Presentation is loading. Please wait.

Presentation is loading. Please wait.

WinTR-20 SensitivityFebruary 20151 WinTR-20 Sensitivity to Input Parameters.

Published byBlake Hutchinson Modified over 8 years ago

Similar presentations

Presentation on theme: "WinTR-20 SensitivityFebruary 20151 WinTR-20 Sensitivity to Input Parameters."— Presentation transcript:

1 WinTR-20 SensitivityFebruary 20151 WinTR-20 Sensitivity to Input Parameters

2 WinTR-20 SensitivityFebruary 20152 Lesson Objectives 1. Identify the various WinTR-20 Input Parameters that affect the volume of runoff and peak discharge predictions. 2. Identify the relative sensitivity of WinTR-20 to its input parameters in predicting the peak and/or volume of runoff. 3. Identify the relative sensitivity of WinTR- 20 to its input parameters in relation to channel routing.

3 WinTR-20 SensitivityFebruary 20153 WinTR-20 Hydrology Model Predicts Volume of Runoff Predicts Peak Rate of Runoff Predicts Entire Hydrograph of Runoff Based on Watershed and Rainfall Characteristics Modeled as Input Parameters Changes to Input Parameters Will Change the Volume and Rate of Runoff Predicted

4 WinTR-20 SensitivityFebruary 20154 WinTR-20 Watershed Input Variables Drainage Area Runoff Curve Number (RCN) Time of Concentration (t c ) Peak Rate Factor (PRF) of Dimensionless Unit Hydrograph (DUH) Antecedent Runoff Condition (ARC)

5 WinTR-20 SensitivityFebruary 20155 WinTR-20 Rainfall Input Variables Depth of Rainfall Rainfall Distribution (includes duration)

6 WinTR-20 SensitivityFebruary 20156 Effects of Variation in Drainage Area % Change in DA results in comparable change to predicted volume and peak of runoff. Be sure DA is being properly identified (be aware of non-contributing areas).

7 WinTR-20 SensitivityFebruary 20157 Effects of Variation in RCN % Change in RCN results in exaggerated change to predicted volume and peak of runoff. RCN can be influenced by stage of vegetal growth and/or antecedent rainfall at time of storm event.

8 WinTR-20 SensitivityFebruary 20158 Effects of Variation in t c % Change in t c results in decreased change to predicted peak rate of runoff (no change in volume). A decrease in t c results in an increase in predicted peak discharge.

9 WinTR-20 SensitivityFebruary 20159 Effects of Variation in Peak Rate Factor % Change in PRF results in nearly similar change to predicted peak rate of runoff (no change in volume). PRF is a watershed based response to excess rainfall assumed to be similar per inch of runoff. Sensitivity to PRF % of PRF Compared to 484

10 WinTR-20 SensitivityFebruary 201510 Effects of Variation in Antecedent Runoff Condition (ARC) ARC values of 1 or 3 alter the RCN selected for assumed ARC 2 conditions. ARC 2 is normally assumed for design. ARC 1 can be used to help calibrate for a known “drought” condition prior to the target storm event (not necessarily accurate). ARC 3 can be used to help calibrate for a known “saturated soil” condition prior to the target storm event (not necessarily accurate).

11 WinTR-20 SensitivityFebruary 201511 ARC Adjustments (Continued) For this example: DA = 1.0 mi 2, t c = 1 hr, RCN = 70, 4.0 inch 24 hr Type II Rainfall ARC 2 – (RCN 70), Q v = 1.33”, Q p = 437 cfs ARC 1 – (RCN 51), Q v = 0.37”, Q p = 65 cfs ARC 3 – (RCN 85), Q v = 2.46”, Q p = 874 cfs WinTR-20 results are very sensitive to changes in ARC. Be sure that assumed change is appropriate or alter RCN within ARC 2 conditions for finer adjustment.

12 WinTR-20 SensitivityFebruary 201512 Effects of Variation in Rainfall Depth % Change in Rainfall Depth results in exaggerated change to predicted volume and peak of runoff. Be sure that the actual Rainfall that has occurred and is being calibrated to is properly identified for the entire watershed.

13 WinTR-20 SensitivityFebruary 201513 Effects of Variation in Rainfall Distribution Design rainfall distributions normally set by location. Can attempt to calibrate to a historical rainfall event of known varying intensity (recording rain gage). Rainfall distribution alone (not depth) only effects the rate of runoff, not the volume.

14 WinTR-20 SensitivityFebruary 201514 Effects of Variation in Rainfall Distribution (Continued) For this example: DA = 1.0 mi 2, t c = 1 hr, RCN = 70, 4.0 inch 24 hr Rainfall Type II - Q p = 437 cfs Type I - Q p = 221 cfs Type IA - Q p = 106 cfs Type III - Q p = 383 cfs WinTR-20 peaks are very sensitive to selection of rainfall distribution. Calibrate with the best known rainfall distribution.

15 WinTR-20 SensitivityFebruary 201515 Effects of Variation in Rainfall Distribution (Continued) For this example: DA = 1.0 mi 2, t c = 1 hr, RCN = 70, 4.0 inch 24 hr Rainfall Type NOAA A - Q p = 479 cfs Type NOAA B - Q p = 432 cfs Type NOAA C - Q p = 391 cfs Type NOAA D - Q p = 353 cfs These rainfall distributions are used in 12 states and the District of Columbia covered in NOAA Atlas 14 Vol. 2.

16 WinTR-20 SensitivityFebruary 201516 Parameter Selection for Desired Change in WinTR-20 Runoff Volume WinTR-20 Parameter to be Changed, Independent of Others Desired Change in Runoff Volume (%) -50%-25%-10%-5%+5%+10%+25%+50% Required Change in Drainage Area -50%-25%-10%-5%+5%+10%+25%+50% Required Change in Rainfall -26%-13%-5%-2.5%+2.5%+5%+12.5%+23% Required Change in RCN -17%-8%-2%-1%+1%+2%+7%+13% Required Change in Time of Concentration N/C Required Change in PRF N/C N/C signifies, No Change possible to alter volume. This parameter does not effect volume prediction.

17 WinTR-20 SensitivityFebruary 201517 Parameter Selection for Desired Change in WinTR-20 Peak Runoff WinTR-20 Parameter to be Changed, Independent of Others Desired Change in Runoff Peak (%) -50%-25%-10%-5%+5%+10%+25%+50% Required Change in Drainage Area -50%-25%-10%-5%+5%+10%+25%+50% Required Change in Rainfall -24%-12%-5%-2.50%+2.5%+5%+11%+21% Required Change in RCN -13.5%-6%-2%-1%+1%+2%+5.5%+11% Required Change in Time of Concentration +150%+50%+15%+7%-6%-12%-26.5%-44% Required Change in PRF -54%-29%-12%-6%+6%+13%+33%+72%

18 WinTR-20 SensitivityFebruary 201518 Combined Parameter Impacts Assumed Normal Run DA = 1 mi 2, RCN =70, t c = 1.0 hr, PRF = 484 Runoff Volume = 1.33”, Peak Rate = 437 cfs Low Run DA = 1 mi 2, RCN =63, t c = 1.25 hr, PRF = 300 Runoff Volume = 0.92”, Peak Rate = 148 cfs High Run DA = 1 mi 2, RCN =77, t c = 0.75 hr, PRF = 600 Runoff Volume = 1.81”, Peak Rate = 904 cfs

19 WinTR-20 SensitivityFebruary 201519 WinTR-20 Channel Routing Model Predicts hydrograph (including peak) at downstream end of reach. Based on cross section and reach characteristics modeled as input parameters. Changes to input parameters will change the peak discharge and hydrograph shape predicted at the end of the reach.

20 WinTR-20 SensitivityFebruary 201520 WinTR-20 Channel and Reach Input Variables Selection of representative cross section Cross section rating table (slope and “n”) Channel length Floodplain length Shape of inflow hydrograph Base flow (if significant)

21 WinTR-20 SensitivityFebruary 201521 WinTR-20 Channel Routing Sensitivity Test Trapezoidal cross section, BW = 15, SS = 2:1 Slope = 0.001 and 0.004 Manning n = 0.03, 0.04, 0.05 Channel length, 0.8 to 1.2 mile Inflow hydrograph, DA = 1, CN = 80, Tc = 0.5 and 1.0, RF = 3.2 inches, Type II storm Base flow = 0.0 60 WinTR-20 runs

22 WinTR-20 SensitivityFebruary 201522 Two Inflow hydrographs Red (higher) is the hydrograph for Tc = 0.5 hour. Green (lower) is the hydrograph for Tc = 1.0 hour.

23 WinTR-20 SensitivityFebruary 201523 Effects of Variation in Length and “n” % Change in length results in less change to predicted peak outflow. % Change in Manning “n” results in less change to predicted peak outflow.

24 WinTR-20 SensitivityFebruary 201524 Effects of Variation in Length and “n” % Change in length and “n” results in less change to predicted peak outflow. Length and “n” less sensitive for Tc = 1.0 hydrograph.

25 WinTR-20 SensitivityFebruary 201525 Effects of Variation in Length and “n” % Change in length and “n” results in less change to predicted peak outflow. Results for steep slope are less sensitive.

26 WinTR-20 SensitivityFebruary 201526 Effects of Variation in Length and “n” % Change in length and “n” results in less change to predicted peak outflow. Results for Tc = 1.0 hydrograph are even less.

27 WinTR-20 SensitivityFebruary 201527 Porcupine Mountains State Park, Michigan

28 WinTR-20 SensitivityFebruary 201528 Questions???

29 WinTR-20 SensitivityFebruary 201529 The End

Download ppt "WinTR-20 SensitivityFebruary 20151 WinTR-20 Sensitivity to Input Parameters."

Similar presentations

Hydrology Rainfall - Runoff Modeling (I)

Hydrology Rainfall - Runoff Modeling (I)
Hydrologic Analysis Dr. Bedient CEVE 101 Fall 2013.

Hydrologic Analysis Dr. Bedient CEVE 101 Fall 2013.
WinTR-20 Calibration ProceduresFebruary 20151 WinTR-20 Calibration Procedures.

WinTR-20 Calibration ProceduresFebruary WinTR-20 Calibration Procedures.
Generating Flow Frequencies – Updating NOAA Atlas Precipitation Frequency for California by: John High, Hydrologist Sacramento District Sacramento District.

Generating Flow Frequencies – Updating NOAA Atlas Precipitation Frequency for California by: John High, Hydrologist Sacramento District Sacramento District.
Unit Hydrograph Reading: Applied Hydrology Sections 7.1-7.3, 7.5, 7.7,

Unit Hydrograph Reading: Applied Hydrology Sections , 7.5, 7.7,
WinTR-55: Introduction and Background zObjectives: The basics History of WinTR-55 Nuts & bolts of algorithms Demo of model interface.

WinTR-55: Introduction and Background zObjectives: The basics History of WinTR-55 Nuts & bolts of algorithms Demo of model interface.
CHARACTERISTICS OF RUNOFF

CHARACTERISTICS OF RUNOFF
Soil Conservation Service Runoff Equation

Soil Conservation Service Runoff Equation
Introduction to Surface Water Hydrology and Watersheds Lecture 1 Philip B. Bedient Rice University November, 2000.

Introduction to Surface Water Hydrology and Watersheds Lecture 1 Philip B. Bedient Rice University November, 2000.
Forest Hydrology: Lect. 18

Forest Hydrology: Lect. 18
Unit Hydrograph Reading: Sections 7.1-7.3, 7.5, 7.7,

Unit Hydrograph Reading: Sections , 7.5, 7.7,
Continuous Hydrologic Simulation of Johnson Creek Basin and Assuming Watershed Stationarity Rick Shimota, P.E. Hans Hadley, P.E., P.G. The Oregon Water.

Continuous Hydrologic Simulation of Johnson Creek Basin and Assuming Watershed Stationarity Rick Shimota, P.E. Hans Hadley, P.E., P.G. The Oregon Water.
Upper Brushy Creek Flood Study – Flood mapping and management Rainfall depths were derived using USGS SIR 2004-5041, Atlas of Depth Duration Frequency.

Upper Brushy Creek Flood Study – Flood mapping and management Rainfall depths were derived using USGS SIR , Atlas of Depth Duration Frequency.
Lecture 14 - 1 ERS 482/682 (Fall 2002) Rainfall-runoff modeling ERS 482/682 Small Watershed Hydrology.

Lecture ERS 482/682 (Fall 2002) Rainfall-runoff modeling ERS 482/682 Small Watershed Hydrology.
UH Unit Hydrograph Model Response Functions of Linear Systems Basic operational rules:  Principle of Proportionality: f(cQ ) = c  f(Q)  Principle of.

UH Unit Hydrograph Model Response Functions of Linear Systems Basic operational rules:  Principle of Proportionality: f(cQ ) = c  f(Q)  Principle of.
Synthetic Unit Hydrographs

Synthetic Unit Hydrographs
Hydrological Modeling FISH 513 April 10, 2002. Overview: What is wrong with simple statistical regressions of hydrologic response on impervious area?

Hydrological Modeling FISH 513 April 10, Overview: What is wrong with simple statistical regressions of hydrologic response on impervious area?
WinTR-20 Project Formulation Hydrology Computer Program

WinTR-20 Project Formulation Hydrology Computer Program
CE 3372 – Lecture 10. Outline  Hydrology Review  Rational Method  Regression Equations  Hydrographs.

CE 3372 – Lecture 10. Outline  Hydrology Review  Rational Method  Regression Equations  Hydrographs.
Estimating Qmax Using the Rational Method

Estimating Qmax Using the Rational Method

Similar presentations

Ads by Google