Smart City Gnosys
Smart city article details
| Title | Developing Dpsir Framework For Managing Climate Change In Urban Areas: A Case Study In Jakarta, Indonesia |
|---|---|
| ID_Doc | 19451 |
| Authors | Kristiadi Y.; Sari R.F.; Herdiansyah H.; Hasibuan H.S.; Lim T.H. |
| Year | 2022 |
| Published | Sustainability (Switzerland), 14, 23 |
| DOI | http://dx.doi.org/10.3390/su142315773 |
| Abstract | From an environmentally conscious and ecological perspective, the sustainability of cities within the effects of climate change are closely related to the wise use of resources and modifications in the ecological status of the environment. In terms of the ecological environment, the sustainability of smart cities entails meeting present and future societal demands for the environment of the water, land, and air, among others. Environmental and the ecological concerns that arise from rapid climate change and monetary developments are shown in the inconsistency between ecological assets, environmental pollution, and the destruction of nature. In this study, the authors aim to develop a strategy to deal with climate change in urban areas using Remote Sensing and the Driver-Pressure-State-Impact-Response (DPSIR) Framework with a case study in Jakarta Smart City. The DPSIR framework, which will be developed and implemented in the city of Jakarta, is a smarter and more sustainable framework that is evaluated through a systematic evaluation of sustainability with quantitative research using the entropy weight method and Partial Least Square-Structural Equation Modeling (PLS-SEM). These methods evaluate 58 representative elements of environments at the urban level, including the shortcomings of earlier research such as data availability, spatial and temporal constraints, and several related ecological indicators, such as soil pH, wind speed, air quality index as well as land changes in the spatial (spatiotemporal) time series. The results of the study show that in the metropolitan city of Jakarta, the Drivers that are related to climate change are the rate of population growth and the rate of industrial growth which, although increases people’s income and GRDP in Jakarta; it also creates Pressures, namely an increase in the amount of water consumption and in the amount of wastewater. Based on these pressures, the environmental conditions (State) of Jakarta city have undergone several environmental changes, such as loss of water supply, changes in wind speed, changes in rainfall, and increasing concentrations of the Air Pollutant Standard Index. The Impact of these three elements resulted in the increase in household and industrial water consumption, an increase in annual electricity consumption, and deteriorating air quality. Hence, the Response to these four interrelated causal variables is that the Jakarta Provincial Government must increase annual funds for the construction of urban community facilities, increase the production capacity of clean water supply, build environment-friendly wastewater treatment facilities, increase the capacity of waste processing infrastructure and transportation fleets, and educate people to use water wisely to reduce the level of water use. © 2022 by the authors. |
| Author Keywords | DPSIR; entropy; framework strategy managing climate change; PLS-SEM; smart city |
Similar Articles
| Id | Similarity | Authors | Title | Published |
|---|---|---|---|---|
17481  | 0.868 | Bibri S.E. | Data-Driven Smart Eco-Cities Of The Future: An Empirically Informed Integrated Model For Strategic Sustainable Urban Development | World Futures, 79, 7-8 (2023) |
| 24070 | 0.864 | Fuady M.; Buraida; Kevin M.A.; Farrel M.R.; Triaputri A. | Enhancing Urban Resilience: Opportunities And Challenges In Adapting To Natural Disasters In Indonesian Cities | Sustainability (Switzerland), 17, 4 (2025) |
| 50787 | 0.864 | Morrison M.; Srinivasan R.S.; Dobbs C. | Smart Ecology Of Cities: Integrating Development Impacts On Ecosystem Services For Land Parcels | Smart Cities: Foundations, Principles, and Applications (2017) |
| 28456 | 0.861 | Hui C.X.; Dan G.; Alamri S.; Toghraie D. | Greening Smart Cities: An Investigation Of The Integration Of Urban Natural Resources And Smart City Technologies For Promoting Environmental Sustainability | Sustainable Cities and Society, 99 (2023) |
| 56017 | 0.86 | Ashgaf I.M.; Utomo D.A.B.; Kusdiwanggo S. | The Linkage Between Economic Growth And Ecology Of Urban Area Development In Indonesia: A Systematic Review | IOP Conference Series: Earth and Environmental Science, 1324, 1 (2024) |
| 12900 | 0.859 | Neves F.R.; de Aquino A.C.B. | Bringing The Green Into The Screen: Remote Sensing And Smart Green Governance In Urban Forest Management | Internet of Things, Part F4006 (2025) |
| 2374 | 0.857 | Ateş M.; Erinsel Önder D. | A Local Smart City Approach In The Context Of Smart Environment And Urban Resilience | International Journal of Disaster Resilience in the Built Environment, 14, 3 (2023) |
| 55139 | 0.856 | Addas A. | The Concept Of Smart Cities: A Sustainability Aspect For Future Urban Development Based On Different Cities | Frontiers in Environmental Science, 11 (2023) |
| 61702 | 0.856 | Obringer, R; Nateghi, R | What Makes A City 'Smart' In The Anthropocene? A Critical Review Of Smart Cities Under Climate Change | SUSTAINABLE CITIES AND SOCIETY, 75 (2021) |
| 21651 | 0.855 | Halder S.; Bose S. | Ecological Quality Assessment Of Five Smart Cities In India: A Remote Sensing Index-Based Analysis | International Journal of Environmental Science and Technology, 21, 4 (2024) |