Management of structural monitoring data of bridges using BIM

Delgado, Juan Manuel Dávila; Butler, Lynda L.; Gibbons, Niamh; Brilakis, Ioannis; Elshafie, Mohammed; Middleton, Campbell

doi:10.1680/jbren.16.00013

Cited by 44 publications

(14 citation statements)

References 12 publications

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“…For example, sensors are used in buildings to monitor temperature variations (Chen et al, 2014), indoor air quality (Kumar et al, 2016), and occupancy (Akkaya et al, 2015). They are also used to monitor power consumption (Suryadevara et al, 2015), structural condition (Davila Delgado et al, 2017;, and surrounding environmental conditions (Martín-Garín et al, 2018). However, current data management frameworks used in the AEC industry cannot handle the ever increasing and diverse data sets.…”

Section: Big Data In Architecture Engineering and Construction (Aec)mentioning

confidence: 99%

Big Data Analytics System for Costing Power Transmission Projects

Delgado

Bilal

Ajayi

et al. 2020

J. Constr. Eng. Manage.

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Inaccurate cost estimates have significant impacts on the final cost of power transmission projects and erode profits. Methods for cost estimation have been investigated thoroughly, but they are not used widely in practice. The purpose of this study is to leverage a Big Data architecture, to manage the large and diverse data required for predictive analytics. This paper presents a Predictive Analytics and Modelling System (PAMS) that facilitates the use of different data-driven cost prediction methods. A 2.75 million-point dataset of power transmission projects has been used as a case study. The proposed Big Data architecture is fit for purpose. It can handle the diverse datasets used in the construction sector. The three most prevalent cost estimation models were implemented (linear regression, support vector regression, and artificial neural networks). All models performed better than the estimated human-level performance. The primary contribution of this study to the Body of Knowledge is an empirical indication that data-driven methods analysed in this study are on average 13.5% better than manual methods for cost estimation of power transmission projects. Additionally, the paper presents a Big Data architecture that can manage and process large varied datasets and seamless scalability.

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Section: Big Data In Architecture Engineering and Construction (Aec)mentioning

confidence: 99%

Big Data Analytics System for Costing Power Transmission Projects

Delgado

Bilal

Ajayi

et al. 2020

J. Constr. Eng. Manage.

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“…Figure 1 shows the completed bridge and its sensor instrumentation arrangement. Real-Time Sensor Data Visualization Using BIM SHM datasets were incorporated into a dynamic BIM environment for visualizing real-time sensor data and associated bridge behavior [7], [8]. Specifically, this can be used to help identify anomalies in the data (due to e.g.…”

Section: Description Of Bridges and Monitoring Programmentioning

confidence: 99%

“…The case study considered two railway bridges in Staffordshire, UK which have pervasive sensor networks installed at the time of construction. The study involves an interdisciplinary collaboration between the Cambridge Centre for Smart Infrastructure and Construction (CSIC) and the Alan Turing Institute (ATI), combining the expertise of bridge monitoring [4], finite element modeling [5], [6], building information modeling (BIM) [7], [8] and statistical modeling [9], [10], with the end objective of creating a working digital twin for the instrumented Staffordshire bridges.…”

Section: Introductionmentioning

confidence: 99%

A Digital Twin of Bridges for Structural Health Monitoring

Cong¹,

Butler²,

Calka³

et al. 2019

Structural Health Monitoring 2019

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“…Because the requirements to adopt BIM during the operational phase are distinctively different than during design and construction, the existing BIM software solutions are not suitable to implement BIM during the operational phase. For example, they lack capabilities to easily compare as-designed and as-built BIM models; to record and use time-series data, such as data related to performance and degradation; and to allow dynamic visualisation of data (Davila Delgado et al 2017;Gerrish et al 2015;Mousa et al 2016).…”

Section: Data-driven and Dynamic Bim Environmentsmentioning

confidence: 99%

Structural Performance Monitoring Using a Dynamic Data-Driven BIM Environment

Delgado

Butler

Brilakis

et al. 2018

J. Comput. Civ. Eng.

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Structural health monitoring data has not been fully leveraged to support asset management due to a lack of effective integration with other datasets. A Building Information Modelling (BIM) approach is presented to leverage structural monitoring data in a dynamic manner. The approach allows for the automatic generation of parametric BIM models of structural monitoring systems that include time-series sensor data; and it enables data-driven and dynamic visualisation in an interactive 3D environment. The approach supports dynamic visualisation of key structural performance parameters, allows for the seamless updating and long-term management of data, and facilitates data exchange by generating Industry Foundation Classes (IFC) compliant models. A newly-constructed bridge near Stafford, UK, with an integrated fibre-optic sensor based monitoring system was used to test the capabilities of the developed approach. The case study demonstrated how the developed approach facilitates more intuitive data interpretation, provides a user-friendly interface to communicate with various stakeholders, allows for the identification of malfunctioning sensors thus contributing to the assessment of monitoring system durability, and forms the basis for a powerful data-driven asset management tool. In addition, this project highlights the potential benefits of investing in the development of data-driven and dynamic BIM environments.

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Management of structural monitoring data of bridges using BIM

Cited by 44 publications

References 12 publications

Big Data Analytics System for Costing Power Transmission Projects

Big Data Analytics System for Costing Power Transmission Projects

A Digital Twin of Bridges for Structural Health Monitoring

Structural Performance Monitoring Using a Dynamic Data-Driven BIM Environment

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