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9. SPATIALLY DISTRIBUTED

9. SPATIALLY DISTRIBUTED . HYDROLOGIC MODELS. Single Cell in Landscape. Evapo - transpiration. Precipitation. Atmosphere. Land Surface. Overland flow. Sub-surface. Sub-surface flow. Single Cell in Landscape. But Outflow in Which Direction?. Evapo - transpiration. Precipitation.

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9. SPATIALLY DISTRIBUTED

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  1. 9. SPATIALLY DISTRIBUTED HYDROLOGIC MODELS

  2. Single Cell in Landscape Evapo- transpiration Precipitation Atmosphere Land Surface Overland flow Sub-surface Sub-surface flow

  3. Single Cell in Landscape But Outflow in Which Direction? Evapo- transpiration Precipitation Atmosphere Land Surface Overland flow Sub-surface Sub-surface flow

  4. Flow Direction Conventions

  5. Flow Direction from DEM TIRIBIELEV all elevations in meters Which way out of cell H9?

  6. Flow Direction from DEM TIRIBIELEV all elevations in meters Which way out of cell H9?

  7. Flow Direction from DEM TIRIBIELEV all elevations in meters Which way out of cell I9?

  8. Flow Direction from DEM TIRIBIELEV all elevations in meters Which way out of cell I9?

  9. Flow Direction from DEM TIRIBIELEV all elevations in meters Which way out of cell I10?

  10. Flow Direction from DEM TIRIBIELEV all elevations in meters Which way out of cell I10?

  11. Constructing Flow Network

  12. Constructing Flow Network

  13. Constructing Flow Network

  14. Constructing Flow Network

  15. Constructing Flow Network

  16. Constructing Flow Network

  17. Constructing Flow Network

  18. Constructing Flow Network

  19. Constructing Flow Network

  20. Constructing Flow Network

  21. Constructing Flow Network

  22. Constructing Flow Network

  23. Complete Flow Network

  24. Computation of Travel Time How Fast? ~ Manning V = f(D, S, n) Slope: From DEM Manning’s n: From channel characteristics Depth: Field estimates Travel time? ~ Distance/V Distance: From flow net to river outlet (Electriona) Each cell can be assigned a travel time for water to reach the outlet.

  25. ISOCHRONES: Surface and subsurface flow characteristics.

  26. Scenario 1: Rainfall falling uniformly spatially (but not temporally)

  27. 1 inch per Hour

  28. 2 inches per Hour

  29. 0.5 inches per Hour

  30. 0.5 “ in first hour Contribution to flood hydrograph

  31. 2” in second hour Combined contributions to flood hydrograph.

  32. 1 “ in third hour Combined contributions to flood hydrograph.

  33. Overall flood hydrograph

  34. Scenario 2: Rainfall falling variably over space, but uniformly over time) 1 2 3 Precipitation not only varies temporally, but also spatially. Can use simple technique like Thiessen polygons to alter inputs to various parts of basin.

  35. Each polygonal area corresponds to a differing set of travel times or isochrones. Rain falling at same time in yellow area will reach outlet later than that in orange area. Rain falling in green area will all arrive at outlet within a 7 hour period, while the rain falling on the orange area will be distributed over a 19 hour period.

  36. Time of Arrival of Cell/Polygon Contributions at Electriona.

  37. SPATIAL VARIABILITY OF INPUTS • Assume that a storm occupies the entire Tiribí basin, but that the quantity of rain it delivers increases towards the headwaters. • As the air is forced to rise it produces greater precipitation at higher elevations. • The low lying orange area receives Excess precipitation of 0.5”.

  38. Response of low lying area to excess precipitation of 0.5 “ in the first hour. Time distributed contribution of lowland areas’ excess precipitation at Electriona.

  39. Response at Electriona to higher areas of the Jorco and Cañas receiving excess precipitation of 1.0” falling during the hour of the storm. Combined effects at Electriona of both the lower (faster, temporally dispersed response, but less excess precipitation), and upper (slower, less dispersed response, to large excess precipitation) parts of the basin.

  40. Response at Electriona to highest areas of the Chiquito and Tres Ríos receiving excess precipitation of 2.0 mm falling during the hour of the storm, but requiring longer travel times to reach the outlet. Combined effects at Electriona of spatially varying excess precipitation inputs falling on cells with varying travel times to outlet. Basically becoming “wetter” as one proceeds away from the outlet.

  41. Now Assume that Low Areas Receive Most Rain from the Storm and Upper Areas the Least

  42. Arbitrarily set a discharge of 4 as a critical flood level • Flood Starts later. Storm Max in Highlands • Flood Starts earlier. Storm Max in Lowlands

  43. Arbitrarily set a discharge of 4 as a critical flood level • Flood Starts later. • Peaks at same time. Storm Max in Highlands • Flood Starts earlier. • Peaks at same time. Storm Max in Lowlands

  44. Arbitrarily set a discharge of 4 as a critical flood level • Flood Starts later. • Peaks at same time. • Lower peak above threshold. Storm Max in Highlands • Flood Starts earlier. • Peaks at same time. • Higher peak above threshold. Storm Max in Lowlands

  45. Arbitrarily set a discharge of 4 as a critical flood level • Flood Starts later. • Peaks at same time. • Lower peak above threshold. • Fewer hours of inundation. Storm Max in Highlands • Flood Starts earlier. • Peaks at same time. • Higher peak above threshold. • More hours of inundation. Storm Max in Lowlands

  46. Scenario 4: Rainfall falling variably over both time and space. 6. 5. 4. 3. 1. 2.

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