Multivariate Water Stress Index Model for Predicting Water Vulnerability

Agustinus Haryanto Pattiraja; Srisanti LMF  Seran; Hamdan   Nurdin; Sulistiowati  Sulistiowati; Stefanus G Engky  Seran; Fransiska Adinda B  Tokan

doi:10.37899/journallamultiapp.v7i2.3072

Agustinus Haryanto Pattiraja Universitas Katolik Widya Mandira, Kota Kupang, Indonesia
Srisanti LMF Seran Universitas Katolik Widya Mandira, Kota Kupang, Indonesia
Hamdan Nurdin Author’s Institution BMKG NTT, Kota Kupang, Indonesia
Sulistiowati Author’s Institution Universitas Dinamika, Surabaya, Indonesia
Stefanus G Engky Seran Universitas Katolik Widya Mandira, Kota Kupang, Indonesia
Fransiska Adinda B Tokan Universitas Katolik Widya Mandira, Kota Kupang, Indonesia

DOI: https://doi.org/10.37899/journallamultiapp.v7i2.3072

Keywords: Water Stress Index, Multivariate Model, Water Availability

Abstract

Sabu Raijua Regency is a semi-arid island region with limited water resources and increasing water demand pressure, thus potentially experiencing high water vulnerability. This study aims to develop a multivariate Water Stress Index (WSI) model to analyze the dominant factors causing water stress and predict the level of water vulnerability in the medium to long term on Sabu Island. The study uses a predictive quantitative approach by combining multivariate regression analysis and spatial analysis based on Geographic Information Systems (GIS). The WSI value for the base year 2023 and the projection for 2033 were calculated using the Water to Availability (WTA) method which has been validated through the reliable discharge from the FJ Mock simulation results and field data. Eight independent variables were analyzed, including population density, water demand, dry spell and wet spell conditions, water availability, and clean water service coverage. The analysis results show that water demand (X3) is the most dominant factor in increasing the WSI value, while water availability (X7) plays a significant role in reducing water stress. Seasonal climate variables and clean water service coverage show relatively weak statistical effects. Spatial analysis identified West Sabu District as the area with the highest and persistent water stress, while Central Sabu and Sabu Liae Districts were at medium vulnerability levels, and Hawu Mehara and East Sabu were relatively lower.

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