Abstract
In this study, we link a water resource management simulator to multi-objective search to reveal the key trade-offs inherent in planning a real-world water resource system. We consider new supplies and demand management (conservation) options while seeking to elucidate the trade-offs between the best portfolios of schemes to satisfy projected water demands. Alternative system designs are evaluated using performance measures that minimize capital and operating costs and energy use while maximizing resilience, engineering and environmental metrics, subject to supply reliability constraints. Our analysis shows many-objective evolutionary optimization coupled with state-of-the art visual analytics can help planners discover more diverse water supply system designs and better understand their inherent trade-offs. The approach is used to explore future water supply options for the Thames water resource system (including London’s water supply). New supply options include a new reservoir, water transfers, artificial recharge, wastewater reuse and brackish groundwater desalination. Demand management options include leakage reduction, compulsory metering and seasonal tariffs. The Thames system’s Pareto approximate portfolios cluster into distinct groups of water supply options; for example implementing a pipe refurbishment program leads to higher capital costs but greater reliability. This study highlights that traditional least-cost reliability constrained design of water supply systems masks asset combinations whose benefits only become apparent when more planning objectives are considered.
Highlights
Population and economic growth drive increased water demand (Vorosmarty et al, 2000) while climate change may further increase stress on the water supplies in some regions (Milly et al, 2008)
The upper left side and lower center of the figure is characterized by a steep cost to reliability gradient
Even if all system goals can and have been translated to one commensurate unit system, planners would lack the ability to understand the trade-offs embodied by different system designs
Summary
Population and economic growth drive increased water demand (Vorosmarty et al, 2000) while climate change may further increase stress on the water supplies in some regions (Milly et al, 2008). Water supply capacity expansions are being considered in many areas, especially in fast growing cities (McDonald et al, 2011). In such cases, water resource system planners are faced with choosing the most appropriate mix of proposed new supply and demand management options for their system. The term ‘‘many-objective” refers to optimizing systems with 4 or more design objectives as introduced by Fleming et al (2005) Both supply and demand management options are considered to meet demands forecasted to 2035. The trade-offs generated by the many objective optimization reveal that ecological, engineered and economic performance can be improved with relatively modest investments.
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