Advantages of a mobile LSPIV method for measuring flood discharges and improving stage–discharge curves

Dramais, Guillaume; Coz, Jérôme Le; Camenen, B.; Hauet, Alexandre

doi:10.1016/j.jher.2010.12.005

Cited by 112 publications

(112 citation statements)

References 14 publications

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“…As part of the RHYTMME project, evaluation of AIGA is also conducted for ungauged basins both in hindcast mode using a historical database of flood damage reports and in realtime mode using feedback from end-users. Besides, as part of the HyMeX international initiative, the FloodScale project (http://floodscale.irstea.fr/frontpage-en?set_language = en) includes the collection of detailed observations from both operational and research hydrometeorological systems as well as from post-event surveys, testing for example the setup of Large Scale Particle Image Velocimetry networks to increase the density of discharge estimation (Le Coz et al 2010, Dramais et al 2011.…”

Section: Discussionmentioning

confidence: 99%

Evaluating flash-flood warnings at ungauged locations using post-event surveys: a case study with the AIGA warning system

Javelle¹,

Demargne

Defrance³

et al. 2014

Hydrological Sciences Journal

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This article presents a comparison between real-time discharges calculated by a flash-flood warning system and post-event flood peak estimates. The studied event occurred on 15 and 16 June 2010 at the Argens catchment located in the south of France. Real-time flood warnings were provided by the AIGA (Adaptation d'Information Géographique pour l'Alerte en Crue) warning system, which is based on a simple distributed hydrological model run at a 1-km 2 resolution using radar rainfall information. The timing of the warnings (updated every 15 min) was compared to the observed flood impacts. Furthermore, "consolidated" flood peaks estimated by an intensive post-event survey were used to evaluate the AIGA-estimated peak discharges. The results indicated that the AIGA warnings clearly identified the most affected areas. However, the effective lead-time of the event detection was short, especially for fastresponse catchments, because the current method does not take into account any rainfall forecast. The flood peak analysis showed a relatively good correspondence between AIGA-and field-estimated peak values, although some differences were due to the rainfall underestimation by the radar and rainfall-runoff model limitations.Key words evaluation; flash flood; ungauged; warning system; post-event survey Evaluation des avertissements de crue éclair sur des bassins non-jaugés en utilisant des relevés post-événement: application avec le système d'avertissement AIGA Résumé Cet article présente une comparaison des débits calculés en temps réel par un système d'avertissement de crues éclair avec des estimations post-événement des pics de crue. L'événement étudié s'est déroulé les 15 et 16 juin 2010 sur le bassin de l'Argens, situé dans le Sud de la France. Les débits en temps réel ont été calculés par le système d'avertissement AIGA (Adaptation d'Information Géographique pour l'Alerte en Crue), qui associe un modèle hydrologique distribué simple et une lame d'eau radar à la résolution de 1 km 2 . La chronologie des avertissements émis a été comparée aux dégâts observés. De plus, des estimations de pic de crue réalisées au cours de relevés de terrain après l'événement ont permis d'évaluer la pertinence des débits estimés par AIGA. Les résultats ont montré qu'AIGA a clairement indiqué les zones les plus affectées par la crue. Cependant, l'anticipation des avertissements a été courte, en particulier sur les bassins rapides, du fait que le système n'intègre pas de prévision de pluie. L'analyse des pics de crue a montré une relative bonne correspondance entre les débits calculés par AIGA et ceux estimés sur le terrain, avec cependant des différences. Celles-ci sont liées à une sous-estimation de la lame d'eau radar sur certains bassins et aux limites du modèle hydrologique.Mots clefs non jaugé ; crue éclair ; système d'avertissement ; relevés post-événement

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Section: Discussionmentioning

confidence: 99%

Evaluating flash-flood warnings at ungauged locations using post-event surveys: a case study with the AIGA warning system

Javelle¹,

Demargne

Defrance³

et al. 2014

Hydrological Sciences Journal

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“…By comparison with the discharges from ADCP, flood estimations based on extrapolated part of the rating curve show significant credibility gaps [4], with a large statistical error of NRMSE = 42.2%. The ADIS indirect flow measurement can be utilized to improve stage-discharge relationships and reduce uncertainties associated with flood discharges [31]. Later on, a combination with The ADIS indirect flow measurement can be utilized to improve stage-discharge relationships and reduce uncertainties associated with flood discharges [31].…”

Section: Discharge Estimationmentioning

confidence: 99%

“…The ADIS indirect flow measurement can be utilized to improve stage-discharge relationships and reduce uncertainties associated with flood discharges [31]. Later on, a combination with The ADIS indirect flow measurement can be utilized to improve stage-discharge relationships and reduce uncertainties associated with flood discharges [31]. Later on, a combination with hydraulic analysis (from experimental investigation or numerical simulation) will be made to achieve further improvement for the LSPIV technique, e.g., capability in assessing various velocity structures over a range of flow conditions [20].…”

Section: Discharge Estimationmentioning

confidence: 99%

Application of an Automated Discharge Imaging System and LSPIV during Typhoon Events in Taiwan

Huang

Young

Liu

2018

Water

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An automated discharge imaging system (ADIS), which is a non-intrusive and safe approach, was developed for measuring river flows during flash flood events. ADIS consists of dual cameras to capture complete surface images in the near and far fields. Surface velocities are accurately measured using the Large Scale Particle Image Velocimetry (LSPIV) technique. The stream discharges are then obtained from the depth-averaged velocity (based upon an empirical velocity-index relationship) and cross-section area. The ADIS was deployed at the Yu-Feng gauging station in Shimen Reservoir upper catchment, northern Taiwan. For a rigorous validation, surface velocity measurements were conducted using ADIS/LSPIV and other instruments. In terms of the averaged surface velocity, all of the measured results were in good agreement with small differences, i.e., 0.004 to 0.39 m/s and 0.023 to 0.345 m/s when compared to those from acoustic Doppler current profiler (ADCP) and surface velocity radar (SVR), respectively. The ADIS/LSPIV was further applied to measure surface velocities and discharges during typhoon events (i.e., Chan-Hom, Soudelor, Goni, and Dujuan) in 2015. The measured water level and surface velocity both showed rapid increases due to flash floods. The estimated discharges from ADIS/LSPIV and ADCP were compared, presenting good consistency with correlation coefficient R = 0.996 and normalized root mean square error NRMSE = 7.96%. The results of sensitivity analysis indicate that the components till (τ) and roll (θ) of the camera are most sensitive parameters to affect the surface velocity using ADIS/LSPIV. Overall, the ADIS based upon LSPIV technique effectively measures surface velocities for reliable estimations of river discharges during typhoon events.

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“…In particular, optical methods such as large-scale particle image ve-locimetry (LSPIV) can be used to estimate flood discharges, and researchers have started leveraging social media and crowdsourcing to collect data for this purpose Dramais et al, 2011). The potential of such data will grow as the availability and pervasiveness of image-capturing devices such as smartphones, surveillance cameras, and unmanned aerial vehicles (Perks et al, 2016) increases.…”

Section: The Need For Comprehensive Urban Flood Datamentioning

confidence: 99%

floodX: urban flash flood experiments monitored with conventional and alternative sensors

Vitry

Dicht

Leitão³

2017

Earth Syst. Sci. Data

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Abstract. The data sets described in this paper provide a basis for developing and testing new methods for monitoring and modelling urban pluvial flash floods. Pluvial flash floods are a growing hazard to property and inhabitants' well-being in urban areas. However, the lack of appropriate data collection methods is often cited as an impediment for reliable flood modelling, thereby hindering the improvement of flood risk mapping and early warning systems. The potential of surveillance infrastructure and social media is starting to draw attention for this purpose. In the floodX project, 22 controlled urban flash floods were generated in a flood response training facility and monitored with state-of-the-art sensors as well as standard surveillance cameras. With these data, it is possible to explore the use of video data and computer vision for urban flood monitoring and modelling. The floodX project stands out as the largest documented flood experiment of its kind, providing both conventional measurements and video data in parallel and at high temporal resolution.

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Advantages of a mobile LSPIV method for measuring flood discharges and improving stage–discharge curves

Cited by 112 publications

References 14 publications

Evaluating flash-flood warnings at ungauged locations using post-event surveys: a case study with the AIGA warning system

Evaluating flash-flood warnings at ungauged locations using post-event surveys: a case study with the AIGA warning system

Application of an Automated Discharge Imaging System and LSPIV during Typhoon Events in Taiwan

floodX: urban flash flood experiments monitored with conventional and alternative sensors

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