All Issue

2025 Vol.58, Issue 12S-3 Preview Page

Research Article

Development and implementation strategies for smart web-based data platform for integrated management of water quality and flow

지능형 수질·유량 통합관리 시스템 개발 및 활용방안 연구

Jungsun Oha*
오 정선a*
aSenior Researcher, Department of Hydro Science and Engineering Research, Korea Institute of Civil Engineering & Building Technology, Goyang, Korea
a한국건설기술연구원 수자원하천연구본부 수석연구원
*Corresponding Author
31 December 2025. pp. 1563-1574
PDF XML Citation
Abstract

This study developed a Smart Web-based Data Platform for Integrated Management of Water Quality and Flow, which enables comprehensive management and analysis of water quality and flow data measured by sensor-equipped unmanned remote systems. The system applies standardized data structures based on ODM2, WaterML 2.0, and RiverML 0.2, automating data collection, preprocessing, quality control, and three-dimensional (3D) visualization. It also supports real-time integration with national platforms such as WAMIS (Water Resources Management Information System) and WEIS (Water Environment Information System). Field applications were conducted at four testbeds such as the Nakdong-Geumho-Jincheon River confluence (Samunjin Bridge area) and Paldang Lake. Analysis results demonstrated that the system could more accurately determine flow ratios at the confluence and quantify the spatial variations of water quality parameters in 3D. At Paldang Reservoir, chlorophyll-a and nutrient concentrations were assessed in 3D, providing baseline data for early detection of algal blooms and for predicting their occurrence and dynamics. Additionally, correlation and regression analyses between water quality parameters and flow data were used to identify influencing factors and establish regression models. This system provides a foundation for integrated management of 3D observational data and quantitative analysis of water quality-flow interactions, and is expected to contribute to the future development of intelligent response systems.

Keywords
Water quality
Flow rate
Integrated management
Web-based data platform
3D data

본 연구에서는 센서가 장착된 무인원격이동체(unmanned remote system)를 기반으로 측정된 수질 및 유량 데이터를 통합적으로 관리·분석할 수 있는 지능형 수질·유량 통합관리 시스템(Smart Integrated Water Data Management System)을 구축하였다. 본 시스템은 ODM2, WaterML 2.0 및 RiverML 0.2 표준구조를 적용하여 데이터의 수집, 전처리, 품질검증, 3차원(3D) 시각화를 자동화하였으며, 국가 수자원관리시스템(WAMIS)과 물환경정보시스템(WEIS)과의 실시간 연계를 지원한다. 현장 적용은 낙동강·금호강·진천천 합류부(사문진교 인근)와 팔당호 등을 대상으로 수행하였다. 분석 결과, 낙동강 ·금호강 ·진천천 합류부에서는 유량비를 좀 더 정확하게 파악할 수 있었고 수질항목들의 공간적 변화를 3차원적으로 정량화하는 데에 효과적이었다. 팔당호에서는 클로로필-a 및 영양염 농도를 3차원적으로 파악함으로써 녹조의 조기탐지, 발생 양상 및 변화를 예측하는 데 기초자료로 활용 가능함을 확인하였다. 또한, 각 수질항목과 유량 데이터 간의 상관·회귀분석을 통해 영향요인을 규명하고 회귀식을 제시하는 데에 활용 가능하였다. 본 시스템은 3차원 관측데이터를 통합 관리하고 수질·유량 상호작용을 정량적으로 분석할 수 있는 기반을 제공하며, 향후 지능형 대응체계로의 전환에 기여할 것으로 기대된다.

키워드
수질
유량
통합관리
데이터 시스템
3차원 데이터
References
1

Choi, H.J., Cho, Y.-C., Yu, S., Song, Y.S., and Ryu, I. (2019). “Analysis of water circulation characteristics for hydraulic and water temperature investigation in Paldang reservoir.” Ecology and Resilient Infrastructure, Vol. 6, No. 1, pp. 12-22.

10.17820/ERI.2019.6.1.012
2

Goblirsch, T., Mayer, T., Penzel, S., Rudolph, M., and Borsdorf, H. (2023). “In situ water quality monitoring using an optical multiparameter sensor probe.” Sensors, Vol. 23, No. 23, 9545. doi: 10.3390/s23239545.

10.3390/s2323954538067918PMC10708653
3

Horsburgh, J.S., Aufdenkampe, A.K., Mayorga, E., Lehnert, K.A., Hsu, L., Song, L., Jones, A.S., Damiano, S.G., Tarboton, D.G., Valentine, D., Zaslavsky, I., and Whitenack, T. (2016). “Observations data model 2: A community information model for spatially discrete Earth observations.” Environmental Modelling & Software, Vol. 79, pp. 55-74.

10.1016/j.envsoft.2016.01.010
4

Jackson, S.R., and Maidment, D.R. (2014). RiverML: A harmonized transfer language for river hydraulic models. Center for Research in Water Resources, The University of Texas at Austin, accessed 25 November 2025, <https://external.ogc.org/twiki_public/pub/HydrologyDWG/NewYorkWorkshop2014/RiverML_Harmonization_August_2014.pdf?utm_source=chatgpt.com>.

5

Jiang, J., Tang, S., Han, D., Fu, G., Solomatine, D., and Zheng, Y. (2020). “A comprehensive review on the design and optimization of surface water quality monitoring networks.” Environmental Modelling & Software, Vol. 132, 104792. doi: 10.1016/j.envsoft.2020.104792.

10.1016/j.envsoft.2020.104792
6

Kim, S., and Kim, S.M. (2017). “Spatial water quality analysis of main stream of Nakdong River considering the inflow of tributaries.” Journal of Korean Society on Water Environment, Vol. 33, No. 6. pp. 640-649.

7

Kwon, D.Y., Kim, J., Park, S., and Hong, S. (2023). “Advancements of remote data acquisition and processing in unmanned vehicle technologies for water quality monitoring: An extensive review. Chemosphere, Vol. 343, 140198. doi: 10.1016/j.chemosphere.2023.140198.

10.1016/j.chemosphere.2023.140198
8

Parsons, D.R., Jackson, P.R., Czuba, J.A., Engel, F.L., Rhoads,,B.L., Oberg, K.A., Best, J.L., Mueller, D.S., Johnson, K.K., and Riley, J.D. (2013). “Velocity Mapping Toolbox (VMT): A processing and visualization suite for movingvessel ADCP measurements.” Earth Surface Processes and Landforms, Vol. 38, No. 11, pp. 1244-1260.

10.1002/esp.3367
9

Romić, D., Castrignanò, A., Romić, M., Buttafuoco, G., Kovačić, M.B., Ondrašek, G., and Zovko M., (2020), “Modelling spatial and temporal variability of water quality from different monitoring stations using mixed effects model theory.” Science of The Total Environment, Vol. 704, 135875. doi: 10.1016/j.scitotenv.2019.135875.

10.1016/j.scitotenv.2019.135875
10

Taylor, P. (ed.) (2014). OGC® WaterML 2.0: Part 1- Timeseries, Version 2.0.1. OGC 10-126r4, Open Geospatial Consortium, Wayland, MA, U.S., p. 151. doi: 10.25607/OBP-611.

10.25607/OBP-611
11

Taylor, P. (ed.) (2016). OGC® WaterML2.0: Part 2 - Ratings, gaugings and sections, Version 1.0. OGC 15-018r2, Open Geospatial Consortium, Wayland, MA, U.S., p. 69. doi: 10.25607/OBP-596.

10.25607/OBP-596
12

Taylor, P., Cox, S., Walker, G., Valentine, D., and Sheahan, P. (2013). “WaterML 2.0: Development of an open standard for hydrological time series data exchange.” Journal of Hydroinformatics, Vol. 16, No. 2, pp. 425-446. doi: 10.2166/hydro.2013.174.

10.2166/hydro.2013.174
13

United States Geological Survey (USGS) (2021). Next Generation Water Observing System (NGWOS), accessed 25 November 2025, <https://www.usgs.gov/mission-areas/water-resources/science/next-generation-water-observing-system-ngwos#overview>.

Information
  • Publisher :KOREA WATER RESOURECES ASSOCIATION
  • Publisher(Ko) :한국수자원학회
  • Journal Title :Journal of Korea Water Resources Association
  • Journal Title(Ko) :한국수자원학회 논문집
  • Volume : 58
  • No :12
  • Pages :1563-1574
  • Received Date : 2025-10-17
  • Revised Date : 2025-11-25
  • Accepted Date : 2025-11-25
  • DOI :https://doi.org/10.3741/JKWRA.2025.58.S-3.1563
Journal Informaiton Journal of Korea Water Resources Association Journal of Korea Water Resources Association
Online Submission
Archives
  • scopus
  • KCI-수자원
  • NRF
  • KOFST
  • KISTI Current Status
  • KISTI Cited-by
  • crosscheck
  • orcid
  • open access
  • ccl
Journal Informaiton Journal Informaiton - close