Papers
Topics
Authors
Recent
Gemini 2.5 Flash
Gemini 2.5 Flash
125 tokens/sec
GPT-4o
53 tokens/sec
Gemini 2.5 Pro Pro
42 tokens/sec
o3 Pro
4 tokens/sec
GPT-4.1 Pro
47 tokens/sec
DeepSeek R1 via Azure Pro
28 tokens/sec
2000 character limit reached

Digital Twins and Civil Engineering Phases: Reorienting Adoption Strategies (2403.02426v2)

Published 4 Mar 2024 in cs.CE, cs.LG, and stat.AP

Abstract: Digital twin (DT) technology has received immense attention over the years due to the promises it presents to various stakeholders in science and engineering. As a result, different thematic areas of DT have been explored. This is no different in specific fields such as manufacturing, automation, oil and gas, and civil engineering, leading to fragmented approaches for field-specific applications. The civil engineering industry is further disadvantaged in this regard as it relies on external techniques by other engineering fields for its DT adoption. A rising consequence of these extensions is a concentrated application of DT to the operations and maintenance phase. On another spectrum, Building Information Modeling (BIM) is pervasively utilized in the planning/design phase, and the transient nature of the construction phase remains a challenge for its DT adoption. In this paper, we present a phase-based development of DT in the Architecture, Engineering, and Construction industry. We commence by presenting succinct expositions on DT as a concept and as a service, and establish a five-level scale system. Furthermore, we present separately a systematic literature review of the conventional techniques employed at each civil engineering phase. In this regard, we identified enabling technologies such as computer vision for extended sensing and the Internet of Things for reliable integration. Ultimately, we attempt to reveal DT as an important tool across the entire life cycle of civil engineering projects, and nudge researchers to think more holistically in their quest for the integration of DT for civil engineering applications.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (220)
  1. “Digital twin shop-floor: a new shop-floor paradigm towards smart manufacturing,” IEEE access, 5, pp. 20418–20427.
  2. “A comparative study on digital twin models,” In AIP Conference Proceedings, Vol. 2073, AIP Publishing.
  3. “Digital twin and big data towards smart manufacturing and industry 4.0: 360 degree comparison,” IEEE Access, 6, pp. 3585–3593.
  4. “Working mode in aircraft manufacturing based on digital coordination model,” The international journal of advanced manufacturing technology, 98, pp. 1547–1571.
  5. “Reengineering aircraft structural life prediction using a digital twin,” International Journal of Aerospace Engineering, 2011.
  6. “Oil and gas digital twins after twenty years. how can they be made sustainable, maintainable and useful?,”.
  7. “Environmental economics and uncertainty: Review and a machine learning outlook,” In Oxford Research Encyclopedia of Environmental Science. Oxford University Press, Aug.
  8. “A bim-data mining integrated digital twin framework for advanced project management,” Automation in Construction, 124, p. 103564.
  9. “Digital twin in industry: State-of-the-art,” IEEE Transactions on Industrial Informatics, 15(4), pp. 2405–2415.
  10. “Roadmap for delivering the information management framework for the built environment,”.
  11. “Principle-based digital twins: a scoping review,”.
  12. “Development of the simulation model for digital twin applications in historical masonry buildings: The integration between numerical and experimental reality,” Computers & Structures, 238, p. 106282.
  13. “Towards civil engineering 4.0: Concept, workflow and application of digital twins for existing infrastructure,” Automation in Construction, 141, p. 104421.
  14. “A digital twin framework for civil engineering structures,” arXiv preprint arXiv:2308.01445.
  15. “A probabilistic graphical model foundation for enabling predictive digital twins at scale,” Nature Computational Science, 1(5), pp. 337–347.
  16. “Digital twinning of self-sensing structures using the statistical finite element method,” Data-Centric Engineering, 3, p. e31.
  17. “Characterising the digital twin: A systematic literature review,” CIRP journal of manufacturing science and technology, 29, pp. 36–52.
  18. “Digital twin: Values, challenges and enablers from a modeling perspective,” Ieee Access, 8, pp. 21980–22012.
  19. “Digital twins: state-of-the-art and future directions for modeling and simulation in engineering dynamics applications,” ASCE-ASME Journal of Risk and Uncertainty in Engineering Systems, Part B: Mechanical Engineering, 6(3), p. 030901.
  20. “Digital twin in manufacturing: A categorical literature review and classification,” Ifac-PapersOnline, 51(11), pp. 1016–1022.
  21. Arup, 2019, “Digital twin – towards a meaningful framework,”.
  22. “The digital twin paradigm for future nasa and us air force vehicles,” In 53rd AIAA/ASME/ASCE/AHS/ASC structures, structural dynamics and materials conference 20th AIAA/ASME/AHS adaptive structures conference 14th AIAA, p. 1818.
  23. “Digital twin: Defnition & value (american institute of aeronautics and astronautics (aiaa) and aerospace industries association (aia)).,”.
  24. “Digital twin: Mitigating unpredictable, undesirable emergent behavior in complex systems,” Transdisciplinary perspectives on complex systems: New findings and approaches, pp. 85–113.
  25. “Digital twin: manufacturing excellence through virtual factory replication,” White paper, 1(2014), pp. 1–7.
  26. IBM, 2024, “What is a digital twin. accessed february 9, 2024. https://www.ibm.com/topics/what-is-a-digital-twin,”.
  27. “Ge digital. minds + machines 2016, meet the digital twin. published 2016. accessed november 17, 2019. https://www.youtube.com/watch?v=2dcz3ol2rtw,”.
  28. Siemens “Siemens. digital twin. accessed february 9, 2024. https://www.plm.automation.siemens.com/global/en/our-story/glossary/digital-twin/24465,”.
  29. “Artificial intelligence-driven digital twin of a modern house demonstrated in virtual reality,” IEEE Access, 11, pp. 35035–35058.
  30. “The fourth industrial revolution: Opportunities and challenges,” International journal of financial research, 9(2), pp. 90–95.
  31. “Digital twins as the next phase of cyber-physical systems in construction,” In ASCE International Conference on Computing in Civil Engineering 2019, American Society of Civil Engineers Reston, VA, pp. 256–264.
  32. “Enabling technologies and tools for digital twin,” Journal of Manufacturing Systems, 58, pp. 3–21 Digital Twin towards Smart Manufacturing and Industry 4.0.
  33. “Adoption of the building information modeling (bim) for construction project effectiveness: The review of bim benefits,” American Journal of Civil Engineering and Architecture, 4(3), pp. 74–79.
  34. “Towards implementation of building information modelling in the,”.
  35. “Reducing embodied carbon during the design process of buildings,” Journal of Building Engineering, 4, pp. 1–13.
  36. “Building information modelling (bim) for sustainable building design,” Facilities, 31(3/4), pp. 138–157.
  37. “Digital twin: Vision, benefits, boundaries, and creation for buildings,” IEEE Access, 7, pp. 147406–147419.
  38. “Digital twin application in the construction industry: A literature review,” Journal of Building Engineering, 40, p. 102726.
  39. “A critical review on structural health monitoring: Definitions, methods, and perspectives,” Archives of computational methods in engineering, pp. 1–27.
  40. “Structural health monitoring of civil engineering structures by using the internet of things: A review,” Journal of Building Engineering, 48, p. 103954.
  41. “Smart sensing technologies for structural health monitoring of civil engineering structures,” Advances in civil engineering, 2010.
  42. “A review of ground-based radar as a noncontact sensor for structural health monitoring of in-field wind turbines blades,” Wind Energy, 21(12), pp. 1435–1449.
  43. “Construction with digital twin information systems,” Data-Centric Engineering, 1, p. e14.
  44. “A review of the roles of digital twin in cps-based production systems,” Procedia manufacturing, 11, pp. 939–948.
  45. “Review of digital twin about concepts, technologies, and industrial applications,” Journal of Manufacturing Systems, 58, pp. 346–361 Digital Twin towards Smart Manufacturing and Industry 4.0.
  46. “Real-time visualization of building information models (bim),” Automation in construction, 54, pp. 69–82.
  47. “Automated plan review for building code compliance using bim,” In Proceedings of 20th International Workshop: Intelligent Computing in Engineering (EG-ICE 2013), pp. 1–10.
  48. “The challenges of using bim in construction dispute resolution process,” In Proceedings of the 53rd ASC Annual International Conference Proceedings, Associated Schools of Construction, Seattle, WA, USA, pp. 5–8.
  49. “Bim-enabled computerized design and digital fabrication of industrialized buildings: A case study,” Journal of Cleaner Production, 278, p. 123505.
  50. “Bim and ontology-based approach for building cost estimation,” Automation in construction, 41, pp. 96–105.
  51. “Formalized knowledge of construction sequencing for visual monitoring of work-in-progress via incomplete point clouds and low-lod 4d bims,” Advanced Engineering Informatics, 29(4), pp. 889–901.
  52. “Building information modeling in construction conflict management,” International journal of engineering business management, 9, p. 1847979017746257.
  53. “Clash detection or clash avoidance? an investigation into coordination problems in 3d bim,” Buildings, 7(3), p. 75.
  54. “Parametric description of bridge structures,” In IABSE Symposium Report, Vol. 94, International Association for Bridge and Structural Engineering, pp. 17–27.
  55. “Improving the robustness of model exchanges using product modeling” concepts” for ifc schema,” In Computing in Civil Engineering (2011). pp. 611–618.
  56. “Modeling and implementation of smart aec objects: an ifc perspective,” In Proceedings of the CIB w78 Conference: Distributing Knowledge in Building, Aarhus School of Architecture, 12–14 June (2002), pp. 1–8.
  57. “A parametric bim approach to foster bridge project design and analysis,” Automation in Construction, 126, p. 103679.
  58. “Elements of parametric design, routledge,” USA and Canada.
  59. “Bim for sustainability analyses,” International Journal of Construction Education and Research, 5(4), pp. 276–292.
  60. “Implementing ‘beam plus’ for bim-based sustainability analysis,” Automation in construction, 44, pp. 163–175.
  61. Evaluating sustainability of architectural designs using building information modeling. the open construction and building technology journal, 4, 1-8.
  62. “Modularized rule-based validation of a bim model pertaining to model views,” Automation in Construction, 63, pp. 1–11.
  63. Pauwels, 2015, “Ifc2rdftools, presentation in the cibw078 workshop on accelerating bim research (last accessed september 2023),” CIBW078 Workshop.
  64. “Validations for ensuring the interoperability of data exchange of a building information model,” Automation in Construction, 58, pp. 176–195.
  65. “Towards a semantic construction digital twin: Directions for future research,” Automation in Construction, 114, p. 103179.
  66. “Semantic web technologies in aec industry: A literature overview,” Automation in construction, 73, pp. 145–165.
  67. “Interlinking life-cycle data spaces to support decision making in highway asset management,” Automation in construction, 64, pp. 54–64.
  68. “An ontology-based analysis of the industry foundation class schema for building information model exchanges,” Advanced Engineering Informatics, 29(4), pp. 940–957.
  69. “Express to owl for construction industry: Towards a recommendable and usable ifcowl ontology,” Automation in construction, 63, pp. 100–133.
  70. “From bim to digital twins: A systematic review of the evolution of intelligent building representations in the aec-fm industry.,” Journal of Information Technology in Construction, 26.
  71. “Quantitative assessment of building constructability using bim and 4d simulation,” Open journal of civil engineering, 6(03), p. 442.
  72. “Bim-based interoperable workflow for energy improvement of school buildings over the life cycle,”.
  73. “Patterns of thermal preference and visual thermal landscaping model in the workplace,” Applied Energy, 255, p. 113674.
  74. “A building information model (bim) and artificial neural network (ann) based system for personal thermal comfort evaluation and energy efficient design of interior space,” Sustainability, 11(18), p. 4972.
  75. “A bim-based web service framework for green building energy simulation and code checking,” Journal of Information Technology in Construction (ITcon), 19(8), pp. 150–168.
  76. “Bim-based acoustic simulation framework,” In 30th CIB W78 International Conference, pp. 99–108.
  77. “A review of building information modeling (bim) and the internet of things (iot) devices integration: Present status and future trends,” Automation in Construction, 101, pp. 127–139.
  78. “Automatic reconstruction of as-built building information models from laser-scanned point clouds: A review of related techniques,” Automation in Construction, 19(7), pp. 829–843.
  79. “Tracking the built status of mep works: Assessing the value of a scan-vs-bim system,” Journal of computing in civil engineering, 28(4), p. 05014004.
  80. “The value of integrating scan-to-bim and scan-vs-bim techniques for construction monitoring using laser scanning and bim: The case of cylindrical mep components,” Automation in Construction, 49, pp. 201–213 30th ISARC Special Issue.
  81. “From bim towards digital twin: strategy and future development for smart asset management,” Service Oriented, Holonic and Multi-agent Manufacturing Systems for Industry of the Future: Proceedings of SOHOMA 2019 9, pp. 392–404.
  82. “Developing a digital twin at building and city levels: Case study of west cambridge campus,” Journal of Management in Engineering, 36(3), p. 05020004.
  83. “Digital twin-enabled anomaly detection for built asset monitoring in operation and maintenance,” Automation in Construction, 118, p. 103277.
  84. “Integration of digital twin and bim technologies within factories of the future,” Magazine of Civil Engineering(1 (101)), p. 10114.
  85. “Iot and digital twin enabled smart tracking for safety management,” Computers & Operations Research, 128, p. 105183.
  86. “Influence of 5g and iot in construction and demolition waste recycling–conceptual smart city design,” Journal of Construction Materials, 1(4), pp. 1–9.
  87. “Comparative study of seamless asset location and tracking technologies,” Procedia Manufacturing, 51, pp. 1138–1145.
  88. “Real-time monitoring of construction sites: Sensors, methods, and applications,” Automation in Construction, 136, p. 104099.
  89. “Integrating automated data acquisition technologies for progress reporting of construction projects,” Automation in construction, 20(6), pp. 699–705.
  90. Gigabyte, 2024, Point cloud.
  91. Introduction to modern photogrammetry John Wiley & Sons.
  92. “A review of mobile mapping systems: From sensors to applications,” Sensors, 22(11), p. 4262.
  93. “Comparison of image-based and time-of-flight-based technologies for three-dimensional reconstruction of infrastructure,” Journal of construction engineering and management, 139(1), pp. 69–79.
  94. “The association between pentraxin 3 in maternal circulation and pathological intrauterine fetal growth restriction,” European Journal of Obstetrics & Gynecology and Reproductive Biology, 185, pp. 1–8.
  95. “Multisensor-driven real-time crane monitoring system for blind lift operations: Lessons learned from a case study,” Automation in Construction, 124, p. 103552.
  96. “Digital construction: From point solutions to iot ecosystem,” Automation in Construction, 93, pp. 35–46.
  97. “An in-depth survey demystifying the internet of things (iot) in the construction industry: Unfolding new dimensions,” Sustainability, 15(2), p. 1275.
  98. “Patterns and trends in internet of things (iot) research: future applications in the construction industry,” Engineering, Construction and Architectural Management, 28(2), pp. 457–481.
  99. “Evaluation of internet of things (iot) application areas for sustainable construction,” Smart and Sustainable Built Environment, 10(3), pp. 387–402.
  100. “A review of wireless-sensor-network-enabled building energy management systems,” ACM Transactions on Sensor Networks (TOSN), 10(4), pp. 1–43.
  101. “Internet of things (iot): A vision, architectural elements, and future directions,” Future generation computer systems, 29(7), pp. 1645–1660.
  102. “Design and simulation of iot systems using the cisco packet tracer,” Advances in Internet of Things, 11(02), p. 59.
  103. Oracle, 2023, “What is a relational database (rdbms),”.
  104. “Ubiquitous computing: object tracking and monitoring in construction processes utilizing zigbee networks,” In Proceedings of the 23rd International Symposium on Automation and Robotics in Construction (ISARC), Citeseer, pp. 287–292.
  105. IBM “What is a database schema?,”.
  106. “Rapid structural condition assessment using radio frequency identification (rfid) based wireless strain sensor,” Automation in Construction, 54, pp. 1–11.
  107. “A simplified relational database schema for transformation of bim data into a query-efficient and spatially enabled database,” Automation in Construction, 84, pp. 367–383.
  108. “Bimql – an open query language for building information models,” Advanced Engineering Informatics, 27(4), pp. 444–456.
  109. “Building performance optimisation: A hybrid architecture for the integration of contextual information and time-series data,” Automation in Construction, 70, pp. 51–61.
  110. “A framework for an integrated nuclear digital environment,” Progress in Nuclear Energy, 87, pp. 97–103.
  111. “D4ar–a 4-dimensional augmented reality model for automating construction progress monitoring data collection, processing and communication,” Journal of information technology in construction, 14(13), pp. 129–153.
  112. “Evolution of close-range detection and data acquisition technologies towards automation in construction progress monitoring,” Journal of Building Engineering, 43, p. 102877.
  113. “A concept for automated construction progress monitoring using bim-based geometric constraints and photogrammetric point clouds.,” J. Inf. Technol. Constr., 20(5), pp. 68–79.
  114. “A review of automated construction progress monitoring and inspection methods,” In Proc. of the 32nd CIB W78 Conference 2015, pp. 421–431.
  115. “Automated continuous construction progress monitoring using multiple workplace real time 3d scans,” Advanced Engineering Informatics, 38, pp. 27–40.
  116. “Computer vision-based interior construction progress monitoring: A literature review and future research directions,” Automation in Construction, 127, p. 103705.
  117. “A systematic classification and evaluation of automated progress monitoring technologies in construction,” In ISARC. Proceedings of the International Symposium on Automation and Robotics in Construction, Vol. 39, IAARC Publications, pp. 120–127.
  118. “Literature review of digital twins applications in construction workforce safety,” Applied Sciences, 11(1), p. 339.
  119. “Framework for location data fusion and pose estimation of excavators using stereo vision,” Journal of Computing in Civil Engineering, 32(6), p. 04018045.
  120. “Continuous localization of construction workers via integration of detection and tracking,” Automation in Construction, 72, pp. 129–142.
  121. “Matching construction workers across views for automated 3d vision tracking on-site,” Journal of Construction Engineering and Management, 144(7), p. 04018061.
  122. “Hardhat-wearing detection for enhancing on-site safety of construction workers,” Journal of Construction Engineering and Management, 141(9), p. 04015024.
  123. “Building information modeling (bim) and safety: Automatic safety checking of construction models and schedules,” Automation in Construction, 29, pp. 183–195.
  124. “Bim-based code checking for construction health and safety,” Procedia Engineering, 196, pp. 454–461 Creative Construction Conference 2017, CCC 2017, 19-22 June 2017, Primosten, Croatia.
  125. “A digital twin approach for tunnel construction safety early warning and management,” Computers in Industry, 144, p. 103783.
  126. “Cost-benefit analysis of bim-enabled design clash detection and resolution,” Construction Management and Economics, 39(1), pp. 55–72.
  127. “Collaborative process to facilitate bim-based clash detection tasks for enhancing constructability,” Journal of the Korea Institute of Building Construction, 12(3), pp. 299–314.
  128. “Building information modeling in project management: necessities, challenges and outcomes,” Procedia-Social and Behavioral Sciences, 210, pp. 87–95.
  129. “Detecting design conflicts using building information models: a comparative lab experiment,” In Proceedings of the CIB W, Vol. 78, p. 2010.
  130. “Automatic clash correction sequence optimization using a clash dependency network,” Automation in Construction, 115, p. 103205.
  131. “Ifc-based clash detection for the open-source bimserver,” In Computing in civil and building engineering, proceedings of the international conference. Nottingham University Press, Nottingham, UK, Vol. 181.
  132. “Diffusion of building information modeling functions in the construction industry,” Journal of Management in Engineering, 34(2), p. 04017060.
  133. “Clash relevance prediction based on machine learning,” Journal of Computing in Civil Engineering, 33(2), p. 04018060.
  134. “Automated multi-objective construction logistics optimization system,” Automation in Construction, 43, pp. 110–122.
  135. “Peeking into the void: Digital twins for construction site logistics,” Computers in Industry, 121, p. 103264.
  136. “Opportunities for enhanced lean construction management using internet of things standards,” Automation in Construction, 61, pp. 86–97.
  137. “Usage of optimization techniques in civil engineering during the last two decades,” Curr. Trends Civ. Struct. Eng, 2(1), pp. 1–17.
  138. “Multi‐objective particle swarm optimization for construction time‐cost tradeoff problems,” Construction Management and Economics, 28(1), pp. 75–88.
  139. “Nondominated archiving multicolony ant algorithm in time–cost trade-off optimization,” Journal of Construction Engineering and Management, 135(7), pp. 668–674.
  140. “An ant colony system based decision support system for construction time-cost optimization,” Journal of Civil Engineering and Management, 18(4), pp. 580–589.
  141. “Discrete particle swarm optimization method for the large-scale discrete time–cost trade-off problem,” Expert Systems with Applications, 51, pp. 177–185.
  142. “An integrated multi-objective optimization model for solving the construction time-cost trade-off problem,” Journal of Civil Engineering and Management, 21(3), pp. 323–333.
  143. “Optimizing construction planning schedules by virtual prototyping enabled resource analysis,” Automation in Construction, 18(7), pp. 912–918.
  144. “Structural health monitoring techniques and technologies for large-scale structures: Challenges, limitations, and recommendations,” Practice Periodical on Structural Design and Construction, 27(3), p. 03122004.
  145. “The vibration monitoring methods and signal processing techniques for structural health monitoring: a review,” Archives of Computational Methods in Engineering, 23, pp. 585–594.
  146. “A review of vibration-based structural health monitoring with special emphasis on composite materials,” Shock and vibration digest, 38(4), pp. 295–324.
  147. “Structural health monitoring of large civil engineering structures,”.
  148. “Real-time digital twin updating strategy based on structural health monitoring systems,” In Model Validation and Uncertainty Quantification, Volume 3: Proceedings of the 38th IMAC, A Conference and Exposition on Structural Dynamics 2020, Springer, pp. 55–64.
  149. “An introduction to structural health monitoring,” Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 365(1851), pp. 303–315.
  150. “Middleware and communication technologies for structural health monitoring of critical infrastructures: A survey,” Computer Standards & Interfaces, 56, pp. 83–100.
  151. “Vibrational based inspection of civil engineering structures,”.
  152. “Structural engineering from an inverse problems perspective,” Proceedings of the Royal Society A, 478(2257), p. 20210526.
  153. “Machine learning algorithms in civil structural health monitoring: A systematic review,” Archives of computational methods in engineering, 28, pp. 2621–2643.
  154. “Multi-image stitching and scene reconstruction for evaluating defect evolution in structures,” Structural Health Monitoring, 10(6), pp. 643–657.
  155. “An advanced vision-based system for real-time displacement measurement of high-rise buildings,” Smart Materials and Structures, 21(12), p. 125019.
  156. “Achievements and challenges in machine vision-based inspection of large concrete structures,” Advances in Structural Engineering, 17(3), pp. 303–318.
  157. “A review of machine vision-based structural health monitoring: Methodologies and applications,” Journal of Sensors, 2016.
  158. “Rich feature hierarchies for accurate object detection and semantic segmentation,” In Proceedings of the IEEE conference on computer vision and pattern recognition, pp. 580–587.
  159. “You only look once: Unified, real-time object detection,” In Proceedings of the IEEE conference on computer vision and pattern recognition, pp. 779–788.
  160. “Semantic instance segmentation with a discriminative loss function,” arXiv preprint arXiv:1708.02551.
  161. “Learning video object segmentation from static images,” In Proceedings of the IEEE conference on computer vision and pattern recognition, pp. 2663–2672.
  162. “Advances in computer vision-based civil infrastructure inspection and monitoring,” Engineering, 5(2), pp. 199–222.
  163. “Determining optical flow,” Artificial Intelligence, 17(1), pp. 185–203.
  164. “Pavement crack detection using the gabor filter,” In 16th international IEEE conference on intelligent transportation systems (ITSC 2013), IEEE, pp. 2039–2044.
  165. “A study of image-based element condition index for bridge inspection,” In ISARC. Proceedings of the International Symposium on Automation and Robotics in Construction, Vol. 30, IAARC Publications, p. 1.
  166. “A novel lbp based methods for pavement crack detection,” Journal of pattern Recognition research, 5(1), pp. 140–147.
  167. “Vision-based automated crack detection for bridge inspection,” Computer-Aided Civil and Infrastructure Engineering, 30(10), pp. 759–770.
  168. “Parametric performance evaluation of wavelet-based corrosion detection algorithms for condition assessment of civil infrastructure systems,” Journal of Computing in Civil Engineering, 27(4), pp. 345–357.
  169. “Crack detection using image processing: A critical review and analysis,” alexandria engineering journal, 57(2), pp. 787–798.
  170. “Automated structural damage detection using one-class machine learning,” In Dynamics of Civil Structures, Volume 4: Proceedings of the 32nd IMAC, A Conference and Exposition on Structural Dynamics, 2014, Springer, pp. 117–128.
  171. “Machine learning for structural health monitoring: challenges and opportunities,” Sensors and smart structures technologies for civil, mechanical, and aerospace systems 2020, 11379, p. 1137903.
  172. “Automated pixel-level pavement crack detection on 3d asphalt surfaces using a deep-learning network,” Computer-Aided Civil and Infrastructure Engineering, 32(10), pp. 805–819.
  173. “An overview of intelligent fault detection in systems and structures,” Structural Health Monitoring, 3(1), pp. 85–98.
  174. Multi-fidelity bayesian optimization in engineering design arXiv, Nov.
  175. Epsilon-greedy thompson sampling to bayesian optimization arXiv, Feb.
  176. “Towards automated post-earthquake inspections with deep learning-based condition-aware models,” arXiv preprint arXiv:1809.09195.
  177. “Simulation-based classification; a model-order-reduction approach for structural health monitoring,” Archives of Computational Methods in Engineering, 25(1), pp. 23–45.
  178. “Review on vibration-based structural health monitoring techniques and technical codes,” Symmetry, 13(11), p. 1998.
  179. Finite element model updating in structural dynamics, Vol. 38 Springer Science & Business Media.
  180. “Automated finite element model updating of a scale bridge model using measured static and modal test data,” Engineering Structures, 102, pp. 66–79.
  181. “Residual structural capacity evaluation of steel moment-resisting frames with dynamic-strain-based model updating method,” Earthquake engineering & Structural Dynamics, 46(11), pp. 1791–1810.
  182. “Review of piezoelectric impedance based structural health monitoring: Physics-based and data-driven methods,” Advances in Structural Engineering, 24(16), pp. 3609–3626.
  183. “Strategies for guided-wave structural health monitoring,” Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, 463(2087), pp. 2961–2981.
  184. “Damage identification in beam-type structures: frequency-based method vs mode-shape-based method,” Engineering structures, 25(1), pp. 57–67.
  185. “Structural damage detection from modal strain energy change,” Journal of engineering mechanics, 126(12), pp. 1216–1223.
  186. “Damage detection in structures using changes in flexibility,” Journal of sound and vibration, 169(1), pp. 3–17.
  187. “Damage detection by finite element model updating using modal flexibility residual,” Journal of sound and vibration, 290(1-2), pp. 369–387.
  188. “Time–frequency analysis in gearbox fault detection using the wigner–ville distribution and pattern recognition,” Mechanical systems and signal processing, 11(5), pp. 673–692.
  189. “Applications of wavelet transforms to damage detection in frame structures,” Engineering structures, 26(1), pp. 39–49.
  190. “Load vectors for damage localization,” Journal of Engineering Mechanics, 128(1), pp. 7–14.
  191. “Hilbert-huang based approach for structural damage detection,” Journal of engineering mechanics, 130(1), pp. 85–95.
  192. “Simulation-based anomaly detection and damage localization: An application to structural health monitoring,” Computer Methods in Applied Mechanics and Engineering, 363, p. 112896.
  193. “A review of novelty detection,” Signal processing, 99, pp. 215–249.
  194. “A comparative evaluation of unsupervised anomaly detection algorithms for multivariate data,” PloS one, 11(4), p. e0152173.
  195. “Isolation forest,” In 2008 eighth ieee international conference on data mining, IEEE, pp. 413–422.
  196. “Lof: identifying density-based local outliers,” In Proceedings of the 2000 ACM SIGMOD international conference on Management of data, pp. 93–104.
  197. “Classification of damage signatures in composite plates using one-class svms,” In 2007 IEEE Aerospace Conference, IEEE, pp. 1–19.
  198. “Adaptive one-class support vector machine for damage detection in structural health monitoring,” In Pacific-Asia Conference on Knowledge Discovery and Data Mining, Springer, pp. 42–57.
  199. “Estimating the support of a high-dimensional distribution,” Neural computation, 13(7), pp. 1443–1471.
  200. “Unsupervised outlier detection in heavy-ion collisions,(2020),” arXiv preprint arXiv:2007.15830.
  201. “The use of pca and signal processing techniques for processing time-based construction settlement data of road embankments,” Advanced Engineering Informatics, 46, p. 101181.
  202. “Cluster-based vibration analysis of structures with gsp,” IEEE Transactions on Industrial Electronics, 68(4), pp. 3465–3474.
  203. “Model-based vs. data-driven approaches for anomaly detection in structural health monitoring: A case study,” In 2021 IEEE International Instrumentation and Measurement Technology Conference (I2MTC), IEEE, pp. 1–6.
  204. “Bat algorithm with principal component analysis,” International Journal of Machine Learning and Cybernetics, 10, pp. 603–622.
  205. “Digital twin, physics-based model, and machine learning applied to damage detection in structures,” Mechanical Systems and Signal Processing, 155, p. 107614.
  206. “Review of surrogate modeling in water resources,” Water Resources Research, 48(7).
  207. “Adaptive explicit decision functions for probabilistic design and optimization using support vector machines,” Computers & Structures, 86(19-20), pp. 1904–1917.
  208. “Limit state function identification using support vector machines for discontinuous responses and disjoint failure domains,” Probabilistic Engineering Mechanics, 23(1), pp. 1–11.
  209. Stochastic subspace via probabilistic principal component analysis arXiv.
  210. Certified reduced basis methods for parametrized partial differential equations, Vol. 590 Springer.
  211. Reduced basis methods for partial differential equations: an introduction, Vol. 92 Springer.
  212. “A reduced-basis element method,” Journal of scientific computing, 17, pp. 447–459.
  213. “Gaussian process subspace prediction for model reduction,” SIAM Journal on Scientific Computing, 44(3), pp. A1428–A1449.
  214. “Sparse bayesian learning and the relevance vector machine,” Journal of machine learning research, 1(Jun), pp. 211–244.
  215. “Sparse bayesian learning for basis selection,” IEEE Transactions on Signal processing, 52(8), pp. 2153–2164.
  216. “Sparse signal recovery with temporally correlated source vectors using sparse bayesian learning,” IEEE Journal of Selected Topics in Signal Processing, 5(5), pp. 912–926.
  217. “Physics informed deep learning (part i): Data-driven solutions of nonlinear partial differential equations,” arXiv preprint arXiv:1711.10561.
  218. “Normal-bundle bootstrap,” SIAM Journal on Mathematics of Data Science, 3(2), May, pp. 573–592.
  219. “On digital twins, mirrors, and virtualizations: Frameworks for model verification and validation,” ASCE-ASME Journal of Risk and Uncertainty in Engineering Systems, Part B: Mechanical Engineering, 6(3), p. 030902.
  220. “Digital twin approach for damage-tolerant mission planning under uncertainty,” Engineering Fracture Mechanics, 225, p. 106766.

Summary

We haven't generated a summary for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Summarize Now