The Study of Seismic Hazard in Near-Fault Areas Using Probabilistic and Deterministic Approach

Earthquake is one of the most common natural disasters in Indonesia and usually destroys both high and low-rise buildings as well as triggers liquefaction and Tsunami. This means it is important to provide a robust building design with the ability to resist earthquake load and other induced phenomen...
Ausführliche Beschreibung

Gespeichert in:

Autor*in:	Grisella Aglia [verfasserIn] Martin Wijaya [verfasserIn] Paulus Pramono Rahardjo [verfasserIn]

Format:	E-Artikel
Sprache:	Englisch

Erschienen:	2023

Schlagwörter:	Earthquake Near-Fault Areas Seismic Hazard Analysis PSHA DSHA

Übergeordnetes Werk:	In: Journal of the Civil Engineering Forum - Universitas Gadjah Mada, 2017, 9(2023), 2
Übergeordnetes Werk:	volume:9 ; year:2023 ; number:2

Links:	Link aufrufen Link aufrufen Link aufrufen Journal toc Journal toc

DOI / URN:	10.22146/jcef.5469

Katalog-ID:	DOAJ090300211

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callnumber-first	T - Technology
author	Grisella Aglia
spellingShingle	Grisella Aglia misc TA1-2040 misc Earthquake misc Near-Fault Areas misc Seismic Hazard Analysis misc PSHA misc DSHA misc Engineering (General). Civil engineering (General) The Study of Seismic Hazard in Near-Fault Areas Using Probabilistic and Deterministic Approach
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topic_title	TA1-2040 The Study of Seismic Hazard in Near-Fault Areas Using Probabilistic and Deterministic Approach Earthquake Near-Fault Areas Seismic Hazard Analysis PSHA DSHA
topic	misc TA1-2040 misc Earthquake misc Near-Fault Areas misc Seismic Hazard Analysis misc PSHA misc DSHA misc Engineering (General). Civil engineering (General)
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title	The Study of Seismic Hazard in Near-Fault Areas Using Probabilistic and Deterministic Approach
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title_sort	study of seismic hazard in near-fault areas using probabilistic and deterministic approach
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title_auth	The Study of Seismic Hazard in Near-Fault Areas Using Probabilistic and Deterministic Approach
abstract	Earthquake is one of the most common natural disasters in Indonesia and usually destroys both high and low-rise buildings as well as triggers liquefaction and Tsunami. This means it is important to provide a robust building design with the ability to resist earthquake load and other induced phenomena. One of the methods commonly used to determine the relevant response spectrum of the bedrock is seismic hazard analysis which can be either Probabilistic Seismic Hazard Analysis (PSHA) or Deterministic Seismic Hazard Analysis (DSHA). The application of PSHA allows the representation of the response spectrum of an earthquake using the return period, thereby providing the engineers with the flexibility of selecting the appropriate natural period. Meanwhile, DSHA is based on geological observations and empirical data that can be easily understood. This research discussed the greater influence of seismic hazard analysis on the bedrock response spectrum of near-fault areas including Bandung situated at a distance of 12.9 km from Lembang Fault, Palu at 3 km from Palu Fault, and Yogyakarta at 8.5 km from Opak Fault. Moreover, EZFRISK Program was used to generate a response spectrum at bedrock and the results showed that PSHA is consistently more conservative than DSHA. It was also noted that there are significant differences at shorter periods for Palu site but these differences were observed at the natural period between 1s and 2s for Bandung and Yogyakarta sites.
abstractGer	Earthquake is one of the most common natural disasters in Indonesia and usually destroys both high and low-rise buildings as well as triggers liquefaction and Tsunami. This means it is important to provide a robust building design with the ability to resist earthquake load and other induced phenomena. One of the methods commonly used to determine the relevant response spectrum of the bedrock is seismic hazard analysis which can be either Probabilistic Seismic Hazard Analysis (PSHA) or Deterministic Seismic Hazard Analysis (DSHA). The application of PSHA allows the representation of the response spectrum of an earthquake using the return period, thereby providing the engineers with the flexibility of selecting the appropriate natural period. Meanwhile, DSHA is based on geological observations and empirical data that can be easily understood. This research discussed the greater influence of seismic hazard analysis on the bedrock response spectrum of near-fault areas including Bandung situated at a distance of 12.9 km from Lembang Fault, Palu at 3 km from Palu Fault, and Yogyakarta at 8.5 km from Opak Fault. Moreover, EZFRISK Program was used to generate a response spectrum at bedrock and the results showed that PSHA is consistently more conservative than DSHA. It was also noted that there are significant differences at shorter periods for Palu site but these differences were observed at the natural period between 1s and 2s for Bandung and Yogyakarta sites.
abstract_unstemmed	Earthquake is one of the most common natural disasters in Indonesia and usually destroys both high and low-rise buildings as well as triggers liquefaction and Tsunami. This means it is important to provide a robust building design with the ability to resist earthquake load and other induced phenomena. One of the methods commonly used to determine the relevant response spectrum of the bedrock is seismic hazard analysis which can be either Probabilistic Seismic Hazard Analysis (PSHA) or Deterministic Seismic Hazard Analysis (DSHA). The application of PSHA allows the representation of the response spectrum of an earthquake using the return period, thereby providing the engineers with the flexibility of selecting the appropriate natural period. Meanwhile, DSHA is based on geological observations and empirical data that can be easily understood. This research discussed the greater influence of seismic hazard analysis on the bedrock response spectrum of near-fault areas including Bandung situated at a distance of 12.9 km from Lembang Fault, Palu at 3 km from Palu Fault, and Yogyakarta at 8.5 km from Opak Fault. Moreover, EZFRISK Program was used to generate a response spectrum at bedrock and the results showed that PSHA is consistently more conservative than DSHA. It was also noted that there are significant differences at shorter periods for Palu site but these differences were observed at the natural period between 1s and 2s for Bandung and Yogyakarta sites.
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title_short	The Study of Seismic Hazard in Near-Fault Areas Using Probabilistic and Deterministic Approach
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