Automatic Detection of Volcanic Unrest Using Blind Source Separation with a Minimum Spanning Tree Based Stability Analysis

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Authors

  • Binayak Ghosh
  • Mahdi Motagh
  • Mahmud Haghshenas Haghighi
  • Magdalena Stefanova Vassileva

Research Organisations

External Research Organisations

  • Technische Universität Berlin
  • Helmholtz Centre Potsdam - German Research Centre for Geosciences (GFZ)
  • University of Tübingen
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Details

Original languageEnglish
Article number9490365
Pages (from-to)7771-7787
Number of pages17
JournalIEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing
Volume14
Publication statusPublished - 19 Jul 2021

Abstract

Repeated synthetic aperture radar (SAR) acquisitions can be utilized to produce measurements of ground deformations and associated geohazards, such as it can be used to detect signs of volcanic unrest. Existing time series algorithms like permanent scatterer analysis and small baseline subset are computationally demanding and cannot be applied in near real time to detect subtle, transient, and precursory deformations. To overcome this problem, we have adapted a minimum spanning tree based spatial independent component analysis method to automatically detect sources related to volcanic unrest from a time series of differential interferograms. For a synthetic dataset, we first utilize the algorithm's capability to isolate signals of geophysical interest from atmospheric artifacts, topography, and other noise signals, before monitoring the evolution of these signals through time in order to detect the onset of a period of volcanic unrest, in near real time. In this article, we first demonstrate our approach on synthetic datasets having different signal strengths and temporal complexities. Second, we demonstrate our approach on a couple of real datasets, one acquired in 2017-2019 over the Colima volcano, Mexico, showing the occurrence of previously unrecognized short-term deformation events and the other over Mt. Thorbjorn in Iceland acquired over 2020. This shows the strength of the deep learning application to differential interferometric SAR measurements, and highlights that deformation events occurring without eruptions, which may have previously been undetected.

Keywords

    Colima volcano, Iceland, independent component analysis (ICA), interferometric synthetic aperture radar (InSAR), Mexico, minimum spanning tree, MtThorbjorn, sentinel-1, volcano

ASJC Scopus subject areas

Cite this

Automatic Detection of Volcanic Unrest Using Blind Source Separation with a Minimum Spanning Tree Based Stability Analysis. / Ghosh, Binayak; Motagh, Mahdi; Haghighi, Mahmud Haghshenas et al.
In: IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, Vol. 14, 9490365, 19.07.2021, p. 7771-7787.

Research output: Contribution to journalArticleResearchpeer review

Ghosh B, Motagh M, Haghighi MH, Vassileva MS, Walter TR, Maghsudi S. Automatic Detection of Volcanic Unrest Using Blind Source Separation with a Minimum Spanning Tree Based Stability Analysis. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing. 2021 Jul 19;14:7771-7787. 9490365. doi: 10.1109/JSTARS.2021.3097895
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title = "Automatic Detection of Volcanic Unrest Using Blind Source Separation with a Minimum Spanning Tree Based Stability Analysis",
abstract = "Repeated synthetic aperture radar (SAR) acquisitions can be utilized to produce measurements of ground deformations and associated geohazards, such as it can be used to detect signs of volcanic unrest. Existing time series algorithms like permanent scatterer analysis and small baseline subset are computationally demanding and cannot be applied in near real time to detect subtle, transient, and precursory deformations. To overcome this problem, we have adapted a minimum spanning tree based spatial independent component analysis method to automatically detect sources related to volcanic unrest from a time series of differential interferograms. For a synthetic dataset, we first utilize the algorithm's capability to isolate signals of geophysical interest from atmospheric artifacts, topography, and other noise signals, before monitoring the evolution of these signals through time in order to detect the onset of a period of volcanic unrest, in near real time. In this article, we first demonstrate our approach on synthetic datasets having different signal strengths and temporal complexities. Second, we demonstrate our approach on a couple of real datasets, one acquired in 2017-2019 over the Colima volcano, Mexico, showing the occurrence of previously unrecognized short-term deformation events and the other over Mt. Thorbjorn in Iceland acquired over 2020. This shows the strength of the deep learning application to differential interferometric SAR measurements, and highlights that deformation events occurring without eruptions, which may have previously been undetected.",
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note = "Funding Information: Manuscript received May 5, 2021; revised June 14, 2021; accepted July 1, 2021. Date of publication July 19, 2021; date of current version August 18, 2021. This work was supported by the HEIBRiDS Research School (https: //www.heibrids.berlin/) and in part by the Helmholtz Incubator Pilot Project TECVOLSA. (Corresponding author: Binayak Ghosh.) Binayak Ghosh is with the GFZ German Research Centre for Geosciences, Technical University Berlin, 10623 Berlin, Germany (e-mail: binghosh@gmail.com).",
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Download

TY - JOUR

T1 - Automatic Detection of Volcanic Unrest Using Blind Source Separation with a Minimum Spanning Tree Based Stability Analysis

AU - Ghosh, Binayak

AU - Motagh, Mahdi

AU - Haghighi, Mahmud Haghshenas

AU - Vassileva, Magdalena Stefanova

AU - Walter, Thomas R.

AU - Maghsudi, Setareh

N1 - Funding Information: Manuscript received May 5, 2021; revised June 14, 2021; accepted July 1, 2021. Date of publication July 19, 2021; date of current version August 18, 2021. This work was supported by the HEIBRiDS Research School (https: //www.heibrids.berlin/) and in part by the Helmholtz Incubator Pilot Project TECVOLSA. (Corresponding author: Binayak Ghosh.) Binayak Ghosh is with the GFZ German Research Centre for Geosciences, Technical University Berlin, 10623 Berlin, Germany (e-mail: binghosh@gmail.com).

PY - 2021/7/19

Y1 - 2021/7/19

N2 - Repeated synthetic aperture radar (SAR) acquisitions can be utilized to produce measurements of ground deformations and associated geohazards, such as it can be used to detect signs of volcanic unrest. Existing time series algorithms like permanent scatterer analysis and small baseline subset are computationally demanding and cannot be applied in near real time to detect subtle, transient, and precursory deformations. To overcome this problem, we have adapted a minimum spanning tree based spatial independent component analysis method to automatically detect sources related to volcanic unrest from a time series of differential interferograms. For a synthetic dataset, we first utilize the algorithm's capability to isolate signals of geophysical interest from atmospheric artifacts, topography, and other noise signals, before monitoring the evolution of these signals through time in order to detect the onset of a period of volcanic unrest, in near real time. In this article, we first demonstrate our approach on synthetic datasets having different signal strengths and temporal complexities. Second, we demonstrate our approach on a couple of real datasets, one acquired in 2017-2019 over the Colima volcano, Mexico, showing the occurrence of previously unrecognized short-term deformation events and the other over Mt. Thorbjorn in Iceland acquired over 2020. This shows the strength of the deep learning application to differential interferometric SAR measurements, and highlights that deformation events occurring without eruptions, which may have previously been undetected.

AB - Repeated synthetic aperture radar (SAR) acquisitions can be utilized to produce measurements of ground deformations and associated geohazards, such as it can be used to detect signs of volcanic unrest. Existing time series algorithms like permanent scatterer analysis and small baseline subset are computationally demanding and cannot be applied in near real time to detect subtle, transient, and precursory deformations. To overcome this problem, we have adapted a minimum spanning tree based spatial independent component analysis method to automatically detect sources related to volcanic unrest from a time series of differential interferograms. For a synthetic dataset, we first utilize the algorithm's capability to isolate signals of geophysical interest from atmospheric artifacts, topography, and other noise signals, before monitoring the evolution of these signals through time in order to detect the onset of a period of volcanic unrest, in near real time. In this article, we first demonstrate our approach on synthetic datasets having different signal strengths and temporal complexities. Second, we demonstrate our approach on a couple of real datasets, one acquired in 2017-2019 over the Colima volcano, Mexico, showing the occurrence of previously unrecognized short-term deformation events and the other over Mt. Thorbjorn in Iceland acquired over 2020. This shows the strength of the deep learning application to differential interferometric SAR measurements, and highlights that deformation events occurring without eruptions, which may have previously been undetected.

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KW - Iceland

KW - independent component analysis (ICA)

KW - interferometric synthetic aperture radar (InSAR)

KW - Mexico

KW - minimum spanning tree

KW - MtThorbjorn

KW - sentinel-1

KW - volcano

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EP - 7787

JO - IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing

JF - IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing

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