This study establishes an optimal arrangement model for urban areas based on Low Impact Development (LID) with consideration of Benefit-Cost Analysis. This model was developed first by defining and formulating the objective function, the constraints, and decision variables. Benefit/Cost ratio was set to be the objective function. The constraints included limitation of each subcatchment area, distribution limitation of LID devices in each area, and the chosen mode of simulation. The decision variables correspond to the allocated areas and amounts of LID devices, which include porous pavements, bioretention cells, infiltration trenches, rain barrels, vegetable swales, green roofs, and tree boxes. Under the allocation, the flooding loss was simulated by Storm Water Management Model (SWMM) in different return periods and resolved with the help of Simulated Annealing (SA). The annual benefit, annual cost, and Benefit/Cost ratio (B/C ratio) were also calculated. When the B/C ration is maximized, the allocation then is the optimal arrangement of LID devices applied to an urban area. Min-Sheng Community in Taipei is exemplified for demonstration of applicability of the optimal model. On the one hand, the efficiency resulted by showing that annual flooding loss decreases from 288 million NTD to 278 million NTD after the optimization. The B/C ratio is calculated as 1.448 with annual benefit is 9.84 million NTD, and the annual cost is 6.79 million NTD. In condition of rainfalls in each return periods, the peak flows and the average delay of peak flows of Fu-Yuan Pumping Station and the subcatchments decreased significantly. Furthermore, the efficiency of low return periods is superior in contrast with which of high return periods. On the other hand, the arrangement of LIDs in urban area takes green roofs and bioretention cells as main devices, which was supplemented with rain barrels and porous pavements. These devices are 80%of the total annual cost. Since infiltration trenches, vegetable swales and tree boxes are used mainly to transport water, the performance of flood reduction is not efficient, these devices are not commended to be considered in flooding decreasing for urban areas. Moreover, arrangement area of LID devices, which accounts for about 18% total area, was considered with the land use of urban areas and the ratio of pending areas: equipping residential district with green roofs and rain barrels, setting up porous pavements, bioretention cells in road districts, and distributing green lands with bioretention units, respectively.