Thermal monitoring of volcanic effusive activity: the uncertainties and outlier detection

Zakšek, Klemen; Pick, Leonie; Shirzaei, Manoochehr; Hort, Matthias

doi:10.1144/sp426.2

Cited by 3 publications

(4 citation statements)

References 69 publications

(110 reference statements)

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“…The detected thermal anomalies are usually quantified by their temperature, area, volcanic radiant power (VRP), or time averaged lava discharge rate (TADR) [14][15][16][17][18][19][20][21][22][23][24]. The uncertainty of single measured spectral radiances depends on numerous factors such as different sensor's point spread function and spectral response functions, different time of overpass, orbit geometry, and spatial resolution [25,26].…”

Section: Thermal Observations Of Active Volcanoesmentioning

confidence: 99%

“…In this case, the signal may be dispersed over several pixels although a typical lava flow is no more than a pixel wide in most satellite instruments. This effect is a result of the imperfect point spread function of the optics on satellite instruments [26,38]. In the case of TET-1, this is a very important step as its spatial sampling is 160 m, but the effective pixel size is twice as large (Table 1).…”

Section: Pre-processingmentioning

confidence: 99%

“…These are most likely the consequence of cloud coverage. In our previous work [25,26] we were dealing with uncertainties in VRP's time series. However, we cannot use the methodology based on the Kalman filter to filter out the outliers, as we have only used the MODVOLC database, which is more convenient than processing a large number of MODIS images.…”

Section: Modis Observationsmentioning

confidence: 99%

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Satellite and Ground Based Thermal Observation of the 2014 Effusive Eruption at Stromboli Volcano

2015

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Abstract:As specifically designed platforms are still unavailable at this point in time, lava flows are usually monitored remotely with the use of meteorological satellites. Generally, meteorological satellites have a low spatial resolution, which leads to uncertain results. This paper presents the first long term satellite monitoring of active lava flows on Stromboli volcano (August-November 2014) at high spatial resolution (160 m) and relatively high temporal resolution (~3 days). These data were retrieved by the small satellite Technology Experiment Carrier-1 (TET-1), which was developed and built by the German Aerospace Center (DLR). The satellite instrument is dedicated to high temperature event monitoring. The satellite observations were accompanied by field observations conducted by thermal cameras. These provided short time lava flow dynamics and validation for satellite data. TET-1 retrieved 27 datasets over Stromboli during its effusive activity. Using the radiant density approach, TET-1 data were used to calibrate the MODVOLC data and estimate the time averaged lava discharge rate. With a mean output rate of 0.87 m 3 /s during the three-month-long eruption, we estimate the total erupted volume to be 7.4ˆ10 6 m 3 .

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Section: Thermal Observations Of Active Volcanoesmentioning

confidence: 99%

Section: Pre-processingmentioning

confidence: 99%

Section: Modis Observationsmentioning

confidence: 99%

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Satellite and Ground Based Thermal Observation of the 2014 Effusive Eruption at Stromboli Volcano

2015

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“…In addition, all contributions were invited as reviewstyle submissions that focus on entirely effusive themes so as to build a manual, inventory and directory as to the current state of the art in operational lava flow tracking and modelling. Part 1 begins with a review of three wellestablished hot spot detection algorithms: MOD-VOLC (Wright 2015), RST-Volc (Pergola et al 2015) and AVHotRR (Lombardo 2015), plus a new algorithm type based on application of the Kalman Filter (Zakšek et al 2015). We also review means of near-real-time multiple sensor targeting to obtain high spectral, spatial and temporal resolution event coverage (Ramsey 2015) plus the use of a sensor web-based networking approach to target all available tracking devices on an effusive crisis .…”

Section: The Bookmentioning

confidence: 99%

Risk evaluation, detection and simulation during effusive eruption disasters

Harris

Groeve

Carn

et al. 2016

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Lava ingress into a vulnerable population will be difficult to control, so that evacuation will be necessary for communities in the path of the active lava, followed by post-event population, infrastructural, societal and community replacement and/or relocation. There is a pressing need to set up a response chain that bridges scientists and responders during an effusive crisis to allow nearreal-time delivery of globally standard 'products' for a timely and adequate humanitarian response. In this chain, the scientific research groups investigating lava remote-sensing and modelling need to provide products that are both useful to, and trusted by, the crisis response community. Requirements for these products include (a) formats that can be immediately integrated into a crisis management procedure, and (b) in an agreed and stable standard. A review of current capability reveals that we are at a point where the community can provide such a response, as is the aim of the RED SEED (Risk Evaluation, Detection and Simulation during Effusive Eruption Disasters) working group. This book is the first production of this group and is intended not only as a directory of current capabilities and operational service providers, but also as a statement of intent and need, while providing a simulation designed to demonstrate how a truly pan-disciplinary response to an effusive crisis could work.

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Conclusion: recommendations and findings of the RED SEED working group

Harris

Carn

Dehn

et al. 2016

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RED SEED stands for Risk Evaluation, Detection and Simulation during Effusive Eruption Disasters, and combines stakeholders from the remote sensing, modelling and response communities with experience in tracking volcanic effusive events. The group first met during a three day-long workshop held in Clermont Ferrand (France) between 28 and 30 May 2013. During each day, presentations were given reviewing the state of the art in terms of (a) volcano hot spot detection and parameterization, (b) operational satellite-based hot spot detection systems, (c) lava flow modelling and (d) response protocols during effusive crises. At the end of each presentation set, the four groups retreated to discuss and report on requirements for a truly integrated and operational response that satisfactorily combines remote sensors, modellers and responders during an effusive crisis. The results of collating the final reports, and follow-up discussions that have been on-going since the workshop, are given here. We can reduce our discussions to four main findings. (1) Hot spot detection tools are operational and capable of providing effusive eruption onset notice within 15 min. (2) Spectral radiance metrics can also be provided with high degrees of confidence. However, if we are to achieve a truly global system, more local receiving stations need to be installed with hot spot detection and data processing modules running on-site and in real time. (3) Models are operational, but need real-time input of reliable time-averaged discharge rate data and regular updates of digital elevation models if they are to be effective; the latter can be provided by the radar/photogrammetry community. (4) Information needs to be provided in an agreed and standard format following an ensemble approach and using models that have been validated and recognized as trustworthy by the responding authorities. All of this requires a sophisticated and centralized data collection, distribution and reporting hub that is based on a philosophy of joint ownership and mutual trust. While the next chapter carries out an exercise to explore the viability of the last point, the detailed recommendations behind these findings are detailed here.

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Thermal monitoring of volcanic effusive activity: the uncertainties and outlier detection

Cited by 3 publications

References 69 publications

Satellite and Ground Based Thermal Observation of the 2014 Effusive Eruption at Stromboli Volcano

Satellite and Ground Based Thermal Observation of the 2014 Effusive Eruption at Stromboli Volcano

Risk evaluation, detection and simulation during effusive eruption disasters

Conclusion: recommendations and findings of the RED SEED working group

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