References

  1. United States Environmental Protection Agency (US EPA), Guidance Specifying Management Measurements for Sources of Non Point Pollution in Coastal Waters, Office of Water, U.S. Environmental Protection Agency, Washington, D.C., 1997.
  2. Federal Highway Administration, Sources and Mitigation of Highway Runoff Pollutants, Federal Highway Administration, Washington, D.C., 1984.
  3. C. Hinman, Low Impact Development Technical Guidance Manual for Puget Sound, January, 2005, 256 p.
  4. M. Simpson, Low Impact Development Modeling to Manage Urban Storm Water Runoff and Restore Predevelopment Site Hydrology, MS Thesis, Colorado State University, Fort Collins, Colorado, 2010.
  5. C. Saraswat, P. Kumar, B.K. Mishra, Assessment of stormwater runoff management practices and governance under climate change and urbanization: an analysis of Bangkok, Hanoi and Tokyo, Environ. Sci. Policy, 64 (2016) 101–117.
  6. Prince George County MD Department of Environmental Resources Programs and Planning Division, Low-impact Development Design Strategies: An Integrated Design Approach, June, 1999, 150 p.
  7. The Interstate Technology Regulatory Council Wetlands Team (ITRC), Technical and Regulatory Guidance Document for Constructed Treatment Wetlands, USA, 2003.
  8. J.S. Tobio, Application of Stormwater Management Model for Optimization of Low Impact Development Techniques in Urban Areas, Master’s Thesis, Kongju National University, Cheonan City, South Korea, 2014.
  9. K.E.D. Madarang, Optimal Approaches for Predicting and Managing Urban Stormwater: Monitoring Strategy, Model Accuracy and Configuration of Stormwater Treatment System, Master’s Thesis, Dongguk University, Seoul, South Korea, 2013.
  10. L.A. Rossman, Modeling Low Impact Development Alternatives with SWMM, W. James, Ed., Dynamic Modeling of Urban Water Systems, Monograph 18, CHI, Guelph, Ontario, 2009, pp. 19–20.
  11. D.J. Rosa, J.C. Clausen, M.E. Dietz, Calibration and verification of SWMM for low impact development, J. Am. Water Resour. Assoc., 51 (2015) 746–757.
  12. A.R.A. Usman, S.S. Lee, Y.M. Awad, K.J. Lim, J.E. Yang, Y.S. Ok, Soil pollution assessment and identification of hyperaccumulating plants in chromated copper arsenate (CCA) contaminated sites, Korea, Chemosphere, 87 (2012) 872–878.
  13. M.K. Stenstrom, M. Kayhanian, First Flush Phenomenon Characterization, Research report for Department of California Transportation, August, 2005.
  14. L.H. Kim, S.O. Ko, S.M. Jeong, J.Y. Yoon, Characteristics of washed-off pollutants and dynamic EMCs in parking lots and bridges during a storm, Sci. Total Environ., 376 (2007) 178–184.
  15. M.C. Maniquiz, S.Y. Lee, L.H. Kim, Long-term monitoring of infiltration trench for nonpoint source pollution control, Water Air Soil Pollut., 212 (2010) 13–26.
  16. Z. Dongquan, C. Jining, W. Haozheng, T. Qingyuan, C. Shangbing, S. Zheng, GIS-based urban rainfall-runoff modeling using an automatic catchment-discretization approach: a case study in Macau, Environ. Earth Sci., 59 (2009) 465.
  17. J. Temperano, O. Aranago, J. Cagiao, J. Suarez, I. Tejero, Stormwater quality calibration by SWMM: a case study in Northern Spain, Water SA, 32 (2006) 55–63.
  18. M.C. Maniquiz, Low Impact Development (LID) Technology for Urban Stormwater Runoff Treatment – Monitoring, Performance, and Design, Ph.D. Dissertation, Kongju National University, Cheonan City, South Korea, 2012.
  19. J.J. Sansalone, S.G. Buchberger, Characterization of solid and metal elements distributions in urban highway stormwater, Water Sci. Technol., 36 (1997) 155–160.
  20. J.C. Alihan, M.C. Maniquiz-Redillas, J.Y. Choi, P.E. Flores, L.H. Kim, Characteristics and fate of stormwater runoff pollutants in constructed wetlands, J. Wetlands Res., 19 (2017) 37–44.