dimensions (width, height and depth) with time as the fourth dimension (4D)[20] and cost as the fifth (5D).[21]
More recently there are also references to a sixth dimension (6D) representing building environmental and sustainability aspects, and a seventh dimension (7D) for through-life facility management, although there are conflicting definitions (6D BIM).[22][23]
BIM therefore covers more than just geometry. It also covers spatial relationships, light analysis, geographic information, and quantities and properties of building components (for example, manufacturers' details).


BIM involves representing a design as combinations of "objects" – vague and undefined, generic or product-specific, solid shapes or void-space oriented (like the shape of a room), that carry their geometry, relations and attributes. BIM design tools allow extraction of different views from a building model for drawing production and other uses. These different views are automatically consistent, being based on a single definition of each object instance.[24] BIM software also defines objects parametrically; that is, the objects are defined as parameters and relations to other objects, so that if a related object is amended, dependent ones will automatically also change.[24] Each model element can carry attributes for selecting and ordering them automatically, providing cost estimates as well as material tracking and ordering.[24]


For the professionals involved in a project, BIM enables a virtual information model to be handed from the design team (architects, landscape architects, surveyors, civil, structural and building services engineers, etc.) to the main contractor and subcontractors and then on to the owner/operator; each professional adds discipline-specific data to the single shared model. This reduces information losses that traditionally occurred when a new team takes 'ownership' of the project, and provides more extensive information to owners of complex structures.



BIM throughout the project life-cycle


Use of BIM goes beyond the planning and design phase of the project, extending throughout the building life cycle, supporting processes including cost management, construction management, project management and facility operation.



Management of building information models


Building information models span the whole concept-to-occupation time-span. To ensure efficient management of information processes throughout this span, a BIM manager (also sometimes defined as a virtual design-to-construction, VDC, project manager – VDCPM) might be appointed. The BIM manager is retained by a design build team on the client's behalf from the pre-design phase onwards to develop and to track the object-oriented BIM against predicted and measured performance objectives, supporting multi-disciplinary building information models that drive analysis, schedules, take-off and logistics.[25][26] Companies are also now considering developing BIMs in various levels of detail, since depending on the application of BIM, more or less detail is needed, and there is varying modeling effort associated with generating building information models at different levels of detail.[27]



BIM in construction management


Participants in the building process are constantly challenged to deliver successful projects despite tight budgets, limited manpower, accelerated schedules, and limited or conflicting information. The significant disciplines such as architectural, structural and MEP designs should be well coordinated, as two things can’t take place at the same place and time. Building Information Modeling aids in collision detection at the initial stage, identifying the exact location of discrepancies.


The BIM concept envisages virtual construction of a facility prior to its actual physical construction, in order to reduce uncertainty, improve safety, work out problems, and simulate and analyze potential impacts.[28] Sub-contractors from every trade can input critical information into the model before beginning construction, with opportunities to pre-fabricate or pre-assemble some systems off-site. Waste can be minimised on-site and products delivered on a just-in-time basis rather than being stock-piled on-site.[28]


Quantities and shared properties of materials can be extracted easily. Scopes of work can be isolated and defined. Systems, assemblies and sequences can be shown in a relative scale with the entire facility or group of facilities. BIM also prevents errors by enabling conflict or 'clash detection' whereby the computer model visually highlights to the team where parts of the building (e.g.:structural frame and building services pipes or ducts) may wrongly intersect.



BIM in facility operation


BIM can bridge the information loss associated with handling a project from design team, to construction team and to building owner/operator, by allowing each group to add to and reference back to all information they acquire during their period of contribution to the BIM model. This can yield benefits to the facility owner or operator.


For example, a building owner may find evidence of a leak in his building. Rather than exploring the physical building, he may turn to the model and see that a water valve is located in the suspect location. He could also have in the model the specific valve size, manufacturer, part number, and any other information ever researched in the past, pending adequate computing power. Such problems were initially addressed by Leite and Akinci when developing a vulnerability representation of facility contents and threats for supporting the identification of vulnerabilities in building emergencies.[29]


Dynamic information about the building, such as sensor measurements and control signals from the building systems, can also be incorporated within BIM software to support analysis of building operation and maintenance.[30]


There have been attempts at creating information models for older, pre-existing facilities. Approaches include referencing key metrics such as the Facility Condition Index (FCI), or using 3D laser-scanning surveys and photogrammetry techniques (both separately or in combination) to capture accurate measurements of the asset that can be used as the basis for a model. Trying to model a building constructed in, say 1927, requires numerous assumptions about design standards, building codes, construction methods, materials, etc., and is therefore more complex than building a model during design.


One of the challenges to the proper maintenance and management of existing facilities is understanding how BIM can be utilized to support a holistic understanding and implementation of building management practices and “cost of ownership” principles that support the full life cycle of a building.  An American National Standard entitled APPA 1000 – Total Cost of Ownership for Facilities Asset Management incorporates BIM to factor in a variety of critical requirements and costs over the life-cycle of the building, including but not limited to: replacement of energy, utility, and safety systems; continual maintenance of the building exterior and interior and replacement of materials; updates to design and functionality; and recapitalization costs.



BIM in land administration and cadastre


BIM can potentially offer some benefit for managing stratified cadastral spaces in urban built environments. The first benefit would be enhancing visual communication of interweaved, stacked and complex cadastral spaces for non-specialists. The rich amount of spatial and semantic information about physical structures inside models can aid comprehension of cadastral boundaries, providing an unambiguous delineation of ownership, rights, responsibilities and restrictions. Additionally, using BIM to manage cadastral information could advance current land administration systems from a 2D-based and analogue data environment into a 3D digital, intelligent, interactive and dynamic one.[31] BIM could also unlock value in the cadastral information by forming a bridge between that information and the interactive lifecycle and management of buildings.[32]



BIM software


The first software tools developed for modelling buildings emerged in the late 1970s and early 1980s, and included workstation products such as Chuck Eastman's Building Description System and GLIDE, RUCAPS, Sonata, Reflex and Gable 4D Series. The early applications, and the hardware needed to run them, were expensive, which limited widespread adoption. ArchiCAD's Radar CH, released in 1984 was the first modelling software made available on a personal computer.[17]


Due to the complexity of gathering all the relevant information when working with BIM on a building project some companies have developed software designed specifically to work in a BIM framework. These packages differ from architectural drafting tools such as AutoCAD by allowing the addition of further information (time, cost, manufacturers' details, sustainability and maintenance information, etc.) to the building model.


There is a BIM module in open source CAD software FreeCAD.



Non-proprietary or openBIM standards


BIM is often associated with Industry Foundation Classes (IFCs) and aecXML – data structures for representing information. IFCs have been developed by buildingSMART (the former International Alliance for Interoperability), as a neutral, non-proprietary or open standard for sharing BIM data among different software applications (some proprietary data structures have been developed by CAD vendors incorporating BIM into their software).


Poor software interoperability has long been regarded as an obstacle to industry efficiency in general and to BIM adoption in particular. In August 2004 a US National Institute of Standards and Technology (NIST) report[33] conservatively estimated that $15.8 billion was lost annually by the U.S. capital facilities industry due to inadequate interoperability arising from "the highly fragmented nature of the industry, the industry’s continued paperbased business practices, a lack of standardization, and inconsistent technology adoption among stakeholders".


An early example of a nationally approved BIM standard is the AISC (American Institute of Steel Construction)-approved CIS/2 standard, a non-proprietary standard with its roots in the UK.



International BIM developments



Asia



Hong Kong


The Hong Kong Housing Authority set a target of full BIM implementation in 2014/2015. BuildingSmart Hong Kong was inaugurated in Hong Kong SAR in late April 2013.[citation needed] The Government of Hong Kong mandates the use of BIM for all government projects over HK$30M since 1 January 2018 [34].



India


In India BIM is also known as VDC: Virtual Design and Construction. Due to its population and economic growth, India has an expanding construction market. In spite of this, BIM usage was reported by only 22% of respondents to a 2014 survey.[35]



Iran


The Iran Building Information Modeling Association (IBIMA) was founded in 2012 by professional engineers from five universities in Iran, including the Civil and Environmental Engineering Department at Amirkabir University of Technology.[36] While it is not currently active, IBIMA aims to share knowledge resources to support construction engineering management decision-making.[37][38]



Malaysia


BIM implementation is targeted towards BIM Stage 2 by the year 2020 led by the Construction Industry Development Board (CIDB Malaysia). Under the Construction Industry Master Plan 2016-2020,[39] it is hoped more emphasis on technology adoption across the project life-cycle will induce higher productivity.



Singapore


The Building and Construction Authority (BCA) has announced that BIM would be introduced for architectural submission (by 2013), structural and M&E submissions (by 2014) and eventually for plan submissions of all projects with gross floor area of more than 5,000 square metres by 2015. The BCA Academy is training students in BIM.[40]



South Korea


Small BIM-related seminars and independent BIM effort existed in South Korea even in the 1990s. However, it was not until the late 2000s that the Korean industry paid attention to BIM. The first industry-level BIM conference was held in April, 2008, after which, BIM has been spread very rapidly. Since 2010, the Korean government has been gradually increasing the scope of BIM-mandated projects. McGraw Hill published a detailed report in 2012 on the status of BIM adoption and implementation in South Korea.[41]



United Arab Emirates


Dubai Municipality issued a circular (196) in 2014 mandating BIM use for buildings of a certain size, height or type. The one page circular initiated strong interest in BIM and the market responded in preparation for more guidelines and direction. In 2015 the Municipality issued another circular (207) titled 'Regarding the expansion of applying the (BIM) on buildings and facilities in the emirate of Dubai' which made BIM mandatory on more projects by reducing the minimum size and height requirement for projects requiring BIM. This second circular drove BIM adoption further with several projects and organizations adopting UK BIM standards as best practice. In 2016, the UAE's Quality and Conformity Commission set up a BIM steering group to investigate statewide adoption of BIM.[42]



Europe



Austria


Austrian standards for digital modeling are summarized in the ÖNORM A 6241, published on March 15, 2015. The ÖNORM A 6241-1 (BIM Level 2), which replaced the ÖNORM A 6240-4, has been extended in the detailed and executive design stages, and corrected in the lack of definitions. The ÖNORM A 6241-2 (BIM Level 3) includes all the requirements for the BIM Level 3 (iBIM).[43]



Czech Republic


The Czech BIM Council, established in May 2011, aims to implement BIM methodologies into the Czech building and designing processes, education, standards and legislation.[44]



Estonia


In Estonia digital construction cluster (Digitaalehituse Klaster) was formed in 2015 to develop BIM solutions for the whole life-cycle of construction.[45] The strategic objective of the cluster is to develop an innovative digital construction environment as well as new VDCM products, Grid and e-construction portal to increase the international competitiveness and sales of Estonian businesses in the construction field. The cluster is equally co-funded by European Structural and Investment Funds through Enterprise Estonia and by the members of the cluster with a total budget of 600 000 euros for the period 2016-2018.



France


In France, a Building transition digital plan - French acronym PTNB - has been created (mandated since 2015 to 2017 and under several ministries). There is also the French arm of buildingSMART, called Mediaconstruct (existing since 1989).



Germany


In December 2015, the German minister for transport Alexander Dobrindt announced a timetable for the introduction of mandatory BIM for German road and rail projects from the end of 2020.[46] Speaking in April 2016, he said digital design and construction must become standard for construction projects in Germany, with Germany two to three years behind The Netherlands and the UK in aspects of implementing BIM.[47]



Ireland


In November 2017, Ireland's Department for Public Expenditure and Reform launched a strategy to increase use of digital technology in delivery of key public works projects, requiring the use of BIM to be phased in over the next four years.[48]



Italy


Through the new D.l. 50, in April 2016 Italy has included into its own legislation several European directives including 2014/24/EU on Public Procurement. The decree states among the main goals of public procurement the "rationalization of designing activities and of all connected verification processes, through the progressive adoption of digital methods and electronic instruments such as Building and Infrastructure Information Modelling".[49] A norm in 8 parts is also being written to support the transition: UNI 11337-1, UNI 11337-4 and UNI 11337-5 were published in January 2017, with five further chapters to follow within a year.


In early 2018 the Italian Ministry of Infrastructure and Transport issued a decree creating a governmental BIM Mandate compelling public client organisations to adopt a digital approach by 2025, with an incremental obligation which will start on 1 January 2019.[50]



Lithuania


Lithuania is moving towards adoption of BIM infrastructure by founding a public body "Skaitmeninė statyba" (Digital Construction), which is managed by 13 associations. Also there is a BIM work group established by Lietuvos Architektų Sąjunga (a Lithuanian architects body). The initiative intends Lithuania to adopt BIM, Industry Foundation Classes (IFC) and National Construction Classification as standard. An international conference "Skaitmeninė statyba Lietuvoje" (Digital Construction in Lithuania) has been held annually since 2012.



The Netherlands


On 1 November 2011, the Rijksgebouwendienst, the agency within the Dutch Ministry of Housing, Spatial Planning and the Environment that manages government buildings, introduced the Rgd BIM Standard,[51] which it updated on 1 July 2012.



Norway


In Norway BIM has been used increasingly since 2008. Several large public clients require use of BIM in open formats (IFC) in most or all of their projects. The Government Building Authority bases its processes on BIM in open formats to increase process speed and quality, and all large and several small and medium-sized contractors use BIM. National BIM development is centred around the local organisation, buildingSMART Norway which represents 25% of the Norwegian construction industry.[citation needed]



Poland


BIMKlaster (BIM Cluster) is a non-governmental, non-profit organisation established in 2012 with the aim of promoting BIM development in Poland.[52] In September 2016, the Ministry of Infrastructure and Construction began a series of expert meetings concerning the application of BIM methodologies in the construction industry.[53]



Portugal


Created in 2015 to promote the adoption of BIM in Portugal and its normalisation, the Technical Committee for BIM Standardisation, CT197-BIM, has created the first strategic document for construction 4.0 in Portugal, aiming to align the country's industry around a common vision, integrated and more ambitious than a simple technology change.[54]



Russia


The Russian government has approved a list of the regulations that provide the creation of a legal framework for the use of information modeling of buildings in construction.[citation needed]



Slovakia


The BIM Association of Slovakia, "BIMaS", was established in January 2013 as the first Slovakian professional organisation focused on BIM. Although there are neither standards nor legislative requirements to deliver projects in BIM, many architects, structural engineers and contractors, plus a few investors are already applying BIM. A Slovakian implementation strategy created by BIMaS and supported by the Chamber of Civil Engineers and Chamber of Architects has yet to be approved by Slovakian authorities due to their low interest in such innovation.[55]



Spain


A July 2015 meeting at Spain’s Ministry of Infrastructure [Ministerio de Fomento] launched the country’s national BIM strategy, making BIM a mandatory requirement on public sector projects with a possible starting date of 2018.[56] Following a February 2015 BIM summit in Barcelona, professionals in Spain's autonomous community of Catalonia established a BIM commission (ITeC) to drive the adoption of BIM in the region.[57]



Switzerland


Since 2009 through the initiative of buildingSmart Switzerland, then 2013, BIM awareness among a broader community of engineers and architects was raised due to the open competition for Basel's Felix Platter Hospital[58] where a BIM coordinator was sought. BIM has also been a subject of events by the Swiss Society for Engineers and Architects, SIA.[59]



United Kingdom


In May 2011 UK Government Chief Construction Adviser Paul Morrell called for BIM adoption on UK government construction projects.[60] Morrell also told construction professionals to adopt BIM or be "Betamaxed out".[61] In June 2011 the UK government published its BIM strategy,[62] announcing its intention to require collaborative 3D BIM (with all project and asset information, documentation and data being electronic) on its projects by 2016. Initially, compliance will require building data to be delivered in a vendor-neutral 'COBie' format, thus overcoming the limited interoperability of BIM software suites available on the market. The UK Government BIM Task Group led the government's BIM programme and requirements,[63] including a free-to-use set of UK standards and tools that define 'level 2 BIM'.[64] In April 2016, the UK Government published a new central web portal as a point of reference for the industry for BIM Level 2.[65] The BIM Task Group continues to develop BIM adoption within the government departments.


Outside of government, industry adoption of BIM from 2016 has been led by the UK BIM Alliance,[66] formed to champion and enable the implementation of BIM Level 2 by 2020, and to connect and represent organisations, groups and individuals working towards digital transformation of the UK's built environment industry. Established as an independent, not-for-profit, collaboratively-based organisation, the UK BIM Alliance's structure has been developed around an executive team[67] and three core activity areas: engagement, programme and operations (internal support and secretariat functions).


National Building Specification (NBS), owned by the Royal Institute of British Architects (RIBA), publishes research into BIM adoption in the UK. There have now been six annual surveys.[68][69][70][71][72][73] The April 2016 survey of 1,000 UK construction professionals revealed that BIM adoption had increased from 13% in 2010 to 54% in 2015.[73]



North America



Canada


Several organizations support BIM adoption and implementation in Canada: the Canada BIM Council (CANBIM, founded in 2008),[74] the Institute for BIM in Canada,[75] and buildingSMART Canada (the Canadian chapter of buildingSMART International).[76]



United States of America


The Associated General Contractors of America and US contracting firms have developed various working definitions of BIM that describe it generally as:



an object-oriented building development tool that utilizes 3-D modeling concepts, information technology and software interoperability to design, construct and operate a building project, as well as communicate its details.[citation needed]

Although the concept of BIM and relevant processes are being explored by contractors, architects and developers alike, the term itself has been questioned and debated[77] with alternatives including Virtual Building Environment (VBE) and virtual design and construction (VDC) also considered. Unlike some countries such as the UK, the US has not adopted a set of national BIM guidelines, allowing different systems to remain in competition.[78]


BIM is seen to be closely related to Integrated Project Delivery (IPD) where the primary motive is to bring the teams together early on in the project.[79] A full implementation of BIM also requires the project teams to collaborate from the inception stage and formulate model sharing and ownership contract documents.


The American Institute of Architects has defined BIM as "a model-based technology linked with a database of project information",[3] and this reflects the general reliance on database technology as the foundation. In the future, structured text documents such as specifications may be able to be searched and linked to regional, national, and international standards.



Africa



Nigeria


BIM has the potential to play a vital role in the Nigerian AEC sector. In addition to its potential clarity and transparency it may help promote standardization across the industry. For instance, Utiome[80] suggests that, in conceptualizing a BIM-based knowledge transfer framework from industrialized economies to urban construction projects in developing nations, generic BIM objects can benefit from rich building information within specification parameters in product libraries, and used for efficient, streamlined design and construction. Similarly, an assessment of the current 'state of the art' by Kori[81] found that medium and large firms were leading the adoption of BIM in the industry. Smaller firms were less advanced with respect to process and policy adherence.
There is little or less adoption of BIM in the built environment due to resistive nature of construction industry to changes or new ways of doing things. Till now, Nigerian construction industry is still working with the 2D conventional CAD system in services and structural designs, although the production could be in 3D system. There is virtually 0% utilization of 4D and 5D systems.



South Africa


The South African BIM Institute, established in May 2015, aims to enable technical experts to discuss digital construction solutions that can be adopted by professionals working within the construction sector. Its initial task was to promote the SA BIM Protocol.[82]


There are no mandated or national best practice BIM standards or protocols in South Africa. Organisations implement company-specific BIM standards and protocols at best (there are isolated examples of cross-industry alliances).[citation needed]



Oceania



Australia


In February 2016, Infrastructure Australia recommended: "Governments should make the use of Building Information Modelling (BIM) mandatory for the design of large-scale complex infrastructure projects. In support of a mandatory rollout, the Australian Government should commission the Australasian Procurement and Construction Council, working with industry, to develop appropriate guidance around the adoption and use of BIM; and common standards and protocols to be applied when using BIM.”[83]



New Zealand


In 2015, many projects in the rebuilding of Christchurch were being assembled in detail on a computer using BIM well before workers set foot on the site. The New Zealand government started a BIM acceleration committee, as part of a productivity partnership with the goal of 20 per cent more efficiency in the construction industry by 2020.[84]



Anticipated future potential


BIM is a relatively new technology in an industry typically slow to adopt change. Yet many early adopters are confident that BIM will grow to play an even more crucial role in building documentation.[85]


Proponents claim that BIM offers:



  1. Improved visualization

  2. Improved productivity due to easy retrieval of information

  3. Increased coordination of construction documents

  4. Embedding and linking of vital information such as vendors for specific materials, location of details and quantities required for estimation and tendering

  5. Increased speed of delivery

  6. Reduced costs


BIM also contains most of the data needed for building performance analysis.[86] The building properties in BIM can be used to automatically create the input file for building performance simulation and save a significant amount of time and effort.[87] Moreover, automation of this process reduce errors and mismatches in the building performance simulation process.


Green Building XML (gbXML) is an emerging schema, a subset of the Building Information Modeling efforts, focused on green building design and operation. gbXML is used as input in several energy simulation engines.[88] With the development of modern computer technology, a large number of building performance simulation tools are available. When choosing which simulation tool to use, the user must consider the tool's accuracy and reliability, considering the building information they have at hand, which will serve as input for the tool. Yezioro, Dong and Leite[89] developed an artificial intelligence approach towards assessing building performance simulation results and found that more detailed simulation tools have the best simulation performance in terms of heating and cooling electricity consumption within 3% of mean absolute error.


Explorations are underway to pair computer network users' personal, private and public authentication choices, geographic mapping systems and evolving cloud computing security architecture models, together, to offer customers of geospatial securitization services intuitive new ways to organize their personal, private and public applications and storage. For individuals, businesses and government authorities who generate and manage building information, new ways to discover, share and work on data, within the context of particular places on earth, will be offered. David Plager, AIA, conjectures that today's web will give way to tomorrow's geo-web where data will be structured first by place (e.g. a postal address) and then by space (Personal (one user), Private (a group of users) and Public (all users)).[citation needed]



BIM-GIS integration



  1. Industrial Foundation Class (IFC) and City Geography Markup Language (CityGML) are two primary and popular standards for BIM-GIS integration.

  2. BIM provides improved solutions for satisfying user requirements with BIM-GIS integration supported by spatio-temporal analysis.[90]



Building information science


BIM will develop as building information science involving systematic theories, concepts, methods, technologies, applications and management for the digitization, visualization, quantitative analysis and decision-making of whole project life cycles in the architecture, engineering and construction (AEC) industry.[90]



See also



  • 6D BIM

  • Architecture

  • BIM Wash

  • Design computing

  • Macro BIM

  • System information modelling

  • Virtual Design and Construction

  • Whole Building Design Guide



References





  1. ^ Eastman, Charles; Fisher, David; Lafue, Gilles; Lividini, Joseph; Stoker, Douglas; Yessios, Christos (September 1974). An Outline of the Building Description System. Institute of Physical Planning, Carnegie-Mellon University..mw-parser-output cite.citation{font-style:inherit}.mw-parser-output q{quotes:"""""""'""'"}.mw-parser-output code.cs1-code{color:inherit;background:inherit;border:inherit;padding:inherit}.mw-parser-output .cs1-lock-free a{background:url("//upload.wikimedia.org/wikipedia/commons/thumb/6/65/Lock-green.svg/9px-Lock-green.svg.png")no-repeat;background-position:right .1em center}.mw-parser-output .cs1-lock-limited a,.mw-parser-output .cs1-lock-registration a{background:url("//upload.wikimedia.org/wikipedia/commons/thumb/d/d6/Lock-gray-alt-2.svg/9px-Lock-gray-alt-2.svg.png")no-repeat;background-position:right .1em center}.mw-parser-output .cs1-lock-subscription a{background:url("//upload.wikimedia.org/wikipedia/commons/thumb/a/aa/Lock-red-alt-2.svg/9px-Lock-red-alt-2.svg.png")no-repeat;background-position:right .1em center}.mw-parser-output .cs1-subscription,.mw-parser-output .cs1-registration{color:#555}.mw-parser-output .cs1-subscription span,.mw-parser-output .cs1-registration span{border-bottom:1px dotted;cursor:help}.mw-parser-output .cs1-hidden-error{display:none;font-size:100%}.mw-parser-output .cs1-visible-error{font-size:100%}.mw-parser-output .cs1-subscription,.mw-parser-output .cs1-registration,.mw-parser-output .cs1-format{font-size:95%}.mw-parser-output .cs1-kern-left,.mw-parser-output .cs1-kern-wl-left{padding-left:0.2em}.mw-parser-output .cs1-kern-right,.mw-parser-output .cs1-kern-wl-right{padding-right:0.2em}


  2. ^ Eastman, Chuck; Tiecholz, Paul; Sacks, Rafael; Liston, Kathleen (2008). BIM Handbook: a Guide to Building Information Modeling for owners, managers, designers, engineers, and contractors (1st ed.). Hoboken, New Jersey: John Wiley. pp. xi–xii. ISBN 9780470185285.


  3. ^ Eastman, Chuck; Tiecholz, Paul; Sacks, Rafael; Liston, Kathleen (2011). BIM Handbook: A Guide to Building Information Modeling for Owners, Managers, Designers, Engineers and Contractors (2nd ed.). Hoboken, New Jersey: John Wiley. pp. 36–37.


  4. ^ Ruffle S. (1986) "Architectural design exposed: from computer-aided-drawing to computer-aided-design" Environments and Planning B: Planning and Design 1986 March 7 pp 385-389. Abstract


  5. ^ Aish, R. (1986) "Building Modelling: The Key to Integrated Construction CAD" CIB 5th International Symposium on the Use of Computers for Environmental Engineering related to Building, 7–9 July.


  6. ^ cited by Laiserin, Jerry (2008), Foreword to Eastman, C., et al (2008), op cit, p.xii


  7. ^ Van Nederveen, G.A.; Tolman, F.P. (1992). "Modelling multiple views on buildings". Automation in Construction. 1 (3): 215–24. doi:10.1016/0926-5805(92)90014-B.


  8. ^ "Autodesk (2002). Building Information Modeling. San Rafael, CA, Autodesk, Inc" (PDF). laiserin.com.


  9. ^ Laiserin, J. (2002) "Comparing Pommes and Naranjas", The Laiserin Letter, December 16, 2002.[unreliable source?]


  10. ^ Laiserin, J. (2003) "The BIM Page", The Laiserin Letter.[unreliable source?]


  11. ^ Laiserin, in his foreword to Eastman, et al (2008, op cit) disclaimed he had coined the term, adding "it is my opinion that the historical record ... shows that Building Information Modeling was not an innovation attributable solely to any individual or entity." (p.xiii)


  12. ^ Laiserin, J. (2003) "LaiserinLetterLetters" (see Laiserin's comment to letter from John Mullan), The Laiserin Letter, January 06 2003.[unreliable source?]


  13. ^ "Prince Philip Medal for engineer behind revolution in Building Information Modelling (22 June 2016)". Royal Academy of Engineering. RAEng. Retrieved 22 July 2016.


  14. ^ Laiserin, J. (2003) "Graphisoft on BIM", The Laiserin Letter, January 20, 2003.[unreliable source?]


  15. ^ ab Lincoln H. Forbes, Syed M. Ahmed, (2010) Modern Construction: Lean Project Delivery and Integrated Practices, CRC Press.


  16. ^ Cinti Luciani, S. Garagnani, R. Mingucci (2012) "BIM tools and design intent. Limitations and opportunities", in K. Kensek, J. Peng, Practical BIM 2012 - Management, Implementation, Coordination and Evaluation, Los Angeles


  17. ^ ab Quirk, Vanessa (7 December 2012). "A Brief History of BIM". Arch Daily. Retrieved 14 July 2015.


  18. ^ M. Dobelis (2013), “Drawbacks of BIM concept adoption”, in the 12th International Conference on Engineering Graphics, BALTGRAF 2013, June 5–7, 2013, Riga, Latvia


  19. ^ "Frequently Asked Questions About the National BIM Standard-United States - National BIM Standard - United States". Nationalbimstandard.org. Archived from the original on 16 October 2014. Retrieved 17 October 2014.


  20. ^ "4D BIM or Simulation-Based Modeling". structuremag.org. Archived from the original on 28 May 2012. Retrieved 29 May 2012.


  21. ^ "ASHRAE Introduction to BIM, 4D and 5D". cadsoft-consult.com. Retrieved 29 May 2012.


  22. ^ "The Theory of Evolution BIM 3D-7D". Retrieved 5 October 2018.


  23. ^ "BIM 3D, 4D, 5D, 6D, 7D". Retrieved 5 October 2018.


  24. ^ abc Eastman, Chuck (August 2009). "What is BIM?".


  25. ^ [1] Archived November 12, 2009, at the Wayback Machine.


  26. ^ "Senate Properties modeling guidelines". Gsa.gov. Archived from the original on 26 February 2012. Retrieved 17 October 2014.


  27. ^ Leite, Fernanda; Akcamete, Asli; Akinci, Burcu; Atasoy, Guzide; Kiziltas, Semiha (2011). "Analysis of modeling effort and impact of different levels of detail in building information models". Automation in Construction. 20 (5): 601–9. doi:10.1016/j.autcon.2010.11.027.


  28. ^ ab Smith, Deke (2007). "An Introduction to Building Information Modeling (BIM)" (PDF). Journal of Building Information Modeling: 12–4.
    [unreliable source?]



  29. ^ Leite, Fernanda; Akinci, Burcu (2012). "Formalized Representation for Supporting Automated Identification of Critical Assets in Facilities during Emergencies Triggered by Failures in Building Systems". Journal of Computing in Civil Engineering. 26 (4): 519. doi:10.1061/(ASCE)CP.1943-5487.0000171.


  30. ^ Liu, Xuesong; Akinci, Burcu (2009). "Requirements and Evaluation of Standards for Integration of Sensor Data with Building Information Models". In Caldas, Carlos H.; O'Brien, William J. Computing in Civil Engineering. pp. 95–104. doi:10.1061/41052(346)10. ISBN 978-0-7844-1052-3.


  31. ^ Atazadeh, Behnam; Kalantari, Mohsen; Rajabifard, Abbas; Ho, Serene; Ngo, Tuan (2016-03-01). "Building Information Modelling for High-rise Land Administration". Transactions in GIS: n/a–n/a. doi:10.1111/tgis.12199. ISSN 1467-9671.


  32. ^ Behnam Atazadeh; Mohsen Kalantari; Abbas Rajabifard; Tom Champion (23 February 2016). "Filling the space" (PDF). RICS Land Journal. Royal Institution of Chartered Surveyors.


  33. ^ Gallaher, Michael P.; O'Connor, Alan C.; Dettbarn, John L.; Gilday, Linda T. (August 2004). Cost Analysis of Inadequate Interoperability in the U.S. Capital Facilities Industry. National Institute of Standards and Technology. p. iv. doi:10.6028/NIST.GCR.04-867.


  34. ^ Government of the Hong Kong SAR (2017). "Adoption of Building Information Modelling for Capital Works Projects in Hong Kong" (PDF). Development Bureau. Retrieved November 8, 2018.


  35. ^ "Sawhney, Anil et al. (2014). State of BIM Adoption and Outlook in India (English). RICS School of the Built Environment, Amity University. Noida, Uttar Pradesh" (PDF). Retrieved 17 October 2014.


  36. ^ "IRAN Building Information Modeling Association (IBIMA), Tehran, IRAN". Ibima.ir. Retrieved 17 October 2014.


  37. ^ Hosseini, Reza; Azari, Ehsan; Tivendale, Linda; Chileshe, Nicholas. "Building Information Modeling (BIM) in Iran: An Exploratory Study (April 2016)". Researchgate. Retrieved 4 December 2016.


  38. ^ Hosseini, Reza; Azari, Ehsan; Tivendale, Linda; Chileshe, Nicholas. "Barriers to adoption of building information modeling (BIM) in Iran: Preliminary results (September 2016)". Researchgate. Retrieved 4 December 2016.


  39. ^ CITP. "CITP". www.citp.my. Retrieved 2016-02-12.


  40. ^ BuildSmart (BCA magazine), December 2011.


  41. ^ "Lee, G., J. Lee, et al. (2012). 2012 Business Value of BIM in South Korea (English). SmartMarket Report. Bedford, MA, McGraw Hill Construction". Analyticstore.construction.com. Retrieved 17 October 2014.


  42. ^ "BIM Summit 2015 calls for greater co-operation". ConstructionWeekOnline.com. Retrieved 6 December 2015.


  43. ^ "Building information modelling (BIM)". austrian-standards.at. Retrieved 22 March 2016.


  44. ^ "Czech BIM Council". The BIM Hub. Retrieved 19 December 2016.


  45. ^ "cluster of digital construction". digitaalehitus.ee. Retrieved 5 June 2016.


  46. ^ White, Jack (16 December 2015). "BIM mandate for transport projects in Germany confirmed for 2020". BIM Crunch. Retrieved 17 December 2015.


  47. ^ "BIM must become standard for construction in Germany says minister". The BIM Hub. Retrieved 18 April 2016.


  48. ^ "Government Strategy to Increase use of Digital Technology in Key Public Works Projects Launched". National Development Plan, 2018 - 2027. Department of Public Expenditure and Reform. 21 November 2017. Retrieved 30 July 2018.


  49. ^ D.lgs. 50/2006, art. 38 com. 1 lett. h


  50. ^ Ciribini, Angelo; De Giuda, Giuseppe; Valaguzza, Sara (21 March 2018). "UK PROCUREMENT FRAMEWORK INFORMS ITALY'S MOVE TO MANDATE BIM". BIM Plus. Retrieved 22 March 2018.


  51. ^ "Vastgoed van en voor het Rijk". Rgd.nl. Retrieved 17 October 2014.


  52. ^ "BIMKlaster". BIMKlaster.org.pl. Retrieved 24 February 2017.


  53. ^ KPMG and Arup. "Building Information Modeling: Ekspertyza dotycząca możliwości wdrożenia metodyki BIM w Polsce ("Building Information Modeling. Expertise concerning the possibility of implementing BIM methodology in Poland")" (PDF). MIB.gov.pl. Retrieved 24 February 2017.


  54. ^ Aguiar Costa, Antonio (4 December 2016). "Construction 4.0 in Portugal". Construction Manager: BIM+. Retrieved 6 December 2016.


  55. ^ BIMaS.sk, BIMaS website. Accessed: 4 September 2015.


  56. ^ Knutt, Elaine (16 July 2015). "Spain launches BIM strategy with pencilled-in 2018 mandate". Construction Manager: BIMplus. Retrieved 20 August 2015.


  57. ^ "La Comissió Construïm el Futur (transl: The Commission Building the Future)". ITeC. Retrieved 7 July 2017.


  58. ^ [2] Archived November 10, 2013, at the Wayback Machine.


  59. ^ "jahrestagung 2013 - sia - schweizerischer ingenieur- und architektenverein". sia - schweizerischer ingenieur- und architektenverein. Retrieved 17 October 2014.


  60. ^ "BIM Roundtable Discussion". Thenbs.com. Retrieved 17 October 2014.


  61. ^ "Adopt bim or be 'Betamaxed out' says Morrell". Building Design. Retrieved 17 October 2014.


  62. ^ "Modern Built Environment - innovateuk". Ktn.innovateuk.org. Retrieved 17 October 2014.


  63. ^ "BIM Task Group - A UK Government Initiative". Bimtaskgroup.org. Retrieved 17 October 2014.


  64. ^ "The level-2 BIM package". BIM Task Group. Retrieved 17 October 2014.


  65. ^ "BIM Level 2". BSI Group. Retrieved 19 April 2016.


  66. ^ Solutions, WebCider Business. "UK BIM Alliance". ukbimalliance.org.


  67. ^ Solutions, WebCider Business. "UKBIMA Executive Team". ukbimalliance.org.


  68. ^ "Putting the 'I' into BIM". Thenbs.com. Retrieved 17 October 2014.


  69. ^ "NBS National BIM Report 2012". Thenbs.com. Retrieved 17 October 2014.


  70. ^ "NBS National BIM Report 2013". Thenbs.com. Retrieved 17 October 2014.


  71. ^ "NBS National BIM Report 2014". Thenbs.com. Retrieved 17 October 2014.


  72. ^ "NBS National BIM Report 2015". Thenbs.com. Retrieved 28 April 2015.


  73. ^ ab "NBS National BIM Report 2016". Thenbs.com. Retrieved 19 April 2016.


  74. ^ "Canada BIM Council".


  75. ^ "Institute for BIM in Canada (IBC)".


  76. ^ "buildingSMART Canada".


  77. ^ "AECbytes Archived Articles". Aecbytes.com. Archived from the original on 21 October 2014. Retrieved 17 October 2014.


  78. ^ Shapiro, Gideon Fink (May 2, 2014). "Setting a Standard in Building Information Modeling (Architect Magazine)". www.architectmagazine.com. Retrieved 2018-03-21.


  79. ^ AIA, C.C., A working Definition: Integrated Project Delivery. 2007, McGraw Hill Construction[page needed]


  80. ^ Utiome, Erezi, Drogemuller, Robin, & Docherty, Michael (2014). "BIM-based lifecycle planning and specifications for sustainable cities of the future : a conceptual approach"


  81. ^ Kori, S. (2013). Toward Adoption of Building Information Modelling in the Nigeria AEC industry. MSc, University of Salford, Manchester.


  82. ^ http://www.biminstitute.org.za/


  83. ^ "Infrastructure Australia recommend BIM mandate for large-scale projects". BIM Crunch. 17 February 2016. Retrieved 16 August 2016.


  84. ^ New Zealand Herald, Tuesday 14 April 2015


  85. ^ Kensek, Karen; Noble, Douglas (2014). Building Information Modeling: BIM in Current and Future Practice (1st ed.). Hoboken, New Jersey: John Wiley.


  86. ^ Kensek, Karen (2014). Building Information Modeling (1st ed.). Hoboken, New York: Routledge. pp. 152–162.


  87. ^ Rahmani Asl, Mohammad; Saied Zarrinmehr; Wei Yan. "Towards BIM-based Parametric Building Energy Performance Optimization". ACADIA 2013.


  88. ^ "Welcome - Green Building XML Schema". Gbxml.org. Retrieved 17 October 2014.


  89. ^ Yezioro, Abraham; Dong, Bing; Leite, Fernanda (2008). "An applied artificial intelligence approach towards assessing building performance simulation tools". Energy and Buildings. 40 (4): 612–20. doi:10.1016/j.enbuild.2007.04.014.


  90. ^ ab Song, Yongze; Xiangyu Wang. "Trends and Opportunities of BIM-GIS Integration in the Architecture, Engineering and Construction Industry: A Review from a Spatio-Temporal Statistical Perspective". ISPRS Int. J. Geo-Inf.




Further reading




  • Hardin, Brad (2009). Martin Viveros, ed. BIM and Construction Management: Proven Tools, Methods and Workflows. Sybex. ISBN 978-0-470-40235-1.


  • Jernigan, Finith (2007). BIG BIM little bim. 4Site Press. ISBN 978-0-9795699-0-6.

  • Kensek, Karen (2014). Building Information Modeling, Routledge.
    ISBN 978-0-415-71774-8

  • Kensek, Karen and Noble, Douglas (2014). Building Information Modeling: BIM in Current and Future Practice, Wiley.
    ISBN 978-1-118-76630-9


  • Kiziltas, Semiha; Leite, Fernanda; Akinci, Burcu; Lipman, Robert R. (2009). "Interoperable Methodologies and Techniques in CAD". In Karimi, Hassan A.; Akinci, Burcu. CAD and GIS Integration. CRC. pp. 73–109. ISBN 978-1-4200-6806-1.

  • Kymmell, Willem (2008). Building Information Modeling: Planning and Managing Construction Projects with 4D CAD and Simulations, McGraw-Hill Professional.
    ISBN 978-0-07-149453-3

  • Krygiel, Eddy and Nies, Brad (2008). Green BIM: Successful Sustainable Design with Building Information Modeling, Sybex.
    ISBN 978-0-470-23960-5

  • Lévy, François (2011). BIM in Small-Scale Sustainable Design, Wiley.
    ISBN 978-0470590898

  • Smith, Dana K. and Tardif, Michael (2009). Building Information Modeling: A Strategic Implementation Guide for Architects, Engineers, Constructors, and Real Estate Asset Managers, Wiley.
    ISBN 978-0-470-25003-7

  • Underwood, Jason, and Isikdag, Umit (2009). Handbook of Research on Building Information Modeling and Construction Informatics: Concepts and Technologies, Information Science Publishing.
    ISBN 978-1-60566-928-1

  • Weygant, Robert S. (2011) BIM Content Development: Standards, Strategies, and Best Practices, Wiley.
    ISBN 978-0-470-58357-9









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