Outline of the training. 6 October 2005, TNMC, Bangkok.

Slides:

Advertisements

Similar presentations

Modelling catchment sediment transfer: future sediment delivery to the Carlisle urban area Tom Coulthard Jorge A. Ramirez Paul Bates Jeff Neal.

Advertisements

Use of a hydrodynamic model to

Development of DRAIN-WARMF Model to Simulate Water Flow & Nitrogen Transport From an Agricultural Watershed: “ Subsurface Flow Component” Shadi Dayyani.

Streamflow and Runoff The character, amount, and timing of discharge from a basin tells a lot about flow paths within the basin Therefore, important to.

CHARACTERISTICS OF RUNOFF

Hydrological Modeling FISH 513 April 10, Overview: What is wrong with simple statistical regressions of hydrologic response on impervious area?

Hydrologic/Watershed Modeling Glenn Tootle, P.E. Department of Civil and Environmental Engineering University of Nevada, Las Vegas

Engineering Hydrology (ECIV 4323)

Soil Water Assessment Tool (SWAT) Model Input

Map Modernization Management Support Best Practices Project - FEMA State of Idaho Idaho Department of Water Resources Boise, Idaho November 2008.

Nam Songkhram model application and field work National consultation with TNMC 20th of April 2006, Bangkok MRCS WUP-FIN.

Dr. R.P.Pandey Scientist F. NIH- Nodal Agency Misconception: A DSS takes decisions ---(No)

Ag. & Biological Engineering

1 Flood Hazard Analysis Session 1 Dr. Heiko Apel Risk Analysis Flood Hazard Assessment.

Introduction to AIM/Impact model Kiyoshi Takahashi National Institute for Environmental Studies.

Discharge (Q) Define (cfs; m 3 /s or “cumecs”) Why is Q Important? How is it measured?

Impact of data quality on watershed management—Need for automatic watershed monitoring By: M. J. Abedini and P. Karimaghaei.

MRC Water Utilisation Programme 20 May 2003 Knowledge Base & DSF Software Presenter: Dr Jon Wicks, Software Integration Specialist in association with.

Assessment of Hydrology of Bhutan What would be the impacts of changes in agriculture (including irrigation) and forestry practices on local and regional.

Hydrology Laboratory Research Modeling System (HL-RMS) Introduction: Office of Hydrologic Development National Weather Service National Oceanic and Atmospheric.

Development of a Watershed-to- Very-Near-Shore Model for Pathogen Fate and Transport Sheridan K. Haack Atiq U. Syed Joseph W. Duris USGS, Lansing, MI.

NWS FLDWAV ANALYSIS TOOL

WUP-FIN training, 3-4 May, 2005, Bangkok Hydrological modelling of the Nam Songkhram watershed.

CE 424 HYDROLOGY 1 Instructor: Dr. Saleh A. AlHassoun.

Twinning water quality modelling in Latvia Helene Ejhed

A MANAGEMENT SYSTEM FOR OPTIMIZING OPERATING RULES OF MULTIPURPOSE RESERVOIRS ALLOWING FOR BOTH EXTREME FLOODS AND ECOLOGICAL PERFORMANCE 4 th International.

National Consultation with TNMC 3 May 2005, Bangkok WUP-FIN Phase II – Bank erosion study.

Engineering Hydrology (ECIV 4323)

Watersheds Chapter 9. Watershed All land enclosed by a continuous hydrologic drainage divide and lying upslope from a specified point on a stream All.

Baird Claytor Hydroelectric Project Sedimentation Study.

Multiple Purpose Dam & Reservoir

Description of WMS Watershed Modeling System. What Model Does Integrates GIS and hydrologic models Uses digital terrain data to define watershed and sub.

Vientiane – Nong Khai modelling status National consultation with TNMC 20th of April 2006, Bangkok MRCS WUP-FIN.

Afghan Water Task Progress Report September 7, 2006 EROS Data Center, Sioux Falls, SD Gregg J. Wiche Doug G. Emerson U. S. Geological Survey Bismarck,

FLOOD MAPPING Menaxhimi i rezikut te permbytjeve Objektivat Gjenerale.

DATA ACQUISITION DATA PROCESSING DATA MODELLING VALUE ADDITION JOURNEY OF RTDSS FROM DATA COLLECTION TO DECISION MAKING 4.

Panut Manoonvoravong Bureau of research development and hydrology Department of water resources.

Habitat Mapping of High Level Indicators at Multiple Scales for Fish and Wildlife.

National Consultation with TNMC 3 May 2005, Bangkok WUP-FIN Phase II – Model development.

Describe the features and characteristics of the Three Gorges Dam.

Nam Songkhram model application and field work MRCS WUP-FIN.

Surface Water Virtual Mission Dennis P. Lettenmaier, Kostas Andreadis, and Doug Alsdorf Department of Civil and Environmental Engineering University of.

Hydrology and application of the RIBASIM model SYMP: Su Yönetimi Modelleme Platformu RBE River Basin Explorer: A modeling tool for river basin planning.

MRC-MDBC STRATEGIC LIAISON PROGRAM BASIN DEVELOPMENT PLANNING TRAINING MODULE 3 SCENARIO-BASED PLANNING for the MEKONG BASIN Napakuang, Lao PDR 8-11 December.

Mekong River Commission Information System/ “WUP-FIN Phase III” Concept The information system development is critical activity for maintaining the MRCS.

Corn Yield Comparison Between EPIC-View Simulated Yield And Observed Yield Monitor Data by Chad M. Boshart Oklahoma State University.

Week 2. Work plan 2 Week 1 Week 2 Hydrological models Hydraulic models 1D quasi 2D 2D (25x25 m) Flood resilience 2D (5x5 m) Structural measures.

Hydrology and application of the RIBASIM model SYMP: Su Yönetimi Modelleme Platformu RBE River Basin Explorer: A modeling tool for river basin planning.

Sanitary Engineering Lecture 4

(Srm) model application: SRM was developed by Martinec (1975) in small European basins. With the progress of satellite remote sensing of snow cover, SRM.

WATER RESOURCES DEPARTMENT

a) Water stored in the rocks below ground

Computer Aided Simulation Model for Instream Flow and Riparia

The effect of climate and global change on African water resources

Basin characteristics Instrumentation and data Measured hydrological

Engineering Hydrology (ECIV 4323)

Change in Flood Risk across Canada under Changing Climate

Distributed modelling

Map-Based Hydrology and Hydraulics

Modeling tools Training Module

Predicting the hydrologic and water quality implications of climate and land use change in forested catchments Dennis P. Lettenmaier Department of Civil.

Living with Streams in Flood

Modelling tools - MIKE11 Part1-Introduction

Surface Water Virtual Mission

Hydrology CIVL341.

Engineering Hydrology (ECIV 4323)

Hydrology CIVL341 Introduction

Engineering Hydrology (ECIV 4323)

Presentation transcript:

Outline of the training. 6 October 2005, TNMC, Bangkok

2 Training objectives updating the data and model development issues deepening the knowledge of the EIA 3D hydrodynamic models with practical training planning of the future activities

3 Schedule

4 Brushing up.... HBV and VMod hydrological models Validation results Development and continuation VMod manual 3D Hydrodynamic model Current status of the application Validation Development and continuation Field work Preliminary results from the field work in Si Songkram

5 Nam Songkhram application area

6 HBV and VMod Data Latest results Continuation

7 Elevation km 2 Heights min 135m max 675 m

8 Weather data 16 precipitation stations Temperature data from one station Evaporation, three stations used Some data gaps Temperature missing Some days and months missing in Pan evaporation

9  1175  1432  2366  1339  1254  1128  1564  2290  2665  1796  1446  2943  1976  1984  1850  1979 Average yearly precipitation

10 Modelling: HBV HBV model has been set up for five subcatchments in the Nam Songkhram watershed The size of the model areas is between 625 and 5029 km 2 Ban Tha Kok Daeng Ban Tha Sri Chomchun Ban Phok Yai Ban Khon Sai Ban Nong Yang

11 Modelling: HBV Simple optimisation of the model parameters completed Model results in calibration period ( ) very good to moderately good Model result in test period ( ) good to moderately good

12 The R2 in calibration period was 0.92 for Nam Songkhram at Ban Tha Kok Daeng 0.81 for Nam Oon at Ban Phok Yai 0.74 for Nam Yam at Ban Khon Sai 0.86 for Huai Khong at Ban Tha Sri Chomchun 0.86 for Huai Hi at Ban Nong Yang The R2 of the test period ( ) was 0.83 for Nam Songkhram at Ban Tha Kok Daeng 0.81 for Nam Oon at Ban Phok Yai 0.73 for Nam Yam at Ban Khon Sai 0.77 for Huai Khong at Ban Tha Sri Chomchun 0.76 for Huai Hi at Ban Nong Yang HBV results

13 Modelling :VMod 2D distributed hydrological model coupled with a 1D hydrodynamic river, reservoir and lake model Physical model of the application area that takes into account variability in elevations, soil properties, vegetation, land use etc.

14 Landuse/Irrigated area Landuse (1997) types are Water Agriculture Irrigated agriculture Evergreen/mixed forest Deciduous forest/scrub 89% of landuse agriculture or irrigated agriculture Irrigated 3280 km 2 (24% of catchment, 2001) New landuse data (2002)

15 Soils Five soil types 80 % acrisol/plintic acrisol Low water retention and conductivity water floodplain alluvial soils (plinthic) acrisol slope complex

16 Modelling: VMod 1 km model grid (resolution can and probably will be increased) Flow network computed from DEM and corrected The number of landuse and soil classes has been reduced to make the calibration and use of the model easier and clearer 5 landuse classes 5 soil classes

17 Modelling: VMod, newest developments Data from four new discharge station added to the model Calibration of the model has continued with this new data New developments of the irrigation practices include the possibility to subtract water from the river to be used in irrigation

18 Computed flow at Ban Tha Kok Daeng compared to measured data The results are much better than the previous results, but there is still room for more improvement R2 is 0.91 in calibration period, 0.84 in test period VMod flow computations, Ban Tha Kok Daeng

19 The other four stations with discharge measurement have been included in the model and their calibration is only in the beginning The computed vs. measured in these new stations is not as good as in Ban Tha Kok Daeng The R2 in calibration period was 0.55 for Nam Oon at Ban Phok Yai (there are still problems with irrigational practices and with the Nam Oon dam here) 0.65 for Nam Yam at Ban Khon Sai 0.58 for Huai Khong at Ban Tha Sri Chomchun 0.80 for Huai Hi at Ban Nong Yang VMod flow computations, other stations

20 VMod: Future tasks Develop further the agricultural water practices (water trapping, discharge and evaporation from paddy fields etc.) Check the floodplains in the hydrological model Add structures that may affect flow Check river dimensions (cross sections) Further calibration of the model Include water quality and erosion components to the model and calibrate these Clarify and execute scenarios (e.g. irrigation, land use and climatological changes)

21 EIA 3D Model Latest development Some preliminary results

22 3D hydrodynamic and WQ application 3D hydrodynamic model coupled with a water quality model 3D hydrodynamics flood arrival time, duration and depth in different locations of the modelled area, other flood characteristics Water quality: sediment concentration, net- sedimentation, oxygen, etc Run through a GIS-type graphical user interface

23 Input data for the 3D model River and floodplain topography Hydrographic atlas data river cross-sections for Nam Songkhram digital elevation map (DEM) for floodplain Boundary conditions Upstream discharge and water level in Mekong Upstream dishcarge in Nam Songkhram Downstream rating curve (in Mekong) Landuse Wind (Precipitation)

24 Modelling: 3D The main tribuaries of the Nam Songkhram have been included in the model (Nam Oon, Nam Yam, Huai Hi...) Model calculation have been visually compared to data from inundated areas Effect of Mekong mainstream waterlevel (backwater effect) Sensitivity to parameter values has been analysed Channel dimension and elevations have been modified (still in progress)

25 Digital elevation model and model area

26 3D view on the wetlands

27 Inundation on Sept 2000

28 3D model grid for NSK model

29 Model animation window

30 Flood duration Flood arrival time

31 Flood depth- Mekong water level low Flood depth- Mekong water level high

32 Output Tool to understand the hydrodynamic of the Nam Songkhram flood plains Scenarios and their impact on the flooding Landuse Climate change Irrigation development Reservoir development Interaction between Nam Songkhram and Mekong Reverse flow Back water effect

33 EIA 3D modelling: Future tasks Include new river cross sections in to the model Check grid heights Include structures that affect flow (enbankments, dams, weirds) Calibrate and verify the model Include water quality calculations Clarify and execute scenarios (e.g. irrigation, land use and climatological changes)

34 Field work at Si Songkram - location

35 Current meter RM9 Current speed Current direction Temperature Conductivity Pressure Turbidity Oxygen

36 Current speed & direction Mekong

37 Vientiane – Nong Khai bank erosion study

38 Vientiane – Nong Khai: 50m grid

39 Vientiane – Nong Khai: model results

40 Field work at Vientiane – Nong Khai

41 Field work at Vientiane – Nong Khai Flow velocity

42 Field work at Vientiane – Nong Khai Backscatter

MRCS/WUP-FIN