Remote Sensing and geographic Information Systems in Identifying and quantifying inflow parameters for reservoir operations: Difference between revisions
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This study presents the results of the developed methodology to estimate inflow using remote sensing as an alternative to the current water-level approach being used locally. It shows that both the IMBAC and the HEC-HMS approach were successful in showing the behavior of watershed response. The second approach was more successful in terms of the immediate potential for operational use. | This study presents the results of the developed methodology to estimate inflow using remote sensing as an alternative to the current water-level approach being used locally. It shows that both the IMBAC and the HEC-HMS approach were successful in showing the behavior of watershed response. The second approach was more successful in terms of the immediate potential for operational use. | ||
Subject Index : Remote sensing, Reservoirs | |||
[[Category: Theses]] | [[Category: Theses]] | ||
[[Category: | [[Category: Geodetic Engineering Thesis]] | ||
[[Category: College of Engineering Thesis]] | [[Category: College of Engineering Thesis]] | ||
[[Category:2010 Thesis]] |
Latest revision as of 19:11, 21 April 2012
Czar Jakiri Sarmiento
(MS Graduated: 2nd Sem 2009-2010)
Abstract
In managing a multipurpose dam, knowledge of water inflow or the amount of water entering the reservoir is essential in planning and scheduling discharges for optimal power production and irrigation supply, and in flood control. Utilization of satellite imagery improves inflow estimates provided by digital spatial data rather than calculations from drawn maps. Satellite imagery yields measurements over an area are obtained instead of extrapolations from point measurements.
Using remote sensing data and GIS, two approaches are developed in this study to estimate inflow: (1) Creation of IMBAC (Inflow Monitoring from Basin Assessment Calculations), a new inflow estimation system using available satellite-derived data and JAVA programming; and (2) Maximizing the use of satellite-derived data for inflow estimation in an existing hydrologic modeling system, the US Army Corps of Engineers’ HEC-HMS (Hydrologic Engineering Center-Hydrologic Modeling System), where three different basin models are used to validate the results—the initial constant model, the SCS curve number model, and the soil moisture accounting model.
The developed approaches to estimate inflow are applied to the Magat watershed; its dam is one of the largest multipurpose dams in Southeast Asia. Its 117-km2 reservoir stores water to irrigate 85,000 hectares of farmland and its 360-MW hydro-power plant provides electricity for Luzon, the Philippines’ largest island. Due to the implementation of the Philippine Electric Power Industry Reform Act (EPIRA) in 2001, management of the reservoir and the dam facilities has to be shared. The dam and the plant intake gates are owned and operated by the National Irrigation Administration. Management of the plant itself is transferred to SN Aboitiz Power Incorporated (SNAP). Authorization of discharges during extreme weather conditions comes from the country’s meteorological agency, the PAGASA. With such a complex nature of the dam’s multi-stakeholder management involving private and public entities with different discharge motivations, a vital decision support system that concerns inflow estimation is paramount.
This study presents the results of the developed methodology to estimate inflow using remote sensing as an alternative to the current water-level approach being used locally. It shows that both the IMBAC and the HEC-HMS approach were successful in showing the behavior of watershed response. The second approach was more successful in terms of the immediate potential for operational use.
Subject Index : Remote sensing, Reservoirs