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RAINFALL-RUNOFF RELATIONSHIPS FOR SMALL, MOUNTAINOUS,
FORESTED WATERSHEDS IN THE EASTERN UNITED STATES
by
NEGUSSIE HAILU TEDELA
(Under the Direction of Todd C. Rasmussen and Steven C. McCutcheon)
ABSTRACT
Runoff is a complex interaction between precipitation and landscape factors. While some
of these factors (e.g., land use and cover, topography, soil characteristics, and hydrologic
condition) have been defined for urban, rangeland, and agricultural drainages, runoff from
mountainous, forested watersheds is poorly understood, especially in the eastern United States.
This study investigated the response of streamflow to rainfall on ten gaged, small watersheds in
the mountainous forests of the eastern United States using two methods to estimate runoff; the
semi-empirical curve number method, and the semi-distributed TOPMODEL.
Alternative techniques for calibrating watershed curve numbers were first assessed to
determine whether these methods provide acceptable estimates. Runoff estimated using tabulated
curve numbers was assessed separately and provided very poor, inadequate runoff estimates for
all ten watersheds. Curve numbers calibrated using rainfall-runoff observations provided
adequate estimates for only four of ten watersheds. Even calibrated curve numbers contain large
uncertainties, thus requiring statistical proof that estimated runoff adequately agrees with
observations for use in critical designs. For ungaged, forested watersheds, estimated curve
numbers should be independently confirmed using data from gaged watersheds with similar
hydrologic conditions. The effects of seasonal variation, forest harvesting, and return period
frequencies on curve numbers were evaluated, and all affect curve numbers under some
circumstances. Design engineers and analysts should consider using these factors to adjust curve
numbers; otherwise, runoff calculations are even poorer estimates.
Watershed runoff responses also were evaluated using the TOPMODEL, which uses
topography to simulate runoff based on the concepts of saturation excess overland flow as
controlled by subsurface processes. The results showed that the TOPMODEL best estimated
runoff at three of the four locations. Results were in general agreement with other the
TOPMODEL studies. The timing, shape and magnitude of the simulated hydrograph during the,
rising, and recession periods of each storm events was very well reproduced by the model. The
relationship between the TOPMODEL topographic index and the curve number for a given
watershed may provide a useful procedure for better estimating runoff from small, mountainous,
forested watershed in the eastern United States.
INDEX WORDS: Curve number, rainfall, runoff, saturation excess, variable source area,
subsurface flow, hydrology, rainfall-runoff relations, TOPMODEL, topographic index, runoff modeling, Generalized Likelihood Uncertainty Estimation, Digital elevation model, forested watersheds, gaged watersheds, ungaged watersheds, mountainous terrain, probability distribution, lognormal distributions, gamma distributions, Weibull distributions, return periods, Goodness of fit tests, growing and dormant seasons, forest harvesting
RAINFALL-RUNOFF RELATIONSHIPS FOR SMALL, MOUNTAINOUS,
FORESTED WATERSHEDS IN THE EASTERN UNITED STATES
by
NEGUSSIE HAILU TEDELA
B.S., Alemaya University, Ethiopia, 1992
M.Eng.S., National University of Ireland, 1997
A Dissertation Submitted to the Graduate Faculty of The University of Georgia in Partial
Fulfillment of the Requirements for the Degree
DOCTOR OF PHILOSOPHY
ATHENS, GEORGIA
2009
RAINFALL-RUNOFF RELATIONSHIPS FOR SMALL, MOUNTAINOUS,
FORESTED WATERSHEDS IN THE EASTERN UNITED STATES
by
NEGUSSIE HAILU TEDELA
Major Professor: Todd C. Rasmussen Steven C. McCutcheon Committee: C. Rhett Jackson
E. William Tollner Wayne T. Swank
Electronic Version Approved: Maureen Grasso Dean of the Graduate School The University of Georgia August 2009
iv
DEDICATION
This dissertation is dedicated to the memory of my mother, Bezabish Ayele, who
emphasized the importance of education and taught me important lessons throughout her life;
and to the memory of my father, Hailu Tedela, who has been my role-model for hard work,
persistence and personal sacrifices, and who instilled in me the inspiration to set high goals and
the confidence to achieve them.
v
ACKNOWLEDGMENTS
I would like to express my gratitude to all faculty, friends, and family members who have
helped me to complete this dissertation. The faculty of the Warnell School of Forest and Natural
Resources and the Faculty of Engineering have provided me with a tremendous graduate
education: they have taught me how to approach scientific and engineering problems; they have
provided me with scientific opportunities and economic support; and they have shown me how to
approach my work as hydrologist.
Several individuals deserve special mention for their contributions to this dissertation.
Steven McCutcheon and Todd Rasmussen have been strong and supportive advisors to me
throughout my Ph.D. studies. They have always given me great freedom to pursue independent
work. They have boosted my confidence by providing me with opportunities and giving me an
equal voice in our work together. I will always appreciate them for their patience, understanding,
and for helping me with the tone and discipline of my writing. They have always been willing to
raise important ideas and to invest their time and energy in improving my work. I am also
thankful to the members of my dissertation committee C. Rhett Jackson, E. William Tollner, and
Wayne T. Swank for their time and patience in assisting my work.
Financial assistance was provided in part by (1) the West Virginia Division of Forestry,
(2) the U.S. Geological Survey through the Georgia Water Resources Institute, and (3) Warnell
School of Forest and Natural Resources. Richard Hawkins of the University of Arizona, Tucson
provided insightful background and guidance on the use, interpretation, and limitations of the
curve number method. Keith Beven (from Lancaster University, UK) and John Dowd (from the
vi
University of Georgia, Athens) are gratefully acknowledged for providing initial guidance and
comments on the TOPMODEL study. The watershed characteristics and rainfall-runoff datasets
required for this study were provided by Wayne Swank and Stephanie Laseter from the U.S.
Forest Service Coweeta Hydrologic Laboratory; Frederica Wood under the supervision of Mary
Beth Adams from the U.S. Forest Service Fernow Timber and Watershed Laboratory; John
Campbell from the U.S. Forest Service Hubbard Brook Experimental Forest; and Josh Romeis
from the University of Georgia Etowah Research Project.
I extend my appreciation to my wife, Frezewd Adnew, who has been patience and
supportive during my stay in graduate school and who has shared the many uncertainties,
challenges, and sacrifices for completing this dissertation. I always admire my daughter, Hannah
Hailu, who has grown into a wonderful 10 years old in spite of her father spending so much time
away from her, working on this dissertation. Finally, I would like to express my appreciation to
my sisters, brothers, and friends for their encouragement and advice throughout my graduate
study.
vii
TABLE OF CONTENTS
Page
ACKNOWLEDGMENTS ...............................................................................................................v
LIST OF TABLES......................................................................................................................... ix
LIST OF FIGURES ....................................................................................................................... xi
CHAPTER
1 INTRODUCTION .........................................................................................................1
Stream flow generation processes .............................................................................1
Rainfall-runoff models .............................................................................................3
Curve number method ..............................................................................................6
TOPMODEL ..........................................................................................................10
Summary .................................................................................................................11
2 INVESTIGATION OF RUNOFF CURVE NUMBER FROM TEN, SMALL,
FORESTED WATERSHEDS IN THE MOUNTAINS OF THE EASTERN
UNITED STATES ..................................................................................................22
3 EFFECTS OF SEASONAL VARIATION AND FOREST HARVESTING ON
RUNOFF FROM TEN, SMALL, MOUNTAINOUS, FORESTED
WATERSHEDS IN THE EASTERN UNITED STATES......................................64
4 RAINFALL AND RUNOFF PROBABILITY DISTRIBUTIONS FOR FOUR,
SMALL, FORESTED WATERSHEDS IN THE MOUNTAINOUS, EASTERN
UNITED STATES .................................................................................................92
viii
5 RUNOFF MODELING OF FOUR SMALL, MOUNTAINOUS, FORESTED
WATERSHEDS IN THE EASTERN UNITED STATES TOPMODEL.............116
6 CONCLUSIONS........................................................................................................156
REFERENCES ............................................................................................................................166
APPENDICES .............................................................................................................................175
A CURVE NUMBER ESTIMATION PROCEDURE..................................................175
B PROBABILITY DISTRIBUTIONS..........................................................................180
ix
LIST OF TABLES
Page
Table 2.1: Characteristics of ten small, forested watersheds in the mountains of the eastern
United States..................................................................................................................54
Table 2.2: Estimated curve numbers for gaged and ungaged watersheds by all procedures and
with estimates of uncertainty.........................................................................................55
Table 2.3: Nash-Sutcliffe efficiency (ENS), coefficient of determination (D), and root mean
square error (RMSE) based on the comparison of measured runoff and runoff
estimated using the curve numbers from the six approaches listed in the table............56
Table 2.4: Representative watershed curve numbers (CN), uncertainty, and paired Student t-tests
of curve-number-based estimates of runoff versus measured .......................................57
Table 2.5: Multiple comparisons of runoff volumes determined using six curve number
procedures from watershed characteristics (tabulated curve number) and measured
rainfall and runoff..........................................................................................................58
Table2.6: Tests of standard asymptotic watershed responses for ordered (and matched in
frequency) rainfall and runoff series .............................................................................59
Table 3.1: Dormant and Growing Seasons ....................................................................................78
Table 3.2: Preharvest and hydrologic effect periods for the three-paired watersheds...................79
Table 3.3: Differences in dormant and growing season mean curve numbers including and
excluding transitions periods.........................................................................................80
Table 3.4: Analysis of variance of seasonal curve numbers including transition periods .............81
x
Table 3.5: Analysis of variance of seasonal curve numbers excluding transition periods ............82
Table 3.6: Mean curve numbers for the preharvest and hydrologic effect periods .......................83
Table 3.7: Analysis of variance of curve numbers computed for preharvest and hydrologic effect
periods ...........................................................................................................................84
Table 4.1: Goodness-of-fit tests for Coweeta 2 annual-maximum-rainfall series .......................108
Table 4.2: Selected probability distributions of observed, annual-maximum runoff and rainfall
and estimated annual-maximum runoff volumes for four mountainous-forested
watersheds ...................................................................................................................109
Table 5.1: Characteristics of four mountainous forested watersheds in the eastern U.S.............138
Table 5.2: Parameter ranges.........................................................................................................139
Table 5.3: Range of topographic index values for all watersheds ...............................................140
Table 5.4: Model efficiencies for Coweeta 36 during calibration testing procedures .................141
Table 5.5: Model efficiencies for Fernow watershed 4 during calibration testing procedures....142
Table 5.6: Model efficiencies for Hubbard Brook 3 during calibration testing procedures ........143
Table 5.7: Mean efficiency of parameters for all watersheds......................................................144
xi
LIST OF FIGURES
Page
Figure 2.1: Locations of watersheds used in this study to evaluate the curve number method in
mountainous-forested eastern watersheds .....................................................................60
Figure 2.2: Asymptotic curve number fit for selected watersheds estimated based on ordered
rainfall and runoff series................................................................................................61
Figure 2.3: Relation between measured and estimated runoff.......................................................62
Figure 2.4: Error (measured minus estimated runoff) as a function of rainfall .............................63
Figure 3.1: Water balance for a short-term rainfall event in which P is rainfall, Q is runoff depth,
Ia is initial abstraction, F is retention, and S is potential maximum retention...............85
Figure 3.2: Study watersheds.........................................................................................................87
Figure 3.3: Curve numbers for growing and dormant seasons including transition periods .........88
Figure 3.4: Curve numbers for growing and dormant seasons excluding transition periods ........89
Figure 3.5: Comparison of mean curve numbers for the three watersheds before tree harvest,
during hydrologic effects, and for the entire record ......................................................90
Figure 3.6: Asymptotic curve numbers for growing and dormant seasons of Coweeta 2 .............91
Figure 4.1: Coweeta 2 probability density function for observed, annual-maximum rainfall.....110
Figure 4.2: Fernow 4 probability density function for observed, annual-maximum Fernow 4...111
Figure 4.3: Probability distributions for the Coweeta 2...............................................................112
Figure 4.4: Probability distributions for the Coweeta 36.............................................................113
Figure 4.5: Probability distributions for the Fernow 4 ................................................................114
xii
Figure 4.6: Probability distributions for the Hubbard Brook 3....................................................115
Figure 5.1: Location of study watersheds ....................................................................................145
Figure 5.2: Digital Elevation Model (DEM) of Coweeta 2 watershed ........................................146
Figure 5.3: Digital Elevation Model (DEM) of Coweeta 36 watershed .....................................147
Figure 5.4: Digital Elevation Model (DEM) of Fernow 4 watershed..........................................148
Figure 5.5: Digital Elevation Model (DEM) of Hubbard Brook watershed ..............................149
Figure 5.6: Distribution of topographic index for all watersheds................................................150
Figure 5.7: Dotty plots for all parameters for the Hubbard Brook watershed 3 ..........................151
Figure 5.8: The spatial pattern of the topographic index classes used in the TOPMODEL as
determined from an analysis of surface topography ...................................................152
Figure 5.9: Comparison of observed and simulated hydrograph for Hubbard Brook watershed153
Figure 5.10: Comparison of observed and simulated hydrograph for Fernow watershed 4........154
Figure 5.11: Comparison of observed and simulated hydrograph for Coweeta watershed 36 ....155
1
CHAPTER 1
INTRODUCTION
Streamflow generation
Runoff occurs when parts of the landscape are saturated or impervious. Two runoff
concepts include infiltration-excess and saturation excess runoff. The infiltration-excess runoff
paradigm assumes that overland flow occurs when the rainfall intensity is greater than the
infiltration rate at the surface soil. The water, in excess of that which infiltrates through the soil
surface, flows across the soil surface to nearby channels (Kirkby, 1985). This process has also
been termed Hortonian runoff. As first described by Horton (1933), two conditions must be
satisfied to generate Hortonian flow (Freeze, 1980). Firstly, rain must fall on the landscape with
an intensity or rate in excess of the dynamic permeability of the surface soil. Secondly, the
duration of rainfall must last longer than the time required to saturate the surface. Infiltration-
excess runoff occurs less frequently (Freeze, 1972) except from (1) disturbed or poorly vegetated
areas that usually have a subhumid or semiarid climate (Wolock, 1993), (2) clay dominated
surface soils, (3) watersheds where bedrock surfaces are exposed, and (4) urban impervious
surfaces. Bonell and Williams (1986) found that a wide range of rainfall intensities on gentle
slopes of semiarid tropical soils produced Hortonian flows because the soil surface is continually
changing due to both biological activity and raindrop impact.
The second type of runoff generation also occurs where the soil surface is saturated and
any further rainfall, even at low intensities, generates runoff that contributes to streamflow. This
more dominant process is termed as saturation-excess runoff generation. A rise in the water table
2
occurs because of a large infiltration rate of water into the soil and down to the saturated
subsurface (Wolock, 1993). The variable spatial extent of the landscape saturated from below
that fluctuates dynamically with watershed wetness is termed the variable source area (Freeze
and Cherry, 1979). Variable source areas can arise from direct rainfall on the landscape or from
return flow of subsurface water to the surface (Dunne and Black, 1970). Saturated surface areas
typically develop near existing stream channels and in depressions or hollows (Dunne et al.,
1975) and expand as more water infiltrates and moves downslope as saturated subsurface flow
(Wolock, 1993).
In temperate forests, soils typically have an enhanced infiltration capacity due to large
leaf fall and decomposition rates that covers the ground in detritus and forms a thick organic
horizon. A thick, porous detritus and organic horizon protects the soil surface from compaction
by raindrop impact and other processes, and the root biomass in the organic horizon maintains
the large permeability and infiltration capacity of the surface soil (Mulungu et al., 2005). In
many forests, overland flow is nonexistent, rare, or occurs infrequently. Toendle (1970) failed to
observe overland flow on the watersheds of the Fernow Experimental Forest in mountainous
West Virginia. Pierce (1967) noted negligible overland flow on the watersheds of the Hubbard
Brook Experimental Forest in the mountains of New Hampshire. The forested southern
Appalachian watersheds with deeply weathered soils generally have enhanced infiltration so that
storm runoff is controlled by rising subsurface saturation (Beven, 2000). In humid forests
generally, the likely runoff mechanism that contributes to streamflow is saturated-excess flow
(Dunne and Black, 1970).
Together with return flows, saturated-excess flow generation is the basis of the variable
source-area concept (Hewlett and Hibbert, 1967). Antecedent soil moisture, available storage
3
capacity (or depth to bedrock or an aquiclude) and other soil characteristics, topography, and
rainfall duration and intensity dictate the dynamic size of variable source areas (Chorley, 1978;
Beven and Kirkby, 1979).
Regardless of the conceptual or modeling approach to streamflow generation, the
important catchment characteristics, topography, soil type, vegetation cover, and depth to the
water table usually vary at multiple spatial scales, often resulting in a complex, nonlinear
relationship between runoff and rainfall. As a result, small plot studies will likely have different
runoff characteristics compared to field-scale studies, and compared to watershed-scale studies.
Runoff variation can be attributed to the complexity of catchment characteristics in small plot
studies, which increases as the size of study sites expands to watershed scales.
Rainfall-runoff models
The development of computer models to simulate rainfall-runoff relationships has been a
prime focus of hydrological research for at least since the 1960s (Crawford and Linsley, 1966)
and has resulted in a proliferation of models. Following Beck (1991), the following sections
describe metric, conceptual, and physically based rainfall-runoff models to note how the methods
investigated in this study are related.
Metric models: Metric (or empirical) models are directly based on observations to
characterize runoff and are formulated with little or no consideration of the hydrologic cycle
(Kokkonen and Jakeman, 2001) so that the model has no theoretical basis. Strictly limited to the
range of data used to formulate the model, empirical models have two basic uses. Firstly,
interpolations over the range of data used to derive the model are feasible in that the computer
codes serve to estimate a response between observations. Secondly, the form and structure of
4
metric models provide insight into the formulation of conceptual models or the derivation of
physically based models, making extrapolation beyond the original observations possible.
The unit hydrograph (Sherman, 1949), formulated as a linear relationship between
rainfall excess and streamflow, is one of the first metric rainfall-runoff models developed
(Kokkonen and Jakeman, 2001). Although the curve number method can be classified as an
empirical model (Kokkonen and Jakeman, 2001) based on infiltrometer, plot, and watershed data
used to derive the table of curve numbers (NRCS, 2001), the curve number was derived from the
principle that water is conserved on a watershed during a storm. Hence, semi-empirical is a
better categorization for the curve number method.
Conceptual models: These models incorporate the important hydrological processes
using mathematical approximations. Conceptually these types of models usually involve
interconnected storage volumes receiving recharge and discharge as appropriate for
representations of component processes of the hydrological cycle (Kokkonen and Jakeman,
2001). Good examples of conceptual watershed models include (1) the Stanford Watershed
Model (Crawford and Linsley, 1966); (2) the Tank model (Sugawara et al., 1983); (3) the
Boughton (1984) model, (4) MODHYDROLOG (Chiew and McMahon, 1994); and (5)
Hydrologiska Bryäns Vattenbalansavdelning (Bergström, 1995). The more component processes
that are represented in the conceptual model the larger the risk of over-parameterization. Freer et
al. (1996), Johnston and Pilgrim (1976), and Spear et al. (1994) document the associated effects
of parametric uncertainty in conceptual hydrologic modeling.
Physically based models: Models with a theoretical basis simulate hydrological
responses based on the governing hydrodynamics and transport equations. A physically based
model is one for which parameters and variables of the governing equations are measurable in
5
the field (Beven, 1983). In hydrology, however, some parameter estimation using empirical
relationships is necessary to solve the governing equations for the complex flows that occur
(Wilcox et al., 1990). Freeze (1972) developed the first physically based model to solve the
Richards equation for unsaturated flow in two dimensions to represent hillslope processes. Later,
Abbott et al. (1986) and Bathurst (1986) developed the Systéme Hydrologique Européen model
and Beven et al. (1987) developed the Institute of Hydrology Distributed Model using similar
mathematical formulations. Physically based models are appealing because of the
mathematically approximations of the real phenomenon are derived from first principles.
However, these models can require difficult-to-obtain data and may have large computational
demands. Beven (1989), Binley and Beven (1989), and Grayson et al. (1992) discuss the
applicability of physically based models.
This method (Beck, 1991) of classifying rainfall-runoff models is not complete. Some
models may have a strong empirical origin, but also have some conceptual basis so that these
cannot be clearly classified as empirical or conceptual models. These types of models can be
classified as semi-empirical. The curve number method is the best example of a semi-empirical
model. Because of spatial variability within a watershed, the conceptual or the physically based
rainfall-runoff models can also be classified as lumped, semi-distributed, or fully distributed.
The lumped-parameter model ignores the spatial heterogeneity of the catchment response
to achieve an important advantage of simplicity (Ponce and Hawkins, 1996). Semi-distributed
models lump some parameters with similar properties together for simplicity and convenience.
The TOPMODEL is semi-distributed because the topographic indexes are commonly lumped
together for regions with similar values. The dominant two approaches to rainfall-runoff
modeling are currently (1) the conceptual lumped-parameter model, and (2) the spatially
6
distributed model. Distributed models attempt to simulate most of the heterogeneous response at
a local scale (Beven, 1989; O’Connell, 1991; Garbrecht et al., 2001). The following two factors
hamper successful applications of spatially distributed models: (1) the extensive, fractal
heterogeneity (Schuller et al., 2001; Tennekoon et al., 2003) in most catchment characteristics
even at small scales and (2) the poor spatial resolution of supporting data (Garbrecht and Martz,
1994; McMaster, 2002). Nachabe and Morel-Seytoux (1995) note that a distributed model is
unlikely to capture watershed heterogeneity at all scales and a numerical model must “lump” the
parameters at some scale of discretization. Conversely, advances in computing speed and
capacity allow greater discretization of some lumped models.
Curve number method
The Natural Resources Conservation Service (NRCS, 2001) curve number procedure is
widely used to estimate runoff resulting from event rainfall because of simplicity, convenience,
and tradition. The curve number lumps the effects of land use and cover, soil type, and
hydrologic condition. The empirical curve number is a direct simplification of a very difficult to
quantify, conceptual storage index, the potential maximum water retention on a watershed. As
the only parameter necessary to relate a rainfall volume to a runoff estimate, the curve number is
also a lumped composite of all the assumptions and approximations used to derive the rainfall-
runoff relationship.
Studies (Ponce and Hawkins, 1996; King et al., 1999; Garen and Moore, 2005; Michel et
al., 2005; and McCutcheon et al., 2006) have examined the accuracy of the curve number
method, and have identified specific weaknesses. Hydrologists and others began to question the
physical basis of the method (Garen and Moore, 2005) soon after Victor Mockus originally
7
conceptualized the curve number equation (Ponce, 1996). The method has been criticized as
obsolete, too simplified, unrealistic, and inaccurate, especially in representing flow amount, rate,
and pathway, and runoff source areas, upon which erosion and water quality estimates depend
(Ponce and Hawkins, 1996; Garen and Moore, 2005). An additional concern is the failure to
account for the temporal variation in rainfall and runoff (Ponce and Hawkins, 1996; King et al.,
1999).
The accuracy of the curve number method in estimating runoff from forested watersheds
has not been thoroughly determined (McCutcheon et al., 2006). Based on the current curve
number table, drainage infrastructure is being over-designed (Schneider and McCuen, 2005). Use
of the curve number method results in inaccurate estimates of runoff volume from forested
watersheds (Hawkins, 1984; Ponce and Hawkins, 1996; McCutcheon, 2003; and McCutcheon et
al., 2006).
The Soil Conservation Service, now the Natural Resource Conservation Service,
developed a nationally consistent rainfall-runoff relationship to carry out the provisions of the
1954 Small Watershed Act, PL-566 using only available data (thus avoiding additional
fieldwork). However, most available rainfall-runoff relationships in 1954 (e.g., Sherman, 1949)
were for gaged watersheds whereas most of the watersheds the Soil Conservation Service had to
assess were ungaged. Two exceptions were the poorly documented rainfall-runoff relationships
by Mockus (1949) and Andrews (1954) of the Soil Conservation Service. These somewhat
generalized relationships did not require a stream gage in the watershed, thus serving as the
initial basis for the generalized Soil Conservation Service runoff equation for the curve number
method. The Soil Conservation Service (NRCS, 2001) expressed the generalized relationship
between rainfall and runoff as follows: the nonlinear rainfall-runoff relationship starts after some
8
water has initially accumulated and approaches an asymptote defined by the observations that the
theoretical maximum runoff volume of any event is equal to the event rainfall volume.
The curve number procedure was a product of approximately two decades (from 1936 to
1954) of studies of rainfall-runoff relationships. According to the National Engineering
Handbook, Section 4 (NRCS, 2001), the development of the procedure concentrated on storms
producing annual floods. These experimental watersheds were less than 260 hectares (1 square
mile) in size and had a single soil group and one cover complex (Yuan et al., 2001). However,
the original data and plots from the 24 watersheds used for the initial development of the curve
number method have been lost over time (Woodward et al., 2002)
Uses of the curve number method
The curve number method relates watershed rainfall to runoff in engineering drainage
design (McCuen, 2005). The ad hoc popularity of the technique follows from the lumping the
complexity of runoff generation into a single watershed potential maximum retention parameter
easily expressed as the curve number (Nachabe, 2006). Ponce and Hawkins (1996) attribute the
use of the method to (1) the limited measures of watershed characteristics expressed by a single
model parameter; (2) the straightforward, consistent determination of runoff; (3) the consistent
flood calculations necessary for engineering design, and (4) the significant agency support
(Jacobs et al., 2003). Important uses include estimation of runoff volume from gaged and
ungaged watersheds, determination of hydrologic effects of changes in land use and treatment,
and as a calibration parameter in watershed models.
Runoff estimation: The main purpose in developing the curve number method was to
determine how much of a typical or design rainfall depth or volume becomes runoff using
9
readily available information. Engineers and hydrologists select an overall runoff index (the
curve number) for a watershed from land use and cover, soil types, and hydrologic condition to
calculate the runoff depth from a specified rainfall depth. Engineers use these runoff estimates to
design structures and practices for water storage and erosion and flood control.
Analyses of land use changes: Changes in land use that involve a significant increase in
imperviousness result in increased surface water runoff and peak flows (Leopold, 1968; Dunne
and Leopold 1978; Goudie, 1990). An increase in surface runoff volume may contribute to
downstream flooding and a net loss of groundwater recharge (Harbor, 1994). Important land use
changes are the result of urbanization, deforestation, and intensification of agriculture, among
others. Accurate land use mapping over large areas is necessary to monitor these changes.
Satellite data are operationally available to study land use changes that can be used in the
analyses of the change in runoff generation.
Parameter in environmental models: Despite the limited scope of intended applications
and identification of several problems (e.g., Ponce and Hawkins, 1996; McCutcheon et al., 2006)
curve numbers are now widely used on an ad hoc basis in environmental fate and transport
models worldwide (Woodward et al., 2002; Jacobs et al., 2003). The curve number approach is
used in (1) water balance and storm routing models (Yu et al., 2001; De Michele and Salvadori,
2002); (2) water quality models (Rode and Lindenschmidt, 2001); (3) coupled meteorological
and hydrological models (Yu et al., 1999); and (4) crop growth models (Irmak et al., 2001).
Special examples include (1) the Chemicals, Runoff, and Erosion From Agricultural
Management Systems (CREAMS; Knisel, 1980); (2) the Erosion Productivity Impact Calculator
(EPIC; Sharpley and Williams, 1990); (3) the Simulator for Water Resources in Rural Basins
(SWRRB; Williams et al., 1985; Arnold et al., 1990); (4) the Soil and Water Assessment Tool
10
(SWAT; Arnold et al., 1993); (5) the Agricultural Non-Point Source Pollution Model (AGNPS;
Young et al., 1989); and (6) the Generalized Watershed Loading Functions (GWLF) for stream
flow and nutrients (Haith and Shoemaker, 1987).
TOPMODEL
The TOPMODEL (TOPography based hydrologic MODEL), which simulates watershed
runoff based on the concept of saturation excess overland and subsurface flow (Campling et al.,
2002), provides the opportunity to examine an alternative conceptual basis compared to the curve
number relationship. Introduced by Kirkby and Weyman (1974), the TOPMODEL (Beven and
Kirkby, 1979) is a semi-distributed, rainfall-runoff model. In particular, the distributed processes
include the dynamics of surface and subsurface contributing areas (Campling, et al., 2002). The
TOPMODEL is a hybrid of the complexity of a distributed, physically based model and the
relative simplicity of a lumped empirical model (Robson et al., 1993). In essence, the model is a
set of modeling tools that combines the computational and parametric efficiency of a lumped
modeling approach but the saturation-excess concept and the conservation of water is the
scientific basis of the simulations (Beven et al., 1995). One of the TOPMODEL tools provides
one of the few, easy-to-use applications of digital terrain models in hydrologic analysis (Beven,
1997) that has been widely tested in a variety of applications.
Because of the variable source area basis, the TOPMODEL may provide a better estimate
of runoff from forested watersheds. This investigation tested the variable source area premise
with the event runoff responses of four small, forested watersheds in the mountains of the eastern
United States. The TOPMODEL topographic indices of the spatial distribution of runoff
generation in the watershed were determined using the digital elevation models for each of the
11
four watersheds. This study evaluated sets of five parameters using the Generalized Likelihood
Uncertainty Estimation (GLUE). Runoff estimation was the criterion for evaluating many
different randomly chosen parameter sets based on likelihood measures to obtain the best-fit
runoff hydrographs for three rain events. Testing of the calibration involved three additional rain
events for each watershed.
Summary
Chapter 2 evaluated the usefulness of the curve number method by comparing observed
and simulated runoff for small, mountainous-forested watersheds in the eastern United States.
The chapter determined the accuracy of the Natural Resource Conservation Service (2001)
tabulated curve numbers and five procedures for obtaining curve numbers based on observed
rainfall and runoff series. Chapter 3 assessed the effects of seasons and forest harvesting on
curve numbers by compiling two sets of series based on growing and dormant seasons and two
different sets based on preharvest and hydrologic effect periods. Chapter 4 matched the best
continuous probability distributions used in hydrology to measured rainfall and runoff series to
investigate runoff at various return periods. Chapter 5 investigated the saturation-excess-based
TOPMODEL as an alternative to using the curve number concept to estimate runoff. Chapter 6
compiles the conclusions of these four investigations.
12
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21
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22
CHAPTER 2
INVESTIGATION OF RUNOFF CURVE NUMBER FROM TEN, SMALL,
FORESTED WATERSHEDS IN THE MOUNTAINS OF THE EASTERN UNITED STATES1
1 Negussie H. Tedela, Steven C. McCutcheon, Todd C. Rasmussen, C. Rhett Jackson, Ernest W. Tollner, Wayne R.
Swank, Richard H. Hawkins, John L. Campbell, and Mary B. Adams. To be submitted to the ASCE, Journal of Hydrologic Engineering.
23
Abstract
The semi-empirical curve number method is widely used to estimate runoff from a
typical or design rainfall event using land use and soil characteristics. Although used for
estimating runoff from forests, previous investigations indicated that these curve-number-based
estimates are imprecise and inaccurate. This investigation evaluated the curve number method
and the accuracy of curve number estimation procedures using series of annual maximum
rainfall and runoff and watershed characteristics for ten, small, forested watersheds located in the
mountains of four eastern states. Poor Nash-Sutcliffe efficiencies and coefficients of
determination established that the Natural Resource Conservation Service tabulated curve
numbers did not adequately estimate runoff for any of the ten watersheds. The major source of
the great uncertainty (based on individual rainfall and runoff volumes) in deriving a single
watershed curve number was the decrease in this runoff index with increasing rainfall magnitude.
Although the mean runoff volume (based on the best possible curve number calibrated for each
watershed) was not significantly different from the mean observed runoff volume for any of the
ten watersheds, the measured and the estimated runoff for individual storms were poorly
correlated for some of the watersheds. All ten watersheds exhibit a standard asymptotic response
of the curve number to event rainfall depth, except for the two located near Fernow, West
Virginia, which had a complacent response. Calibrated curve numbers for gaged, forested
watersheds can involve large uncertainties. Practitioners should only use these uncertain curve
numbers if statistical analyses confirm that estimated runoff adequately agrees with observations.
For ungaged forested watersheds, curve numbers determined from soil hydrologic group and
hydrologic condition using the Natural Resources Conservation Service tables, should be
24
independently confirmed using locally calibrated curve numbers from gaged watersheds with
similar hydrologic conditions
Keywords: Curve number, runoff-rainfall relationship, watershed, forest, runoff modeling,
hydrology, gaged watersheds, ungaged watersheds,
Curve number method
The curve number method is a semi-empirical technique for determining the runoff depth
or volume as a function of land use and treatment, soil hydrologic group, surface condition, and
rainfall depth. The method is widely used because of simplicity, convenience, publication in a
government handbook, and the tradition of extensive ad hoc use. The Soil Conservation Service
introduced the method in 1954, using approximately twenty years of infiltration or rainfall-runoff
observations from small, rural watersheds (NRCS, 2001; McCutcheon et al., 2006). The Soil
Conservation Service developed the method originally for cropland and rangeland to assess
varying land uses and soil characteristics for designing national flood controls (Rallison and
Miller, 1982). The curve number method is therefore useful for agricultural watersheds,
moderately useful for rangelands, and performs poorly for forests (Hawkins, 1993). The method
was extended to urban runoff design (SCS, 1975), now a dominant application.
Use of curve number method
The use of curve numbers has evolved since 1954. Despite the limited scope of intended
applications and identification of several problems (e.g., Ponce and Hawkins, 1996; Jacobs et al.,
2003; McCutcheon et al., 2006), curve numbers are now widely used in environmental fate and
25
transport models worldwide (Woodward et al., 2002). The following types of models are based
on the curve number approach:
• Water balance and storm routing models (Yu et al., 2001; De Michele and
Salvadori, 2002)
• Water quality models (Rode and Lindenschmidt, 2001)
• Coupled meteorological and hydrological models (Yu et al., 1999)
• Crop growth models (Irmak et al., 2001)
Specific examples of models include the
• Chemicals, Runoff, and Erosion From Agricultural Management Systems
(CREAMS; Knisel, 1980)
• Erosion Productivity Impact Calculator (EPIC; Sharpley and Williams, 1990)
• Simulator for Water Resources in Rural Basins (SWRRB; Williams et al., 1985;
Arnold et al., 1990)
• Soil and Water Assessment Tool (SWAT; Arnold et al., 1993)
• Agricultural Non-Point Source Pollution Model (AGNPS; Young et al., 1989)
• Generalized Watershed Loading Functions (GWLF) for stream flow and nutrients
(Haith and Shoemaker, 1987)
The curve number method has a number of limitations, which are not widely recognized
(Ponce and Hawkins, 1996; Jacobs et al., 2003; McCutcheon et al., 2006) and that are rarely
noted in textbooks (e.g., Hammer and MacKichan, 1981; Roberson et al., 1988; Bras, 1990;
Helweg, 1991; Bedient and Huber, 1992). Chief among the limitations is that the method does
not represent runoff rates, paths, and source areas upon which erosion and water quality
simulations depend. In addition, the Natural Resource Conservation Service (and Soil
26
Conservation Service, before) never adapted the method to estimate forest runoff, only runoff
from agricultural lands, rangelands, and urban areas. Furthermore, the accuracy of the curve
number method has not been thoroughly evaluated (McCutcheon et al., 2006) and using the
curve number table (NRCS, 2001) for engineering design may not provide reliable estimates of
runoff (Schneider and McCuen, 2005). Use of the curve number method to estimate runoff
volume from forested watersheds usually results in unacceptable estimates runoff (Ponce and
Hawkins, 1996; McCutcheon, 2003; Jacobs et al., 2003; Garen and Moore, 2005; Michel et al.,
2005; Schneider and McCuen, 2005; McCutcheon et al., 2006).
These poorly recognized and misunderstood limitations evidently have led to a number of
misinterpretations and misapplications. As a result, this study investigated the curve number
method to evaluate the applicability and accuracy for forested watersheds.
Curve number and runoff equation
The curve number method estimates runoff depth or volume, Q, from rainfall depth or
volume, P, based on the conservation of water in a watershed
QFIP a ++= (2.1)
and two hypotheses that can be expressed on a typical or design event basis, as
S
F
IP
Q
a
=−
(2.2)
SIa λ= (2.3)
where Ia is the watershed initial abstraction (includes interception, depression storage, and
infiltration losses prior to ponding and the commencement of overland or quick flow); F is the
typical event retention of water; S is the potential maximum retention of water after the initial
27
abstraction Ia occurs; and λ is the dimensionless initial abstraction ratio or coefficient. Typically
expressed in inches for practice in North America and millimeters in most other parts of the
world, rainfall, runoff, initial abstraction, retention, and potential maximum retention have the
dimensions of volume or depth (volume normalized by watershed area). Equation (2.1) is a
simple continuity relationship introduced to determine a typical event runoff of sufficiently
limited duration so that evapotranspiration is negligible (Yuan et al., 2001). The partitioning of
rainfall into runoff and retention is based on the first hypothesis [Equation (2.2)]. This hypothesis
expressed as the ratio of runoff Q to the effective rainfall (event rainfall excluding initial
abstraction) P - Ia is equal to the ratio of watershed moisture retention F as a result of the rainfall,
to the potential maximum retention S (Ponce and Hawkins, 1996).
The potential maximum retention (S), the maximum amount of water that can be
temporarily stored or retained according to the antecedent conditions on a watershed, is constant
for a particular storm. However, potential maximum retention varies somewhat from storm to
storm because of the variation of soil moisture, mainly due to antecedent rainfall (Yuan et al.,
2001). Nevertheless, the Soil Conservation Service assumed that the potential maximum
retention was constant for each watershed as long as land cover and use, and hydrologic
condition did not change. The retention (F), defined as the difference between typical event
rainfall P and typical event runoff Q, also varies from one storm to a different storm because the
magnitude of storm rainfall varies. The Soil Conservation Service approach specifically ignored
storm rainfall-runoff dynamics including changes in rainfall intensity, event duration, infiltration
rates, and runoff hydrographs. Because retention, F, is assumed to be constant for a given rainfall
volume despite varying rainfall intensities and durations and potential maximum retention S
constant for a watershed, the method was not intended to accurately estimate runoff for specific
28
rainfall events. The curve-number-based estimate of runoff is only the typical or average
response to a given rainfall volume (Ponce, 1996). However, the Natural Resource Conservation
Service (2001) handbook encouraged curve number use in developing a rainfall excess interval
for unit hydrographs.
The relation between initial abstraction, Ia , and potential maximum retention, S, has not
been fundamentally defined. The original circa 1954 linear relationship [Equation (2.3)] is
necessary to avoid an independent estimation of initial abstraction, Ia. Equation (2.3) was
justified based on daily measurements of rainfall and runoff on watersheds of fewer than four
hectares (ten acres), but half of the initial abstractions derived from daily observations were
between 0.095 and 0.38 (NRCS, 2001). Despite the large uncertainty, a standard value for the
initial abstraction ratio, λ = 0.2, was adopted by the Soil Conservation Service. Later studies in
the United States and other countries documented initial abstraction ratios varying between 0.00
< λ < 0.38 (Ponce and Hawkins, 1996). Victor Mockus, a pioneer of the curve number method
(Ponce, 1996), agreed with changing the original ratio of λ = 0.2 to 0.1 or 0.3, or any other value,
if the data under consideration warranted. Most troubling, Mockus said that the method was
developed for storm events, but the determination of λ = 0.2 was based on daily measurements of
rainfall and runoff because these were the only data available for the analyses.
As the method is currently practiced, typical event runoff, Q, can be computed with the
curve number based on the land use and cover, hydrologic soil group and condition, and the
rainfall depth by combining Equations (2.1) and (2.2) as
( )SIP
IPQ
a
a
+−−
=2
(2.4)
29
Equation (2.4) is valid for P > Ia and Q = 0 otherwise; no runoff occurs when the rainfall depth is
less than or equal to the initial abstraction, Ia. With initial abstraction included in Equation (2.4),
the actual retention, F = P – Q, asymptotically approaches a constant, S + Ia, as storm event total
rainfall increases.
For λ = 0.2, Equation (2.4) becomes
Q =P − 0.2S( )2
P + 0.8S( ) for P > 0.2S
Q = 0 for P ≤ 0.2S (2.5)
Besides rainfall, P, that is monitored widely in the United States and other countries, Equation
(2.5) contains only one other parameter (potential maximum retention S, which varies between 0
and ∞). For convenience in practical applications, potential maximum retention, S, was defined
in terms of a dimensionless parameter, CN (curve number), which was designed to vary in a
more restricted range of 100 ≥ CN ≥ 0 as follows:
101000
−=CN
S ⇒ 10
1000
+=S
CN (S in inches) (2.6a)
or
254400,25
−=CN
S ⇒254
400,25
+=S
CN (S in millimeters) (2.6b)
The Soil Conservation Service selected 1000 and 10 (in inches) as expressed in Equation (2.6a)
or 25,400 and 254 (in millimeters) in Equation (2.6b) to have the same units as potential
maximum retention, S. Zero potential maximum retention (S = 0 or CN = 100) represents an
impermeable watershed; CN = 0 represents a mathematical upper bound to the potential
maximum retention (S = ∞), which is an infinitely abstracting watershed. According to current
30
practice, specification of an event rainfall depth and the watershed curve number CN should
allow an estimate of watershed runoff using Equations (2.5) and (2.6).
Watershed curve numbers are estimated based on land use, hydrologic condition, and
hydrologic soil group for ungaged watersheds from standard tables (NRCS, 2001) or calculated
by algebraic rearrangement of Equations (2.5) and (2.6) for gaged watersheds as
( ) 105425
1000
21
2 +
+−+
=PQQQP
CN (2.7a)
or
( ) 2545425
400,25
21
2 +
+−+
=PQQQP
CN (2.7b)
Measured pairs of rainfall volume, P, and runoff volume, Q, are used in Equation (2.7) to
determine the curve number CN. The pairs of P and Q are the measured rainfall and direct runoff
from a storm event in inches or millimeters for Equations (2.7a) and (2.7b), respectively.
Study watersheds
Ten small, forested watersheds in the mountains of four eastern states (Figure 2.1)
provided rainfall-runoff measurements, and were located in the Etowah River basin (Georgia),
Coweeta Hydrologic Laboratory (North Carolina), Fernow Experimental Forest (West Virginia),
and Hubbard Brook Experimental Forest (New Hampshire). Long-term records of rainfall and
runoff were available except for the watersheds, Etowah 2 and 3 (Table 2.1). The study includes
four watersheds from the Coweeta Hydrologic Laboratory (Coweeta 2, 28, 36, and 37), and two
watersheds each from the Fernow Experimental Forest (Fernow 3 and 4) and Hubbard Brook
Experimental Forest (Hubbard Brook 3 and 5). The size of watersheds ranges from 12.26 to
31
144.1 hectares (30.29 to 356.1 acres) and elevation ranges from 488 to 1,591.4 meters (1,601 to
5,221 feet).
The Etowah River basin is located in the Blue Ridge Physiographic Province of the north
Georgia. This study complied information from two from total of thirteen forested watersheds
from the northern portion of the Etowah basin within the Chattahoochee National Forest.
Elevation ranges between 451 and 710 meters (1,480 feet to 2,329 feet) and average slope varies
from 10.1 to 12.6 percent. Etowah 2 and 3 soils are fine loam, sandy loam, and sandy.
The Coweeta Hydrological Laboratory is located in the Blue Ridge Physiographic
Province of the southern Appalachian Mountains, near Otto, NC. The Laboratory elevation
ranges from 675 to 1,592 meters (2,215 to 5,223 feet) and average slope ranges between 60.2 to
70.6 percent. The Coweeta soil depth averages approximately 7 m (23 ft) in depth at low to mid
elevations (Coweeta 2) and is much more shallower (<2 m, 6.6 ft) at high elevations (Coweeta
36) (McCutcheon et al., 2006). Of the 17 instrumented watersheds at Coweeta, this study
evaluated four. These four encompassed the range in elevation, vegetation, soil depth, rainfall,
and other climatic factors and hence in hydrologic response found in the Coweeta Hydrological
Laboratory. The soils are inceptisols and ultisols (Typic Hapludults and Humic Hapludults). The
forest cover included northern hardwoods, cove hardwoods, xeric oak and pine, oak and hickory,
and mixed oak (USDA, 2004).
The Fernow Experimental Forest lies in the Allegheny Mountain section of the
unglaciated Allegheny Plateau and had ten experimental watersheds. Fernow elevations range
from 533 to 1,113 meters (1,749 to 3,652 feet) with generally steep slopes. Almost all Fernow
soils (including the sandstone, shale, and limestone soils) are well-drained, medium textured
loams and silt loams characterized by stoniness. Average soil depth to bedrock ranged for the
32
most part from 91 centimeters to 152 centimeters (36 inches to 60 inches) and humus depth
averaged approximately 6 centimeters (2 inches). The forest cover included northern red oak,
chestnut oak, white oak, scarlet oak, black oak, and upland oak (Reinhart et al., 1963).
The Hubbard Brook Experimental Watershed was located in the White Mountain
National Forest. The bowl-shaped Hubbard Brook Valley has hilly terrain, ranging in elevation
from 222 to 1,015 meters (728 to 3,330 feet). The Experimental Forest had seven instrumented
watersheds, two of which were used in this investigation. Soils are predominantly well-drained
spodosols derived from glacial till with a sandy loam texture. Average soil depth, including
unweathered till, was approximately 2 meters (6 feet) from surface to bedrock, although this was
highly variable. Average humus depth of Hubbard Brook is 6.9 centimeters (2.7 inches). The
second-growth forest is even-aged and consists of 80 percent to 90 percent northern hardwoods
and 10 to 20percent spruce (USDA, 2004).
Determination and testing of curve numbers
Five procedures were used to determine gaged watershed curve numbers from rainfall-
runoff series, including the: (1) arithmetic mean (Bonta 1997), (2) median (NRCS, 2001), (3)
geometric mean (NRCS, 2001), (4) standard asymptotic fit (Sneller, 1985; Hawkins, 1993), and
(5) nonlinear least squares fit (Hawkins, 1993). This investigation compared these five curve
numbers calibrated to gaged watersheds with the tabulated curve number based on the
corresponding forested watershed hydrologic soil class and condition (NRCS, 2001). Table 2.2
summarizes these methods and the Appendix provides additional information about how these
procedures were used to determine curve numbers.
33
This study used annual series of maximum rainfall and of maximum runoff volume for
the record available for each watershed (NRCS, 2001) located at Coweeta, Fernow, and Hubbard
Brook. The maximum peak flow of the year and the associated rainfall was the basis of the
annual series for Fernow and Hubbard Brook. The maximum runoff volume of each year of the
record at Coweeta was the basis of these annual series. The Etowah 2 and 3 watersheds,
however, had only 21 months of measured rainfall-runoff and, hence, all storms with 25
millimeters (one inch) or more of total rainfall volume and the corresponding measured runoff
volume are used for partial duration series. Etowah events with rainfall of fewer than 25
millimeters (one inch) produced minimal runoff and thus were not useful for this evaluation.
The five methods to determine a watershed curve number and the Natural Resources
Conservation Service (2001) tabulation produced six estimates for each watershed. This study
used the six curve numbers and the rainfall series for each watershed to generate series of
estimated runoff for comparison with the corresponding series observed runoff of an equal
number. The investigation estimated watershed runoff, Q, using Equations (5) and (7). The
investigation assessed the relative accuracy of the six procedures for calculating runoff from the
rainfall depth in comparison to measured runoff using the coefficient of efficiency or Nash-
Sutcliffe efficiency (Nash and Sutcliffe, 1970)
( )
( )∑
∑
=
=
−
−−=
n
i
ooi
n
i
cioi
NS
E
1
2
1
2
1 (2.8)
and the coefficient of determination
( )
( )∑
∑
=
=
−
−−=
n
i
ooi
n
i
eici
D
1
2
1
2
1 (2.9)
34
where n is the total number of rainfall-runoff events in the period of record (Table 2.1), i is the
number of each event from 1 to n, Qoi is the observed storm runoff, Qci is the computed runoff,
oQ is the mean of the observed runoff, and Qei the estimated runoff obtained from the regression
of Qoi and Qci.
The coefficient of efficiency, ENC, describes the degree of association between the
observed and measured runoff, as does the coefficient of determination. Although a good
measure of the association between the observed and the calculated runoff, the coefficient of
determination does not reveal systematic error (Aitkin, 1973). If the observed and estimated
runoff are highly correlated but biased (not randomly deviating from the perfect correlation of
observed versus estimated runoff), the coefficient of efficiency, ENS, is smaller than the
coefficient of determination D (Aitkin, 1973). Both the coefficient of determination, D, and the
coefficient of efficiency, ENS, is always less than unity and large values may indicate accurate
estimates of runoff volume (Hope and Schulze, 1981; McCuen et al., 2005; Jain and Sudheer,
2008). The coefficient of efficiency for unbiased estimates, based on linear relationships, range
between 0 to 1, corresponding to no or minimal correlation to perfect correlation, respectively.
Yet, linear relationships are rare in hydrology. A negative coefficient of efficiency, ENS, can
occur for biased estimates and establishes that the mean of the series of all observed maximum
annual runoff for a watershed is a better estimate than the runoff calculated with the runoff
equation based on the curve number.
Santhi et al. (2001) used an arbitrary criterion of coefficient of efficiency ENC > 0.5 to
evaluate monthly runoff estimates using the Soil Water Assessment Tool (SWAT), based on the
curve number method. Lim et al. (2006) the coefficient of efficiency ENC = 0.67 “acceptable” for
simulations of annual runoff using the curve number method but used criteria of 0.5 and 0.6 for
35
daily direct runoff calibrations of the curve number. A coefficient of efficiency ENC = 0.51 was
“acceptable” for uncalibrated curve numbers for a watershed that was 68 percent urbanized.
Parajuli et al. (2009) used a coefficient of efficiency ENC = 0.40 solely to decide that SWAT
default curve numbers required calibration. Similar to Moriasi et al. (2007), Parajuli et al. (2009)
classified coefficients of efficiency and determination as excellent (> 0.90), very good (0.75 to
0.89), good (0.50 to 0.74), fair (0.25 to 0.49), poor (0 to 0.24), and unsatisfactory (< 0.0). Sheikh
et al. (2009) deemed a coefficient of efficiency ENC = 0.77 to be evidence that daily discharge
simulations “agreed well” with observations. Lane et al., (2005) introduced an arbitrary
coefficient of efficiency (ENC > 0.7) criterion to indicate adequate agreement between estimated
and observed flow duration curves and number of days of zero-flow but relied upon t tests of the
significance of the differences. Luo et al. (2008) classified SWAT simulations as good (ENC >
0.75), and satisfactory (ENC = 0.36 to 0.75) but also conducted hypothesis testing of correlation.
Rode et al. (2007) and Renaud and Brown (2008) were careful to use the coefficient of
efficiency to compare one model calibration to another. Rode et al. (2007) further noted the
coefficient of efficiency is typically more sensitive to the number of data. McCuen et al. (2005)
derived hypothesis tests and confidence intervals to define significance of magnitudes of the
coefficient of efficiency and notes that the index is sensitive to bias, outliers and in some
situations, number of data. Jain and Sudheer (2008) calculated large coefficients of efficiency,
including values of 0.98, 0.91, 0.86, and 0.64, for four case studies of poor estimates for
discharge rating curves and a rainfall runoff relationship
In addition, this testing used the root mean square error as an index of the variance
between the observed and computed runoff
( )∑=
−−
=n
iieioi QQ
nRMSE
1
2
2
1 (2.10)
36
This statistical testing also compared estimated runoff to measured runoff using the two-tailed
paired Student t-test at the 0.05 significance level. The null and alternative hypotheses
determined if the differences in the estimated and the corresponding measured runoff were
significantly different from zero. Finally, Duncan multiple comparison tests determined
significant differences between the six estimated runoff volumes and the corresponding
observations.
Results of testing curve numbers
Table 2.2 presents the variations of curve numbers for each watershed derived by the five
approaches plus the appropriate curve numbers tabulated by the National Resources
Conservation Service (2001) for ungaged drainages. Table 2.2 also reports the appropriate
measure of the uncertainty for each of the different curve numbers calculated by the six
approaches evaluated by study. The magnitude of the range, the appropriate measure of
uncertainty for the median, varied from 27 (Fernow 4) to 48.5 (Coweta 37) and for the geometric
mean, the 95 percent confidence interval varied from 19.6 (Coweeta 37) to 55.9 (Coweeta 36).
The magnitude for the 95 percent confidence interval for the arithmetic means varied from 23.4
(Coweeta 28) to 50.4 (Coweeta 2).
Figure 2.2 strongly indicates that most of the large uncertainty in determining a single
calibrated curve number for a watershed is due to variation with event rainfall magnitudes. As
the event, rainfall volume increases the curve number decreases for all ten watersheds (four not
shown).
From Table 2.2, 80 percent of the geometric mean curve numbers for the ten watersheds
were greater than curve numbers based on the other estimation procedures. For the exceptions,
37
Etowah 2 and Hubbard Brook 5, the median yielded the largest calibrated curve number. For 40
percent of the watersheds (Table 2.2), the arithmetic mean occurred between the similar-in-
magnitude, geometric mean and median. The curve numbers based on the nonlinear least squares
fit and the asymptote of the standard watershed response were always smaller than the median,
geometric mean, and arithmetic mean curve numbers.
Table 2.3 records the statistics used to test the applicability and accuracy of the curve
number method to estimate runoff from tabulated curve numbers for ungaged watersheds and
from the five approaches to determine calibrated curve numbers for gaged watersheds. Figure 2.3
presents observed runoff Qo versus estimated runoff Qe to illustrate the deviation from the perfect
correlation Qo = Qe for the “best” curve numbers calibrated. Figure 2.4 better illustrated the bias
in runoff estimates based on the “best” curve numbers.
The accuracy of curve numbers (Table 2.3) in estimating runoff comparable to the
observed runoff was investigated using the Nash-Sutcliffe efficiency ENS [Equation (2.9)] and the
coefficient of determination D [Equation (2.8)]. For Etowah 2, Hubbard Brook 3, and Hubbard
Brook 5, a simple average for each one of the observed runoff series was a better estimate of the
runoff than estimates using the tabulated curve numbers (due to the negative Nash-Sutcliffe
efficiencies in Table 2.3). For 60 percent of the watersheds (Coweeta 36, Coweeta 37, Fernow 3,
Fernow 4, Hubbard Brook 3, and Hubbard Brook 5), differences in the Nash-Sutcliffe efficiency
and coefficient of determination (Table 2.3) established runoff bias as indicated in Table 2.2 and
Figure 2.4.
For each watershed listed in Table 2.3, the root mean square error was greatest for the
curve number estimate that was the greatest or smallest. Nevertheless, this measure of bias varied
little between the six approaches to select a curve number for any given watershed. Coweeta 37
38
(third shortest period of record or third fewest degrees of freedom) consistently had the largest
root mean square error for all six approaches; Etowah 3 (next to the smallest degrees of
freedom), consistently the smallest.
In Table 2.3, neither the coefficients of efficiency nor determination indicated that runoff
based on the five methods of calibration and the asymptotic curve number was highly correlated
with observations. The limited correlation may be consistent with the large uncertainty recorded
in Table 2.2 and Figures 2.3 and 2.4. For Coweeta 36, Coweeta 37, and Hubbard Brook 3, little
bias was evident from the similar magnitude of the Nash-Sutcliffe efficiency and the coefficient
of determination. Based on the differences between the coefficients of efficiency and
determination, five of ten runoff estimates based on the asymptotic curve number indicated bias;
30 percent based on the nonlinear least squares; and 10 percent based on the arithmetic mean
curve number. Nevertheless, none of the indications of bias was as severe as the biases of the
tabulated curve numbers for Coweeta 36, Coweeta 37, Fernow 3, Fernow 4, Hubbard Brook 4,
and Hubbard Brook 5. Figure 2.4 for the “best” curve numbers indicated some bias for almost all
of the watersheds. This results provides evidence for the bias in all the observed versus estimated
runoff and is due to lack of an explicit means for soil moisture accounting.
Table 2.4 listed the best curve numbers calibrated for each of the ten watersheds with one
of five methods tested. The paired Student t-test established that none of the estimated runoff
based on the best curve number differed from observed with a 0.05 chance of error.
The Duncan multiple comparison tests in Table 2.5 established that the estimated runoff
based on the tabulated curve number (TQ) was significantly different from the observed runoff
from Coweeta 36, Coweeta 37, Fernow 3, Fernow 4, Hubbard Brook 3, and Hubbard Brook 5.
Using the means in Table 2.5, the runoff estimates based on the geometric mean curve number
39
was ranked first or second for all ten watersheds. The median ranked first for Etowah 2 and
Hubbard Brook 5. Regardless of the rankings, the multiple comparison tests (Table 2.5) revealed
no significant difference (at the 0.05 percent level of significance) in using the median,
geometric mean, and arithmetic mean curve numbers to estimate runoff for all ten watersheds.
Sneller (1985) suggested an arbitrary, unproven criterion to determine whether the
standard asymptotic fit to watershed curve numbers was adequate [Equation (A-9); the measured
range of rainfall covers 90 percent of the slopes of the rainfall-curve number watershed
response]. Table 2.6 showed that the rainfall records should be suitable to determine standard
asymptotic curve numbers according to Sneller (1985), except for Fernow 3 and Fernow 4,
because the maximum rainfalls recorded for each watershed were greater than 58.496/k
millimeters or 2.303/k inches for the length of record used in this study. The constants k and the
asymptotic curve number arose from fitting the empirical curve number-rainfall relationship to
the observed event rainfalls and estimated curve numbers [see Equations (A-6) to (A-14)].
Accuracy and applicability of curve numbers
For Etowah 2 and the Hubbard Brook watersheds, the estimated runoff based on the
tabulated curve numbers (NRCS, 2001) was so poor that the average of the series of observed
runoff for these drainages provided better estimates. Runoff estimated for the tabulated curve
numbers for six of the ten watersheds was significantly smaller than the observed as noted in
Table 2.5. Only the tabulated curve numbers for Coweeta 2, Coweeta 28, and Etowah 3 provided
adequate runoff estimates. Seventy percent of the tabulated curve numbers resulted in less
estimated runoff compared to the extensive observations of up to 68 years of record. The smaller
Nash-Sutcliffe efficiencies compared to the coefficient of determination for the higher elevation
40
Coweeta 36 and Coweeta 37, Fernow, and Hubbard Brook and Figure 2.3, establish that
estimated runoff only marginally correlates to observed runoff and may be biased (Aitkin, 1973;
McCuen et al., 2005).
The reason for the biased tabulated curve numbers for the National Resources
Conservation Service (2001) land use category “woods” is difficult to determine. The original
watershed rainfall-runoff measurements used in circa 1954 to estimate the tabulated curves for
“woods” is missing (Hawkins, 2006) and this investigation could not confirm the accuracy of the
table or the degree of uncertainty associated with each entry. The only possible sources of error
to contemplate were the assigned soil hydrologic group and the selected hydrologic condition of
good.
One source of early concern for the field of hydrology in using the curve number method
was that many soils may be misclassified, especially those in the Groups B and C (Neilsen and
Hjelmfelt, 1998). Nevertheless, the likelihood of misclassification at these national experimental
forests is limited and cannot explain all of these large discrepancies in curve numbers. If the
higher elevation Coweeta 36 and 37 soils were hypothetically in Group C, not B for example, the
curve number 70 for woods would better agree with curve numbers determined from rainfall-
runoff measurements. As recently as 2005, a U.S. Department of Agriculture soil scientist
reexamined the Fernow soils and changed the hydrologic group from B to C, a curve number
change from 55 to 70. However, even a change to Group D (77) would not match curve number
calibrations for the Fernow and Hubbard Brook rainfall-runoff observations. Moreover, Group D
is definitely not consistent with the National Engineering Handbook (NRCS, 2001) guidance,
especially for steep mountain forests where high water tables and waterlogged soils are rare
outside of a few landslide-prone areas.
41
Several independent personal observations of the good hydrologic conditions maintained
and expected in national forests and experimental forests puts this specification beyond doubt for
the curve number procedure as written (NRCS, 2001). As a result, neither selection of soil
hydrologic group nor hydrologic condition explained all of the severe bias of the woods land-use
category in consistently underestimating runoff. If the curve number method consistently
underestimated runoff from undeveloped forest, the effect of urbanization will be consistently
overestimated and drainage controls overestimated, perhaps to explain part of the annual
overdesign costs estimated to be as great as $2 billion per year (Schneider and McCuen, 2005).
Because the tabulated curve numbers were unreliable, the next important question was,
can an engineer or hydrologist calibrate the watershed curve number from gage data and
extrapolate to a similar ungaged watershed? Prior to addressing this issue, this investigation
examined the procedures to derive a watershed curve number from series of rainfall-runoff
observations (for which standardization is lacking).
The calculation of watershed curve numbers from rainfall-runoff measurements had
precedent but lacked justification and rationale. The Natural Resources Conservation Service
(2001) based the tabulated curve numbers on the median—easily determined graphically from
rainfall P versus runoff Q. Later citing Yuan (1933) as the only proof, the Natural Resources
Conservation Service (2001) designated the geometric mean as the appropriate way to express
the watershed curve number and calculate 95 percent confidence intervals. The geometric mean
closely approximates the median if the distribution of curve numbers determined for a watershed
is lognormal (Yuan, 1933) but proof of this curve number lognormality did not appear in the
literature. Nevertheless, Tables 2.2, 2.3, and 2.5 indicated that the distribution was approximately
lognormal for these ten mountainous watersheds because the runoff estimated from the median
42
and geometric mean curve numbers was not significantly different. However, because the
arithmetic mean curve number falls between the median and geometric mean for 40 percent of
the watersheds, statistical proof of the lognormal distribution as the best fit may not be possible
for these observations. Bonta (1997) seemed to be the first to calculate the arithmetic mean curve
number but also did not justify this choice with proof that the curve number distributions were
normal.
Unlike the means and median, some of the nonlinear least squares fit and asymptotic
curve numbers produced significantly different runoff estimates as noted in Table 2.5. Forty
percent of the watersheds had runoff estimated based on the asymptotic curve number
significantly different from observations. The asymptotic curve numbers for the Etowah
watersheds estimated unsatisfactory runoff due to negative coefficients of efficiency. Using the
nonlinear-least-squares-fit curve number, Etowah 2 had the only unsatisfactory estimated runoff.
Coweeta 2 was a watershed for which none of the calibrated curve numbers produced
runoff estimates significantly different from the observed. Yet the runoff estimated using the
nonlinear least squares fit and asymptotic curve numbers was significantly different from that
estimated using the means and median.
The asymptotic curve number based runoff was significantly different from the estimated
runoff based on geometric mean curve number for Coweeta 36 but not significantly different
from the observed runoff. For Fernow, estimated runoff from both watersheds was significantly
different from that estimated with the asymptotic curve versus the estimated with means and
median and versus the measured. Also for Fernow, the estimated runoff based on the nonlinear-
least-squares-fit curve number was significantly different from that based on the geometric mean
but not the observed. For Etowah 2, Etowah 3, Coweeta 28, Coweeta 37, Hubbard Brook 3, and
43
Hubbard Brook 5, the t-test did not resolve any differences in runoff estimates and the observed,
which indicated some lack of robustness in the t-test. That estimated runoff based on the
asymptotic curve number was not significantly different for all ten watersheds seemed to be a
reflection of the high degree of variance of event curve numbers (Tables 2.2 and 2.4) from the
single watershed curve number based on central tendencies, minimization of least squares, and
the asymptotic limit. The nonlinear-least-squares-fit curve number was always smaller that the
watershed curve numbers derived from central tendencies on all ten watersheds, but these four
methods to calibrate the curve number never produce runoff that was significantly different from
the observed. (However, Etowah 2 runoff estimates were unsatisfactory based on the nonlinear
least squares fit.) Therefore, the Duncan multiple comparison tests did not distinguish any
advantage to choosing the median, geometric mean, arithmetic mean, or nonlinear-least-squares-
fit curve numbers; all are equally capable of estimating runoff to at least within a five percent
chance of error for these small mountainous-forested watersheds. Nevertheless, coefficient of
efficiency for Etowah 2 indicated some lack of robustness in the t-tests.
Using the Nash-Sutcliffe efficiency in Table 2.4 to rank these equally valid methods, the
median ranked best for 70 percent of the watersheds. Nevertheless, any of the other three
methods provided better estimates of the great uncertainty (as 95-percent confidence intervals
versus the range of curve numbers) in single-value watershed curve numbers.
Even after the adoption of the method for urban hydrology (SCS, 1975) and use with
well-defined design rainfalls (e.g., 10-year and 100-year rainfall return intervals), the
inconsistency with using curve numbers based on return intervals of two years were not
explicitly noted until recently (McCutcheon et al., 2006). (The median, geometric mean, and
arithmetic mean curve numbers by definition have a return interval of two years or a probability
44
of occurrence of 50 percent if now skew is present.) Further, after Sneller (1985) and Hawkins
(1993) noted that watershed curve numbers are typically a function of storm event rainfall
volume (Figure 2.2), the implied assumption of lognormality and adequacy of the median or
geometric mean curve numbers have never been examined. The probabilistic approaches of
Hjelmfelt (1980), Pilgrim and Cordery (1993), and Titmarsh et al. (1995) seem to recognize that
watershed curve numbers varied as return intervals before McCutcheon et al. (2006) noted the
need to calibrate curve numbers for specific design return intervals. Because each measured
rainfall volume has a frequency of occurrence, McCutcheon et al. (2006) could relate a return
interval to a variable watershed curve number as Titmarsh et al. (1995) and Pilgrim and Cordery
(1993) accomplished differently earlier.
The finding that all ten mountainous-forested watershed curve numbers varied with event
rainfall explained several issues involving the curve number method. Firstly, the standard (or
perhaps complacent for Fernow) responses clearly explains in Table 2.2 why the asymptotic
curve numbers associated with infinitely or very large rainfall was always less than the geometric
mean, arithmetic mean, and median associated with a two-year return interval. Secondly, the
variability with event rainfall explained much but not all of the large uncertainty in calibrated
curve numbers. Finally, this large variability for forested watersheds with event rainfall
explained why a single watershed curve number was difficult to select. As Titmarsh et al. (1995)
and McCutcheon et al. (2006) noted, many watersheds seem to require a variable curve number
that is different for different design intervals, not the single watershed curve number that Mockus
and the Soil Conservation originally conceived (Ponce, 1996; NRCS, 2001).
The wide differences in magnitudes of ranges and 95-percent confidence intervals
indicated that the response of a watershed depends on the range of maximum annual rainfall,
45
antecedent moisture, rainfall intensity, and type of seasons (dormant or growing). Variable
source areas responsible for runoff generation vary in size depending on the magnitude of
rainfall, which results the amount of rainfall influence the values of curve number. For all
watersheds, the curve number values decrease as the magnitude of rainfall increase (Figure 2.2).
In addition, the curve number method lacks a method that considers initial moisture content of
the soil because the preexisting condition affects the rate of runoff generation.
This investigation could not distinguish between any of the methods of calibrating a
singular watershed curve number from rainfall-runoff measurements and a central-tendency-
based curve number. The exception was that the asymptotic curve number produced
unsatisfactory or different estimates of runoff than observed for 60 percent of the watersheds.
One estimate based on the nonlinear least squares fit was unsatisfactory, but this was for Etowah
2 for which only 21 months of observations were available and variability of rainfall events
greater than 25 millimeters (1 inch) may have been different than the variability for the other
series of annual maximum runoff. Although this investigation could not rule out use of calibrated
curve numbers with a 2-year return interval for a singular watershed curve number mountainous
forests, these can only be resorted to when a practitioner expects limited curve number
variability. For high variability in mountainous-forested watershed curve numbers the
practitioner should estimated the curve numbers for the asymptotic limit (infinite return interval)
and 10-year, 100-year, and other design return intervals.
Limited uses and additional investigation necessary
Although the curve number method was widely used for estimating runoff depths or
volumes, practitioners may have only poorly understood the limitations and uncertainties,
46
especially for ungaged forested watersheds of the mountainous eastern United States. The
Natural Resource Conservation Service (2001) tabulated curve numbers based on ungaged
watershed characteristics were not adequate to estimate runoff from ten small forested
watersheds in the mountainous eastern United States. Most of the runoff estimated from the
tabulated curve numbers was unreliable. Even the misclassification of the soil hydrologic group
was not adequate to explain the significant bias in runoff estimates. Therefore, practitioners
should not use the current Natural Resource Conservation Service (2001) tabulations for
“woods” to estimate runoff for designs and careful policy analysis involving forested watersheds.
At best, engineers and hydrologist must confirm estimated runoff from mountainous-forested
eastern watersheds with independent runoff estimates if the practitioner cannot calibrate curve
numbers with rainfall-runoff measurements collected from very similar watersheds prior to use
in design calculations or for policy deliberations.
For models that use the curve number as a lumped parameter, the same effective
guidance holds. Model applications should only use tabulated curves as initial values in a careful
calibration procedure. Applications used in policy determinations and design should carefully
evaluate calibrations and model tests for goodness of fit and bias (McCuen et al., 2005).
Of the five calibration procedures, only the asymptotic curve number was unreliable as a
singular estimate of a mountainous-forested watershed curve number. Additional investigation is
necessary to confirm fully the use of the nonlinear least squares fit. The Duncan multiple
comparison tests were not sufficiently robust to distinguish between calibrated curve numbers
based on the median, geometric mean, or arithmetic mean for mountain-forested watersheds.
Therefore, the geometric mean with the 95-percent confidence interval recommended by the
Natural Resource Conservation Service (2001) seems best to provide an estimate of the
47
uncertainty involved with each calibration. The 95-percent confidence interval or a similar
expression of uncertainty is necessary to support a decision on whether use to the 2-year curve
number as a crude approximation of a singular watershed curve number for a continuum of
design return intervals. For large uncertainties of +1or greater, calibrated curve numbers should
be matched to the design return intervals of interest by taking the variability of curve numbers
with event rainfall into account.
The likelihood of simply updating the Natural Resource Conservation Service (1998,
2001) table of curve numbers seems remote despite a call by Schneider and McCuen (2005). The
original information on which the Soil Conservation Service based the table has been lost for the
most part and the original concept that a single lumped index for each watershed largely refuted
(Hawkins, 1993). In addition, the current tabulation is very specific to original assumption that
the initial abstraction was twenty percent of the potential maximum retention. More productive
would seem to be a derivation of a new simplified method to correct the residual effect of the
curve number varying with the state variable, event rainfall. A new derivation could be tailored
to modern web-based computing and advances in remote sensing including uses of digital
elevation models and geographic information systems.
Acknowledgments
Financial assistance provided in part by (1) the West Virginia Division of Forestry, (2)
the U.S. Geological Survey through the Georgia Water Resources Institute, and (3) Warnell
School of Forest and Natural Resources. Richard Hawkins of the University of Arizona, Tucson
provided insightful background and guidance on the use, interpretation, and limitations of the
curve number method. The watershed characteristics and rainfall-runoff series required for this
48
study were provided by Wayne Swank and Stephanie Laseter from the U.S. Forest Service
Coweeta Hydrologic Laboratory; Frederica Wood, from the U.S. Forest Service Fernow Timber
and Watershed Laboratory; John Campbell, from the U.S. Forest Service Hubbard Brook
Experimental Forest; and Josh Romeis from the University of Georgia Etowah Research Project.
References
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54
Table 2.1 Characteristics of ten small, forested watersheds in the mountains of the eastern United States
Watershed
Period
of
record
(years)
Area
(hectares)
Hydrologic
soil group Dominant aspect
Elevation
range
(meters)
Channel
length
(meters)
Ave-
rage
slope
(%)
Annual
rainfall
(millimeters)
Etowah 2 <2 28.0 C: 50.6 %, B: 49.4 %
East by southeast 451 to 524 541 10.1 1448*
Etowah 3 <2 31.0 C: 48.3 %, B: 51.7 %
Southeast 518 to 710 600 12.6 1448*
Coweeta 2 68 12.3 B South by southeast 709 to 1004 392 60.2 1812
Coweeta 28 29 144.1 B East 964 to 1551 3923 52.2 2340
Coweeta 36 59 46.6 B East by southeast 1021 to 1542 1327 65.3 2015
Coweeta 37 37 108.0 B East by northeast 1033 to 1591 1257 70.6 2015
Fernow 3 53 34.3 C South 730 to 860 714 20.6 1450
Fernow 4 53 38.7 C East by southeast 740 to 865 683 20.6 1450
Hubbard Brook 3 48 42.4 A: 39.9 %, B: 39.9 %, C: 20.2 %
Southwest 527 to 732 961 27.5 1370
Hubbard Brook 5 43 21.9 A: 48.8 %, B: 48.8 %, C: 2.4 %
Southeast 488 to 762 1265 27.5 1370
*Source: http://pubs.usgs.gov/wri/wri934076/stations/02389000.html
55
Table 2.2 Estimated curve numbers for gaged and ungaged watersheds by all procedures and with estimates of uncertainty
Watershed Tabulated
(range)
Median
(range)
Geometric
mean
(95 %
confidence
interval)
Arithmetic
mean ± 95
% extreme
Nonlinear least
squares fit
(± SE)*
Standard
asymptotic
(r2, SE)**
Etowah 2 62.6
(43, 80) 67.3
(39.9 to 85.4) 66.3
(42.7 to 73.9) 65.6 ± 19.5
55.0 (45.1, 64.9)
62.6 (0.26, 2.25)
Etowah 3 62.2
(42, 79) 61.4
(34.3 to 77.3) 62.0
(37.7 to 74.2) 71.1 ± 18.3
40.4 (33.1, 47.7)
37.5 (0.85, 3.89)
Coweeta 2 55
(35, 74) 58.0
(32.3 to 88.7) 58.2
(30.8 to 81.3) 57.5 ± 25.2
45.8 (32.5, 59.1)
50.3 (0.74, 0.708)
Coweeta 28 55
(35, 74) 60.6
(37.3 to 88.8) 61.2
(34.4 to 82.6) 60.3 ± 11.7
56.5 (45.0, 68.0)
53.9 (0.76, 1.42)
Coweeta 36 55
(35, 74) 71.5
(55.2 to 99.1) 75.1
(37.8 to 93.7) 72.5 ± 21.5
68.1 (56.8, 79.4)
63.5 (0.63, 1.46)
Coweeta 37 55
(35, 74) 71.7
(50.7 to 99.2) 75.3
(62.3 to 81.9) 73.1 ± 19.2
70.2 (60.5, 79.9)
66.6 (0.598, 1.50)
Fernow 3 70
(51, 85) 83.9
(62.5 to 99.2) 88.7
(48.4 to 98.7) 85.1 ± 16.9
82.6 (74.3, 90.9)
73.1 (0.90, 1.93)
Fernow 4 70
(51, 85) 84.2
(71.5 to 98.5) 89.8
(49.4 to 98.4) 86.5 ± 14.7
84.0 (76.9, 91.1)
72.7 (0.91, 2.04)
Hubbard Brook 3 46
(27, 66) 83.7
(57.4 to 98.7) 84.9
(55.9 to 96.0) 82.6 ± 19.3
81.9 (72.1, 91.7)
82.7 (0.0008, 0.302)
Hubbard Brook 5 41
(23, 61) 84.1
(58.2 to 97.2) 84.0
(55. to 95.7) 81.7 ± 19.8
80.9 (70.9, 90.9)
81.6 (0.15, 0.566)
* SE is the standard error of curve numbers] ** r2 is the Pearson correlation coefficient and SE is the standard error of the curve number
56
Table 2.3. Nash-Sutcliffe efficiency (ENS), coefficient of determination (D), and root mean square error (RMSE) based on the
comparison of measured runoff and runoff estim
ated using the curve numbers from the six approaches listed in the table
NRCS TABULATED
MEDIA
N
GEOMETRIC M
EAN
ARITHMETIC M
EAN
STANDARD
ASYMPTOTIC
NONLIN
EAR LIST
SQUARES FIT
WATERSHED
ENS
D
RMSE
ENS
D
RMSE
ENS
D
RMSE
ENS
D
RMSE
ENS
D
RMSE
ENS
D
RMSE
ETOWAH 2
-0.0956
0.1083
0.3017
0.0590
0.1337
0.2974
0.0360
0.1287
0.2983
0.0171
0.1250
0.2989
-0.0956
0.1083
0.3017
-0.7150
0.0527
0.3110
ETOWAH 3
0.0985
0.1412
0.0839
0.1006
0.1398
0.0840
0.0990
0.1409
0.0839
0.0998
0.1403
0.0839
-0.5000
0.0083
0.0901
-0.3390
0.0113
0.0900
COWEETA 2
0.3725
0.3768
0.4699
0.3619
0.3817
0.4680
0.3606
0.3819
0.4679
0.3649
0.3809
0.4683
0.3289
0.3659
0.4740
0.1729
0.3486
0.4804
COWEETA 28
0.5559
0.6402
0.8345
0.6045
0.6297
0.8466
0.6007
0.6286
0.8478
0.6059
0.6302
0.8460
0.4982
0.6439
0.8302
0.5863
0.6373
0.8379
COWEETA 36
0.4573
0.7739
0.7798
0.7733
0.7890
0.7534
0.7436
0.7904
0.7509
0.7678
0.7894
0.7526
0.7140
0.7840
0.7622
0.7721
0.7872
0.7565
COWEETA 37
0.3904
0.7644
1.0013
0.7778
0.7780
0.9720
0.7617
0.7794
0.9689
0.7755
0.7786
0.9707
0.7365
0.7729
0.9832
0.7741
0.7773
0.9736
FERNOW 3
0.2171
0.6205
0.4559
0.6111
0.6125
0.4607
0.5568
0.6077
0.4636
0.6092
0.6114
0.4614
0.3230
0.6199
0.4563
0.6029
0.6137
0.4600
FERNOW 4
0.2684
0.7559
0.3625
0.7240
0.7432
0.3718
0.6622
0.7341
0.3784
0.7219
0.7396
0.3744
0.3660
0.7553
0.3630
0.7225
0.7434
0.3716
HUBBARD BROOK 3
-0.4537
0.6366
0.8329
0.7323
0.7478
0.6938
0.7308
0.7475
0.6942
0.7286
0.7480
0.6942
0.7292
0.7479
0.6936
0.7239
0.7480
0.6935
HUBBARD BROOK 5
-0.5928
0.5162
0.9360
0.6784
0.7069
0.7286
0.6787
0.7069
0.7286
0.6744
0.7082
0.7269
0.6737
0.7083
0.7268
0.6678
0.7085
0.7265
57
Table 2.4 Representative watershed curve numbers (CN), uncertainty, and paired Student t-tests of curve-number-based estimates of runoff versus measured
Watershed
Curve number
estimation
procedure*
CN Uncertainty Degrees of
freedom t statistic Probability < |t|
Etowah 2 Median 67.3 39.9 to 85.4** 13 -0.6556 0.5235
Etowah 3 Median 61.4 34.3 to 77.3** 16 -0.8655 0.3996
Coweeta 2 Tabulated 60.3 35.0 to 74.0** 67 -0.9693 0.3359
Coweeta 28 Arithmetic mean 60.3 48.6 to 72.0*** 28 -0.9498 0.3503
Coweeta 36 Median 71.5 55.2 to 99.1** 58 -0.5022 0.6174
Coweeta 37 Median 71.7 50.7 to 99.2** 36 0.0203 0.9839
Fernow 3 Median 83.9 62.5 to 99.2** 52 0.5046 0.6160
Fernow 4 Median 84.2 76.5 to 98.9** 52 1.6548 0.1040
Hubbard Brook 3 Median 83.7 57.4 to 98.7** 47 -0.4725 0.6387
Hubbard Brook 5 Geometric mean 84.0 80.8 to 86.7*** 42 -1.1654 0.2504
* Procedures selected based on the ranking of coefficients of efficiency (Table 2.3) ** Range *** 95 percent confidence interval
58
Table 2.5 M
ultiple comparisons of runoff volumes determined using six curve number procedures from watershed characteristics
(tabulated curve number) and m
easured rainfall and runoff
Coweeta 2
Coweeta 28
Coweeta 36
Coweeta 37
Fernow 3
Duncan
grouping
Mean
N
Method
Duncan
grouping
Mean
N
Method
Duncan
grouping
Mean
N
Method
Duncan
grouping
Mean
N
Method
Duncan
grouping
Mean
N
Method
A
0.965
68
GMQ
A
2.21
29
GMQ
A
3.14
59
GMQ
A
3.87
37
GMQ
A
1.80
53
GMQ
A
0.955
68
MQ
A
2.16
29
MQ
A
B
2.92
59
AMQ
A
3.66
37
AMQ
A
B
1.55
53
AMQ
A
0.930
68
AMQ
A
2.14
29
AMQ
A
B
2.83
59
MQ
A
3.53
37
OBQ
A
B
1.51
53
OBQ
A
B
0.812
68
TQ
A
1.98
29
OBQ
A
B
2.77
59
OBQ
A
3.53
37
MQ
A
B
1.47
53
MQ
A
B
C
0.727
68
OBQ
A
1.84
29
LSQ
A
B
2.55
59
LSQ
A
3.39
37
LSQ
B
1.399
53
LSQ
B
C
0.611
68
ASQ
A
1.72
29
TQ
B
C
2.19
59
ASQ
A
B
2.74
37
ASQ
C
0.882
53
ASQ
C
0.446
68
LSQ
A
1.58
29
ASQ
C
1.57
59
TQ
B
2.05
37
TQ
C
0.748
53
TQ
Fernow 4
Etowah 2
Etowah 3
Hubbard Brook 3
Hubbard Brook 5
Duncan
grouping
Mean
N
Method
Duncan
grouping
Mean
N
Method
Duncan
grouping
Mean
N
Method
Duncan
grouping
Mean
N
Method
Duncan
grouping
Mean
N
Method
A
1.696
53
GMQ
A
0.321
14
MQ
A
0.187
17
TQ
A
1.72
48
GMQ
A
1.68
43
MQ
A
B
1.464
53
AMQ
A
0.299
14
GMQ
A
0.184
17
GMQ
A
1.64
48
MQ
A
1.67
43
GMQ
A
B
1.425
53
OBQ
A
0.283
14
AMQ
A
0.179
17
AMQ
A
1.59
48
OBQ
A
1.54
43
OBQ
A
B
1.34
53
MQ
A
0.239
14
OBQ
A
0.176
17
ASQ
A
1.58
48
ASQ
A
1.52
43
AMQ
B
1.31
53
LSQ
A
0.225
14
ASQ
A
0.175
17
MQ
A
1.57
48
AMQ
A
1.51
43
ASQ
C
0.7435
53
ASQ
A
0.225
14
TQ
A
0.131
17
LSQ
A
1.53
48
LSQ
A
1.47
43
LSQ
C
0.6387
53
TQ
A
0.188
14
LSQ
A
0.0821
17
OBQ
B
0.204
48
TQ
B
0.145
43
TQ
Notes: (1) Means with the same Duncan grouping letter (A
, B, or C) were not significantly different at a probability of 0.05. (2) N was the number of pairs of
rainfall-runoff observations. (3) Abbreviations for the methods were TQ is the runoff estim
ated using the Natural Resource Conservation Service (2001)
tabulated curve number, MQ is the runoff estim
ated using the median curve number, GMQ is the runoff estim
ated using the geometric mean, AMQ is the runoff
estimated using the arithmetic m
ean, LSQ is the runoff estim
ated using the nonlinear-least-squares-fit curve number, ASQ is the runoff estim
ated using the
asymptotic curve number,,and OBQ is the observed runoff.
59
Table 2.6 Tests of standard asymptotic watershed responses for ordered (and matched in frequency) rainfall and runoff series
Maximum rainfall Pmax*
Constant k** 58.496 k-1 2.303 k
-1
Watershed
(millimeters) (inches) (inch-1) (millimeters -1) (millimeters) (inches)
Etowah 2 126 4.97 1.53 38.9
38.3 1.51
Etowah 3 150 5.90 0.50 12.7
116 4.56
Coweeta 2 239 9.41 0.60 15.2
96.7 3.81
Coweeta 28 245 9.65 0.40 10.2
146 5.76
Coweeta 36 315 12.4 0.28 7.1
205 8.08
Coweeta 37 318 12.5 0.30 7.6
196 7.70
Fernow 3 162 6.38 0.29 7.4
202 7.94
Fernow4 162 6.38 0.26 6.6
223 8.79
Hubbard Brook 3
213 8.39 2.10 53.3
27.8 1.09
Hubbard Brook 5
213 8.39 1.81 46.0
32.3 1.27
* Maximum rainfall observed during the period of record ** k is a constant [L-1] used to fit curve number-rainfall relationships to determine the asymptotic curve numbers [see Equations (A-6) to (A-14)]
60
Figure 2.1 Locations of watersheds used in this study to evaluate the curve number method in mountainous-forested eastern watersheds
61
30
40
50
60
70
80
90
100
0 40 80 120 160 200 240
Rainfall volume (millimeters)
Curve number
CN(P) = 50.3 + (100-50.3) * EXP(-0.6049*P)
CNO = 100 / (1+P/2)
50
60
70
80
90
100
0 2 4 6 8 10 12
Rainfall (inches)
Curve number …..
CN(P) = 63.5 + (100-63.5) * EXP(-0.2515*P)
CNO = 100 / (1+P/2)
Coweeta 36
60
70
80
90
100
0 40 80 120 160 200 240 280 320
Rainfall (millimeters)
Curve number
CN(P) = 66.6 + (100 - 66.6) * EXP(-0.299*P)
CNO = 100 / (1+P/2)
40
50
60
70
80
90
100
0 50 100 150 200 250 300
Rainfall (millimeters)
Curve number
CN(P)=53.9+(100-53.9)*EXP(-0.4001*P)
CNO = 100 / (1+P/2)
70
75
80
85
90
95
100
0 40 80 120 160
Rainfall (millimeters)
Curve number
CN(P) = 72.7 + (100-72.7) * EXP(-
0.2620*P)
CNO = 100 /
(1+P/2)
70
75
80
85
90
95
100
0 40 80 120 160 200
Rainfall (millimeters)
Curve number
CN(P)=81.58+(100-81.58)*EXP(-1.8101P)
CNO = 100/ (1+P/2)
Figure 2.2 Asymptotic curve number fit for selected watersheds estimated based on ordered rainfall and runoff series
Coweeta 2
Coweeta 28
Coweeta 37
Coweeta 28
Hubbard Brook 5
Coweeta 28
Coweeta 28
Fernow 4
62
0
1
2
3
4
5
0 1 2 3 4 5
Measured runoff volume in inches
Estim
ated runoff volume in inches……….
1:1
0
10
20
30
40
50
0 10 20 30 40 50
Measured runoff in millimeters
Estimated runoff in m
illimeters.
1:1
Etowah 2
0
20
40
60
80
100
0 20 40 60 80 100
Measured runoff in millimeters
Estimated runoff in m
illimeters.
1:1
Fernow 4
0
50
100
150
200
250
0 50 100 150 200 250
Measured runoff in millimeters
Estimated runoff in m
illimeters
1:1
Coweeta 36
0
20
40
60
80
100
120
0 20 40 60 80 100 120
Measured runoff in millimeters
Estimated runoff in m
illimeters.
1:1
Fernow 3
0
30
60
90
120
150
180
0 30 60 90 120 150 180
Measured runoff in millimeters
Estimated runoff in m
illimeters
1:1
Hubbard Brook 3
Figure 2.3 Relation between measured and estimated runoff. Median curve number of 67.3 for Etowah 2; median curve number of 61.4 for Etowah 3; arithmetic mean curve number of 57.4 for Coweeta 2; median curve number of 71.5 for Coweeta 36; median curve number of 71.7 for Coweeta 37; median curve number of 83.9 for Fernow 3; median curve number of 84.2 for Fernow 4; median curve number of 83.7 for Hubbard Brook 3; and geometric mean curve number of 84 for Hubbard Brook 5.
63
-80
-60
-40
-20
0
20
40
60
80
0 50 100 150 200 250
Rainfall in millimeters
Error in m
illimeters
Coweeta 2
-80
-60
-40
-20
0
20
40
60
80
0 50 100 150 200 250
Rainfall in millimeters
Error in m
illimeters
Coweeta 36
-60
-40
-20
0
20
40
60
0 25 50 75 100 125
Rainfall in millimeters
Error in m
illimeters
Etowah 2
-60
-40
-20
0
20
40
60
0 25 50 75 100 125 150
Rainfall in millimeters
Error in m
illimeters
Fernow 3
-30
-20
-10
0
10
20
30
0 25 50 75 100 125 150
Rainfall in millimeters
Error in m
illimeters
Fernow 4
-60
-40
-20
0
20
40
60
0 25 50 75 100 125 150 175 200
Rainfall in millimeters
Error in m
illimeters
Hubbard
Brook 3
Figure 2.4 Error (measured minus estimated runoff) as a function of rainfall. Median curve number of 67.3 for Etowah 2; median curve number of 61.4 for Etowah 3; arithmetic mean curve number of 57.4 for Coweeta 2; median curve number of 71.5 for Coweeta 36; median curve number of 71.7 for Coweeta 37; median curve number of 83.9 for Fernow 3; median curve number of 84.2 for Fernow 4; median curve number of 83.7 for Hubbard Brook 3; and geometric mean curve number of 84 for Hubbard Brook 5.
64
CHAPTER 3
EFFECTS OF SEASONAL VARIATION AND FOREST HARVESTING ON
RUNOFF FROM TEN, SMALL, MOUNTAINOUS, FORESTED
WATERSHEDS IN THE EASTERN UNITED STATES2
2 Negussie Tedela, Steven McCutcheon, Todd Rasmussen, Rhett Jackson, Earnest W. Tollner, Wayne Swank, John
Campbell, and Mary B. Adams. To be submitted to the Journal of the American Water Resources Association.
65
Abstract
Dormant and growing seasons should affect runoff-rainfall relationships for deciduous
forests. However, the Natural Resource Conservation Service curve number method does not
explicitly consider seasonal variation in estimating runoff. In addition, many studies indicate that
streamflow increases after forest harvest because of the decreases in evapotranspiration. No
evidence exists, however, that resulting streamflow increases can be translated to a difference in
curve numbers between the preharvest and hydrologic effect periods. This study evaluated the
effects of seasonal variation and forest harvest practices on curve numbers derived using annual
maximum series of observed rainfall and runoff for forested watersheds. The investigation used
three pairs of watersheds, including three with undisturbed forest cover, to investigate these
effects. The analysis partitioned observed rainfall and runoff according to the dormant and
growing seasons and separately into preharvest and hydrologic effect periods. Curve numbers
calibrated for the growing seasons seem to be smaller than those for the dormant seasons for all
watersheds. the variances of growing-season curve numbers for three of the six watersheds were
significantly different from that of the dormant season with transition periods included, while
four of the six watersheds showed significant difference when the transition periods were
excluded from the analysis. Curve numbers specific to the growing and dormant seasons are
recommended for each watershed. The paired studies suggest that forest harvesting would
definitely increase streamflow and curve numbers. However, the increase in curve number is not
significant for some of the treatments because of the effect on curve number is much more
variable than the effect on total annual flow and may even be inverted in some years or in some
seasons. In most cases, the periods of clearcutting effects are too short to accurately relate any
66
forest management practice to changes in curve numbers compared to longer preharvest and
control watershed records.
Keywords: Curve number, dormant and growing seasons, forest harvesting, runoff-rainfall
relationship, watershed, forest, runoff modeling, hydrology, gaged watersheds,
ungaged watersheds,
Forested watershed response to seasons and harvest
The curve number method is widely used for estimating runoff because of the
convenience and simplicity. The effect of seasonal variation on runoff volume has not been
explicitly incorporated in the curve number method and as a result ignores the impact of seasonal
variation of evapotranspiration and interception. The method uses a constant value of initial
abstraction (Ia) equaling 20 percent of the potential maximum retention, which is may not be
appropriate for both dormant and growing seasons. Jacobs and Srinivasan (2005) pointed out a
need for seasonal applications of the method. Runoff estimation with annually consistent
parameters has limited application because watershed response varies substantially between
seasons. For example, the seasonal tank model by Paik et al. (2005) successfully simulated
runoff with less error compared to the non-seasonal model. In the southeastern United States,
more than half of the land area is forested, and evapotranspiration from forested watersheds can
vary from 85 percent of annual rainfall in coastal Florida to 50 percent in the cool southern
Appalachian Mountains (Sun et al., 2002). In general, forests have larger evapotranspiration
rates than nonirrigated agricultural or urban landscapes. Varying the curve number on a seasonal
67
basis, therefore, may result in more accurate runoff estimation and improve the understanding of
curve number performance overall.
In principle, estimation of runoff depth (Q) from rainfall depth (P) using the curve
number method is based on water conservation for a short-term event, during which
evapotranspiration is secondary
QFIP a ++= (3.1)
where Ia is the initial abstraction and F is the watershed retention of water during the typical
response to a given rainfall. Both initial abstraction Ia and retention F are subject to some
seasonal variation. Increased initial abstraction Ia and retention F will decrease runoff for the
same amount of event rainfall, P (Figure 3.1). The deciduous forest growing season is ultimately
characterized by a full canopy, which maximizes evapotranspiration and interception of sunlight
and rainfall by forest and plant leaves and results in increased initial abstraction Ia and reduced
runoff. The deciduous forest dormant season has less evapotranspiration and rainfall interception
by vegetation. This study evaluated the applicability of the curve number method of hydrologic
analysis to seasonal forested watershed responses.
Many studies investigated the effects of forest harvest on streamflow in the United States
(e.g., Hibbert, 1967; Swank and Helvey, 1970; Swift and Swank, 1981; Troendle and King,
1987; Swank et al., 2001). Most attribute streamflow increases after forest harvest to decreases
in evapotranspiration. The removal of trees reduces transpiration and soil moisture depletion.
The paired watershed approach assesses effects of forest harvest on streamflow (Swank
and Helvey, 1970; Swanson et al., 1986; Van Haveren, 1988) using regression and other
analyses. The design avoids the two major problems encountered in uncontrolled experiments,
climate and inter-watershed variability. A preharvest regression of treatment and control
68
watershed streamflow serves as a calibration of watershed responses to some climatic variation.
Postharvest streamflow is then regressed to assess the level and significance of treatment effects.
The paired watershed technique was extended in this study to evaluate the effect of forest harvest
on streamflow curve numbers and evaluate the difference before the treatment comparable with
the hydrologic effect periods.
Watershed analysis
The forested watersheds selected for investigation of seasonal variation of curve number
were designated Etowah 2 and Etowah 3 in north Georgia; Coweeta 2 and Coweeta 36 in North
Carolina; Fernow 4 in West Virginia; and Hubbard Brook 3 in New Hampshire (Figure 3.2).
Each watershed was undisturbed by harvesting, clearcutting, or other management activities
throughout the period of record and for significant periods before designation as controls. A
detailed description of these watersheds is available in Tedela et al. (2008) and McCutcheon et
al. (2006). This study used measured long-term rainfall-runoff series ranging from 48 to 68
years, except for the Etowah watersheds, which had only 21 months of observations available.
Table 3.1 defined the growing and dormant seasons for these watersheds plus two
transition months between seasons. Tedela et al. (2007) noted that no clear distinction or criteria
existed to classify these transition months as growing or dormant season, but exclusion of
rainfall-runoff events during these two months improved seasonal curve number calibrations
because these periods exhibit some characteristics of both seasons. Because no criteria existed to
define these transitions, this study investigated the effect of seasonal variation with and without
excluding the transitional periods to assess both effects.
69
The observed rainfall and runoff series divided according to the two seasons, resulted in a
watershed series of curve numbers (CN) based on
( ) 105425
1000
21
2 +
+−+
=PQQQP
CN (3.2a)
or
( ) 2545425
400,25
21
2 +
+−+
=PQQQP
CN . (3.2b)
where the measured rainfall (P) and direct runoff (Q) from individual storm events were in
inches for Equation (3.4a) or millimeters for Equation (3.4b). This study arithmetically averaged
the curve numbers for each season to estimate a mean for the growing season and a mean for the
dormant season.
This investigation compared the mean curve numbers for the growing season (CNg) to the
mean curve numbers of the dormant season (CNd) with and without transition periods using the
analysis of variance (ANOVA) at the 0.05 level of significance. The null and alternative were
• Null hypothesis: no significant difference existed between curve numbers for the
growing and dormant seasons
• Alternative hypothesis: a significant difference existed between curve numbers for the
two seasons
The application of the analysis of variance rejected the null hypotheses if the calculated
probability was less than the level of significance. The alternative hypothesis was accepted if the
probability was greater than 0.05.
This study analyzed paired Coweeta 36 and Coweeta 37, Fernow 3 and Fernow 4, and
Hubbard Brook 3 and Hubbard Brook 5 to determined the hydrologic effect periods from previous
70
studies and hence to investigate the effect of forest harvesting on curve number. Coweeta 36,
Fernow 4, and Hubbard Brook 3 were control watersheds; while Coweeta 37, Fernow 3, and
Hubbard Brook 5 watersheds are treated watersheds (Table 3.2).
All woody vegetation was cut on the 43.7-hectare (108.0-acre) Coweeta 37 and left on
the ground to avoid any hydrologic effect of road and landing construction in 1963 (Table 3.2).
The U.S. Forest Service had partially cut 31.7-hectares (78.3-acres) from Fernow 3 in 1969,
leaving only trees 2.5-centimeters (1-inch) in diameter at breast height or smaller and without
disturbing a 3-hectare (7.4-acre) protective strip extending approximately 20 meters (66 feet)
along each side of the stream channel. Careful construction of logging roads provided efficient
harvesting of forest products without harming other resources (Patric, 1980) and demonstrated
best management practices for West Virginia and other states. Prior to this 1969 diameter limit
cut, 13 percent, 8 percent, and 6 percent of the basal area was harvested intensively in 1958,
1963, and 1967, respectively (Table 3.2). Hubbard Brook 5 was clearcut during the winter of late
1983 and early 1984. The U.S. Forest Service harvested all trees greater than 5 centimeters (2
inches) in diameter at breast height and removed both boles and branches from the watershed
with skidders (Table 3.2). A feller-buncher harvested all accessible trees with hydraulic shears;
while on steeper slopes, chainsaws were used (McCutcheon et al., 2006).
The paired watershed analysis of Coweeta 36 and 37 revealed that water yields changed
due to the tree cutting during 1963 to 1973 and water yields returned to preharvest in 1974
(Patric, 1980). In comparison with the paired hydrologic control of Fernow 4, Fernow 3 water
yields during the preharvest period of 1951 to 1956 were not remarkably different from those
yields measured during and after the diameter limit cuts of 1958, 1963, and 1967. However,
water yields increased from 1969 to 1975 due to the 1969 and 1972 clearcutting, defining a
71
distinct period of hydrologic effects (Patric, 1980). Hydrologic effects for Hubbard Brook 5 of
only one year in duration increased soil moisture and, as a result, maximum flows increased 40
percent. Summer peak flows increased 20 percent (Hornbeck et al., 1997).
Rainfall-runoff pairs separated into preharvest and hydrologic effect series, were the basis
for computing curve numbers for each event from which the means were derived separately for
preharvest and hydrologic effect periods for all treated watersheds. The curve numbers for the
preharvest period (CNpt) was compared to the curve numbers of the hydrologic effect periods
(CNhe), using the analysis of variance (ANOVA) at the 0.05 level of significance. The null and
alternative hypotheses were
• Null hypothesis: no significant difference existed between curve numbers for the
preharvest and hydrologic effects periods
• Alternative hypothesis: a significant difference existed between curve numbers for the
two periods
Seasonal and harvest effects
Curve numbers computed for the growing seasons were smaller than for the dormant
seasons for all watersheds, in both cases whether the transition periods were included or
excluded (Figures 3.3 and 3.4, and Table 3.3). Coweeta 2 and Etowah 3 have the largest and
smallest variations in curve numbers, respectively. The difference between the dormant and
growing season curve numbers for Etowah 3 was only 2.7 when the transition periods are
included and 5.4 when the transition periods were excluded (Table 3.3). The difference between
the dormant and growing season curve numbers for Coweeta 2 was 14.1 when the transition
periods were included and 11.6 when the transition periods were excluded. Excluding the
72
transitional months increased the variation in dormant and growing season curve numbers for
Coweeta 36, Etowah 3, and Hubbard Brook 3.
The analysis of variance (Tables 3.4 and 3.5) showed that the mean curve numbers of the
growing seasons computed from only three of the six watersheds were significantly different
from that of the dormant season mean curve numbers at the 0.05 level of significance. The effect
of the seasonal transitions on the analysis was ambiguous. If the transitions were included in the
analysis, the dormant and growing season curve numbers for Coweeta 2, Coweeta 36, and
Fernow 4 were significantly different. The dormant and growing season curve numbers for
Coweeta 2, Fernow 4, and Hubbard Brook 3 were significantly different with the transitions
excluded from the analysis. The insignificant difference between the seasonal curve numbers for
Etowah 2 and Etowah 3 is probably due to the limited 21-month records. Although the curve
numbers for Coweeta 2 and Fernow 4 were clearly seasonal, the indications of seasonality for
Coweeta 36 and Hubbard Brook 3 were ambiguous. In addition, the asymptotic curve numbers of
the growing and the dormant seasons showed numerical difference (Figure 3.6) for Coweeta 2.
However, the curve number and rainfall datasets were not suitable to fit a standard asymptotic
curve number equation and are not shown here.
Curve numbers computed for the preharvest period are smaller than for the hydrologic
effect period for all six watersheds some of the differences are insignificant (Table 3.6 and
Figure 3.5). The differences between mean curve numbers computed for preharvest and
hydrologic effect periods are 8.4 and 16.6 for Coweeta 37 and Hubbard Brook 5, respectively.
For Fernow 3, the preharvest mean curve number differed from the mean curve number
computed for the period including the diameter limit harvests of 1958, 1963, and 1967 by 8.1.
The preharvest mean differed with the mean for the hydrologic effect period that included the
73
partial clearcutting of 1969 and 1972 by 3.6 (Table 3.6). Hubbard Brook 5 and Fernow 3 had the
largest and smallest differences in curve numbers between the hydrologic effect and preharvest
periods, respectively.
The analysis of variance (Table 3.7) showed that preharvest mean curve number for
Coweeta 37 and mean curve number for the hydrologic effect period (1963 to 1973) were
significantly different at the 0.05-level of significance. The preharvest mean curve number for
the Fernow 3 and the mean curve number determined during the forest harvest of 13 percent, 8
percent, and 6 percent of the basal area in 1958, 1963, and 1968, respectively, were also
significantly different at the 0.05 level of significance. However, the Fernow 3 mean curve
number measured during the hydrologic effects of clearcutting in 1969 and 1972 was not
significantly different (at the 0.05 level of significance) from the preharvest mean curve number
(Figures 3.5 and Table 3.7).
Hornbeck et al. (1997) could only distinguish an effect of the Hubbard Brook 5
clearcutting on annual water yield in water year 1984, but the maximum annual storm of was
clearly an exceptional event. The 1984 maximum runoff was exceptional compared to the
maximum rainfall of that year. This 1984 exceptional event produced the largest curve number
calculated for any annual maximum rainfall-runoff event for the 49-year record. The fewer years
of record available to calculate curve numbers, the more imprecision increases and the greater
the chance that these short periods have sets of curve numbers that are statistically different.
Greater runoff curve numbers observed after forest harvest showed that runoff estimates
would also be greater for a particular watershed compared to the runoff estimate before the
treatment periods [see Equations (3.1) and (3.2)].
74
Conclusions
Three of six watersheds showed significant curve number differences between the
growing and dormant seasons. The insignificant effect of seasonal variation for some of the
watersheds was attributed to the variability of curve numbers. Therefore, runoff estimation with
annually consistent curve numbers has limited application because the watershed response may
vary seasonally.
Paired studies at three watersheds showed that forest harvesting increased streamflow
and, hence, curve numbers. However, the increase in curve number was not significant for the
Fernow 3 clearcutting. Large observed uncertainties were consistent with results by Hibbert
(1967), who found the hydrological response to forest harvests highly variable and, for the most
part, unpredictable. This variability was reflected id the great uncertainty observed in the curve
numbers. Furthermore, gains in streamflow, as Swank and Helvey (1970) described, are only
temporary since regrowth offsets changes in evapotranspiration brought about by the initial
cutting.
Acknowledgments
Financial assistance provided in part by (1) the West Virginia Division of Forestry, (2)
the U.S. Geological Survey through the Georgia Water Resources Institute, and (3) the Warnell
School of Forest and Natural Resources. Richard Hawkins of the University of Arizona, Tucson
provided insightful background and guidance on the use, interpretation, and limitations of the
curve number method. The observed watershed characteristics and rainfall-runoff series required
for this study were provided by Wayne Swank and Stephanie Laseter from the U.S. Forest
Service Coweeta Hydrologic Laboratory; Frederica Wood, from the U.S. Forest Service Fernow
75
Timber and Watershed Laboratory; John Campbell, from the U.S. Forest Service Hubbard Brook
Experimental Forest; and Josh Romeis from the University of Georgia Etowah Research Project.
References
Hawkins, R. H. 1998. Local sources for runoff curve numbers. Eleventh Annual Symposium of
the Arizona Hydrological Society, September 23-26, Tucson, Arizona.
Hibbert, A. R. 1967. Forest treatment effects on water yield. In: International Symposium on
Forest Hydrology, Sopper, W. E. and Lull, H. W. (Eds.), Proceedings of a National
Science Foundation Advanced Science Seminar, Pergamon Press, New York, New York,
527–543.
Hornbeck, J. W., C. W. Martin, and C. Eagar. 1997. Summary of water yield experiments at
Hubbard Brook Experimental Forest, New Hampshire. Canadian Journal of Forest
Research 27: 2043-2052.
Jacobs, J. H. and R. Srinivasan. 2005. Effects of curve number modification on runoff estimation
using WSR-88D rainfall data in Texas watersheds. Journal of Soil and Water
Conservation 60(5): 274-278.
McCutcheon, S. C., Tedela N. H., Adams, M. B., Swank, W., Campbell, J. L., Hawkins, R. H.,
Dye, C. R. 2006. Rainfall-runoff relationships for selected Eastern U.S. forested
mountain watersheds: Testing of the curve number method for flood analysis. Report
prepared for the West Virginia Division of Forestry, Charleston, West Virginia.
Paik, K., J. H. Kim, H. S. Kim, and D. R. Lee. 2005. A conceptual rainfall-runoff model
considering seasonal variation. Hydrological Processes 19: 3837-3850.
76
Patric, J. H. 1980. Effects of wood products harvest on forest soil and water relations. Journal of
Environmental Quality 9(1): 73-80.
Sun, G., S. G. McNulty, D. M. Amatya, R. W. Skaggs, L. W. Swift, J. P. Shepard, and H.
Riekerk. 2002. A comparison of the hydrology of the coastal forested wetlands/pine
flatwoods and the mountainous uplands in the Southern U.S. Journal of Hydrology
263(1-4): 92-104.
Swank, W. T. and J. D. Helvey. 1970. Reduction of streamflow increases following regrowth of
clearcut hardwood forests. In Symposium on the Results of Research on Representative
and Experimental Basins, International Association of Scientific Hydrology and United
Nations Educational, Scientific and Cultural Organization, Wellington, New Zealand,
346-360.
Swank, W. T., J. M. Vose, and K. J. Elliott. 2001. Long-term hydrologic and water quality
responses following commercial clearcutting of mixed hardwoods on a southern
Appalachian catchment. Forest Ecology and Management 143(1-3): 163–178.
Swanson, R. H., D. L. Golding, R. L. Rothwell, and P. Y. Bernier. 1986. Hydrologic effects of
clear-cutting at Marmot Creek and Streeter watersheds, Alberta. Northern Forestry Center
Information Report NOR-X-278, Canadian Forestry Service, Edmonton, Alberta,
Canada, 27 pp.
Swift, L. W. and W. T. Swank. 1981. Long term responses of stream-flow following clearcutting
and regrowth. Hydrological Sciences Bulletin 26(3): 245-256.
Tedela, N. H., T. C. Rasmussen, and S. C. McCutcheon. 2007. Effects of seasonal variation on
runoff curve number for selected watersheds of Georgia -- preliminary study, In
77
Proceedings of the 2007 Georgia Water Resources Conference, March 27-29, University
of Georgia, Athens.
Troendle, C. A. and R. M. King. 1987. The effect of partial and clearcutting on streamflow at
Deadhorse Creek, Colorado. Journal of Hydrology 90(1-2): 145-157.
Van Haveren, B. P. 1988. A reevaluation of the Wagon Wheel Gap forest watershed experiment.
Forest Science 34: 208-214.
Van Mullein, J. A., D. E. Woodward, R. H. Hawkins, and A. T. Hjelmfelt. 2002. Runoff curve
number method: Beyond the handbook. In Hydrologic Modeling for the 21st Century,
Second Federal Interagency Hydrologic Modeling Conference, July 28-August 1, U.S.
Geological Survey Advisory Committee on Water Information, Las Vegas, Nevada.
78
Table 3.1 Dormant and growing seasons
Seasons Watershed
Growing Dormant
Transition periods
Coweeta 2 May to October November to April April to May, October to November
Coweeta 36 May to October November to April April to May, October to November
Etowah 2 April to October November to March March to April, October to November
Etowah 3 April to October November to March March to April, October to November
Fernow 4 May to October November to April April to May, October to November
Hubbard Brook 3 May 16 to September 15 September 16 to May 15 April 15 to May 30, September 16 to October 30
79
Table 3.2 Preharvest and hydrologic effect periods for the three-paired watersheds
Watershed Treatment
Area
(hectares)
Total period
of record
(years)
Preharvest
period (years)
Hydrologic
effect period
(years)
Fernow 3 Diameter limit cutting (1958, 1963, 1967), clearcut (1969, 1972)
34.3 53 1951 to 1957 (7 years)
1969 to 1975 (7 years)
Fernow 4 Control 38.7 49 N/A N/A
Coweeta 36 Control 46.6 59 N/A N/A
Coweeta 37 Clearcut (1963) 43.7 37
1944 to
1947, 1949
to 1951,
1953 to
1957, 1962
(13 years)*
1963 to 1973 (11 years)
Hubbard Brook 3 Control 42.4 41 N/A N/A
Hubbard Brook 5 Clearcut during the winter of late 1983 and early 1984
21.9 43 1962 to 1982 (21 years)
Mid-1983 to mid-1984 (1 year)
* Coweeta Hydrologic Laboratory did not collect runoff data during the 1948, 1952, and 1958 to 1961 water years.
80
Table 3.3 Differences in dormant and growing season mean curve numbers including and
excluding transitions periods
Including transition months Excluding transition months
Watershed Season
Mean Difference Mean Difference
Growing 48.4 50.1 Coweeta 2
Dormant 62.5
14.1
61.7
11.6
Growing 67.5 68.2
Coweeta 36
Dormant 74.8
7.3
76.2
7.9
Growing 65.3 7.0 64.3 5.4
Etowah 2
Dormant 72.3 69.8
Growing 63.1 58.9
Etowah 3
Dormant 65.8
2.7
64.1
5.2
Growing 80.9 81.5
Fernow 4
Dormant 89.7
8.8
89.3
7.8
Growing 80.3 80.3
Hubbard Brook 3
Dormant 84.6
4.3
89.5
9.2
81
Table 3.4 Analysis of variance of seasonal curve numbers including transition periods
Degrees of freedom
Watersheds
Group Error Total
F- statistic Probability > F
Etowah 2 1 12 13 1.94 0.1891
Etowah 3 1 15 16 1.35 0.2630
Coweeta 2 1 66 67 15.98 0.0002
Coweeta 36 1 57 58 8.64 0.0048
Fernow 4 1 51 52 17.34 0.0001
Hubbard Brook 3 1 46 47 2.36 0.1312
82
Table 3.5 Analysis of variance of seasonal curve numbers excluding transition periods
Degrees of freedom Wartershed
Group Error Total
F Probability > F
Etowah 2 1 8 9 2.61 0.1449
Etowah 3 1 6 7 0.19 0.6750
Coweeta 2 1 42 43 15.86 0.0003
Coweeta 36 1 34 35 3.71 0.0620
Fernow 4 1 40 41 14.56 0.0005
Hubbard Brook 3 1 33 34 10.1 0.0032
83
Table 3.6 Mean curve numbers for the preharvest and hydrologic effect periods
Watershed (CNpt) (CNhe) (CNt) CNhep
Difference between
CNpt and CNhe
Difference between
CNpt and CNhep
Coweeta 37 68.2 76.6 73.1 — 8.4 —
Fernow 3 81.7 89.9 82.9 85.4 8.1 3.6
Hubbard Brook 5 80.6 97.2 81.7 — 16.6 —
CNpt is preharvest mean curve number; CNhe is hydrologic effect mean curve number; CNt is mean curve number for the entire period; and CNhep is mean curve number for hydrologic effect of partial clear cutting of Fernow 4.
84
Table 3.7 Analysis of variance of curve numbers computed for preharvest and hydrologic effect periods
Degrees of freedom Watershed
Group Error Total
F statistic Probability > F
Coweeta 37 1 22 23 8.45 0.0082
Fernow 3* 1 15 16 4.55 0.0499
Fernow 3** 1 11 12 0.04 0.8389
Hubbard Brook 3 1 0 1 - -
* Period of effects from diameter limit cuts in 1958, 1963, and 1967 ** Partial cutting
85
Figure 3.1 Water balance for a short-term rainfall event in which P is rainfall, Q is runoff depth, Ia is initial abstraction, F is retention, and S is potential maximum retention.
Q
Ia
F
P
S
88
Watersheds
Coweeta 2 Coweeta 36 Etowah 2 Etowah 3 Fernow 4 Hubbard B. 3
Curve Number
0
20
40
60
80
Growing
Dormant
Figure 3.3 Curve numbers for growing and dormant seasons including transition periods
89
Watersheds
Coweeta 2 Coweeta 36 Etowah 2 Etowah 3 Fernow 4 Hubbard B. 3
Curve Number
0
20
40
60
80
Growing
Dormant
Figure 3.4 Curve numbers for growing and dormant seasons excluding transition periods
90
Watersheds
Coweeta 37 Fernow 3 Hubbard Brook 5
Curve number
40
50
60
70
80
90
100
Curve number for the pretreatment period
Curve number for the hydrologic effect period
Curve number for the entire record period
Curve number for the hydrologic effect of partial clearcutting of Fernow 3
Figure 3.5 Comparison of mean curve numbers for the three watersheds before tree harvest, during hydrologic effects, and for the entire record
91
20
30
40
50
60
70
80
90
100
0 1 2 3 4 5 6 7 8 9 10
Rainfall Volume in inches
Curve number....
Dormant season
Growing season
CN(P)=47+(100-47)*EXP(-0.3305*P)
CNO = 100/ (1+P/2)
CN(P)=33.5+(100-33.5)*EXP(-0.4250*P)
Figure 3.6 Asymptotic curve numbers for growing and dormant seasons of Coweeta 2
92
CHAPTER 4
RAINFALL AND RUNOFF PROBABILITY DISTRIBUTIONS FOR FOUR, SMALL,
FORESTED WATERSHEDS IN THE MOUNTAINOUS, EASTERN UNITED STATES3
3 Negussie Tedela, Steven McCutcheon, Todd Rasmussen. To be submitted to the Journal of the Hydrologic Engineering
93
Abstract
This study investigated probability distributions for annual-maximum rainfall and runoff
observations to evaluate the distributions of estimated runoff volumes based on the Natural
Resource Conservation Service curve number method. The observations of rainfall and runoff
volumes occurred at four forested experimental watersheds in the mountains of North Carolina,
West Virginia, and New Hampshire. Goodness-of-fit tests defined the appropriate cumulative
probability distribution for each series of annual-maximum rainfall or runoff. This study applied
the Cramer-von Mises and Anderson-Darling goodness–of-fit tests to select appropriate rainfall
and runoff distributions for each watershed. The gamma distribution was appropriate for all
observed rainfall and runoff volumes, except for the Hubbard Brook 3 rainfall observations. The
Weibull distribution was best for estimated runoff volumes from all the watersheds except for
Hubbard Brook 3. The lognormal distribution best matches the estimated runoff volume from
Hubbard Brook 3. Differences between the distributions of the estimated and observed, annual-
maximum runoff volumes demonstrate the weakness of the Natural Resources Conservation
Service curve number method. The estimated runoff volumes of Coweeta 2 are in agreement
with the observed runoff for average conditions (50 percent probability of occurrence or two-
year return period). For the rest of the three watersheds, the tabulated curve number seems to
yield runoff that occurred once every one hundred years. The tabulated curve number may yield
runoff for events occurring rarely and under-estimate runoff for the rest of the distribution. The
results showed the bias that could occur in using the tabulated curve number method for these
watersheds.
94
Keywords: Curve number, runoff-rainfall relationship, normal, runoff modeling, probability,
return periods, lognormal distribution, gamma distribution, and Weibull
distribution, goodness of fit, chi-square, Kolmogorov-Smirnov, Cramer-von Mises,
Anderson-Darling, forested watershed, mountains, hydrology, gaged watersheds,
ungaged watersheds
Introduction
Based on the prior applications by Pilgrim and Cordery (1993) and Schaake et al. (1967)
to peak flows, Hjelmfelt (1980) assumed that ordering and matching of the annual-maximum
rainfall and runoff volumes by probabilities is the best method to determine the probability
distribution. Hawkins et al. (2005) and Schneider and McCuen (2005) used this method because
the joint frequency of an event rainfall volume and the event runoff volume has been ignored in
most hydrologic design problems. However, independent ranking of rainfall and runoff decreases
the quantifiable uncertainty in the determination of curve numbers and runoff distributions and
thus can be misleading but not necessarily inaccurate (McCutcheon et al., 2006).
This study independently ranked the observed, annual-maximum rainfall and runoff
volumes and estimated runoff volumes to determine cumulative probability distributions for four
small, forested watersheds in the mountains of the eastern United States. The tabulated curve
numbers of the Natural Resource Conservation Service were the basis of the runoff estimates.
The objectives were to (1) apply goodness-of-fit tests for hypothesis testing and assess whether
various probability distributions were consistent with the observations, (2) examine the
probability distributions of the observed and estimated runoff volumes to asses how well these
distributions match for various return periods.
95
Matching probability distributions to represent observations or estimates involved testing
the measurements for independence and origination from identical populations (Chin, 2006).
Before the advent of widespread electronic computing, hydrologists plotted and visually matched
different continuous probability distributions to observations. The current (2009) art is to apply
goodness-of-fit hypothesis-testing to match various probability distributions (Appendix) with the
measurements, consistent with the underlying process generating the measured rainfall or runoff
(Chin, 2006).
Some goodness-of-fit tests only determine if the observed or estimated, annual-maximum
rainfall or runoff comes from a normally distributed population, which rarely occurs in
hydrologic analysis. The more general tests used in hydrology (Hann, 2002) are discussed in the
following paragraphs.
The chi-square test (Snedecor and Cochran, 1989) determines if a series of observations
or estimates came from a population with type of distribution. The chi-square (χ2) goodness-of-
fit statistic is
( )∑=
−=
k
i i
ii
E
EO
1
2
2χ (4.1)
where k is the total number of classes of bins, Oi is the observed frequency for class i, and Ei is
the expected frequency for class i. For this test, the investigator classifies observations or
estimates by putting the information put into defined classes that have been called bins (from the
industrial process of sorting size products into containers). One limitation is that the chi-square
statistic depends on how the observations or estimates are classified. Another limitation is that
the method requires each class have five or greater observations or estimates for the chi-square
approximation to be valid.
96
The Kolmogorov-Smirnov test (Chakravart et al., 1967) also determines if a sample
comes from a population with a specific distribution but the maximum discrepancy between
observations and a specific empirical distribution is the basis. The Kolmogorov-Smirnov statistic
(D) for a given distribution function F(x) and a distribution from observations or estimates, Fn (x)
is
( ) ( )xFxFD n −= max (4.2)
where max indicates the maximum discrepancy. The Weibull empirical distribution is one
function that cannot be assessed using Kolmogorov-Smirnov statistic. Mathematically the test is
similar to the Kolmogorov test.
The Cramer-von Mises statistic W2 (Anderson, 1962) is used for judging the goodness-
of-fit of a probability distribution F* compared to a given distribution F(x), and is found using:
( ) ( )[ ] ( )xdFxFxFW
2
*2 ∫∞
∞−
−= (4.3)
Tests may involve unclassified estimates or observations. Also, this test is satisfactory for
symmetric and skewed distributions.
The Anderson-Darling test (Stephens, 1974) is a modification of the Kolmogorov-
Smirnov test used to test if a series of observations or estimates came from a population with a
specific empirical distribution. This test gives more weight to the tails of a distribution than does
the Kolmogorov-Smirnov test. The Anderson-Darling (A2) statistic is
SNA −−=2 (4.4)
where N is the sample size, and
( ) ( ) ( )( )[ ]iNi
N
i
XFXFN
iS −+
=
−+−
=∑ 1
1
1lnln12
(4.5)
97
in which F(Xi) is the cumulative distribution function of the specified distribution, and Xi are the
ordered rainfall or runoff.
Many hydrologists do not use the chi-square and Kolmogorov-Smirnov tests when testing
hydrologic frequency distributions, because of their lack of sensitivity to low-frequency events
and the large probability of accepting the hypothesis when the hypothesis is actually false (Haan,
2002). The chi-square test is further limited to having at least five observations or estimates
within each class or class interval (Hann, 2002). Furthermore, the chi-square statistic loses
information in a test of a continuous distribution by grouping estimates into classes (Chakravarti
et al., 1967). The Cramer-von Mises and Anderson-Darling statistics are superior to the
Kolmogorov-Smirnov statistic, which is superior to the chi-squared statistic. The Cramer-von
Mises and Anderson-Darling tests make a comparison of two distributions or populations over a
range of data, rather than looking for a marked difference at one point (Chakravarti et al., 1967).
The annual-maximum observed rainfall and observed and estimated runoff series in this study
were not suitable for the chi-square test because of the frequency (the number of occurrences in a
particular class interval) is less than five for some of the classes. Therefore, this investigation
applied the Kolmogorov-Smirnov, Cramer-von Mises, and Anderson-Darling tests, but focused
on the later two superior statistics.
Study watersheds
This study included four watersheds, two from the Coweeta Hydrologic Laboratory,
North Carolina (Coweeta 2 and Coweeta 36), and one watershed each from the Fernow
Experimental Forest, West Virginia (Fernow 4), and the Hubbard Brook Experimental Forest,
New Hampshire (Hubbard Brook 3). These watersheds were controls, which had not been
98
disturbed for many years. The size of watersheds ranged from 12.26 hectares (30.29 acres) to
108.0 hectares (267 acres).
The Coweeta Hydrological Laboratory is located in the Blue Ridge Physiographic
Province of the southern Appalachian Mountains, near Otto, North Carolina. Coweeta 2
elevation ranges from 1,086 to 1,482 meters (3,563 to 4,862 feet). Coweeta 36 elevation ranges
from 710 to 1,010 meters (2,330 feet to 3,314 feet). The Coweeta soil depth averages
approximately 7 meters (23 feet) in depth at lower (Coweeta 2) to mid elevations and is more
shallow (less than 2 meters or 6.6 feet) at high elevations (Coweeta 36) (McCutcheon et al.,
2006). The forest cover includes northern hardwoods, cove hardwoods, xeric oak and pine, oak
and hickory, and mixed oak (USDA, 2004). The Coweeta 2 and 36 controls were uncut and
undisturbed since 1927 but Coweeta 36 was partially defoliated by a fall cankerworm infestation
between 1975 and 1979 (McCutcheon et al., 2006).
The Fernow Experimental Forest lies in the Allegheny Mountain section of the
unglaciated Allegheny Plateau. The Fernow 4 elevations ranged from 735 to 865 meters (2,411
to 2837 feet) over steep slopes. Depths of soils at Fernow are typically 1 meter (3 feet) with 6
centimeters (2.5 inches) of humus. The forest cover included northern red oak, chestnut oak,
white oak, scarlet oak, black oak, and upland oaks (Reinhart et al., 1963). Fernow 4 was last cut
for timber at various times during circa 1905 to 1910 and the watershed was untreated and
undisturbed since May 1, 1951 (McCutcheon et al., 2006).
The Hubbard Brook Experimental Forest was located in the White Mountain National
Forest. The bowl-shaped Hubbard Brook Valley had hilly terrain. Elevation of Hubbard Brook 3
ranges from 522 to 716 meters (1,712 to 2,349 feet). Average stony soil depth of Hubbard Brook
was 50.3 centimeters or 19.8 inches with an average depth of 6.9 centimeters or 2.7 inches of
99
humus. The present forest cover was 80 to 90 percent northern hardwoods and 10 to 20 percent
spruce (USDA, 2004). Hubbard Brook 3 was a hydrologic control last cut 1890 to 1920 with
some residual stands more than 200 years old, but the hurricane of 1938 downed some timber
that was salvaged (McCutcheon et al., 2006).
Probability analyses
A probability formula (i.e., plotting position) was required to convert ranked series of
annual-maximum rainfall and runoff into frequency distributions, but several alternative
formulas existed. Some of these were extensions of existing formulas (such as Hazen and
Weibull) used in the systematic analysis of flood records (In-na and Nguyen, 1988). The Hazen
(1914), Weibull (1939), Blom (1958), Gringorten (1963), and Cunnane (1978) probability
formulas are examples of the formulas used to calculate the probability of occurrence (Pi) have
the general form (Chow, 1964)
1+−−−
=baN
amPi (4.6)
where m is the ordered sequence of annual-maximum rainfall or runoff volumes, N is total
number of observations, and a and b are constants. For the Hazen formula a = -m + 1 and b = -N
+ m, for the Weibull formula a = b = 0, for the Blom formula a = b = 0.375, for the Gringorten
formula a = b = 0.44, and for the Cunnane formula a = b = 0.4.
The Gringorten (1963) formula gives longer return periods for the larger floods in a
series, which recognizes that the true return period of the larger floods is probably longer than
the value computed with the Weibull plotting position formula (Linsley et al., 1982). Therefore,
the Gringorten probability formula
100
( )( )12.0
44.0
+−
=N
mPi (4.7)
was selected for this analysis.
For comparison to annual-maximum observations, runoff volumes Q (inches) were
computed from an algebraic rearrangement of the curve number runoff equations as
( )[ ]( )[ ]8008
20022
+−−+
=PCNCN
PCNQ (4.8)
where CN is the curve number tabulated (NRCS, 2001) or calibrated for a particular watershed
and P (inches) is the annual-maximum volume of rainfall. For each rainfall volume and the
watershed curve number, Equation (4.8) produced an estimate of the annual-maximum runoff.
This investigation compared the estimated runoff distribution to the measured rainfall and
measured runoff volumes using the probability distributions that match these observations.
After the ranking of the annual-maximum rainfall and runoff independently for Coweeta
2, Coweeta 36, Fernow 4, and Hubbard Brook 3, this analysis established the probability of
occurrence based on the number of events in each series and the Gringorten probability formula.
This analysis selected the appropriate probability distributions to match the observed rainfall,
observed runoff, and estimated runoff for each watershed based on goodness-of-fit tests. The
quantiles (1, 2, 3, 10, 25, 50, 75, 90, 91, 92, and 99 percent) were determined for the selected
probability distribution; more for the two extremes of the distribution compared to central part of
the distribution. This focuses the statistical assessment at the two extremes where more
variations occur between the observed, annual-maximum rainfall and runoff series and the
selected frequency distributions.
Many probability distributions have been proposed but the lognormal, Weibull, gamma
(Pearson type III), and normal (see the Appendix for definitions) are the most frequently applied
101
in hydrology (Chin, 2006). In this analysis (Figures 4.1 and 4.2), these four distributions were
compared with observed, annual-maximum rainfall and runoff, and estimated, annual-maximum
runoff based on the goodness of fit. The Kolmogorov-Smirnov (D), Cramer-von Mises (W2), and
Anderson-Darling (A2) tests [Equations (4.2), (4.3), and (4.4)] were used for hypothesis testing
where the null (Ho) and alternative (HA) hypotheses were
H0: the stated distribution matched the observations or estimates of annual-maximum
rainfall or runoff
HA: the stated distribution did not match the observations or estimates of annual-
maximum rainfall or runoff
The null hypothesis that a specific distribution matched observations or estimates was rejected if
the probability is less than the significance level (α = 0.05), the probability that the sample could
have been drawn from the population being tested given that the null hypothesis was true. A
probability of 0.05, for example, indicates that would be only a 5 percent chance of drawing the
sample if the null hypothesis was actually true. Probability close to zero signals that the null
hypothesis is false and typically, a difference is very likely to exist.
A comparison of the distributions of measured and estimated, annual-maximum runoff
described whether the magnitude of the selected curve number adequately estimated the
measured runoff volume at various exceedance probabilities. The shape of the computed runoff
volume distribution provided insight into whether the curve number method was applicable to a
particular watershed and for what segments of the measured distribution.
102
Probability distributions
Table 4.1 shows the Kolmogorov-Smirnov, Cramer-von Mises, and Anderson-Darling
tests used to select the cumulative probability distribution that matched the observed, annual-
maximum rainfall from Coweeta 2. The same procedure is used to select the probability
distribution for observed rainfall and runoff volumes and estimated runoff volumes (computed
based on the Natural Resource Conservation Service tabulated curve numbers) for each
watershed. More than one type of probability distributions matched the annual-maximum rainfall
and runoff volumes.
The results of the goodness-of-fit tests for the annual-maximum rainfall series of
Coweeta 2 (Table 4.1) showed that the gamma, lognormal, and Weibull distributions matched
observations, while the normal distribution did not at the 5 percent level of significance. The
Cramer-von Mises and Anderson-Darling statistics are the same for the gamma and Weibull
distributions (Table 4.1). Based on all tests, the probability of accepting the null hypothesis (the
gamma distribution matched the Coweeta 2 observed, annual-maximum rainfall) is more than 50
percent.
The summary of the selected probability distributions together with the scale parameter
(β) and shape parameter (γ) (defined in the Appendix) is in Table 4.2. The gamma distribution
matched the observed, annual-maximum runoff and rainfall volumes for all watersheds except
for the observed rainfall volume on Hubbard Brook 3. The Weibull distribution matched the
estimated, annual-maximum runoff from all the watersheds except for Hubbard Brook 3. The
lognormal distribution matched the observed, annual-maximum rainfall and estimated annual-
maximum runoff for Hubbard Brook 3.
103
The Weibull distribution matched the observed, annual-maximum runoff from Coweeta 2
and Coweeta 36 and observed rainfall of Fernow 4. The lognormal distribution also matched the
observed, annual-maximum rainfall of Coweeta 2 and Coweeta 36 and observed runoff volumes
for Fernow 4 and Hubard Brook 3. For the estimated, annual-maximum runoff volumes from all
watersheds and for observed rainfall volume of Hubbard Brook 3, no other distributions matched
because of the smaller probability of accepting the null hypothesis (Table 4.2).
Figure 4.3 showed that the gamma distribution matched the observed, annual-maximum
rainfall and runoff and the Weibull distribution matched estimated runoff for Coweeta 2.
Although the gamma and Weibull distributions matched the annual-maximum runoff and the
gamma and lognormal distributions matched rainfall for Coweeta 2, this investigation selected
the gamma distribution for consistency. The Coweeta 2 estimated runoff based on the Natural
Resource Conservation Service (2001) tabulated curve number only agreed with the observed
runoff volumes for a return interval of once every three years or frequency of 33 percent.. The
tabulated curve number estimates annual-maximum runoff poorly outside the probabilities
between 55 percent and 20 percent or between 1.8 years and 5 years recurrence interval (Figure
4.3). Thus, the tabulated curve number originally based on the median (probability of 50 percent)
should not be used to estimate design storms of once in 10-years or less frequent, or very
frequent events.
The annual-maximum runoff from Coweeta 36 also matched the gamma and Weibull
distributions and the rainfall the gamma and lognormal distributions. However, this study
selected the gamma distribution for consistency. Figure 4.4 established that the tabulated Natural
Resource Conservation Service (2001) curve number estimated runoff that only agrees at once in
104
one hundred years for Coweeta 36. Practitioners must calibrate curve numbers for these
watersheds to estimate runoff at other return periods.
Figure 4.5 shows the selected gamma distribution matched the observed, annual-
maximum rainfall and runoff and the Weibull distribution matched estimated runoff to a degree
for Fernow 4. The annual-maximum runoff matched the gamma and lognormal distributions and
the rainfall the gamma and Weibull distributions of Fernow 4 but this study selected the gamma
distribution. The estimated runoff based on the tabulated curve number for Fernow 4 watershed
only approached the observed, annual-maximum runoff at a 1 percent probability. However, the
Weibull distribution, the only empirical function in agreement with the estimated runoff,
intersects the gamma distributions matched to the observed runoff at 8 percent probability. The
Weibull distribution overestimates all design runoffs except the 2-year event at a probability of
50 percent that was underestimated. The accuracy of runoff estimation decreased as the
probability of occurrence increased. Practitioners must calibrate the curve number for each
design runoff probability for Fernow 4.
Figure 4.6 showed the annual-maximum distribution of observed rainfall volume,
observed runoff volume, and estimated runoff volume based on tabulated curve number for
Hubbard Brook 3. The lognormal distribution matched the measured, annual-maximum rainfall
and estimated runoff volumes, while the gamma distribution matched the observed runoff for
Hubbard Brook 3. Unlike the other watersheds, in which the gamma distribution matched both
observed, annual-maximum rainfall and runoff volumes, the study selected the lognormal
distribution based on the goodness-of-fit tests to match the observed rainfall volume. The
estimated, annual-maximum runoff based on the tabulated curve number for Hubbard Brook 3
did not come close to any observations (Figure 4.6).
105
Single watershed curve number in doubt
None of the Natural Resource Conservation Service (2001) tabulated curve numbers
estimated accurate runoff from small, mountainous-forested watersheds in the eastern United
States. For all four watersheds investigated, a new curve number is necessary for each important
design storm. Nevertheless, the curve number method--as currently applied--may be too
uncertain to produce tabulations for each design event ranging from once in 2 years to once in
100 years and sometimes longer.
This investigation did not find a single empirical distribution to match the observed,
annual-maximum rainfall and runoff. Although, the gamma distribution matched rainfall and
runoff for all watersheds except for the observed rainfall on the Hubbard Brook 3 watershed, for
which only a lognormal distribution was applicable. Only the Weibull or lognormal distributions
matched estimated runoff based on the tabulated curve numbers.
References
Anderson, T. W. 1962. On the distribution of the two-sample Cramer-von Mises criterion.
Annals of Mathematical Statistics 33(3): 1148-1159.
Blom, G. 1958. Statistical Estimates and Transformed Beta Variables. Wiley, New York, New
York.
Chakravarti, I. M., R. G. Laha, and J. Roy. 1967. Handbook of Methods of Applied Statistics,
Volume I. John Wiley and Sons, 392-394.
Chin, D. A. 2006. Water Resources Engineering. 2nd Ed. Prentice Hall, Upper Saddle River, New
Jersey.
Chow, V. T., ed. 1964. Handbook of Applied Hydrology. McGraw-Hill, New York, New York.
106
Cunnane, C. 1978. Unbiased plotting position - a review. Journal of Hydrology 37(3-4): 205-
222. doi:10.1016/0022-1694(78)90017-3.
Gringorten, I. I. 1963. A plotting rule for extreme probability paper. Journal of Geophysical
Research 68(3) 813-814.
Haan, C. T. 2002. Statistical Methods in Hydrology. Iowa State University Press, Ames.
Hawkins, R. H., E. D. Woodward, J. Ruiyun, J. E. VanMullem, and A. T. Hjelmfelt. 2005.
Runoff Curve Number method: examination of the initial abstraction ratio. ASCE
Watershed Management CN Workshop, Williamsburg, Virginia, originally given at the
Federal Interagency Hydrologic Modeling Conference, July 2002, Las Vegas, Nevada.
Hazen, A. 1914. Storage to be provided in impounding reservoirs for municipal water supply.
Transaction of the American Society of Civil Engineers paper 1308, 77: 1547-1550. (from
Cunnane, 1978).
Hjelmfelt, A. T. 1980. Empirical investigation of curve number techniques. Journal of
Hydraulics Engineering Division, 106(HY9): 1471-1476.
In-na, N. and V. T. A. Nguyen. 1989. An unbiased plotting position formula for the general
extreme value distribution. Journal of Hydrology 106(3-4): 193-209.
McCutcheon, S. C., Tedela N. H., Adams, M. B., Swank, W., Campbell, J. L., Hawkins, R. H.,
Dye, C. R. 2006. Rainfall-runoff relationships for selected Eastern U.S. forested
mountain watersheds: Testing of the curve number method for flood analysis. Report
prepared for the West Virginia Division of Forestry, Charleston, West Virginia.
Pilgrim, D. H. and I. Cordery. 1993. Flood runoff. In Handbook of Hydrology, D. R. Maidment,
ed. McGraw-Hill, New York, New York, Chapter 9: 9.1-9.42.
107
Reinhart, K. G., A. R. Eschner, and G. R. Tremble, Jr. 1963. Effect on streamflow of four forest
practices. U.S. Department of Agriculture Forest Service Research Paper NE-1,
Northeastern Forest Experiment Station, Upper Darby, Pennsylvania.
Schaake, J. C., J. C. Geyer, and J. W. Knapp. 1967. Experimental examination of the rational
method. Journal of the Hydraulics Division 93(HY6): 353-370.
Schneider, L. E. and R. H. McCuen. 2005. Statistical guideline for curve number generation.
Journal of Irrigation and Drainage Engineering 131(3): 282-290.
Snedecor, G. W. and W. G. Cochran. 1989. Statistical Methods. 8th Ed. Iowa State University
Press, Ames.
Stephens, M. A. 1974. EDF statistics for goodness of fit and some comparisons. Journal of the
American Statistical Association 69(347): 730-737.
U.S. Department of Agriculture (USDA). 2004. Experimental forests and ranges of the USDA
Forest Service, General Technical Report NE-321, Northern Research Station, Newtown
Square, Pennsylvania, 178 pp.
Weibull, W. 1939. A statistical theory of strength of materials. Ingenioers vetenskapsakad, 151
pp. (from Hirsch, 1987).
108
Table 4.1 Goodness-of-fit tests for Coweeta 2 annual-maximum-rainfall series
a. Lognormal distribution
Test Statistic Probability
Kolmogorov-Smirnov, D 0.0509 Probability > D >0.150
Cramer-von Mises, W2 0.0268 Probability > W2 >0.500
Anderson-Darling, A2 0.2014 Probability > A2 >0.500
b. Weibull distribution
Test Statistic Probability
Kolmogorov-Smirnov, D * Probability > D *
Cramer-von Mises, W2 0.1058 Probability > W2 0.086
Anderson-Darling, A2 0.6155 Probability > A2 0.106
c. Gamma distribution
Test Statistic Probability
Kolmogorov-Smirnov, D 0.0789 Probability > D >0.250
Cramer-von Mises, W2 0.0470 Probability > W2 >0.500
Anderson-Darling, A2 0.2824 Probability > A2 >0.500
d. Normal distribution
Test Statistic Probability
Kolmogorov-Smirnov, D 0.1394 Probability > D <0.010
Cramer-von Mises, W2 0.2108 Probability > W2 <0.005
Anderson-Darling, A2 1.2198 Probability > A2 <0.005
109
Table 4.2 Selected probability distributions of observed, annual-maximum runoff and rainfall and estimated annual-maximum runoff volumes for four mountainous-forested watersheds
Selected distribution Watershed
Tabulated
curve
number Data
Primary Secondary
Scale
parameter
(β)*
Shape
parameter
(γ)*
Observed runoff Gamma Weibull 0.579 1.257
Estimated runoff Weibull ** 0.876 4.824 Coweeta 2
Observed rainfall Gamma Lognormal 0.876 4.824
Observed runoff Gamma Weibull 1.102 2.510
Estimated runoff Weibull ** 1.516 0.919 Coweeta 36
Observed rainfall Gamma Lognormal 1.238 4.575
Observed runoff Gamma Lognormal 0.326 4.383
Estimated runoff Weibull ** 0.676 0.711 Fernow 4
Observed rainfall Gamma Weibull 0.526 5.048
Observed runoff Gamma Lognormal 0.977 1.632
Estimated runoff Lognormal ** -3.155 2.072 Hubbard Brook 3
Observed rainfall Lognormal ** 1.006 0.486
*Scale and shape parameters are for the primary distributions. ** No other empirical distribution adequately these observations or estimates.
112
Probability in percent
0.1 1 10 30 50 70 90 99
Rainfall and runoff volume (mm)
0.01
0.1
1
10
100
Observed runoff volume
Observed rainfall volume
Estimated runoff volume
Gamma distribution fitted to observed runoff
Gamma distribution fitted to observed rainfall volume
Weibull distribution fitted to estimated runoff volume
Figure 4.3 Probability distributions for the Coweeta 2
113
Probability in percent
0.1 1 10 30 50 70 90 99
Rianfall and runoff volume (mm)
0.01
0.1
1
10
100
Observed rainfall volume
Gamma distribution fitted to observed runoff
Gamma distribution fitted to observed rainfall volume
Weibull distribution fitted to estimated runoff volume
Observed runoff volume
Estimated runoff volume
Figure 4.4 Probability distributions for the Coweeta 36
114
Probability in percent
0.1 1 10 30 50 70 90 99
Rianfall and runoff volume (mm)
0.01
0.1
1
10
100
Observed runoff volume
Observed rainfall volume
Estimated runoff volume
Gamma distribution fitted to observed runoff
Gamma distribution fitted to observed rainfall volume
Weibull distribution fitted to estimated runoff volume
Figure 4.5 Probability distributions for the Fernow 4
115
Probability in percent
0.1 1 10 30 50 70 90 99
Rianfall and runoff volume (mm)
0.01
0.1
1
10
100
Observed runoff volume
Observed rainfall volume
Estimated runoff volume
Gamma distribution fitted to observed runoff
Lognormal distribution fitted to observed rainfall volume
Lognormal distribution fitted to estimated runoff volume
Figure 4.6 Probability distributions for the Hubbard Brook 3
116
CHAPTER 5
RUNOFF MODELING OF FOUR SMALL, MOUNTAINOUS-FORESTED
WATERSHEDS IN THE EASTERN UNITED STATES USING TOPMODEL4
4 Negussie Tedela, Todd Rasmussen, Steven McCutcheon, John Dowd, Rhett Jackson, Earnest W. Tollner, Wayne
Swank, John Campbell, and Mary B. Adams. To be submitted to the ASCE, Journal of Hydrologic Engineering.
117
Abstract
Runoff responses of four forested watersheds in eastern United States were investigated
using the TOPMODEL, a semi-distributed watershed model that uses topographic information to
simulate runoff at the watershed outlet based on the concepts of saturation excess overland flow
and subsurface flow. The use of the TOPMODEL in single-event runoff modeling is investigated
in this study. The model utilizes a topographic index as an indicator of the likely spatial
distribution of rainfall excess generation in the watershed. The topographic index values within
the watershed are determined using the digital terrain analysis procedures in conjunction with
digital elevation model (DEM) data. Five parameter sets are evaluated on performance of the
runoff prediction using the Generalized Likelihood Uncertainty Estimation (GLUE)
methodology, which involves evaluating many different randomly chosen parameter sets based
on likelihood measures to obtain the best-fit runoff hydrograph. These parameters are calibrated
based on three storm events and tested using three additional storm events for each watershed.
The results show that the model best predict runoff for Hubbard Brook 3 and Fernow 4
watersheds. However, the model performance in predicting runoff is relatively poor for the
Coweeta 36 and generally failed to simulate runoff for Coweeta 2 watershed at an acceptable
efficiency. Overall, some of the calibration results obtained in this study are in general agreement
with the results documented from previous studies using the TOPMODEL.
Keywords: runoff; TOPMODEL; runoff modeling; topographic index; subsurface flow,
rainfall-runoff relationship, watershed, variable source area, saturation excess, GLUE, curve
number
118
Introduction
Temperate forested watersheds typically have a large infiltration capacity due to the
presence of vegetation and a thick organic horizon supported by decomposing vegetation on the
surface. These features protect the surface from compaction and dispersion due to raindrop
impact. Also, root biomass maintains the highly permeability and infiltration capacity of the
surface soil. For example, southern Appalachian watersheds are forested with soils that are
deeply weathered and generally have a large infiltration capacity. In these watersheds,
stormwater runoff is largely controlled by subsurface responses (Beven 2000). On the Fernow
experimental watersheds in West Virginia, overland flow has never been observed (Toendle
1970). Overland flow is also negligible on Hubbard Brook watersheds (Pierce, 1967). The likely
runoff mechanism in humid forests is surface saturated-excess flow (Dunne and Black 1970).
This mechanism may dynamically generate runoff during a storm in a mountainous watershed,
not just near stream channels but also in depressions or hollows (Dunne et al., 1975). Together
with return flow, this process is known as the variable source-area concept (Hewlett and Hibbert;
1967). The dynamics of this concept are controlled by the topography, soils, antecedent
moisture, and rainfall characteristics. Topographic indices were introduced in an effort to take
these factors into account (Beven and Kirkby, 1979).
The TOPMODEL (TOPography based hydrologic MODEL) was first introduced by
Kirkby and Weyman (1974) to simulate runoff from a watershed based on the concept of
saturation excess overland flow and subsurface flow (Campling et al. 2002). The TOPMODEL
(Beven and Kirkby, 1979) is a physically based rainfall-runoff model that aims to reproduce the
hydrological behavior of watersheds in a semi-distributed way, in particular, the dynamics of
surface and subsurface contributing areas (Campling, et al. 2002). The model provides a
119
compromise between the complexity of fully distributed process models and the relative
simplicity of lumped empirical models (Robson et al. 1993). In general, the model represents a
set of modeling tools that combines the computational and parametric efficiency of a lumped
modeling approach with the link to physical theory (Beven et al. 1995a).
One of the features of recent progress in hydrological modeling has been the more
widespread availability of digital terrain models and the integration of hydrological modeling
with geographical information systems. The TOPMODEL provides one of the few easy to use
model structures that can make use of digital terrain model (DTM) data (Beven, 1997) and has
been used in a wide variety of applications. Beven et al. (1995a) provide a review of the history
of the TOPMODEL, the variants, and a summary of applications. They indicate that the
TOPMODEL is not a single model structure that will be of general applicability, but more a set
of conceptual tools that can be used to simulate hydrological processes in a relatively simple
way, particularly the dynamics of surface or subsurface contributing areas. Bhaskar et al. (2005)
use the model to simulate runoff at the watershed outlet based on the concept of saturation excess
overland flow and subsurface flow. Unlike the traditional application of this model to continuous
rainfall-runoff data, they use the model in single event runoff modeling.
The development of the TOPMODEL theory (Beven, 2000) is based on three
assumptions
• There is a saturated zone in equilibrium with a steady recharge rate over an upslope
contributing area.
• The watertable is almost parallel to the surface such that the effective hydraulic gradient
is equal to the local surface slope, tan β.
120
• The transmissivity profile may be described by experimental function of storage deficit,
with the value of To when the soil is just saturated to the surface (zero deficits).
TOPMODEL theory
As Bhaskar (2005) described, the rainfall-runoff equations used by the TOPMODEL are
derived from: (1) Darcy’s law, (2) the continuity equation, and (3) the assumption that the
saturated hydraulic conductivity decreases exponentially as depth below the land surface
increases. Darcy’s law in the TOPMODEL takes the form,
( ) ( )mD
ioiieTq/tan −= β (5.1)
where the index i refers to a specific location in the watershed, qi is the downslope flow beneath
the water table per unit contour length [L2 T-1], tan βi refers to the average inflow slope angle, To
is the surface transmissivity [L2 T-1] at location i, m is a transmissivity decay parameter [L], and
Di is the moisture deficit (amount of moisture required to saturate the soil) at location i [L]. The
continuity equation is represented by the quasi-steady-state recharge rate to the water table,
iii arq = (5.2)
where ri is the recharge rate [L T-1] to the water table and ai is the upslope contributing area per
unit contour length [L2 L-1] at any location i in the watershed. Combining (Equations 5.1 and 5.2)
and rearranging gives an expression for the moisture deficit, Di, at any particular location i
within the watershed (Beven et al. 1995a),
−=
io
ii
iT
armD
βtanln (5.3)
The variable, Di in the above equation can be expressed in terms of the average moisture deficit
(D ) for the entire watershed as
121
( ) ( )[ ]eoii TTmDD lnln −−−−= λλ (5.4)
where
( )iii a βλ tanln= (5.5)
is the local topographic index and Te is defined as the average transmissivity value for the entire
watershed or subwatershed and is equal to
o
i
e TA
T ∑
= ln1
(5.6)
The watershed average topographic index value, λ, in Equation (5.4) is equal to
( )∑
=i
iiaA
βλ tanln1
(5.7)
where A is the entire area of the watershed or subwatershed. Equation (5.4) is the fundamental
equation for describing runoff production within the TOPMODEL; this equation defines the
degree of saturation for each topographic index value λi at any location within the watershed. If
one assumes Te equal to To in Equation (5.4), Di depends on D and the deviation of the local
topographic index, λi, from λ. Since small values of Di are associated with larger values of the
topographic index, λi, the higher the topographic index value at any location in the watershed, the
smaller amount of moisture that will be needed to saturate the soil profile for that location. In the
TOPMODEL version used in (Beven et al. 1995b), the hydraulic conductivity, K, decreases
exponentially with depth.
The hydraulic conductivity and transmissivity have the relation
T = Kb (5.8)
where b is the assumed average depth of the soil moisture deficit zone. Hence the transmissivity
below the watershed surface can be expressed as
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( )mD
oieTT/−= (5.9)
where T [L2 T-1] is the transmissivity value for a local moisture deficit, Si. This relationship is
used in the development of Equation (5.4) above.
There are three main soil profile zones considered for runoff production in the
TOPMODEL. These are the root zone, the unsaturated zone, and the saturated zone (Beven et al.
1995a). When the root zone exceeds the field capacity of the soil, excess moisture contributes to
moisture storage in the unsaturated zone. Beven et al. (1995a) describe in detail the equations
describing flow through the unsaturated and saturated zones in the TOPMODEL. A brief
summary follows.
The vertical flux through the unsaturated zone is represented by
diuzvi tDq ϕ= (5.10)
where, qvi has units of [L/T], φuz is the moisture storage in the unsaturated zone at each time step
at location i [L], Si is the moisture deficit in the unsaturated zone at location i at each time step
[L], and td is the time delay per unit depth of deficit [T L-1]. In the above equation, the term in the
denominator, Si td, represents a time constant that increases with the soil moisture deficit.
The recharge rate to the saturated zone at any time step from the unsaturated zone is qvi
Ai, where Ai is the fractional area (fraction of total watershed area at location i) associated with
topographic index class i. This recharge is summed over the total number of topographic index
classes, n, to get the total recharge to the saturated zone
i
n
i
viv AqQ ∑=
=1
(5.11)
at the current time step. Once Qv [L T-1] enters the saturated zone, the flow in the saturated zone
or subsurface flow, Qb [L T-1], is
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( )mD
ob eQQ −= (5.12)
The flow Qb can also appear at the surface when the soil profile is fully saturated, such as at the
bottom of a hillslope. Qo [L/T] in Equation (5.12) is the subsurface flow when the soil is fully
saturated (i.e., when D = 0) and is equal to A (e-γ) where A is the total watershed area and γ is the
average soil-topographic index, given by
( )[ ]∑
= ioi TaA
βγ tan/ln1
(5.13)
For constant transmissivity, To, within the watershed, γ P= 1/To.
The recharge rate to the saturated zone, Qv (Equation 5.11) and the subsurface flow from
the saturated zone, Qb, (Equation 5.12) are used to update the value of the average moisture
deficit, in the watershed at each time step ∆t [T]. This is represented by
( ) tQQDDtt vbt ∆−+=−−
−11
1 (5.14)
where the subscript t represents the current time interval. Note that the initial value ofD , (i.e.,
when t = 0) is calculated from Equation (5.12) using the initial value of the observed hydrograph
as Qb. The total contribution to the watershed outlet at any time step, Qi (simulated flow), is the
sum of the subsurface flow, Qb, and the saturation excess overland flow, Qovr. The overland flow,
Qovr is calculated as the product of the depth of saturation excess and the fractional area of the
topographic index values that are generating the saturation excess.
Similarity of TOPMODLE and curve number method
Nachabe (2006) discussed the relation between the TOPMODEL and the curve number
method based on the initial suggestion of Boughton (1987), Steenhuis et al. (1995), and Lyon et
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al. (2004) that the curve number equation (Equation 5.15) simulates watershed runoff as an
ensemble of buckets with variable soil moisture deficit.
( )SIP
IPQ
a
a
+−−
=2
(5.15 a)
( )SP
PQ
e
e
+=
2
(5.15 b)
where Q is runoff depth, P is rainfall depth, Ia is the initial abstraction (includes interception,
depression storage, and infiltration losses prior to ponding and the commencement of overland
flow); S is the maximum retention capacity, which are typically expressed in inches, and Pe is P -
Ia. Equation (5.15 a) is valid for P > Ia and Q = 0 otherwise.
To adopt the curve number method simulate runoff from variable sources, the fraction of
watershed producing runoff should be the slope of the runoff equation (Equation 5.15 b) and
mathematically expressed as
( )22
1SP
S
A
A
dP
dQ
ew
s
e +−== (5.16)
where As and Aw are saturated and total areas of the watershed. The fraction of runoff source
area, As /Aw, increases monotonically with rainfall depth Pe; thus, as expected, the source area
fraction predicted by the curve number equation ranges from zero to a maximum of one, when Pe
approaches infinity. Equation (5.16) can be interpreted as a probability distribution function of
moisture deficit, Di (Equation 5.17) (Nachabe 2006).
( )ei
w
s PDFA
A<= (5.17)
With this interpretation, areas of the watershed with Di ≤ Pe will be the runoff sources. The
second observation made by Boughton leads to the conclusion that S in Equation (5.15)
125
approachesD , the watershed average moisture deficit, but only as Pe approaches infinity.
Therefore, assuming variable source runoff, an estimate of S can be
ii
c
i
c
ADA
dADA
DS ∆=== ∑∫11
(5.18)
Di can be estimated from available land cover, land use, and soil maps (Garbrecht et al., 2001).
Typically, Di is calculated in a particular land segment ∆Ai and then the summation is carried
over the entire watershed area. Setting S equal to potential watershed infiltration abstraction is
consistent with the definition of this term (Rallison, 1980). Nevertheless, when adapted for
variable source runoff, the curve number method implies that some water areas have infinite
storage, which cannot be physically realistic. The potential maximum retention S is equal to
D only in the limit as the entire watershed becomes runoff source area.
The curve number method can be considered similar in concept to the TOPMODEL, if
both methods simulate the expansion of a saturation source area using a probability function of
moisture deficit. For the two methods to predict a similar watershed saturation source for all
rainfall Pe, these should have similar probability distribution functions of moisture deficit. After
eliminating Pe between Equations (5.17) and (5.18), the two probability distribution functions are
matched by setting
( )( )2
2
1SD
SDF
i
i+
−= (5.19)
with Di calculated from the topographic index using
( ){ }λβ −−= tanln amDDi (5.20)
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The cumulative histogram of topographic index can be calculated from a DEM and the moisture
deficit Di (the left-hand side of Equation 5.18), and the right-hand side of Equation 5.18 is fitted
to this cumulative histogram.
Study watersheds
The study included four watersheds (Figure 5.1) from the Coweeta Hydrologic
Laboratory, North Carolina (Coweeta 2, and 36), and one watershed each from the Fernow
Experimental Forest, West Virginia (Fernow 4), and Hubbard Brook Experimental Forest, New
Hampshire (Hubbard Brook 3). The watersheds were selected because these are controls that
have not been disturbed for many years. The size of watersheds ranges from 12.26 hectares
(30.29 acres) to 108.0 hectares (267 acres) (Table 5.1). The elevation ranges from 222 meters
(728 feet) to 1,592 meters (5,223 feet) above sea level.
The Coweeta Hydrological Laboratory is located in the Blue Ridge Physiographic
Province of the southern Appalachian Mountains, near Otto, North Carolina. The Laboratory
elevation ranges from 675 to 1,592 meters (2,215 to 5,223 feet). The Coweeta soil depth
averages approximately 7 meters (23 feet) in depth at low to mid elevations (Coweeta 2) and is
much more shallower (<2 meters, 6.6 feet) at high elevations (Coweeta 36) (McCutcheon et al.,
2006). The forest cover includes northern hardwoods, cove hardwoods, xeric oak/pine,
oak/hickory, and mixed oak (USDA, 2004). Coweeta 2 and Coweeta 36 are Control watersheds
remaining uncut and undisturbed since 1927 but Coweeta 36 was partially defoliated by fall
cankerworm infestation from 1975 to 1979 (McCutcheon et al., 2006).
The Hubbard Brook Experimental Watershed is located in the White Mountain National
Forest. The bowl-shaped Hubbard Brook Valley has hilly terrain, ranging in elevation from 222
127
meters to 1015 meters (728 to 3330 feet). Average soil depth of Hubbard Brook is 50.3
centimeters or 19.8 inches with average depth of 6.9 centimeters or 2.7 inches of humus. The
present forest cover is composed of 80 to 90 percent northern hardwoods and 10 to 20 percent
spruce-fir (USDA, 2004). Hubbard Brook watershed 3 is a hydrologic control with last cut 1890
to 1920 with some residual stands more than 200 years old, although some timber downed by
hurricane of 1938 and salvaged (McCutcheon et al., 2006).
The Fernow Experimental Forest lies in the Allegheny Mountain section of the
unglaciated Allegheny Plateau and has ten experimental watersheds. Fernow elevations range
from 533 meters to 1113 meters (1749 feet to 3652 feet) with generally steep slopes. Depths of
soils at Fernow are typically 1 meter (3 feet) with 6 centimeters (2.5 inches) of humus. The forest
cover includes: northern red oak, chestnut oak, white oak, scarlet oak, black oak, and upland
oaks (Reinhart et al. 1963). Watershed 4 was last cut for timber harvest at various times during
circa 1905 to 1910 and the watershed is untreated, undisturbed control since May 1, 1951
(McCutcheon et al. 2006). A detail description of Coweeta, Fernow, and Hubbard brook
watersheds is provided by McCutcheon et al. 2006.
Methods
Measured rainfall-runoff datasets are used for the study as input data. Continuous rainfall
and runoff data at a fixed hourly interval are used for Hubbard Brook 3, Coweeta 2, and Coweeta
36 watersheds, while the interval used for Fernow watershed 4 is 15 minutes. Six pairs of rainfall
and runoff datasets are used for each watershed because of unavailability of continuous rainfall
and runoff dataset at a fixed time step for the entire length of storm durations. All longer duration
storm runoffs were excluded from the datasets to avoid the effect of evapotranspiration. Digital
128
Elevation Model (DEM) at a resolution of 10 meter is used for Coweeta and Hubbard Brook
watersheds and a 3-meter DEM resolution is used for Fernow watershed.
The elevation data at various formats are converted to be compatible to Arc Map GIS.
The boundaries of each watershed are used to clip the DEM data specific to the corresponding
watershed (Figures 5.2 to 5.5). The clipped DEMs are converted to text file using GIS
conversion tool to be used for Digital Terrain Model (DTM) analysis. The DTM Analysis
program is utilized to derive a distribution of ln (a/tanβ) values (Equation 5.5) from a regular
raster grid of elevations for each watershed using the multiple direction flow algorithm of Quinn
et al (1995). The DTM analysis has the topographic index distribution calculation and automatic
sink removal options. The topographic index distribution calculation requires that only elevations
of points within the watershed are supplied, all other values in the matrix being set to a value of
9999.0 (m).
Output from the DTM analysis is a histogram of the distribution of the topographic index
(ln (a/tanβ)) values (Figure 5.6). A file of the topographic index values are used for map output
in the TOPMODEL programs for each watershed. A topographic index values are used in the
model as an indicator of the likely spatial distribution of rainfall excess generation in the
watershed. Three types of data files are required to run the TOPMODEL. The watershed data file
specifies the topographic index, routing and parameter data for the watershed being simulated.
The simulated event rainfall and runoff data are specified using the inputs data file. The
evapotranspiration data are not included in the input file assuming that the data has insignificant
effect in the event based simulated runoff. The map data file provided a raster map of the
topographic index value for use in the mapping of the model predictions.
129
The parameters (Table 5.2) are (1) m, the exponential transmissivity function or recession
curve [L]; (2) ln (To), the natural logarithm of the effective transmissivity of the soil when just
saturated [L2T-1]; (3) SRmax, the soil profile storage available for transpiration, i.e. an available
water capacity [L]; (4) SRinit, the initial storage deficit in the root zone [L]; and (5) ChVel, an
effective surface routing velocity for scaling the distance/area or network width function (linear
routing is assumed) [LT-1]. These parameters are calibrated using three storm events and verified
using three additional storm events for each watershed (Tables 5.4 to 5.6). The criteria used in
the calibration process determine the parameter set yielding the highest Nash and Sutcliffe
efficiency (Nash and Sutcliffe, 1970) value defined by Equation 5.21.
A large number of Monte Carlo runs have been made using uniform random samples of
the parameters chosen for inclusion in the analysis. The outputs of Monte Carlo simulation files
are compatible with the Generalised Likelihood Uncertainty Estimation (GLUE) analysis. The
GLUE package provided tools for sensitivity analysis using the results of Monte Carlo
simulations. Within GLUE, each parameter set is evaluated in terms of a likelihood measure of
agreement with the available observations. The only formal requirement of the chosen likelihood
measure as Beven and Freer (2001) indicated is that the statistic should be zero for simulations
that are not consistent with the observations and which are rejected as non-behavioral and that
should increase monotonically as the performance of the model in reproducing the required
characteristics of the available observations improves. The parameters are always treated as a set
within GLUE so that interactions between the parameters in producing a good fit to the
observations are treated implicitly in the likelihood measure associated with each parameter set
(Beven and Freer, 2001). The Nash suit cliff efficiency, which is used for the likelihood
definition in this study, is defined as
130
( )
( )∑
∑
=
=
−
−−=
N
i
ooi
n
i
cioi
NS
E
1
2
1
2
1 (5.21)
where Qoi is the observed storm runoff, Qci is the computed runoff, oQ is the mean of the
observed runoff, Qei the estimated runoff obtained from the regression line of Qoi and Qci, n is the
total number time step used, and i is the number of each time step from 1 to n.
Figure 5.7 shows an example of the distribution of the likelihood measure (as dotty plots)
for a selection of parameters for the model for the Hubbard Brook 3 watershed. The dotty plots
are projections of the surface of the likelihood measure within a five-dimension parameter space
onto single parameter axes. As such, these plots cannot easily reveal any complex interactions
between parameters that result in good fits (Beven and Freer, 2001).
Routing is used in the model to recognize the effects of travel time within the watershed.
The routing method used in the TOPMODEL is a time area routing method. In the time area
method of watershed routing, the travel time in the watershed is divided into equal intervals. At
each time interval, the area within the watershed boundaries and the specific distance increment
will contribute to the flow at the watershed outlet. The partial flow at the watershed outlet from
each subarea is equal to the product of the rainfall excess produced multiplied by the area of the
contributing portion of the watershed. Summing the partial flows of all contributing areas at each
time step gives the total flow at the watershed outlet for each time step in the hydrograph (Ponce,
1989).
The model used root zone and unsaturated zone model structures, requiring minimal
additional parameters (Beven et al. 1995a). The dynamics of the saturated zone stores assumed
131
an exponential decline in conductivity with depth. Table 5.2 lists parameters required for the
model and the ranges assigned to each for the Monte Carlo simulations.
Results and discussion
A topographic index values are determined for all grid cells using GRIDATB (a multiple
flow direction algorithm) for each watersheds. The distribution of the topographic index values
for all watersheds is illustrated in Figure 5.8 (fractional area, As /A versus Topographic index
values). Higher values of the topographic index indicate higher potential of the landscape to
generate runoff to become wet. The average values of the topographic index, λ, (see Equation
5.7) are 5.86, 5.13, 4.65, and 6.36 for Coweeta 2, Coweeta36, Fernow 4, and Hubbard Brook 3,
respectively (Table 5.3). Fernow 4 has the lowest (0.81) and the highest (13.88) topographic
index values. The high topographic index band widened from the upstream side of the streams
down towards the watershed outlet (Figure 5.8). The low topographic index classes are
associated with the upland areas, which did not contribute directly to runoff. In all cases, the
map (Figure 5.8) showed a trend of increasing topographic index values from the escarpment to
around the lower stream channel areas, indicating that the runoff-contributing areas were largely
located along the stream channel of the watersheds.
The top ranked parameter sets, out of the 10,000 randomly selected parameter sets run for
the first three storm events, used to select parameter sets having the same values for all events.
This procedure was repeated for all watersheds during the calibration process. The selected
parameter sets are tested assigning the same values of parameter sets and run the model for the
remaining three storm events. The range of the parameters used together with the efficiency of
the model during the calibration and testing procedures is given in Table 5.7.
132
Figure 5.7 shows the scatter plots of maximum likelihood versus parameter values. All
values with negative efficiency are excluded from the plots. The scatter plots show the
exponential transmissivity function or recession curve parameter (m) is the most sensitive to
model performance for all watersheds compared to the other parameters. The scatter plot had a
peaked band of dots, which meant that the best model performances occurred for parameter sets,
for example, having m values between 0.008 and 0.016 meter for Hubbard Brook watershed 3.
The scatter plot of the initial storage deficit in the root zone parameter (SRinit) indicated a
tendency of achieving better results between 0.0 and 0.01 meter, but high modeling efficiencies
are also obtained from values as high as 0.02 meter. The scatter plot of the soil profile storage
available for transpiration, i.e. an available water capacity (SRmax), the natural logarithm of the
effective transmissivity of the soil when just saturated (ln To) and an effective surface routing
velocity (ChVel) parameters were completely flat topped across the range of parameter values set.
In general, the scatter plots indicated a high degree of equifinality between parameter sets,
meaning that wide ranges of parameter values were included in the parameter sets (Beven 2000).
The simulated hydrograph during the calibrating and testing procedures compared well
with the observed hydrograph for Hubbard Brook 3 and Fernow 4 watersheds. The timing, shape
and magnitude of the simulated hydrograph during the, rising, peak, and recession periods of
each storm events was very well reproduced by the model (Figures 5.10 and 5.11). The Nash
Sutcliffe efficiency during the calibration and testing procedures are 93.4 percent and 87.9
percent for Fernow 4 and 91.0 percent and 82.7 percent for Hubbard Brook 3 (Table 5.7). All
hydrographs generated in the TOPMODEL are in units of m/time step used or (m3/time step/m2)
and the results are shown in the same units. The Coweeta 36 showed relatively poor performance
(calibrating and testing Nash Sutcliffe efficiency of 76.9 percent and 70.3 percent) compared to
133
Fernow 4 and Hubbard Brook 3 watersheds (Table 5.7 and Figure 5.9). The TOPMODEL failed
to simulate runoff for the selected storm events of Coweeta 2 watershed. During the calibration
procedure, the same values of parameter sets were not obtained for Coweeta 2. This means a
single set of parameter would not provide a good fit to the observed runoff. In most of the storm
events, the top ranked parameter sets, out of the 10,000 randomly selected parameter sets failed
to provide a good performance of the model. The unique watershed characteristic of Coweeta 2
is that the watershed has greater soil depth compared to the other watershed. The other reason
could be the shape of the watershed has longer length and narrower width compared to rest of the
watersheds. Probably, this is the reason that the model does not perform well for Coweeta 2
watershed.
Conclusions
Tests of TOPMODEL calibrations for three single rainfall events on four small, forested
watersheds showed very good hydrograph simulations for three drainages. The calibrations for
watersheds produced a common parameter set for all three, calibration rainfall events on each
drainage. Coweeta 2 required different parameter sets for each of the three calibration storms.
The deeper soil of Coweeta 2 is perhaps the reason for the poor performance.
Acknowledgments
Financial assistance provided in part by funds from The U.S. Geological Survey through
the Georgia institute of Water Resources, and Warnell School of Forest and Natural Resources.
Professor K. J. Beven from Lancaster University, UK is gratefully acknowledged for providing
initial guidance and comments on this study. The watershed characteristics, rainfall, and runoff
134
datasets required for the study are provided by Wayne Swank and Stephanie from the Coweeta
Hydrologic Laboratory; Frederica Wood, from the Fernow Timber and Watershed Laboratory;
and John Campbell, from the Hubbard Brook Experimental Forest.
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247–253.
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how to use it in the TOPMODEL framework. Hydrological Processes 2(9): 161-182.
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138
Table 5.1 Characteristics of four mountainous forested watersheds in the eastern United States
Watershed Area
(hectares) Dominant aspect
Elevation
range
(meters)
Channel
length
(meters)
Average
slope
(%)
Annual
precipitation
(millimeter)
Coweeta 2 12.3 South by southeast 709 - 1004 392 60.2 1812
Coweeta 36 46.6 East by southeast 1021 - 1542 1327 65.3 2015
Fernow 4 38.7 East by southeast 740 - 865 683 20.6 1450
Hubbard Brook 3 42.4 Southwest 527 - 732 961 27.5 1370
139
Table 5.2 Parameter ranges
Parameters Symbol Units Range
Exponential transmissivity function m [L] 0.005 - 0.05
The natural logarithm of the effective transmissivity of the soil LnTo [L2T-1] 1.0 - 10.0
Soil profile storage available for transpiration SRmax [L] 0.01 - 1.0
Initial storage deficit in the root zone SRinit [L] 0.0 - 1.0
Channel velocity ChVel [LT-1] 1000 - 5000
140
Table 5.3 Range of topographic index values for all watersheds
Values of Topographic Index
Watershed Smallest Largest
Fractional area weighted average
Coweeta 2 2.68 12.12 5.86
Coweeta 36 2.26 13.00 5.13
Fernow 4 0.81 13.88 4.65
Hubbard Brook 3 2.70 13.87 6.36
141
Table 5.4 Model efficiencies for Coweeta 36 during calibration testing procedures
Date Efficiency
Calibration Testing m LnTo SRmax SRinit
Channel
Velocity
[LT-1]. Calibration Testing
1/20/1954 1/31/1982 0.0341 5.20 0.060 0.00002 3998 0.842762 0.638917
6/3/1967 11/25/1987 0.0341 5.20 0.060 0.00002 3998 0.753704 0.842337
3/11/1968 10/3/1995 0.0341 5.20 0.060 0.00002 3998 0.710455 0.629113
Average 0.768974 0.703456
Notes: m is the exponential transmissivity function or recession curve [L]; LnTo is the natural logarithm of the effective transmissivity of the soil when just saturated [L2T-1]; SRmax is the soil profile storage available for transpiration, i.e. an available water capacity [L]; SRinit is the initial storage deficit in the root zone [L]
142
Table 5.5 Model efficiencies for Fernow watershed 4 during calibration testing procedures
Date Efficiency
Calibration Testing m LnTo SRmax SRinit
Channel
Velocity
[LT-1]. Calibration Testing
10/15/1954 8/10/1984 0.0144 6.59 0.0139 0.0027 3498 0.94246 0.81967
5/26/1956 3/5/1989 0.0144 6.59 0.0139 0.0027 3498 0.94906 0.89976
6/5/1981 2/18/2000 0.0144 6.59 0.0139 0.0027 3498 0.91147 0.91791
Average 0.93433 0.87911
Notes: m is the exponential transmissivity function or recession curve [L]; LnTo is the natural logarithm of the effective transmissivity of the soil when just saturated [L2T-1]; SRmax is the soil profile storage available for transpiration, i.e. an available water capacity [L]; SRinit is the initial storage deficit in the root zone [L]
143
Table 5.6 Model efficiencies for Hubbard Brook 3 during calibration testing procedures
Date Efficiency
Calibration Testing m LnTo SRmax SRinit
Channel
Velocity
[LT-1]. Calibration Testing
2/11/1966 11/27/1993 0.0139 3.82 0.0184 0.0033 4828 0.91773 0.81992
10/19/1989 12/11/1996 0.0139 3.82 0.0184 0.0033 4828 0.90326 0.76568
8/10/1990 9/16/1999 0.0139 3.82 0.0184 0.0033 4828 0.9096974 0.89653
Average 0.91023 0.82738
Notes: m is the exponential transmissivity function or recession curve [L]; LnTo is the natural logarithm of the effective transmissivity of the soil when just saturated [L2T-1]; SRmax is the soil profile storage available for transpiration, i.e. an available water capacity [L]; SRinit is the initial storage deficit in the root zone [L]
144
Table 5.7 Mean efficiency of parameters for all watersheds
Calibrated parameters Mean Efficiency
Watershed
m LnTo SRmax SRinit
Channel
Velocity
[LT-1].
Calibration Verification
Coweeta 36 0.0341 5.20 0.0600 0.00002 3998 0.77 0.70
Fernow 4 0.0144 6.59 0.0139 0.00271 3498 0.93 0.88
Hubbard Brook 3
0.0138 3.82 0.0184 0.00331 4828 0.91 0.83
Notes: m is the exponential transmissivity function or recession curve [L]; LnTo is the natural logarithm of the effective transmissivity of the soil when just saturated [L2T-1]; SRmax is the soil profile storage available for transpiration, i.e. an available water capacity [L]; SRinit is the initial storage deficit in the root zone [L]
150
.
0.00
0.02
0.04
0.06
0.08
3 4 5 6 7 8 9 11 12
Topographic Index
Histogram of fractional area (As/A)
Coweeta 2
As = Saturated area
A = Total area
0.0
0.2
0.4
0.6
0.8
1.0
2 3 4 5 6 7 8 9 10 11 12
Topographic Index
Commutative farctional area (As/A)
Coweeta 2
As = Saturated area
A = Total area
0.00
0.02
0.04
0.06
0.08
0.10
0.12
2 4 5 6 7 9 10 11 13
Topographic Index
Histogram of fractional area (As/A)
Coweeta 36
As = Saturated area
A = Total area
0.0
0.2
0.4
0.6
0.8
1.0
0 2 4 6 8 10 12 14
Topographic Index
Commutative fractional area (As/A)
Coweeta 36
As = Saturated area
A = Total area
0.00
0.02
0.04
0.06
0.08
0.10
0.12
1 2 3 4 5 6 7 8 9 10 11 12 13
Topographic Index
Histogram of fractional area (As/A)
Fernow 4
As = Saturated area
A = Total area
0.0
0.2
0.4
0.6
0.8
1.0
0 2 4 6 8 10 12 14 16
Topographic Index
Commutative fractional area (As/A)
Fernow 4
As = Saturated area
A = Total area
0.00
0.02
0.04
0.06
0.08
0.10
3 4 5 6 7 8 9 11 12 13 14
Topographic Index
Histogram of fractional area (As/A)
Hubbard Brook 3
As = Saturated area
A = Total area
0.0
0.2
0.4
0.6
0.8
1.0
0 2 4 6 8 10 12 14 16
Topographic Index
Cumulative fractional area (As/A)
Hubbard Brook 3
As = Saturated area
A = Total area
Figure 5.6 Distribution of topographic index for all watersheds
151
0
0.2
0.4
0.6
0.8
1
0.00 0.01 0.02 0.03 0.04 0.05 0.06
Exponential transmissivity function (m )
Efficiency (ENS)
Range = 0.005 - 0.05
0
0.2
0.4
0.6
0.8
1
0 2 4 6 8 10 12
Natural logatithm of the effective transmissivity
of the soil when saturated (lnT o )
Efficiency (ENS)
Range = 1 -10
0
0.2
0.4
0.6
0.8
1
0.00 0.02 0.04 0.06 0.08 0.10 0.12
Available water capacity (SR max )
Efficiency (E
NS)
Range = 0.01 - 1.0
0
0.2
0.4
0.6
0.8
1
0 0.01 0.02 0.03 0.04 0.05 0.06
Initial storage deficit in the root zone (SR int )
Efficiency (ENS)
Range = 0 - 1
0
0.2
0.4
0.6
0.8
1
0 1000 2000 3000 4000 5000 6000
Surface routing velocity (Ch Vel )
Efficiency (ENS)
Range = 1000 - 5000
Figure 5.7 Dotty plots for all parameters for the Hubbard Brook watershed 3. Each dot represents one simulation with different randomly chosen parameter values within the ranges as shown in Table 5.2.
152
(a) Coweeta 2
(c) Fernow 4
(b) Coweeta 36
(d) Hubbard Brook 3
Figure 5.8.The spatial pattern of the topographic index classes used in the TOPMODEL as determined from an analysis of surface topography.
153
Figure 5.9 Comparison of observed and simulated hydrograph for Hubbard Brook watershed 3 [(a) Calibration and (b) Testing]
154
Figure 5.10 Comparison of observed and simulated hydrograph for Fernow watershed 4 [(a) Calibration and (b) Testing]
155
0
5
10
15
20
25
30
35
1 21 41 61 81 101 121 141
Time step (1 hour)
Rainfall (mm)
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
Runoff (mm / tim
e step)
Rainfall
Observed runoff
Simulated runoff
Date: 01-20-1954(a)
0
10
20
30
40
50
60
70
1 21 41 61 81 101 121
Time step (1 hour)
Rainfall (mm)
0
1
2
3
4
5
6
7
8
9
Runoff (mm / tim
e step)
Rainfall
Observed runoff
Simulated runoff
Date: 06-03-1967(a)
0
10
20
30
40
50
60
1 11 21 31 41 51 61 71 81 91
Time step (1 hour)
Rainfall (mm)
0
1
2
3
4
5
6
Runoff (mm / tim
e step)
Rainfall
Observed runoff
Simulated runoff
Date: 03-11-1968(a)
0
10
20
30
40
50
1 11 21 31 41 51 61 71
Time step (1 hour)
Rainfall (mm)
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
Runoff (mm / tim
e step)
Rainfall
Observed runoff
Simulated runoff
Date: 01-31-1982(b)
0
10
20
30
40
50
1 21 41 61 81 101
Time step (1 hour)
Rainfall (mm)
0
1
2
3
4
5
6
7
8
9
10
11
12
Runoff (mm / tim
e step)
Rainfall
Observed runoff
Simulated runoff
Date: 11-25-1987(b)
0
10
20
30
40
50
60
70
1 21 41 61 81
Time step (1 hour)
Rainfall (mm)
0
1
2
3
4
5
6
7
8
9
Runoff (mm / tim
e step)
Rainfall
Observed runoff
Simulated runoff
Date: 10-03-1995(b)
Figure 5.11 Comparison of observed and simulated hydrograph for Coweeta watershed 36 [(a) Calibration and (b) Testing]
156
CHAPTER 6
CONCLUSIONS
The Natural Resources Conservation Service (2001) tabulated curve numbers based on
soil hydrologic group, land use, and surface condition were not adequate to estimate runoff for
the ten small, mountainous-forested watersheds in the eastern United States. All runoff values
estimated from Natural Resources Conservation Service tabulated curve numbers were
significantly biased. Therefore, the current Natural Resources Conservation Service (2001)
tabulations for “woods” should not be used to estimate runoff in forested watersheds unless the
estimated curve numbers are independently confirmed using calibration data from gaged
watersheds with similar hydrologic conditions.
The curve numbers determined from annual maximum series of observed rainfall and
runoff indicate wide variability from average runoff conditions for a particular watershed and,
hence, a unique curve number does not provide an adequate estimate of runoff volume. Observed
and estimated runoff volumes were not highly correlated for six of ten-forested watersheds.
Therefore, the calibrated curve numbers for gauged, forested watersheds also contain large
uncertainties, and should only be used if statistical analyses confirm that estimated runoff
adequately agrees with observations.
No significant difference (at the 0.05 level of significance) exists in using either of the
median, geometric mean, or arithmetic mean curve number (computed from measured rainfall
and runoff events) to estimate runoff for all watersheds. However, for some watersheds the
157
estimates based on any of the central tendency based curve number did not agree with
measurements. .
The growing-season curve numbers were significantly different from that of the dormant
season curve numbers for only three of the six gaged watersheds. The lack of statistical evidence
of seasonal effects was apparently due to the large uncertainties in curve numbers
Paired studies on three watersheds suggested that timber harvesting increased streamflow
and, hence, increased curve numbers derived from observed rainfall and runoff data. However,
the increase in curve number was not significant (at the 0.05 level of significance) for one of
three clearcuts
The probability distributions of three watersheds (out of four watersheds) demonstrated
that the Natural Resources Conservation Service tabulated curve number method estimated
runoff for extreme rainfall events, occurring once in one hundred years or longer. This means,
the tabulated curve number may predict runoff for events occurring rarely and under predicts
runoff for less frequent rainfall events. In general, the four discrete distributions of estimated
runoff only crossed the discrete observed runoff distribution a single point or short interval and
these points or intervals did not consistently correspond to the two-year return intervals for the
which the tabulated curve numbers were developed. The limited intersections at different return
intervals also imply that single watershed curve numbers for these four watersheds may not be
adequate. The gamma distribution matched the observed annual maximum rainfall and runoff for
all watersheds.
The TOPMODEL provides a better prediction of runoff for three of the four watersheds
considered. However, the model failed to simulate runoff accurately for one of (Coweeta 2) the
158
watersheds at an acceptable efficiency. The TOPMODEL could only be calibrated for Coweeta 2
with three different sets of parameters for the three rainfall events selected for calibration.
159
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176
APPENDICES
APPENDIX A
CURVE NUMBER ESTIMATION PROCEDURES
The Natural Resources Conservation Service curve number tabulation: The tabulated curve
number for each watershed was determined from (1) the hydrologic soil groups (Table 2.1), (2)
“woods” land cover, and (3) good hydrologic condition (protected from grazing, with liter and
shrubs covering the soil) for an average condition as shown in Table A.1. For watersheds having
more than one hydrologic soil group, the procedure requires selection of curve numbers for each
hydrologic soil group from Table A.1 and the area-weighted-average curve number was the
tabulated watershed curve number referred to in the text. Equations (2.5) and (2.6), using the
weighted curve number, were applied to calculate runoff.
Table A.1 Runoff curve number for the hydrologic soil and land cover complex, average condition, and initial abstraction Ia = 0.2 x potential maximum retention S (NRCS, 2001)
Hydrologic soil group Land use
Hydrologic condition A B C D
Poor 45 66 77 83
Fair 36 60 73 79 Woods
Good 25 55 70 77
Arithmetic mean and median: For each pair of series of measured rainfall and measured
runoff, the procedure computed curve numbers from Equation (2.7). The curve numbers were
ranked and the value for which one-half were larger and one-half smaller was the median. The
arithmetic mean curve number was a simple average of the curve number series.
177
Geometric mean or the Natural Resources Conservation Service statistical method: The
curve number was determined for each watershed using the following procedure:
1. The potential maximum retention for each pair of runoff Q and rainfall P was computed
as
( )PQQQPS 5425 2 +−+= (A-1)
2. The mean µ and standard deviation δ of the logarithms of potential maximum retention S
was
( )N
SS
∑=log
logµ (A-2)
( )1
log2
log
log −
−= ∑
N
S S
S
µδ (A-3)
where N was the number of pairs of rainfall and runoff in the series. The mean of the
transformed potential maximum retention, the mean (log S), was equivalent to the median
of the series of the potential maximum retention if the distribution is lognormal (Yuan,
1933).
3. The geometric mean of the potential maximum retention in base 10 logarithms was
S
GMS log10µ= (A-4)
4. The geometric mean curve number was
10
000,1
+=
GM
GMS
CN (A-5)
Nonlinear Least Squares Fit: For a pair of watershed series of observed rainfall P and
observed runoff Qo, the optimal potential maximum retention S was that which minimized the
objective function
178
( ) ( )2
1
∑=
−=N
i
ioi QQObjf (A-6)
where Qi is the runoff computed from the curve number runoff Equation (2.5). The square root
of the minimum objective function divided by N (number of observations of rainfall and runoff)
was the standard error (Richard Hawkins, University of Arizona, personal communication,
February 17, 2006).
The measure of fractional variance reduction R2 (Richard Hawkins, University of
Arizona, personal communication, February 17, 2006) is similar to the linear regression
coefficient r2 for the tradition linear least squares
2
2 1
−=
Qo
e
s
sR (A-7)
where sQo is the standard deviation of the observed runoff and se is the standard error.
Asymptotic method: Both the runoff series and the rainfall series were ranked separately
by magnitude and matched by order to compute the corresponding curve numbers. Individual
runoff depths were not necessarily associated with the original rainfalls that caused flow
response. Sneller (1985) and Hawkins (1993) identified three types of watershed responses
(standard, complacent, and violent). The most typical is the standard response that occurs when
the ratio of rainfall and runoff becomes constant for increasing rainfall and curve number
decreases to an ultimate or asymptotic limit CN∞ (Figure 2.2). The complacent response occurs
when surface runoff is very small even with large storms indicating only channel and local
impervious area runoff and no curve number limit is reached for increasing rainfall. A watershed
response is violent when the watershed starts producing more runoff after the rainfall has
exceeded a certain amount (Sneller, 1985).
179
The procedure fitted the empirical curve number versus event rainfall equation developed
by Sneller (1985) and Hawkins (1993) for the standard response to determine the asymptotic
curve number CN∞ and constant k [L-1]
)exp()100()( kPCNCNPCN −−+= ∞∞ (A-8)
where P was the rainfall volume in the dimension of length [L]. The violent rainfall-curve
number response (Hawkins, 1993) was
( ) ( )[ ]kpCNPCN −−= ∞ exp1 (A-9)
In the complacent response, runoff is a linear function of rainfall (Hawkins, 1993)
CPQ = (A-10)
where C is a constant that can be determined from rainfall-runoff measurments. For watersheds
in which the maximum measured rainfall was associated with a curve number that approached
the asymptotic limit, Sneller (1985) developed an arbitrary criterion to categorize the response as
standard or complacent
9.00
0 max ≥−
−
∞=
=
ββ
ββ
P
PP (A-11)
where βP=0, βPmax and β∞ are the slopes of the relationship between rainfall and the curve number
at which rainfall equals zero, at the maximum measured rainfall amount, and at infinity,
respectively. The threshold Pmax occurs where the relationship between rainfall and the curve
number (Figure 2.2) has gone through 90 percent of the change in slope from the slope at P = 0
to the slope equal to 0 as P approaches infinity. The slope is
( ) ( )( )kkPCNP
CN−−−== ∞ exp100
δδ
β (A-12)
At P = 0
180
( )∞= −−== CNkP
CNP 1000 δ
δβ (A-13)
At P = Pmax
( ) ( )maxmax exp100 kPCNkP
CNP −−−== ∞δ
δβ (A-14)
At P = ∞
( ) ( )[ ] 0exp100 =∞−−−== ∞∞ kCNkP
CN
δδ
β (A-15)
Transforming Equation (A-11) with Equations (A-13), (A-14), and (A-15) led to the maximum
measured rainfall in inches [Equation (A-14a)] and in millimeters [Equation (A-14b)].
kP
303.2max ≥ (A-16a)
or
kP
496.58max ≥ (A-16b)
If the maximum rainfall recorded for a watershed is less than 2.303/k inches or 58.496/k
millimeters, the asymptotic method of determining a curve number lacks sufficient rainfall
observations to be valid according to Sneller (1985).
181
APPENDIX B
PROBABILITY DISTRIBUTIONS
• Probability density function (PDF) is any function f (x) that describes the probability
density in terms of the input variables in a manner described below.
f (x) is greater than or equal to zero for all values of x.
The total area under the graph is 1:
( ) 1=∫∞
∞−
dxxf (A1)
The actual probability can then be calculated by taking the integral of the function f (x) by
the integration interval of the input variable x. For example, the probability of the
variable X being within the interval [1, 5] would be
( ) ( )dxxfX ∫=≤≤5
1
51Pr (A2)
• Cumulative distribution function (CDF), also called probability distribution function
or just distribution function, describes the probability distribution for a real-valued
random variable X. For every real number x, the CDF of X is given by
( ) ( )xXPxFx x ≤=→ (A3)
where the right hand side represents the probability that the random variable X taken on a
value less than or equal to x. The probability that X lies in the interval (a, b] is, therefore,
F (b) – F (a) if a < b. A capital F for a cumulative distribution function is conventional in
contrast to the lower-case f used for probability density function. The CDF of f can be
defined in terms of the probability density function f as follows:
( ) ( ) 1== ∫∞
∞−
dttfxF (A4)
182
wher f (t) is a function which varies with time
• Empirical distribution function (EDF) is a cumulative probability distribution function
that concentrates probability (1/n) at each of the n numbers in a sample expressed as.
( ) ( )∑=
≤=n
i
in xXIn
xF1
1 (A5)
where I (Xi ≤ x) is an indicator of event (Xi ≤ x)
• Shape parameter (γ): is a parameter that allows a distribution to take on a variety of
shapes, depending on the value of the shape parameter.
• Location parameter (µ): is a parameter that simply shifts the graph left or right on the
horizontal axis
• Scale parameter (β): is a parameter that has an effect of stretching out or squeezing the
probability distribution function
• Normal distribution: is a distribution that has a general formula for the probability
density function which can be expressed as
( )( ) ( )
πβ
βµ
2
222−−
=xe
xf x ≥ µ; β > 0 (A6)
where µ is the location parameter and β is the scale parameter. The case where µ = 0 and
β = 1 is called the standard normal distribution. The equation for the standard normal
distribution is
( )π2
22xexf
−
= x ≥ 0 (A7)
Since the general form of probability functions can be expressed in terms of the standard
distribution, all subsequent formulas in this section are also given for the standard form
of the function in addition to the general form.
183
• Lognormal distribution: A variable X is lognormally distributed if Y = Ln (X) is
normally distributed with "Ln" denoting the natural logarithm. The general formula for
the probability density function of the lognormal distribution is
( )( )( )( ) ( )( )
( ) πγµ
γβµ
2
222//ln
−=
−−
x
exf
x
x ≥ µ; β, γ > 0 (A8)
where γ is the shape parameter, µ is the location parameter and β is the scale parameter.
The case where µ = 0 and β = 1 is called the standard lognormal distribution. The
equation for the standard lognormal distribution is
( )( ) ( )( )
πγ
γ
2
222/ln
x
exf
x−
= x ≥ 0; γ > 0 (A9)
• Gamma distribution: is a distribution that has a general formula for the probability
density function
( ) ( ) ( )
( )γββµ βµγ
Γ−
=−−− xex
xf
1
x ≥ µ; γ, β > 0 (A10)
where γ is the Shape parameter, µ is the location parameter β is the scale parameter, and Г
(a) is the gamma function which has the formula
( ) dteta ta −∞
−∫=Γ0
1 (A11)
The case where µ = 0 and β = 1 is called the standard Gamma distribution and described
as
( ) ( ) ( )
( )γ
γ
Γ=
−− xexxf
1
x ≥ 0; γ > 0 (A12)
• Weibull distribution: has a general form of probability density function
184
( )( )
( )( )( )γβµγ
βµ
βγ /
1
−−
−
−= xe
xxf x ≥ µ; γ, β > 0 (A13)
where γ is the shape parameter, µ is the location parameter and β is the scale parameter.
The case where µ = 0 and β = 1 is called the standard Weibull distribution. The case
where µ = 0 is called the 2-parameter or standard Weibull distribution. The equation for
the standard Weibull distribution reduces to
( ) γγγ xexxf −−= )1( x ≥ 0; γ > 0 (A14)
since the general form of probability functions can be expressed in terms of the standard
distribution.
• Goodness-of-fit tests: indicate whether a sample comes from a specific distribution.
Statistical techniques often rely on observations having come from a population that has a
distribution of a specific form (e.g., normal, lognormal, and Weibull).