TY - GEN
T1 - System dynamics modeling of the conjunctive-use of surface and subsurface water
AU - Ho, Chih Chao
AU - Yang, Chao Chung
AU - Chang, Liang-Jeng
AU - Yeh, Ming Sheng
PY - 2007/12/1
Y1 - 2007/12/1
N2 - The conjunctive use of surface and subsurface water is used commonly for offering stable supplies in water resources management. Conventionally, the process of supply distribution model development can be classified as simulation method, describing system behaviors and operating rules directly, and optimization method, describing system behaviors by constraint equation and imitating operating rules by objective function. Owing to the allocation is spatial dependency and operating rules is temporal dependency, many researches prefer to construct conjunctive use models by "optimization method" then by "simulation method". However, subject to the selected optimal methodology, such as linear programming or dynamic programming, modelers need to hypothesize or simplify the system. Hence, this study provides a powerful object oriented simulation modeling, system dynamics, alternative to optimization method for representing complex systems and analyzing their dynamics behavior. In system dynamics, the relation between structure and behavior is based on the concept of stock-flow diagrams. The process of model development, combining program flowchart with spatial system configuration, provokes modeler can build model easily. In this study, we also consider system expansion such as increasing new supply sources, and capacity expansion such as water treatment plant. We attempt to demonstrate this approach is a suitable methodology for constructing the complex water resources modeling.
AB - The conjunctive use of surface and subsurface water is used commonly for offering stable supplies in water resources management. Conventionally, the process of supply distribution model development can be classified as simulation method, describing system behaviors and operating rules directly, and optimization method, describing system behaviors by constraint equation and imitating operating rules by objective function. Owing to the allocation is spatial dependency and operating rules is temporal dependency, many researches prefer to construct conjunctive use models by "optimization method" then by "simulation method". However, subject to the selected optimal methodology, such as linear programming or dynamic programming, modelers need to hypothesize or simplify the system. Hence, this study provides a powerful object oriented simulation modeling, system dynamics, alternative to optimization method for representing complex systems and analyzing their dynamics behavior. In system dynamics, the relation between structure and behavior is based on the concept of stock-flow diagrams. The process of model development, combining program flowchart with spatial system configuration, provokes modeler can build model easily. In this study, we also consider system expansion such as increasing new supply sources, and capacity expansion such as water treatment plant. We attempt to demonstrate this approach is a suitable methodology for constructing the complex water resources modeling.
KW - Capacity expansion
KW - Operating rule
KW - Supply distribution
KW - System dynamics
KW - System expansion
UR - http://www.scopus.com/inward/record.url?scp=80051657193&partnerID=8YFLogxK
U2 - 10.1061/40927(243)256
DO - 10.1061/40927(243)256
M3 - Conference contribution
SN - 9780784409275
T3 - Restoring Our Natural Habitat - Proceedings of the 2007 World Environmental and Water Resources Congress
BT - Restoring Our Natural Habitat - Proceedings of the 2007 World Environmental and Water Resources Congress
T2 - 2007 World Environmental and Water Resources Congress: Restoring Our Natural Habitat
Y2 - 15 May 2007 through 19 May 2007
ER -