Difference between revisions of "BCRW 2023"
Line 121: | Line 121: | ||
''Keywords'' | ''Keywords'' | ||
[[Web3]], [[Blockchain]], [[Material Passports]], [[Data Management]]. | [[Web3]], [[Blockchain]], [[Material Passports]], [[Data Management]]. | ||
+ | |||
+ | ===Blockchain-based smart contract generation and visualization in BIM environment: Technical adoption for secured construction management=== | ||
+ | [https://www.linkedin.com/in/xuling-ye-shelain/ Xuling Ye] | Watch [[File:VideoRecord-Icon.png |Left|22px|link=https://www.youtube.com/watch?v=JhTLAPbqkWE]] | ||
+ | |||
+ | ''Abstract'' | ||
+ | |||
+ | This presentation explores the integration of blockchain-based smart contracts with Building Information Modeling (BIM) to address critical needs in construction management, including data security, traceability, and process automation. By examining four distinct construction phases and addressing research gaps related to isolated smart contract design, code-based logic, limited data storage, and the absence of a universal framework, this research endeavors to empower stakeholders to independently design and validate smart contracts. The outcomes of this study include the establishment of a Process-embedded Smart Contract List (PeSCL) to link BIM and process-related documents, the development of a mapping from process models to smart contracts, and the visualization of smart contract logic in real-time through Business Process Model and Notation (BPMN) diagrams, offering a promising path to enhance the technical aspects of secure construction management in the digital age. | ||
+ | |||
+ | ''Keywords'' | ||
+ | [[Smart contracts]], [[Blockchain]], [[BIM]], [[Construction management]], [[BPMN]], [[Business process automation]]. | ||
+ | |||
+ | ===Smart Contracts and DAOs: Bumps in the legal road, dead end, or an improving map?=== | ||
+ | [https://www.linkedin.com/in/drgavinpjohnson/ Gavin Johnson] | Watch [[File:VideoRecord-Icon.png |Left|22px|link=https://www.youtube.com/watch?v=D2YLQFqh5iI]] | ||
+ | |||
+ | ''Abstract'' | ||
+ | |||
+ | ''Keywords'' | ||
+ | [[*]], [[*]], [[*]]. | ||
+ | |||
+ | ===Decentralized contract management in construction=== | ||
+ | [https://www.linkedin.com/in/purva-gupta-76a22819/ Purva Gupta] | Watch [[File:VideoRecord-Icon.png |Left|22px|link=https://www.youtube.com/watch?v=2JD1277PDtI]] | ||
+ | |||
+ | ''Abstract'' | ||
+ | |||
+ | Achieving trust and collaboration by revamping the contract management process using digitization and automation is seen as a research area yet to be explored where the focus is on dispute avoidance instead of dispute resolution. Having identified that, our research was motivated to build upon the capabilities of blockchain technology and smart contracts and develop a digital and automated contract management system based on two main elements: 1. a decentralized blockchain platform and 2. computable contract clauses. The decentralized system supported by smart contracts would enable certain execution of contract terms, transparent communication through a decentralized stakeholder network, and clear accountability in terms of data stamps and digital signatures. | ||
+ | |||
+ | ''Keywords'' | ||
+ | [[Automation]], [[Smart contracts]], [[Blockchain]], [[Construction law]], [[Legal tech]], [[Contract management]]. | ||
+ | |||
+ | ===Session 3: Discussion=== | ||
+ | Watch [[File:VideoRecord-Icon.png |Left|22px|link=https://www.youtube.com/watch?v=y4yeyF1Nyn8]] | ||
+ | |||
+ | ==Session 4== | ||
+ | |||
+ | ===Keynote: Towards a blockchain-enabled automated construction contract: why? when? how? (and if)=== | ||
+ | [https://www.linkedin.com/in/david-greenwood-5774aa40/ David Greenwood] | Watch [[File:VideoRecord-Icon.png |Left|22px|link=https://www.youtube.com/watch?v=Ocqoo-hXSl8]] | ||
+ | |||
+ | ''Abstract'' | ||
+ | |||
+ | Contractual problems in the construction industry, especially the disputes that arise from them have long been recognised as a problem. The impact in terms of cost, time, and in many cases quality, of contractual disputes is enormous; for instance the cost to the global construction market in 2020 was estimated to be over US$48 billion. One of main causes of dispute is poor contract management, occasioned by various factors including inaccurate documents, lack of proper records, unclear roles and responsibilities, ineffective communication, incompetence, and corruption. The prospect of deploying distributed ledgers and smart contracts on a blockchain to automate or semi automate contractual processes is an attractive one as the characteristics of blockchain (transparency, consensus, immutability, security etc.) may address many of the factors that cause problems in current traditional contract administration. A team at Northumbria University (UK) are about to finalise a prototype blockchain-based infrastructure that performs the elements of the claims management process of the FIDIC 2017 Standard Form of Contract. The functionality of the prototype appears to be robust. A user-interface is nearing completion, and this will enable scenario-testing and its user-acceptability to be investigated. Further research is expected to be required on those challenges that are apparent, and those that emerge from these tests. | ||
+ | |||
+ | ''Keywords'' | ||
+ | [[Smart legal contracts]], [[Contract administration]], [[Claims management]], [[FIDIC contract]]. | ||
+ | |||
+ | ===Keynote Presentation + Coding Session: Decentralised Autonomous Organisations in AEC=== | ||
+ | [https://www.linkedin.com/in/theodoredounas/ Theodore Dounas] | Watch [[File:VideoRecord-Icon.png |Left|22px|link=https://www.youtube.com/watch?v=2wM6qj2zS3M]] | ||
+ | |||
+ | ''Abstract'' | ||
+ | |||
+ | ''Keywords'' | ||
+ | [[*]], [[*]], [*]]. | ||
+ | |||
+ | =Day 3 – Industry Adoption (Business Adoption)= | ||
+ | |||
+ | ==Session 5== | ||
+ | |||
+ | ===ESG Responsive contracts in Construction using Smart Legal Contracts and DLT=== | ||
+ | [https://www.linkedin.com/in/niallroche/ Niall Roche] | Watch [[File:VideoRecord-Icon.png |Left|22px|link=https://www.youtube.com/watch?v=NjxhKLflLXw]] | ||
+ | |||
+ | ''Abstract'' | ||
+ | MISSING VIDEO | ||
+ | |||
+ | ''Keywords'' | ||
+ | [[*]], [[*]]. | ||
+ | |||
+ | ===Security-minded OpenBIM CDE for Building Data Management Using Encryption and Distributed Ledger Technology=== | ||
+ | [https://www.linkedin.com/in/moumita-maya-das/ Moumita Das] | Watch [[File:VideoRecord-Icon.png |Left|22px|link=https://www.youtube.com/watch?v=KG8wE4vEV8g]] | ||
+ | |||
+ | ''Abstract'' | ||
+ | Construction projects generate a large amount of digital information during the design, construction, and operation phases that require sharing and management across stakeholders from multiple domains. It is well established that effective building data management strategies, using rules, programs, and practices to regulate, safeguard, and improve the value of project information assets (such as BIM, documents, and IoT) with a Common Data Environment (CDE) is recommended for streamlining coordination and effective data sharing. among project partners to ensure project success in terms of cost and time. However, the existing CDEs are faced with several error-inducing methods/gaps that - put sensitive information (especially BIM is hard to regulate) at risk of loss of privacy and integrity, resulting in incomplete BIM model delivery during design and construction phases, failure to hold contractually bound stakeholders accountable for their actions, and more. In particular, the problems in existing CDEs are identified as follows- (1) privacy of sensitive information in BIM models, (2) efficient and automated coordination in multi-domain submission management and accountability of delivery teams, (3) Completeness of the BIM deliverables and accountability of stakeholders during the construction phase. | ||
+ | Therefore, the proposed “Security-minded OpenBIM CDE for Building Data Management Using Encryption and Distributed Ledger Technology” framework captures information from Open BIM models using the IFC format, IoT Sensors, and documents and deploys encryption and blockchain technologies to facilitate data privacy, data integrity, data accessibility, and delivery team accountability. It deploys a – (1) Functional Partial Encryption Method using OpenBIM to encrypt sensitive information of BIM models at a fine-grained level while maintaining the functionality of BIM models to perform engineering analysis such as clash detection as opposed to file-based encryption, (2) Blockchain-based Dynamic Dependency Workflow using OpenBIM to manage to improve coordination and accountability in large projects with numerous domains and complex and dynamic interlinkage among submissions from different domains, (3) Blockchain-based Completeness Checking Issue Management Workflow using OpenBIM to facilitate automatic checking of completion of marked changes in BIM models for faster/efficient issue resolution. The proposed framework was applied to an ongoing large construction project in Hong Kong. | ||
+ | |||
+ | ''Keywords'' | ||
+ | [[Blockchain]], [[Built Environment]], [[Security, Versioning]], [[Issue Management]]. |
Revision as of 19:32, 19 October 2023
Contents of the 4th Blockchain in Construction Research Workshop, hosted by Ruhr-University Bochum and Forum Digital Technologies Berlin in collaboration with the Construction Blockchain Consortium. The workshop took place from the 28th to the 30th of August 2023 in the Forum Digital Technologies building, Berlin, Germany and online. This workshop presented early and ongoing research in the field of blockchain and distributed ledger technologies for the construction sector.
Contents
- 1 Presentations
- 2 Day 1 - Blockchain & IoT (Technology)
- 2.1 Session 1
- 2.1.1 Workshop Host Keynote
- 2.1.2 Keynote: Blockchain for Full Lifecycle Management: From Design, Construction, to Facility Management
- 2.1.3 Blockchain-as-BIM-service (BaBS): Secure and decentralized common data environment for BIM collaboration
- 2.1.4 Optimizing Collaboration: A Management Framework for BIM and Blockchain Integration
- 2.1.5 Decentralized common data environment
- 2.1.6 Blockchain for regenerative built environment governance
- 2.1.7 Session 1: Discussion
- 2.2 Session 2
- 2.1 Session 1
- 3 Day 2 – Smart Contracts & DAO (Law and Management)
- 3.1 Session 3
- 3.1.1 Keynote: Insights of Blockchain in Logistics & Supply Chain Management
- 3.1.2 Web3 for Trustworthy Data in Transitioning to a Circular Built Environment
- 3.1.3 Blockchain-based smart contract generation and visualization in BIM environment: Technical adoption for secured construction management
- 3.1.4 Smart Contracts and DAOs: Bumps in the legal road, dead end, or an improving map?
- 3.1.5 Decentralized contract management in construction
- 3.1.6 Session 3: Discussion
- 3.2 Session 4
- 3.1 Session 3
- 4 Day 3 – Industry Adoption (Business Adoption)
Presentations
Day 1 - Blockchain & IoT (Technology)
Session 1
Workshop Host Keynote
Markus König | Watch
Keynote: Blockchain for Full Lifecycle Management: From Design, Construction, to Facility Management
Jack C.P. Cheng | Watch
Abstract
Blockchain-as-BIM-service (BaBS): Secure and decentralized common data environment for BIM collaboration
Xingyu Tao | Watch
Abstract
Optimizing Collaboration: A Management Framework for BIM and Blockchain Integration
Amer Hijazi | Watch
Abstract
Implementing blockchain technology in the construction industry's supply chain and asset management operations is made more likely by BIM, which is no longer arguable. Most currently available scholarly work has been on how this integration may occur, mainly through introducing the blockchain as a new tool allowing transparency transactions for BIM delivery without utilising it as technology innovation in leveraging a new way of working on going beyond stakeholders' coordination to stakeholders' collaboration. However, there is still a gap in how to put the blockchain application in motion for implementation, rather than offering only a conceptual framework or technical prototype that overlooks the value proposition of going digital via this integration. Subsequent to the prototyping, the early involvement of the stakeholders enables the integration logic. There are always new stakeholders to consider whenever a new technological paradigm is introduced. The difficulty would be figuring out what is needed for adoption and getting everyone involved on board (buy-in) to get the implementation process moving. Considering the above, this work aims to provide the foundation for integrating BIM and blockchain as a management solution for implementation in the form of a stakeholder's development stack defining the stakeholders, their roles and motivations. The proposed solution will be able to put the integration of BIM and blockchain in motion for implementation alongside its key disruption points. This serves as a catalyst that might enable a shift towards the progression of structured information towards machine-readable datasets (ideal platform).
Decentralized common data environment
Klaudia Jaskula | Watch
Abstract
Blockchain for regenerative built environment governance
Hongyang Wang | Watch
Abstract
This presentation focuses on the challenges and potential solutions for governance in the implementation of Blockchain for the regenerative built environment. The lack of effective governance systems is identified as a key obstacle in advancing the practical realization of regenerative concepts. To address this issue, in this presentation, I propose the use of Blockchain Technology as a governance tool to establish socio-economic-ecologic structures for information, complex systems processes, and inclusive ownership and value.
Session 1: Discussion
Session 2
Keynote: Blockchain and IoT-enabled Supply Chain Management for Modular Integrated Construction (MiC): From a COVID-19 Expediency to a Post-Pandemic Common Practice
Wilson W.S. Lu | Watch
Abstract
The renaissance of modular/offsite construction has enabled us to re-config key construction resources such as labor, materials, and integrated modules from various geographically dispersed places. However, it also adds complications to the already-complex cross-border construction supply chain management (SCM). This situation was further exacerbated by the COVID-19 pandemic, during which many social distancing measures (e.g., border closures, working from home) have been imposed. Researchers, practitioners, policy-makers, and the like have been very resourceful to develop various innovations to overcome the difficulties and allow construction to serve as the ‘knight’ to recure economy during the difficult time. In this talk, Prof. Lu will share how blockchain, building information modelling (BIM), and i-core (their in-house developed IoTs) can be used to enhance construction SCM in the Hong Kong–Mainland China links during the COVID-19 pandemic. Their solutions and awarding winning technologies were implemented in real-life Modular Integrated Construction (MiC) projects for remote e-inspection, cross-border SCM, and on-site installation on a daily basis. They developed three professional apps, which can be used separately or as a whole based on the blockchain-BIM-IoTs-enabled digital twin system. Now the borders are re-opened and the businesses are back to usual, Prof. Lu pleas that the efficient and less expensive solutions should go beyond a COVID-19 expediency to a post-pandemic common practice for cross-border construction SCM.
Keynote Presnetation + Focus Group: Considerations of Human Data Interaction for Blockchain in Construction
Jennifer Li | Watch
Abstract
This keynote presentation is a precursor to a focus group session that aims to explore the open challenges identified in a previous study on human data interaction (HDI) and blockchain. In the keynote, an introduction of the current concept of HDI is given, that is, the pace of technological advancement and the ubiquitous nature of computing are changing the interactions between humans and data. Informed consent remains a challenge so understanding more about how humans and data interact is paramount. HDI is, therefore, about manipulation and comprehension of big data sets, with a focus on personal data and their implications regarding decision-making and subsequent action-taking. Three pillars of HDI are presented as defined by Richard Mortier: agency, legibility and negotiability, then the outcomes of a focus group identifying considerations of HDI and blockchain are highlighted: technical factors (immutability, data storage, transparency, system design, integrating technologies); non-technical factors (ethics, economic models, environmental, political, social); and overlapping factors (governance, data usage, data privacy, control of data). The open challenges identified in a previous study are then to be explored in a focus group with the delegates of the BCRW 2023. They are as follows:
1. Does blockchain increase the level of HDI in construction? 2. How does blockchain interact with HDI along the intersection of factors mentioned above? 3. What data types (and the associated HDIs) are suitable for blockchain in the built environment? 4. When we say HDI in construction, do we mostly refer to individuals or larger social groups? And what are the implications of that? 5. Are we looking at how HDI could support the implementation of blockchain in construction? Or at HDI emanating from the usage of blockchain in construction? 6. [How] Do we rethink data ownership with Web3?
Keywords Agency, Blockchain, Human-Data Interaction (HDI), Legibility, Negotiability.
Day 2 – Smart Contracts & DAO (Law and Management)
Session 3
Keynote: Insights of Blockchain in Logistics & Supply Chain Management
Maximilian Austerjos | Watch
Abstract
Supply chain management in general and logistics in particular are predestined for the use of blockchain technology. By using blockchain technology, trust in partner companies, sustainable processes and productivity gains can be achieved, which are essential for sustainable development: Smart contracts enable automated and trusted information and financial transactions that improve the efficiency and resilience of supply chains. In addition, the integration of Internet of Things (IoT) devices and sensors into the blockchain enables the collection and sharing of real-time data, leading to better monitoring and tracking of goods. However, for widespread technological penetration and the creation of productive blockchain networks, certain conditions must be met. This presentation will describe how blockchain technology has been successfully used in various application projects in the field of supply chain management. Using example projects from the areas of customs clearance, dangerous goods transport and robot cooperation, it will be shown how diverse blockchain-based solutions can be implemented with reusable software and hardware modules. In addition, the approach of collaborative development between research institutions and companies in open source communities is described in order to promote the development and implementation of these solutions and to produce commodities.
Keywords Logistics, Supply Chain Management, Open Source.
Web3 for Trustworthy Data in Transitioning to a Circular Built Environment
Meliha Honic and Jens Hunhevicz | Watch
Abstract
The urgency to transition from a linear to a circular economy has become increasingly apparent as the construction industry faces resource depletion and greenhouse gas emissions. However, data-related challenges hinder the adoption of circular business models. To enable a circular built environment, comprehensive data availability throughout the value chain is essential. Material passports, digital records containing vital information about materials and products embedded in buildings, play a crucial role in this transition. Nevertheless, the often siloed and centralized storage and management of material passport data pose risks of inaccessibility over time. This presentation will focus on the potential of Web3, the vision to decentralize the internet, to address these challenges. Web3 uses blockchain at its core to return data ownership to the end user. Combined with decentralized data storage protocols, the vision is to store data without relying on gatekeepers. Web3, with its decentralized nature, can offer promising solutions for establishing trust and integrity in data management. By using blockchain, a transparent and auditable system for recording and verifying material passport data can be created. In addition, Web3 could help create a new decentralized approach to data access and ownership with decentralized applications, reducing the risk of data loss by ensuring the accessibility of information to all stakeholders through address or token-based access mechanisms. Finally, crypto-economic incentive systems and market mechanisms based on smart contracts hold potential in fostering data sharing and maintenance throughout the data's life cycle. These mechanisms can incentivize stakeholders to contribute and update data, ensuring the ongoing availability and accuracy of material passport information. Overall, we aim to provide an overview of the opportunities that exist with Web3 in the context of the transition to a circular built environment based on our research at the CEA lab. To ensure the circularity of data in line with the circularity of products, we suggest that Web3 could help ensure the trustworthiness and accessibility of data throughout the value chain, while potentially creating incentives that enable the sharing and long-term maintenance of datasets.
Keywords Web3, Blockchain, Material Passports, Data Management.
Blockchain-based smart contract generation and visualization in BIM environment: Technical adoption for secured construction management
Xuling Ye | Watch
Abstract
This presentation explores the integration of blockchain-based smart contracts with Building Information Modeling (BIM) to address critical needs in construction management, including data security, traceability, and process automation. By examining four distinct construction phases and addressing research gaps related to isolated smart contract design, code-based logic, limited data storage, and the absence of a universal framework, this research endeavors to empower stakeholders to independently design and validate smart contracts. The outcomes of this study include the establishment of a Process-embedded Smart Contract List (PeSCL) to link BIM and process-related documents, the development of a mapping from process models to smart contracts, and the visualization of smart contract logic in real-time through Business Process Model and Notation (BPMN) diagrams, offering a promising path to enhance the technical aspects of secure construction management in the digital age.
Keywords Smart contracts, Blockchain, BIM, Construction management, BPMN, Business process automation.
Smart Contracts and DAOs: Bumps in the legal road, dead end, or an improving map?
Gavin Johnson | Watch
Abstract
Decentralized contract management in construction
Purva Gupta | Watch
Abstract
Achieving trust and collaboration by revamping the contract management process using digitization and automation is seen as a research area yet to be explored where the focus is on dispute avoidance instead of dispute resolution. Having identified that, our research was motivated to build upon the capabilities of blockchain technology and smart contracts and develop a digital and automated contract management system based on two main elements: 1. a decentralized blockchain platform and 2. computable contract clauses. The decentralized system supported by smart contracts would enable certain execution of contract terms, transparent communication through a decentralized stakeholder network, and clear accountability in terms of data stamps and digital signatures.
Keywords Automation, Smart contracts, Blockchain, Construction law, Legal tech, Contract management.
Session 3: Discussion
Session 4
Keynote: Towards a blockchain-enabled automated construction contract: why? when? how? (and if)
David Greenwood | Watch
Abstract
Contractual problems in the construction industry, especially the disputes that arise from them have long been recognised as a problem. The impact in terms of cost, time, and in many cases quality, of contractual disputes is enormous; for instance the cost to the global construction market in 2020 was estimated to be over US$48 billion. One of main causes of dispute is poor contract management, occasioned by various factors including inaccurate documents, lack of proper records, unclear roles and responsibilities, ineffective communication, incompetence, and corruption. The prospect of deploying distributed ledgers and smart contracts on a blockchain to automate or semi automate contractual processes is an attractive one as the characteristics of blockchain (transparency, consensus, immutability, security etc.) may address many of the factors that cause problems in current traditional contract administration. A team at Northumbria University (UK) are about to finalise a prototype blockchain-based infrastructure that performs the elements of the claims management process of the FIDIC 2017 Standard Form of Contract. The functionality of the prototype appears to be robust. A user-interface is nearing completion, and this will enable scenario-testing and its user-acceptability to be investigated. Further research is expected to be required on those challenges that are apparent, and those that emerge from these tests.
Keywords Smart legal contracts, Contract administration, Claims management, FIDIC contract.
Keynote Presentation + Coding Session: Decentralised Autonomous Organisations in AEC
Theodore Dounas | Watch
Abstract
Day 3 – Industry Adoption (Business Adoption)
Session 5
ESG Responsive contracts in Construction using Smart Legal Contracts and DLT
Niall Roche | Watch
Abstract MISSING VIDEO
Security-minded OpenBIM CDE for Building Data Management Using Encryption and Distributed Ledger Technology
Moumita Das | Watch
Abstract Construction projects generate a large amount of digital information during the design, construction, and operation phases that require sharing and management across stakeholders from multiple domains. It is well established that effective building data management strategies, using rules, programs, and practices to regulate, safeguard, and improve the value of project information assets (such as BIM, documents, and IoT) with a Common Data Environment (CDE) is recommended for streamlining coordination and effective data sharing. among project partners to ensure project success in terms of cost and time. However, the existing CDEs are faced with several error-inducing methods/gaps that - put sensitive information (especially BIM is hard to regulate) at risk of loss of privacy and integrity, resulting in incomplete BIM model delivery during design and construction phases, failure to hold contractually bound stakeholders accountable for their actions, and more. In particular, the problems in existing CDEs are identified as follows- (1) privacy of sensitive information in BIM models, (2) efficient and automated coordination in multi-domain submission management and accountability of delivery teams, (3) Completeness of the BIM deliverables and accountability of stakeholders during the construction phase. Therefore, the proposed “Security-minded OpenBIM CDE for Building Data Management Using Encryption and Distributed Ledger Technology” framework captures information from Open BIM models using the IFC format, IoT Sensors, and documents and deploys encryption and blockchain technologies to facilitate data privacy, data integrity, data accessibility, and delivery team accountability. It deploys a – (1) Functional Partial Encryption Method using OpenBIM to encrypt sensitive information of BIM models at a fine-grained level while maintaining the functionality of BIM models to perform engineering analysis such as clash detection as opposed to file-based encryption, (2) Blockchain-based Dynamic Dependency Workflow using OpenBIM to manage to improve coordination and accountability in large projects with numerous domains and complex and dynamic interlinkage among submissions from different domains, (3) Blockchain-based Completeness Checking Issue Management Workflow using OpenBIM to facilitate automatic checking of completion of marked changes in BIM models for faster/efficient issue resolution. The proposed framework was applied to an ongoing large construction project in Hong Kong.
Keywords Blockchain, Built Environment, Security, Versioning, Issue Management.