Evaluating the Interdependencies of Infrastructure Critical Systems during Earthquake Event: A Case Study for Padang City

Shubandrio, Fuad Dellany; El-Maissi, Ahmad Mohamad; Kassem, Moustafa Moufid; Masrilayanti, Masrilayanti; Rahmat, Siti Rahyla; Nazri, Fadzli Mohamed

doi:10.3390/su142315926

Cited by 4 publications

(6 citation statements)

References 25 publications

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“…Underground installations or spaces, e.g., tunnels or mines, often hold mechanical loads, temperature and humidity roughly constant, but may yield damage to SHM transducers and systems by exposure to corrosive media. Earthquake prone locations require special attention if the SHM system is able to monitor structures during or after seismic events of a specified magnitude [ 39 , 40 ].…”

Section: Relevant Operational Environmentsmentioning

confidence: 99%

“…Critical infrastructure resilience in general, as discussed in [ 70 ], comprises aspects of robustness, redundancy, resourcefulness and rapidity. The complexity and interdependency of modern infrastructure [ 40 ] makes mitigating damage from natural hazards difficult. Besides the damage due to mechanical loads, the SHM system operation may be affected by power failures, interruption of signal lines or telecommunication problems.…”

Section: Mitigation Of Effects From Variable Service Environmentsmentioning

confidence: 99%

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A Review of Approaches for Mitigating Effects from Variable Operational Environments on Piezoelectric Transducers for Long-Term Structural Health Monitoring

Brunner

2023

Sensors

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Extending the service life of ageing infrastructure, transportation structures, and processing and manufacturing plants in an era of limited resources has spurred extensive research and development in structural health monitoring systems and their integration. Even though piezoelectric transducers are not the only sensor technology for SHM, they are widely used for data acquisition from, e.g., wave-based or vibrational non-destructive test methods such as ultrasonic guided waves, acoustic emission, electromechanical impedance, vibration monitoring or modal analysis, but also provide electric power via local energy harvesting for equipment operation. Operational environments include mechanical loads, e.g., stress induced deformations and vibrations, but also stochastic events, such as impact of foreign objects, temperature and humidity changes (e.g., daily and seasonal or process-dependent), and electromagnetic interference. All operator actions, correct or erroneous, as well as unintentional interference by unauthorized people, vandalism, or even cyber-attacks, may affect the performance of the transducers. In nuclear power plants, as well as in aerospace, structures and health monitoring systems are exposed to high-energy electromagnetic or particle radiation or (micro-)meteorite impact. Even if environmental effects are not detrimental for the transducers, they may induce large amounts of non-relevant signals, i.e., coming from sources not related to changes in structural integrity. Selected issues discussed comprise the durability of piezoelectric transducers, and of their coupling and mounting, but also detection and elimination of non-relevant signals and signal de-noising. For long-term service, developing concepts for maintenance and repair, or designing robust or redundant SHM systems, are of importance for the reliable long-term operation of transducers for structural health monitoring.

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Section: Relevant Operational Environmentsmentioning

confidence: 99%

Section: Mitigation Of Effects From Variable Service Environmentsmentioning

confidence: 99%

A Review of Approaches for Mitigating Effects from Variable Operational Environments on Piezoelectric Transducers for Long-Term Structural Health Monitoring

Brunner

2023

Sensors

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“…The first type is intrinsic or direct damage that is caused directly from different types of hazardous incidents on the triggered system itself i.e., structural and geotechnical failure of piers in bridges, columns failure in buildings, and damaged embankments for roadway systems. On the other hand, the second type is eccentric or indirect damage that is described by the cascading effect of CI on other surrounding one in integrated infrastructural system such as, the affect of collapsed building debris on the surrounding road networks or the cascading effect of road embankments on different lifelines beneath roadway systems [5] .…”

Section: Introductionmentioning

confidence: 99%

“…This research is not focusing on the technical development of the integrated vulnerability assessment method, where, it has been developed and investigated in our previous research studies [ 5 , 6 ]. Mainly, the focus in this studies on the challenges facing the development of the CI integrated assessment models during multi-hazard incidents, the importance of deploying the integrated vulnerability assessment models and indices for advancing the disaster risk reduction strategies, and the role of digital technologies in improving these integrated assessment models.…”

Section: Introductionmentioning

confidence: 99%

Resilient critical infrastructures: An innovative methodological perspective for critical infrastructure (CI) integrated assessment models by inducing digital technologies during multi-hazard incidents

El‐Maissi,

Kassem,

Mohamed Nazri

2024

MethodsX

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“…The interconnectivity and interdependencies of different urban components (buildings, infrastructure, open spaces, the social component [34]) create efficient service delivery, but the failure of one component may result in cascade effects with severe consequences. Therefore, some studies deal with the impact of buildings on the road transportation infrastructure [35,36] and interdependency between critical infrastructure [37], while others address social influences [38,39] and the significance of open spaces [40][41][42]. However, a holistic approach to the assessment of a city's seismic performance should encompass the complexity of an urban system as a whole, including its main physical and social components and the dynamic interactions between them [34].…”

Section: Introductionmentioning

confidence: 99%

Framework for a City’s Performance Assessment in the Case of an Earthquake

Koren

Rus

2023

Buildings

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A comprehensive assessment of a city’s vulnerability and resilience is a prerequisite for an effective response to a natural disaster, such as an earthquake. However, an appropriate method for assessing the seismic performance of a complex urban system is still being researched. To address this gap, the purpose of this paper is to introduce a method for seismic performance assessment of a city as a socio-physical system. Therefore, various studies of individual urban components and their interactions were combined into a holistic framework and presented in a case study of a small mid-European town. The seismic vulnerability of the building inventory was assumed or assessed based on the fragility curves adopted from the literature on similar European building stock. Seismic scenarios of different earthquake intensity (PGA of 0.15 g and 0.30 g) combined with conservative and risky approaches were applied. Considering the human perspective, urban performance was evaluated on the basis of accessibility to urban services that satisfy basic human needs (for survival and protection) via graph theory measures of global efficiency and the shortest path. The temporal aspect (before the earthquake, immediately after it, after evacuation, and after recovery) was also included to obtain a comprehensive resilience assessment. It turned out that a stronger earthquake (PGA of 0.30 g) would have far-reaching consequences for the urban performance of the investigated town, and the old city center would be particularly affected. Following the event, the system’s performance is less than half as effective compared to the initial level, indicating a sharp deterioration in the quality of life as reflected in the possibility of meeting basic human needs.

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Evaluating the Interdependencies of Infrastructure Critical Systems during Earthquake Event: A Case Study for Padang City

Cited by 4 publications

References 25 publications

A Review of Approaches for Mitigating Effects from Variable Operational Environments on Piezoelectric Transducers for Long-Term Structural Health Monitoring

A Review of Approaches for Mitigating Effects from Variable Operational Environments on Piezoelectric Transducers for Long-Term Structural Health Monitoring

Resilient critical infrastructures: An innovative methodological perspective for critical infrastructure (CI) integrated assessment models by inducing digital technologies during multi-hazard incidents

Framework for a City’s Performance Assessment in the Case of an Earthquake

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