APPENDIX B Hydrologic Model Spring Event

Similar documents
APPENDIX C - Hydrologic Model Summer Event

Flood Forecasting Tools for Ungauged Streams in Alberta: Status and Lessons from the Flood of 2013

9. PROBABLE MAXIMUM PRECIPITATION AND PROBABLE MAXIMUM FLOOD

Performance of two deterministic hydrological models

The Importance of Snowmelt Runoff Modeling for Sustainable Development and Disaster Prevention

Basic Hydrologic Science Course Understanding the Hydrologic Cycle Section Six: Snowpack and Snowmelt Produced by The COMET Program

Central Asia Regional Flash Flood Guidance System 4-6 October Hydrologic Research Center A Nonprofit, Public-Benefit Corporation

Storm and Runoff Calculation Standard Review Snowmelt and Climate Change

Radar precipitation for winter hydrological modelling

Lake Tahoe Watershed Model. Lessons Learned through the Model Development Process

Impacts of climate change on flooding in the river Meuse

Missouri River Basin Water Management Monthly Update

4. THE HBV MODEL APPLICATION TO THE KASARI CATCHMENT

Snow Melt with the Land Climate Boundary Condition

Disentangling Impacts of Climate & Land Use Changes on the Quantity & Quality of River Flows in Southern Ontario

2017 Fall Conditions Report

2015 Fall Conditions Report

Design Storms for Hydrologic Analysis

Upper Missouri River Basin December 2017 Calendar Year Runoff Forecast December 5, 2017

Flood Risk Assessment

Presented by Jerry A. Gomez, P.E. National Hydropower Association Northeast Regional Meeting - September 17, 2009

The elevations on the interior plateau generally vary between 300 and 650 meters with

Modeling of peak inflow dates for a snowmelt dominated basin Evan Heisman. CVEN 6833: Advanced Data Analysis Fall 2012 Prof. Balaji Rajagopalan

Assessment of extreme flood characteristics based on a dynamic-stochastic model of runoff generation and the probable maximum discharge

Hydrologic Forecast Centre Manitoba Infrastructure, Winnipeg, Manitoba. FEBRUARY OUTLOOK REPORT FOR MANITOBA February 23, 2018

Speakers: NWS Buffalo Dan Kelly and Sarah Jamison, NERFC Jeane Wallace. NWS Flood Services for the Black River Basin

Lecture 6: Precipitation Averages and Interception

Snowmelt runoff forecasts in Colorado with remote sensing

Lecture 8: Snow Hydrology

NRC Workshop Probabilistic Flood Hazard Assessment (PFHA) Jan 29-31, Mel Schaefer Ph.D. P.E. MGS Engineering Consultants, Inc.

HEC-HMS Lab 4 Using Frequency Storms in HEC-HMS

2016 Fall Conditions Report

Summary of the 2017 Spring Flood

P. Marsh and J. Pomeroy National Hydrology Research Institute 11 Innovation Blvd., Saskatoon, Sask. S7N 3H5

Hydrologic Forecast Centre Manitoba Infrastructure, Winnipeg, Manitoba. MARCH OUTLOOK REPORT FOR MANITOBA March 23, 2018

Table (6): Annual precipitation amounts as recorded by stations X and Y. No. X Y

PLANNED UPGRADE OF NIWA S HIGH INTENSITY RAINFALL DESIGN SYSTEM (HIRDS)

CFCAS project: Assessment of Water Resources Risk and Vulnerability to Changing Climatic Conditions. Project Report II.

March 1, 2003 Western Snowpack Conditions and Water Supply Forecasts

Watershed simulation and forecasting system with a GIS-oriented user interface

TABLE OF CONTENTS. 3.1 Synoptic Patterns Precipitation and Topography Precipitation Regionalization... 11

Prediction of rainfall runoff model parameters in ungauged catchments

Evaluating extreme flood characteristics of small mountainous basins of the Black Sea coastal area, Northern Caucasus

IMPLEMENTATION OF AN ICE JAM PREDICTOR WITH USER INTERFACE

HyMet Company. Streamflow and Energy Generation Forecasting Model Columbia River Basin

Missouri River Basin Climate Outlook 1 May Dr. Dennis Todey State Climatologist South Dakota State Univ.

SNOW AS POTENTIAL FLOOD THREAT

Modelling snow accumulation and snow melt in a continuous hydrological model for real-time flood forecasting

Workshop: Build a Basic HEC-HMS Model from Scratch

APPENDIX 6.5-B Knight Piésold Kitsault Mine Climate Change Assessment Letter KITSAULT MINE PROJECT ENVIRONMENTAL ASSESSMENT APPENDICES

The effectiveness of the Natural Resource Conservation Service (NRCS) and Huff rainfall distribution methods for use in detention basin design

Fenhe (Fen He) Map of River. Table of Basic Data. China 10

RELATIVE IMPORTANCE OF GLACIER CONTRIBUTIONS TO STREAMFLOW IN A CHANGING CLIMATE

SNOW AND GLACIER HYDROLOGY

Extreme Rain all Frequency Analysis for Louisiana

2017 January Conditions Report Manitoba Hydrologic Forecasting and Coordination Branch Manitoba Infrastructure

Instructions for Running the FVS-WRENSS Water Yield Post-processor

Review of existing statistical methods for flood frequency estimation in Greece

Climate also has a large influence on how local ecosystems have evolved and how we interact with them.

The following information is provided for your use in describing climate and water supply conditions in the West as of April 1, 2003.

January 2011 Calendar Year Runoff Forecast

The role of snowpack in producing floods under heavy rainfall

Souris River Basin Spring Runoff Outlook As of March 1, 2019

JUNE 2004 Flood hydrology of the Waiwhetu Stream

Daytime long-wave radiation approximation for physical hydrological modelling of snowmelt: a case study of southwestern Ontario

Upper Missouri River Basin February 2018 Calendar Year Runoff Forecast February 6, 2018

A Synopsis of the December 1-4, 2007 Storm Events

HOUR-TO-HOUR SNOWMELT RATES AND LYSIMETER OUTFLOW DURING AN ENTIRE ABLATION PERIOD

Detailed Storm Rainfall Analysis for Hurricane Ivan Flooding in Georgia Using the Storm Precipitation Analysis System (SPAS) and NEXRAD Weather Radar

INFLOW DESIGN FLOOD CONTROL SYSTEM PLAN 40 C.F.R. PART PLANT YATES ASH POND 2 (AP-2) GEORGIA POWER COMPANY

Missouri River Basin Water Management Monthly Update

Drought Monitoring with Hydrological Modelling

Modelling runoff from large glacierized basins in the Karakoram Himalaya using remote sensing of the transient snowline

Climatic Change Implications for Hydrologic Systems in the Sierra Nevada

PRELIMINARY DRAFT FOR DISCUSSION PURPOSES

1. Evaluation of Flow Regime in the Upper Reaches of Streams Using the Stochastic Flow Duration Curve

Baseflow Analysis. Objectives. Baseflow definition and significance

Oregon Water Conditions Report May 1, 2017

Lecture 2: Precipitation

Solution: The ratio of normal rainfall at station A to normal rainfall at station i or NR A /NR i has been calculated and is given in table below.

Stochastic Modeling of Extreme Floods on the American River at Folsom Dam

Results of Intensity-Duration- Frequency Analysis for Precipitation and Runoff under Changing Climate

Using PRISM Climate Grids and GIS for Extreme Precipitation Mapping

Bill Kappel. Doug Hultstrand. Applied Weather Associates

Muskrat Falls Project - CE-13 (Public) Page 1 of 170

Hydrologic Overview & Quantities

Missouri River Basin Water Management Monthly Update

The indicator can be used for awareness raising, evaluation of occurred droughts, forecasting future drought risks and management purposes.

Prediction of Snow Water Equivalent in the Snake River Basin

Missouri River Flood Task Force River Management Working Group Improving Accuracy of Runoff Forecasts

Impacts of snowpack accumulation and summer weather on alpine glacier hydrology

Weather to Climate Investigation: Snow

INVISIBLE WATER COSTS

Climate change projections for Ontario: an updated synthesis for policymakers and planners

Generation of synthetic design storms for the Upper Thames River basin

Canadian Prairie Snow Cover Variability

Hydrologic Forecast Centre. Manitoba Infrastructure. Winnipeg, Manitoba FEBRUARY FLOOD OUTLOOK REPORT FOR MANITOBA.

Operational Perspectives on Hydrologic Model Data Assimilation

The relationship between catchment characteristics and the parameters of a conceptual runoff model: a study in the south of Sweden

What we are trying to accomplish during the winter season

Transcription:

Jock River Flood Risk Mapping (within the City of Ottawa) Hydrology Report July 2004 PageB1 APPENDIX B Hydrologic Model Spring Event Snowmelt+Rainfall Calibration and Validation Results Design Events Explanation of AES rain+snowmelt extreme value analysis Stage-Storage-Discharge: Richmond Fen Goodwood Marsh

Jock River Flood Risk Mapping (within the City of Ottawa) Hydrology Report July 2004 PageB2 Calibration and Validation Results For the Spring runoff in 2003, snowpack data provided by the RVCA and temperature/rainfall data from AES Ottawa CDA were used to synthesize an input hyetograph for the Spring hydrologic model of the Jock River. The synthesis process is discussed, in more detail, in the Design Flows section and requires the use of a snowpack melt-factor in developing the input hyetograph. For the calibration and validation exercise, in which the elements of the hydrologic model are refined (API, infiltration, Tp, and CN), the melt-factor is a variable and is different for each year. It was determined by developing a best fit between observed snowpack behaviour and simulated snowpack behaviour. Figure B1(a) illustrates the impact of melt-factor on estimating snow pack melt behaviour by comparing observed water equivalent and estimated water equivalent (using melt-factor) during the Spring 2003 runoff: for this runoff event, a melt-factor of 1.99 was chosen as providing the best estimation of snowpack behaviour. While a melt-factor of 1.15 appears to provide a better fit with observed data, the tail-end of the snowpack depletion simulation using this factor, would significantly overestimate melt volume. The resulting synthetic hydrograph at Moodie Drive and the observed hydrograph at Moodie Drive were compared and adjustments made in the hydrologic model (API, infiltration, Tp, CN) until there was a best fit between peak magnitude, volume of runoff and timing. The final calibration result is provided in Figure B1(b): the best fit is adequate and the peak and volume are overestimated by 30% and 15% respectively. Spring runoff events in 1978, 1993, 1997 and 1998 were then simulated by the model and results were compared with observed flows. The comparison is illustrated in Figure B2 and shows a range of fit for peak, volume and timing. For two events the peak magnitudes are within 5% while for two others, they range between 15% and 30%. This suggests appropriate validation of the model. Additional validation of the model is obtained by comparing the results of Return Period design event simulations with the results of SSFA of the observed record of maximum instantaneous peak flows at Moodie Drive. Table B3 compares the results of three different design event assumptions regarding CN value during Spring runoff: The first uses a fixed CN value of 35 and allows, in the SWMHYMO simulation, for snowmelt to be stored in the snowpack for release over a period of time; the acceptability of this approach was confirmed by a recent project completed for the City of Gatineau (JFSA). the second uses a fixed CN value of 90 to reflect frozen ground conditions and the high degree of imperviousness but no storage component. The third uses a CN that varies according to Antecedent Precipitation Index (API), Initial Abstraction (IA) and a storage factor (Sk) similar to the CN* approach used in QUALHYMO.

Jock River Flood Risk Mapping (within the City of Ottawa) Hydrology Report July 2004 PageB3 The comparison indicates that the CN=35 modeling assumptions provide peak flows that are within 5% of the SSFA results for observed Spring peaks at Moodie Drive, for the 25, 50 and 100 year events. This provides additional support for model validity in the Jock River watershed. Design Flows The estimates of Spring flow, based on hydrologic model, were developed with several assumptions: 1. Return Period synthetic springmelt hyetographs (hourly precipitation inputs in terms of snowmelt and rainfall) could be based on Return Period snowmelt+rainfall volumes developed by AES. a. These volumes are provided in the form of intensity, duration, frequency relationships (see Table B2). b. They were derived from statistical analysis (Gumbel Extreme Value) of maximum annual snowmelt+rainfall volumes: the volumes were developed for 1 to 30 day periods based on observed precipitation (snow + rain) and temperature at the Ottawa CDA site from 1890 through to 1997 (see Table B1). c. annual volumes were estimated by Environment Canada using a snowpack accumulation/depletion algorithm as identified in Figure B5 2. a 10 day melt event, as illustrated in Figure B3, is a reasonable duration for a springmelt hyetograph: flow simulation results correlate well with the 100 year SSFA results for the Moodie Drive gauge as shown in Table B3. 3. these volumes have been distributed over the 10 day duration in the following manner: The 1 day volume from Table B2 is assigned to day 5; the 2 day volume minus the 1 day volume is assigned to day 6; the 3 day volume minus the 1 day plus 2 day volumes is assigned to day 4 (alternating volume placement about day 5). And so on until the 10 day event is constructed in terms of volume allocation on a daily basis. 4. A sine curve distribution could be used to allocate snowmelt+rainfall volume on an hourly basis for each day of the 10 day event. The final simulated runoff hydrographs, for Spring events at Moodie Drive, with Return Periods ranging from 2 years to 100 years, are provided in Figure B4.

Table B3 Validation At Moodie Drive - SSFA/observed vs. Design Event SPRING (Dec-Apr) Flows (m3/s) Return Period (years) Flow Flow Type 2 5 10 25 50 100 Estimation Technique Design Event Qmax inst 80 109 128 158 182 206 (10 day return period rainfall+snowmellt) (CN=35) Design Event Qmax inst 83 123 150 183 208 233 (10 day return period rainfall+snowmellt) (CN=90) Design Event Qmax inst 64 95 119 152 177 200 (10 day return period rainfall+snowmellt) (CN=variable) SSFA LP3 Qmax inst 91 123 142 160 181 196 (observed)

Jock River Flood Risk Mapping (within the City of Ottawa) Hydrology Report July 2004 PageB4 Explanation of AES rain+snowmelt extreme value analysis Prepared by: Hydrometeorology Division, Canadian Climate Centre, Atmospheric Environment Service Daily rainfall and snowmelt estimates for the noted stations are analysed assuming a Gumbel extreme value distribution. Data are for the period of record shown on the attached computer printout. The results provide annual extreme values for durations from 1 to 30 days and estimated amounts for return periods up to 100 years. The snowmelt estimates were based on degree-day type equations. Five different snowmelt equations were used giving five different sets of snowmelt values. Data The input data used in this analysis and in the calculation of the snowmelt estimates were daily maximum and minimum temperatures, daily rainfall total and daily depth of fresh snow measurements by ruler. A snow density of 0.1 was assumed to convert snow depth into its water equivalent. Such snow measurements may not be spatially representative. The snowmelt estimates should therefore be considered with the same precaution in mind. Snowmelt Calculation Daily snowmelt estimates were calculated using degree-day type equations. Five different equations were used and a description of each is given below. The units of measure indicated below are the units used in the original presentation of the model. All models and resulting output have been converted to metric (SI) units in the computer software. The algorithm for accumulating and depleting the snow pack is given in Figure B5. Method of Analysis The algorithm is based upon synthetic snowpacks which are accumulated according to the daily snowfall measurements and depleted according to the snowmelt as determined by each of the snowmelt models. The algorithm ceases to operate when the synthetic snowpack is reduced to zero. Daily rainfall is added to the daily snowmelt as calculated by each model and the maxima of the combined rain plus snowmelt values are used to determine the annual maximum series for the different durations. Maximum annual values for rainfall plus snowmelt for each of the five snowmelt estimate data sets were determined for 1 to 30 day periods. These annual maximum value series were then analyzed assuming a Gumbel extreme value (EV1) distribution and using a method of moments fit (see Hogg and Carr, 1985) to derive extreme value estimates for return periods up to 100 years. The annual maximum values for each duration period have been tabulated together with the starting date of each maximum event. No attempt was made to estimate missing data. Periods with missing data were not analyzed for maximum values but an annual maximum was still deter mined provided 90% of the data were

Jock River Flood Risk Mapping (within the City of Ottawa) Hydrology Report July 2004 PageB5 available for the critical period of the year as specified on the printout. Such annual maxima based on an incomplete data year are flagged; (**). Rigorous testing of the annual maximum series for goodness of fit to the Gumbel distribution has not been done. However, plots of several randomly chosen series on Gumbel graph paper have shown reasonably good fits. (See Louie and Hogg, 1980) References Hogg, W.D. and D.A. Carr, 1985. Rainfall Frequency Atlas for Canada. 90 pp., Supply & Services Canada, ISBN 0-660-52992-0, Ottawa. Louie, P.Y.T. and W.D. Hogg, 1980. Extreme Value Estimates of Snowmelt, Proc. CDN. Hydrol. Symp.: 80. PP 64-78. NRC Ottawa 1) Model 1 - Eastern Canada Forested Basin SM1 = 0.0397 (Ta - 27.6) (inches/day) Ta = mean daily air temperatures F Ref: Pysklywec, D.W., K.S. Davar and D.I. Bray (1968): Snowmelt at an Index Plot, Water Resour. Res., 4(5), 937-946. 2) Model 2 - Western North America Mountain Basin SM2 = (0.074 + 0.007 R) (Ta - 32) + 0.05 (inches/day) R = daily rainfall in inches Ta = mean daily air temperature F Ref: United States Army Corps of Engineers (1956): Snow Hydrology, North Pacific Division, Portland, Oregon 3) Model 3 - Western Canada Mountain Basin SM3 = 3.0 (Ta + TCA) (((Tx - TN)/8) + TN) (mm/day) Ta = mean daily air temperatures C Tx = maximum daily temperature C TN = minimum daily temperature C TCA = (TN/4.4) but must be IN THE RANGE OF 0 TO 1.5 Ref: Quick, M.C. and A. Pipes (1975): The UBC Watershed Model, Proceedings of Symposium in Bratislava, Application of Mathematical Models in Hydrology and Water Resource Systems, IAHS Pub. No. 115 4) Model 4 - Southern Ontario SM4 = 0.02 (Tx - 32) (inches/day) Tx = maximum daily air temperature F Ref: Bruce, J.P. and R.H. Clark (1966): Introduction to Hydro meteorology, p. 257, Pergamon Press, Toronto 5) Model 5 - Modification of Model 4 SM5 = 0.08 (Ta - 32) (inches/day) Ta = mean daily air temperature F

Jock River Flood Risk Mapping (within the City of Ottawa) Hydrology Report July 2004 PageB6 FIGURE B5 ALGORITHM FOR ACCUMULATING AND DEPLETING THE SNOWPACK INITIALIZE SNOWPACK TO ZERO INPUT DAILY MAX. & MIN. TEMP. PLUS DAILY RAIN AND SNOW TEST END OF DATA --- YES--- STOP NO ADD SNOWFALL DATA TO SNOWPACK CALCULATE DAILY SNOWMELT TEST SNOWMELT > SNOWPACK --- YES ----- NO MAKE SNOWMELT EQUAL --------------- TO SNOWPACK DEPLETE SNOWPACK BY AMOUNT OF DAILY SNOWMELT