Startseite Curve number estimation using rainfall and runoff data from five catchments in Sudan
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Curve number estimation using rainfall and runoff data from five catchments in Sudan

  • Salma Ibrahim EMAIL logo , Babikir Brasi , Qingchun Yu und Magdi Siddig
Veröffentlicht/Copyright: 29. März 2022
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Aus der Zeitschrift Open Geosciences Band 14 Heft 1

Abstract

The United States Natural Resources Conservation Services Curve Number (NRCS-CN) method uses the CN and rainfall to calculate runoff. However, there are still some uncertainties in the method, such as choosing the most appropriate CN value. Therefore, this study attempts to evaluate the effectiveness of using the NRCS-CN method to estimate the runoff of five catchments in Sudan. For each catchment, CN values were obtained from the number of observed rainfall-runoff events using the NRCS table, arithmetic mean, median, and geometric mean methods. For each method, Nash–Sutcliffe efficiency (NSE) was obtained to evaluate the fit between the observed and runoff, and negative NSE values were found for all methods. Negative values of NSE indicate that the observed runoff and estimated runoff are not well fitted, and the NRCS-CN method is not suitable for runoff calculation in the study areas.

Keywords: curve number; Sudan; catchment; runoff; rainfall and linear relationship

1 Introduction

Runoff estimation from rainfall is of great significance in flood control research. In addition, direct runoff estimates are important for power generation, agriculture, and irrigation in a lot of countries [1]. There are various ways to estimate runoff. The Soil Conservation Service Curve Number (SCS-CN) method is the most commonly used method for estimating runoff, and it was renamed as the Natural Resources Conservation Services Act (NRCS) in 1994 [2]. CN tables were developed by the United States Department of Agriculture. CN usually ranges between 30 and 10 [3]. Low runoff is represented by minimum values of CN, while CN values approaching 100 represent high runoff. The United States Department of Agriculture developed this method; it relies on land use and land cover types of the American agricultural catchments. The characteristics of land use and land cover in Sudan are likely to be different from those in the United States. Land use, soil type, antecedent water conditions, treatment, and surface conditions are the main factors affecting runoff generation. The disadvantages of the NRCS-CN method include a single parameter containing a variety of factors (such as land use, soil type, antecedent water condition, and surface conditions) rendering the method very delicate, the influence of spatial scale, intensity, and temporal distribution of rainfall and the effect of adjacent moisture condition are not considered [2]. In general, the Sudan curve numbers are obtained from the NRCS-CN tables, and the curve numbers in these tables may not be applicable to Sudan, as the NRCS-CN tables depend on the land features of the United States. In this article, the authors attempt to evaluate the use of the NRCS-CN method to estimate runoff in five catchments in Sudan. Using NRCS-CN tables, CN values were estimated in a Geographic Information System (GIS) [4]. Shuttle Radar Topography Mission 30m resolution (SRTM30) is the Digital Elevation Model (DEM) used in this research [5]. Rainfall-runoff events were used to calculate the CN using three statistical methods (arithmetic mean, median, and geometric mean).

2 Methods

2.1 Study area

The study areas are distributed in different parts of Sudan. The first study area is the Abufargha catchment in the eastern region of Sudan in Al Gadarif State (Figure 1a). Abufargha catchment has a drainage area of 92.4 km2 and its outlet coordinates are 14°02′ N and 35°22′ E. The second study area is the Eldilling catchment in the southern region of Sudan in South Kordofan State (Figure 1b). The Eldilling catchment has a drainage area of 484.84 km2 and its outlet coordinates are 13°11′ N and 29°59′ E. The third study area is the Erigi catchment in the western region of Sudan in North Darfor State (Figure 1c). The Erigi catchment has a drainage area of 73.3 km2 and its outlet coordinates are 14°00′ N and 24°31′ E. The fourth study area is the Tiflo catchment in the western region of Sudan in North Darfor State (Figure 1d). The Tiflo catchment has a drainage area of 329.87 km2 and its outlet coordinates are 14°24′ N and 23°32′ E. The last one is the Abasya catchment in the southern region of Sudan in South Kordofan State (Figure 1e).” The Abasya catchment has a drainage area of 289.23 km2 and its outlet coordinates are 12°10′ N and 31°19′ E. The DEM is a fundamental dataset for the simulation of the stream network; it is useful for the delineation of the watershed and the illustration of the topographic variations in the area. In this study, the DEM with 30 m horizontal spatial resolution was used, mosaicked, and processed.

Figure 1 (a) Location of Abufargha catchment, (b) location of Eldilling catchment, (c) location of Erigi catchment, (d) location of Tiflo catchment, and (e) location of Abasya catchment.
Figure 1 (a) Location of Abufargha catchment, (b) location of Eldilling catchment, (c) location of Erigi catchment, (d) location of Tiflo catchment, and (e) location of Abasya catchment.
Figure 1

(a) Location of Abufargha catchment, (b) location of Eldilling catchment, (c) location of Erigi catchment, (d) location of Tiflo catchment, and (e) location of Abasya catchment.

3 Data sets

Daily rainfall-runoff events from five catchments were obtained from Sudan Meteorological Authority and Ministry of Water Resources, Irrigation, and Electricity. Each of the catchment’s daily events were used to estimate the CN. Measuring stations at each catchment outlet were used to measure runoff. Daily rainfall and runoff were measured in millimeter (mm) units. Thiessen Polygon method was used to represent the average rainfall over study areas. In this study, events having runoff coefficients greater than 1% were used. The number of events for Abufargha, Eldilling, Erigi, Tiflo, and Abasya catchments is 24, 28, 36, 17, and 18, respectively. The period of daily events for the Abufargha catchment is from 1981 to 2008, from 1974 to 1986 for Eldilling catchment, from 1966 to 1975 for Erigi catchment, from 1965 to 1973 for Tiflo catchment, and from 1968 to 1973 for the Abasya catchment.

4 Curve number estimation

4.1 CN estimation using NRCS-CN tables

To estimate CN using NRCS-CN tables, Arcmap 10.5 was used. The common estimation method of NRCS-CN by using Arcmap 10.5 is as follows:

  1. Selection and drawing of the outlines of the catchments.

  2. Determination of the catchment areas.

  3. Mapping of the soil types and land use for catchment areas.

  4. Changing of the soil types to hydrologic soil groups.

  5. Overlaying of the land use and hydrologic soil group maps to identify each unique land use, soil group polygon, and to compute the area of each polygon.

  6. Allocation of a CN to each singular polygon based on the NRCS-CN tables [6].

The total CN of the catchment is calculated by area weighting of the polygons of the land use-soil group in the catchment.

5 NRCS-CN estimation from daily rainfall and runoff data

The formula for estimating runoff depth using NRCS-CN is as follows:

(1) Q = ( P 0.2 S ) 2 P + 0.8 S , P > 0.2 S ,

(2) Q = 0 , P < 0.2 S ,

where P is the depth of rainfall (mm), Q is the depth of runoff (mm), and S is the potential maximum storage [7]. The general equation of NRCS-CN is given by:

(3) S = P λ + ( 1 λ ) Q ( 1 λ ) 2 Q 2 + 4 λ P Q 2 λ 2 ,

where P is the depth of rainfall (mm), Q is the depth of runoff (mm), λ is the initial abstraction (Ia) coefficient, and S is potential maximum storage [2]. By knowing the rainfall and runoff data in the catchments, CN is estimated by applying equations (3) and (4). Considering λ to be equal to 0.2, equation (3) will be [8]:

(4) S = 5 [ P + 2 Q ( 4 Q 2 + 5 P Q ) 1 2 ] .

CN is estimated from S:

(5) CN = 100 254 S + 254 .

Arithmetic mean [9], the median, and geometric mean [10] were used to obtain CN values from rainfall-runoff data.

The depths of rainfall and runoff are substituted into equation (4) to obtain the values of the computed and measured S. When S is substituted into equation (5), the computed and measured CN can be obtained. Equation (6) was used to obtain the CN using the geometric mean method.

(6) CN = 100 1 + 10 log S ¯ 254 .

5.1 Statistical analyses

The coefficient of determination (R 2), the NSE, and percentage mean bias (PBIAS) were utilized for the statistical analyses. R 2, NSE, and PBIAS were computed using equations (7)–(9) [11].

(7) R 2 = i = 1 n ( Q obs Q ¯ obs ) ( Q est Q ¯ est ) i = 1 n ( Q obs Q ¯ obs ) 2 × i = 1 n ( Q est Q ¯ est ) 2 0.5 2 ,

(8) NSE = i = 1 n ( Q est Q obs ) 2 i = 1 n ( Q obs Q ¯ obs ) 2 ,

(9) PBIAS = i = 1 n ( Q obs Q est ) × X 100 i = 1 n Q obs ,

where Q obs is the value of the observed runoff, Q ¯ obs is the average of the observed runoff, Q est is the value of the estimated runoff, and Q ¯ est is the average value of the estimated runoff.

If R 2 is greater than 0.5, it is considered “acceptable.” NSE values range from −∞ to 1, and can be considered as “very good” if 0.75 < NSE ≤1; “good,” if 0.65 < NSE ≤75; “satisfactory,” if 0.50 <NSE ≤0.65; and “unsatisfactory,” if NSE ≤0.50. The PBIAS positive and negative values indicate model underestimation bias. The PBIAS can be considered “very good” if PBIAS < ±10%; “good,” if 10% ≤ PBIAS < ±15%; “satisfactory,” if 15% ≤ PBIAS < ±25%; and “unsatisfactory,” if PBIAS ≥ ±25% [11].

6 Results and discussion

In order to generate the CN based on NRCS-CN tables, soil maps, land use maps, and hydrological soil maps were prepared. The results are as described below:

6.1 Hydrological soil map

For each catchment, the generated hydrologic soil group was used as the input of the CN in ArcMap 10.5. It is a feature of the soil mapping unit and each soil mapping unit is allocated to a particular hydrological group: A, B, C, and D [10]. The watershed has different soil groups according to which the soil code has been assigned. Clay loam was taken as hydrologic group D, sandy clay loam as soil group C, loam as soil group B, and sandy loam as hydrologic group A. The hydrologic groups A, B, C, and D formed in Arcmap 10.5 are shown in Table 1 and Figure 2(a)–(e). Due to different infiltration rates, each soil group has different runoff. The soil in group A has the lowest runoff potential, while the soil in group D has the highest runoff potential [12].

Table 1

Soil groups of catchments

Catchment Hydro group Area (%)
Abufargha C 100
Eldilling A 22.4
C 0.76
D 76.9
Erigi A 97.7
B 2.3
Tiflo B 100
Abasya C 4.6
D 95.6
Figure 2 (a) Soil group of Abufargha catchment, (b) soil group of Eldilling catchment, (c) soil group of Erigi catchment, (d) soil group of Tiflo catchment, and (e) soil group of Abasya catchment.
Figure 2

(a) Soil group of Abufargha catchment, (b) soil group of Eldilling catchment, (c) soil group of Erigi catchment, (d) soil group of Tiflo catchment, and (e) soil group of Abasya catchment.

6.2 Land cover maps

In the present study, the supervised classification was carried out in ArcMap 10.5. Two land use land cover grades such as residential and agricultural exist [4]. The land use land cover maps are shown in Table 2 and Figure 3(a)–(e).

Table 2

Land use of catchments

Catchment Land use Area (%) Land use reclassification
Abufargha Croplands 86.9 Agricultural
Cities 13.10 Medium residential
Eldilling Open deciduous Shrubland 4.70 Agricultural
Closed grassland 0.32 Agricultural
Cropland 1.67 Agricultural
Crop with opened woody vegetation 93.31 Agricultural
Erigi Open grassland with sparse shrubs 15.90 Agricultural
Cropland 84.10 Agricultural
Tiflo Open grassland 25.40 Agricultural
Spare grassland 74.64 Agricultural
Abasya Open deciduous Shrubland 0.22 Agricultural
Cropland 0.31 Agricultural
Crop with opened woody vegetation 99.47 Agricultural
Figure 3 (a) Land use types of Abufargha catchment, (b) land use types of Eldilling catchment, (c) land use types of Erigi catchment, (d) land use types of Tiflo catchment, and (e) land use types of Abasya catchment.
Figure 3

(a) Land use types of Abufargha catchment, (b) land use types of Eldilling catchment, (c) land use types of Erigi catchment, (d) land use types of Tiflo catchment, and (e) land use types of Abasya catchment.

6.3 Generating CN maps

The land use map, soil map, and the DEM as inputs are first imported into ArcMap 10.5. The HEC-GeoHMS extension tool of Arcmap 10.5 was used to generate the CN grid [12]. The appropriate code is given to the soil type. Soil code provides the hydrologic soil group in the area. Then, the land use and hydrologic soil group are combined to form a new merged soil and land use map. The CN look up table (Table 3) was created and the appropriate CN value was assigned for each soil land map [13]. The CN values for each catchment using the NRCS-CN tables are shown in Table 3 and Figure 4(a)–(e).

Table 3

CN lookup table

Land use A B C D
Medium residential 57 72 81 86
Agricultural 66 77 78 87
Figure 4 CN grid based on NRCS-CN tables, soil maps, and land use maps of (a) Abufargha catchment, (b) Eldilling catchment, (c) Erigi catchment, (d) Tiflo catchment, and (e) Abasya catchment.
Figure 4

CN grid based on NRCS-CN tables, soil maps, and land use maps of (a) Abufargha catchment, (b) Eldilling catchment, (c) Erigi catchment, (d) Tiflo catchment, and (e) Abasya catchment.

6.4 CN estimation using rainfall and runoff data

For each catchment, rainfall-runoff events were analyzed and the CN values, R 2, NSE, and PBIAS were estimated for five catchments as shown in Table 4. CN values for the Abufargha, Eldilling, Erigi, Tiflo, and Abasya catchments range from 82.94 (NRCS-CN table) to 90.96 (geometric mean), from 82.43 (NRCS-CN table) to 87.19 (median), from 67.13 (NRCS-CN table) to 93.11 (geometric mean), from 77 (NRCS-CN table) to 94.63 (median), and 86.597 (NRCS-CN table) to 98.71 (geometric mean), respectively. R 2 for Abufargha, Eldilling, Erigi, Tiflo, and Abasya catchments are 0.575–0.621, 0.509–0.5533, 0.239–0.625, 0.061–0.746, and 0.5368–0.632, respectively. NSE values for Abufargha, Eldilling, Erigi, Tiflo, and Abasya catchments are −2.941 to −20.441, −21.655 to −38.1557, −2.365 to −6.874, −161.937 to −1846.635, and −522.935 to −2763.9, respectively. The PBIAS for Abufargha, Eldilling, Erigi, Tiflo, and Abasya catchments are 217.565–400.011, 459.040–8599.886, 281.614–1614.411, 1194.876–1903.735, and 1149.784–2660.558, respectively.

Table 4

Estimated curve numbers and statistical analyses

Catchment Method CN R 2 NSE PBIAS (%)
Abufargha NRCS table 82.94 0.575 −20.441 217.565
Arithmetic mean 87.88 0.619 −3.441 303.380
Median 87.54 0.621 −2.941 294.978
Geometric mean 90.96 0.598 −10.977 400.011
Eldilling NRCS table 82.43 0.509 −21.655 459.040
Arithmetic mean 83.12 0.5197 −24.543 85.999
Median 87.19 0.5533 −38.1557 583.051
Geometric mean 87.18 0.5533 −38.1152 582.755
Erigi NRCS table 67.13 0.239 −2.958 281.614
Arithmetic mean 90.74 0.625 −2.989 295.482
Median 91.19 0.624 −2.365 281.3296
Geometric mean 93.11 0.619 −6.874 1,614.411
Tiflo NRCS table 77 0.061 −161.937 1,194.876
Arithmetic mean 90.50 0.689 −883.373 1,358.468
Median 94.63 0.746 −1,846.635 1,903.735
Geometric mean 93.90 0.736 −1,604.722 1,767.090
Abasya NRCS table 86.597 0.5368 −522.935 1,149.784
Arithmetic mean 90.06 0.565 −801.583 1,284.274
Median 95.43 0.603 −1,698.02 1,823.094
Geometric mean 98.71 0.632 −2,763.9 2,660.558

It is noted that NSE values of the five catchments are all negative. These negative values indicate the difference between the observed and estimated runoff (poor fit). Previous studies have shown that SCS-CN has poor performance in areas with high infiltration rates, such as areas with predominant sand soils [14]. The literature review has also revealed that λ the initial abstraction (Ia) coefficient may not be equal to 0.2 [7], which would affect the fit between the observed and estimated runoff. All the values of PBIAS were positive, indicating that runoff was underestimated [15,16,17,18]. Except for the NRCS table method for the Erigi and Tiflo catchments, all methods have R 2 value greater than 0.5. This result shows the significance of prospective studies on the use of the CN method in the Sudanese catchments, such as the one developed in this study [19,20,21,22,23,24,25]. The author recommends measuring the initial abstraction (Ia) to understand the actual value of initial abstraction coefficient (λ) to know the actual value of λ. The initial abstraction coefficient (λ) will affect the fit between the observed and estimated runoff, because some previous studies have shown that λ may not be equal to 0.2 [26,27,28,29,30,31].

7 Conclusion

There are still some uncertainties in the (NRCS-CN) method, such as choosing the most appropriate CN value. This study aimed to evaluate using the NRCS-CN method to estimate the runoff of five catchments in Sudan. The first study area is the Abufargha catchment in the eastern region of Sudan. The second study area is the Eldilling catchment in the southern region of Sudan, the third study area is the Erigi catchment in the western region of Sudan, the fourth study area is the Tiflo catchment in the western region of Sudan, and the last one is the Abasya catchment in the southern region of Sudan. For each catchment, CN values were obtained from the number of observed rainfall-runoff events using the NRCS table, arithmetic mean, median, and geometric mean methods. The R 2, the NSE, and PBIAS were utilized for the statistical analysis. R 2, NSE, and PBIAS were computed for five catchments. NSE values of the five catchments are all negative. These negative values indicate the difference between the observed and estimated runoff and the NRCS-CN method is not suitable for runoff calculation in the study areas.

Acknowledgements

This study was supported by School of Water Resources and Environment, China university of Geosciences (Beijing). The authors are very grateful to Suzan Mustafa (Ministry of Water Resources, Irrigation, and Electricity-Khartoum, Sudan) for her support and guidance during the study.

  1. Author contributions: Salma Ibrahim and Babikir Barsi conceived the presented idea. Salma Ibrahim and Magdi Siddig collected the data. Salma Ibrahim developed the theory and performed the computations. Salma Ibrahim, Babikir Barsi, and Qingchun Yu verified the analytical methods. Salma Ibrahim wrote the manuscript with support from Babikir Barsi, Qingchun Yu, and Magdi Siddig. All authors have agreed to the final manuscript.

  2. Conflict of interest: Authors state no conflict of interest.

References

[1] Chow VT, Maidment DR, Mays LW. Applied Hydrology. 1987;1–540.Suche in Google Scholar

[2] Alagha MO, Gutub SA, Elfeki AM. Estimation of NRCS curve number from watershed morphometric parameters: a case study of Yiba watershed in Saudi Arabia. Int J Civ Eng Technol. 2016;7(2):247–65.Suche in Google Scholar

[3] Feyereisen GW, Strickland TC, Bosch DD, Truman CC, Sheridan JM, Potter TL. Curve number estimates for conventional and conservation tillages in the southeastern. Coast Plain. 2008;63(3):120–8.10.2489/jswc.63.3.120Suche in Google Scholar

[4] Rao GS, Giri MVSS, Mohan S, Sowmya P. Estimation of SCS-curve number for kaddam watershed using remote sensing and GIS. Int J Creat Res. 2017;5(3):203–8.Suche in Google Scholar

[5] Taylor P, Hong Y. International journal of remote estimation of global SCS curve numbers using satellite remote sensing and geospatial data. In J Remote Sens. October 2011;29(2):37–41.Suche in Google Scholar

[6] Boorman DB, Hollis JM, Lilly A. Hydrology of soil types: a hydrologically-based classification of the soils of the United Kingdom. Rep - UK Inst Hydrol. 1995. Report No. 126.Suche in Google Scholar

[7] Do Valle Junior LCG, Rodrigues DBB, de Oliveira PTS. Initial abstraction ratio and curve number estimation using rainfall and runoff data from a tropical watershed. Rev Bras Recur Hidr. 2019;24:1–9.10.1590/2318-0331.241920170199Suche in Google Scholar

[8] Shi ZH, Chen LD, Fang NF, Qin DF, Cai CF. Research on the SCS-CN initial abstraction ratio using rainfall-runoff event analysis in the three gorges area. China Catena [Internet]. 2009;77(1):1–7.10.1016/j.catena.2008.11.006Suche in Google Scholar

[9] Bonta JV. Determination of watershed curve number using derived distributions. J Irrig Drain Eng. 1997;123(1):28–36.10.1061/(ASCE)0733-9437(1997)123:1(28)Suche in Google Scholar

[10] Tedela NH, McCutcheon SC, Rasmussen TC, Hawkins RH, Swank WT, Campbell JL, et al. Runoff curve numbers for 10 small forested watersheds in the mountains of the eastern united states. J Hydrol Eng. 2012;17(11):1188–98.10.1061/(ASCE)HE.1943-5584.0000436Suche in Google Scholar

[11] Moriasi DN, Arnold JG, Van Liew MW, Bingner RL, Harmel RD, Veith TL. Model evaluation guidelines for systematic quantification of accuracy in watershed simulations. Trans ASABE. 2007;50(3):885–900.10.13031/2013.23153Suche in Google Scholar

[12] Khaddor I, Achab M, Soumali MR, Alaoui AH. Rainfall-runoff calibration for semi-arid ungauged basins based on the cumulative observed hyetograph and SCS storm model: Application to the Boukhalef watershed (Tangier, North Western Morocco). J Mater Env Sci. 2017;8(10):3795–808.Suche in Google Scholar

[13] Merwade V. Hydrologic Modeling using HEC-HMS Opening a HEC-HMS project. School of Civil Engineering, Purdue University; 2012.Suche in Google Scholar

[14] Oliveira PTS, Nearing MA, Hawkins RH, Stone JJ, Rodrigues DBB, Panachuki E, et al. Curve number estimation from Brazilian Cerrado rainfall and runoff data. J Soil Water Conserv. 2016;71(5):420–29.10.2489/jswc.71.5.420Suche in Google Scholar

[15] Bartlett MS, Parolari AJ, Mcdonnell JJ, Porporato A. Beyond the SCS-CN method: a theoretical framework for spatially lumped rainfall-runoff response. Water Resour Res. 2016;52(6):4608–27.10.1002/2015WR018439Suche in Google Scholar

[16] Merwade V, Outcomes L, Data I, Cover L. Creating SCS curve number grid using land cover and soil data preparing land use data for CN grid. School of Civil Engineering, Purdue University; 2019. p. 1–10.Suche in Google Scholar

[17] Abdel-magid HIM, Shigidi AMT. Hydrologic analysis of digital elevation models using archydro extension. Sudan Eng Soc J. 2010;59:1998.Suche in Google Scholar

[18] Viessman W, Lewis L, Warren Viessman JG, Lewis GL, Knapp JW. Introduction to Hydrology-1. Upper Saddle River, NJ: Prentice Hall; 2003. p. 751.Suche in Google Scholar

[19] Tassew BG, Belete MA, Miegel K. Application of HEC-HMS model for flow simulation in the Lake Tana basin: the case of gilgel abay catchment, upper blue Nile Basin, Ethiopia. 2019;6(1):1–17.10.3390/hydrology6010021Suche in Google Scholar

[20] Soulis KX, Valiantzas JD. SCS-CN parameter determination using rainfall-runoff data in heterogeneous watersheds – the two-CN system approach. Hydrol Earth Syst Sci. 2012;16:1001–15.10.5194/hess-16-1001-2012Suche in Google Scholar

[21] Baltas EA, Dervos NA, Mimikou MA. Technical note: determination of the SCS initial abstraction ratio in an experimental watershed in Greece. Hydrol Earth Syst Sci. 2007;11(6):1825–9.10.5194/hess-11-1825-2007Suche in Google Scholar

[22] D’Asaro F, Grillone G. Runoff curve number method in sicily: CN determination and analysis of the initial abstraction ratio. 4th Fed Interag Conf Las Vegas, NV, June 27–July 1, 2010. 2010;1–12.Suche in Google Scholar

[23] Woodward DE, Hawkins RH, Jiang R, Hjelmfelt Junior AT, Van Mullem JA, Quan DQ. Runoff curve number method: examination of the initial abstraction ratio. In: 2003 World Water And Environmental Resources Congress. Philadelphia; 2003. p. 1–10.10.1061/40685(2003)308Suche in Google Scholar

[24] Tan WJ, Khor JF, Ling L, Huang YF. Misuse of Lambda (λ) in NRCS-CN Model. Conference on Civil and Environmental Engineering. 2018;07006:51–2.10.1051/e3sconf/20186507006Suche in Google Scholar

[25] Baumbach T, Burckhard SR, Kant JM. Watershed modeling using Arc hydro tools. Geo HMS, and HEC-HMS. Civil and Environmental Engineering Faculty Publications. 2; 2015.Suche in Google Scholar

[26] Elhakeem M, Papanicolaou AN. Estimation of the runoff curve number via direct rainfall simulator measurements in the state of Iowa. USA: European Water Resources Association (EWRA); 2009.10.1007/s11269-008-9390-1Suche in Google Scholar

[27] Blume T, Zehe E, Bronstert A, Blume T, Zehe E, Bronstert A. Rainfall – runoff response, event-based runoff coefficients and hydrograph separation. Hydrological Sciences–Journal–des Sciences Hydrologiques. 2010;52(5):6667.10.1623/hysj.52.5.843Suche in Google Scholar

[28] Asaro FD, Grillone G. Empirical investigation of curve number method parameters in the mediterranean area. J Hydrol Eng. 2012;October:1141–52.10.1061/(ASCE)HE.1943-5584.0000570Suche in Google Scholar

[29] Das P, Islam A, Dutta S, Dubey AK, Sarkar R. Estimation of runoff curve numbers using a physically-based approach of preferential flow modelling. IAHS-AISH Proc Rep. 2014;363(October):443–8.Suche in Google Scholar

[30] Banasik K, Krajewski A, Sikorska A, Hejduk L. Curve number estimation for a small urban catchment from recorded rainfall-runoff events. Arch Env Prot. 2014;40(3):75–86.10.2478/aep-2014-0032Suche in Google Scholar

[31] Gharde KD, Mahale DM, Idate SS. Estimation of curve numbers for different soil conservation measures in lateritic soil of south Konkan region. IJSC, India. 2014;42(1):10–16.Suche in Google Scholar
Received: 2021-03-21
Revised: 2022-01-13
Accepted: 2022-02-21
Published Online: 2022-03-29

© 2022 Salma Ibrahim et al., published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 International License.

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  24. Urban green service equity in Xiamen based on network analysis and concentration degree of resources
  25. Spatio-temporal analysis of East Asian seismic zones based on multifractal theory
  26. Delineation of structural lineaments of Southeast Nigeria using high resolution aeromagnetic data
  27. 3D marine controlled-source electromagnetic modeling using an edge-based finite element method with a block Krylov iterative solver
  28. A comprehensive evaluation method for topographic correction model of remote sensing image based on entropy weight method
  29. Quantitative discrimination of the influences of climate change and human activity on rocky desertification based on a novel feature space model
  30. Assessment of climatic conditions for tourism in Xinjiang, China
  31. Attractiveness index of national marine parks: A study on national marine parks in coastal areas of East China Sea
  32. Effect of brackish water irrigation on the movement of water and salt in salinized soil
  33. Mapping paddy rice and rice phenology with Sentinel-1 SAR time series using a unified dynamic programming framework
  34. Analyzing the characteristics of land use distribution in typical village transects at Chinese Loess Plateau based on topographical factors
  35. Management status and policy direction of submerged marine debris for improvement of port environment in Korea
  36. Influence of Three Gorges Dam on earthquakes based on GRACE gravity field
  37. Comparative study of estimating the Curie point depth and heat flow using potential magnetic data
  38. The spatial prediction and optimization of production-living-ecological space based on Markov–PLUS model: A case study of Yunnan Province
  39. Major, trace and platinum-group element geochemistry of harzburgites and chromitites from Fuchuan, China, and its geological significance
  40. Vertical distribution of STN and STP in watershed of loess hilly region
  41. Hyperspectral denoising based on the principal component low-rank tensor decomposition
  42. Evaluation of fractures using conventional and FMI logs, and 3D seismic interpretation in continental tight sandstone reservoir
  43. U–Pb zircon dating of the Paleoproterozoic khondalite series in the northeastern Helanshan region and its geological significance
  44. Quantitatively determine the dominant driving factors of the spatial-temporal changes of vegetation-impacts of global change and human activity
  45. Can cultural tourism resources become a development feature helping rural areas to revitalize the local economy under the epidemic? An exploration of the perspective of attractiveness, satisfaction, and willingness by the revisit of Hakka cultural tourism
  46. A 3D empirical model of standard compaction curve for Thailand shales: Porosity in function of burial depth and geological time
  47. Attribution identification of terrestrial ecosystem evolution in the Yellow River Basin
  48. An intelligent approach for reservoir quality evaluation in tight sandstone reservoir using gradient boosting decision tree algorithm
  49. Detection of sub-surface fractures based on filtering, modeling, and interpreting aeromagnetic data in the Deng Deng – Garga Sarali area, Eastern Cameroon
  50. Influence of heterogeneity on fluid property variations in carbonate reservoirs with multistage hydrocarbon accumulation: A case study of the Khasib formation, Cretaceous, AB oilfield, southern Iraq
  51. Designing teaching materials with disaster maps and evaluating its effectiveness for primary students
  52. Assessment of the bender element sensors to measure seismic wave velocity of soils in the physical model
  53. Appropriated protection time and region for Qinghai–Tibet Plateau grassland
  54. Identification of high-temperature targets in remote sensing based on correspondence analysis
  55. Influence of differential diagenesis on pore evolution of the sandy conglomerate reservoir in different structural units: A case study of the Upper Permian Wutonggou Formation in eastern Junggar Basin, NW China
  56. Planting in ecologically solidified soil and its use
  57. National and regional-scale landslide indicators and indexes: Applications in Italy
  58. Occurrence of yttrium in the Zhijin phosphorus deposit in Guizhou Province, China
  59. The response of Chudao’s beach to typhoon “Lekima” (No. 1909)
  60. Soil wind erosion resistance analysis for soft rock and sand compound soil: A case study for the Mu Us Sandy Land, China
  61. Investigation into the pore structures and CH4 adsorption capacities of clay minerals in coal reservoirs in the Yangquan Mining District, North China
  62. Overview of eco-environmental impact of Xiaolangdi Water Conservancy Hub on the Yellow River
  63. Response of extreme precipitation to climatic warming in the Weihe river basin, China and its mechanism
  64. Analysis of land use change on urban landscape patterns in Northwest China: A case study of Xi’an city
  65. Optimization of interpolation parameters based on statistical experiment
  66. Late Cretaceous adakitic intrusive rocks in the Laimailang area, Gangdese batholith: Implications for the Neo-Tethyan Ocean subduction
  67. Tectonic evolution of the Eocene–Oligocene Lushi Basin in the eastern Qinling belt, Central China: Insights from paleomagnetic constraints
  68. Geographic and cartographic inconsistency factors among different cropland classification datasets: A field validation case in Cambodia
  69. Distribution of large- and medium-scale loess landslides induced by the Haiyuan Earthquake in 1920 based on field investigation and interpretation of satellite images
  70. Numerical simulation of impact and entrainment behaviors of debris flow by using SPH–DEM–FEM coupling method
  71. Study on the evaluation method and application of logging irreducible water saturation in tight sandstone reservoirs
  72. Geochemical characteristics and genesis of natural gas in the Upper Triassic Xujiahe Formation in the Sichuan Basin
  73. Wehrlite xenoliths and petrogenetic implications, Hosséré Do Guessa volcano, Adamawa plateau, Cameroon
  74. Changes in landscape pattern and ecological service value as land use evolves in the Manas River Basin
  75. Spatial structure-preserving and conflict-avoiding methods for point settlement selection
  76. Fission characteristics of heavy metal intrusion into rocks based on hydrolysis
  77. Sequence stratigraphic filling model of the Cretaceous in the western Tabei Uplift, Tarim Basin, NW China
  78. Fractal analysis of structural characteristics and prospecting of the Luanchuan polymetallic mining district, China
  79. Spatial and temporal variations of vegetation coverage and their driving factors following gully control and land consolidation in Loess Plateau, China
  80. Assessing the tourist potential of cultural–historical spatial units of Serbia using comparative application of AHP and mathematical method
  81. Urban black and odorous water body mapping from Gaofen-2 images
  82. Geochronology and geochemistry of Early Cretaceous granitic plutons in northern Great Xing’an Range, NE China, and implications for geodynamic setting
  83. Spatial planning concept for flood prevention in the Kedurus River watershed
  84. Geophysical exploration and geological appraisal of the Siah Diq porphyry Cu–Au prospect: A recent discovery in the Chagai volcano magmatic arc, SW Pakistan
  85. Possibility of using the DInSAR method in the development of vertical crustal movements with Sentinel-1 data
  86. Using modified inverse distance weight and principal component analysis for spatial interpolation of foundation settlement based on geodetic observations
  87. Geochemical properties and heavy metal contents of carbonaceous rocks in the Pliocene siliciclastic rock sequence from southeastern Denizli-Turkey
  88. Study on water regime assessment and prediction of stream flow based on an improved RVA
  89. A new method to explore the abnormal space of urban hidden dangers under epidemic outbreak and its prevention and control: A case study of Jinan City
  90. Milankovitch cycles and the astronomical time scale of the Zhujiang Formation in the Baiyun Sag, Pearl River Mouth Basin, China
  91. Shear strength and meso-pore characteristic of saturated compacted loess
  92. Key point extraction method for spatial objects in high-resolution remote sensing images based on multi-hot cross-entropy loss
  93. Identifying driving factors of the runoff coefficient based on the geographic detector model in the upper reaches of Huaihe River Basin
  94. Study on rainfall early warning model for Xiangmi Lake slope based on unsaturated soil mechanics
  95. Extraction of mineralized indicator minerals using ensemble learning model optimized by SSA based on hyperspectral image
  96. Lithofacies discrimination using seismic anisotropic attributes from logging data in Muglad Basin, South Sudan
  97. Three-dimensional modeling of loose layers based on stratum development law
  98. Occurrence, sources, and potential risk of polycyclic aromatic hydrocarbons in southern Xinjiang, China
  99. Attribution analysis of different driving forces on vegetation and streamflow variation in the Jialing River Basin, China
  100. Slope characteristics of urban construction land and its correlation with ground slope in China
  101. Limitations of the Yang’s breaking wave force formula and its improvement under a wider range of breaker conditions
  102. The spatial-temporal pattern evolution and influencing factors of county-scale tourism efficiency in Xinjiang, China
  103. Evaluation and analysis of observed soil temperature data over Northwest China
  104. Agriculture and aquaculture land-use change prediction in five central coastal provinces of Vietnam using ANN, SVR, and SARIMA models
  105. Leaf color attributes of urban colored-leaf plants
  106. Application of statistical and machine learning techniques for landslide susceptibility mapping in the Himalayan road corridors
  107. Sediment provenance in the Northern South China Sea since the Late Miocene
  108. Drones applications for smart cities: Monitoring palm trees and street lights
  109. Double rupture event in the Tianshan Mountains: A case study of the 2021 Mw 5.3 Baicheng earthquake, NW China
  110. Review Article
  111. Mobile phone indoor scene features recognition localization method based on semantic constraint of building map location anchor
  112. Technical Note
  113. Experimental analysis on creep mechanics of unsaturated soil based on empirical model
  114. Rapid Communications
  115. A protocol for canopy cover monitoring on forest restoration projects using low-cost drones
  116. Landscape tree species recognition using RedEdge-MX: Suitability analysis of two different texture extraction forms under MLC and RF supervision
  117. Special Issue: Geoethics 2022 - Part I
  118. Geomorphological and hydrological heritage of Mt. Stara Planina in SE Serbia: From river protection initiative to potential geotouristic destination
  119. Geotourism and geoethics as support for rural development in the Knjaževac municipality, Serbia
  120. Modeling spa destination choice for leveraging hydrogeothermal potentials in Serbia
https://doi.org/10.1515/geo-2022-0356
Schlagwörter für diesen Artikel
curve number; Sudan; catchment; runoff; rainfall and linear relationship
Creative Commons
BY 4.0

Artikel in diesem Heft

  1. Regular Articles
  2. Study on observation system of seismic forward prospecting in tunnel: A case on tailrace tunnel of Wudongde hydropower station
  3. The behaviour of stress variation in sandy soil
  4. Research on the current situation of rural tourism in southern Fujian in China after the COVID-19 epidemic
  5. Late Triassic–Early Jurassic paleogeomorphic characteristics and hydrocarbon potential of the Ordos Basin, China, a case of study of the Jiyuan area
  6. Application of X-ray fluorescence mapping in turbiditic sandstones, Huai Bo Khong Formation of Nam Pat Group, Thailand
  7. Fractal expression of soil particle-size distribution at the basin scale
  8. Study on the changes in vegetation structural coverage and its response mechanism to hydrology
  9. Spatial distribution analysis of seismic activity based on GMI, LMI, and LISA in China
  10. Rock mass structural surface trace extraction based on transfer learning
  11. Hydrochemical characteristics and D–O–Sr isotopes of groundwater and surface water in the northern Longzi county of southern Tibet (southwestern China)
  12. Insights into origins of the natural gas in the Lower Paleozoic of Ordos basin, China
  13. Research on comprehensive benefits and reasonable selection of marine resources development types
  14. Embedded deformation of the rubble-mound foundation of gravity-type quay walls and influence factors
  15. Activation of Ad Damm shear zone, western Saudi Arabian margin, and its relation to the Red Sea rift system
  16. A mathematical conjecture associates Martian TARs with sand ripples
  17. Study on spatio-temporal characteristics of earthquakes in southwest China based on z-value
  18. Sedimentary facies characterization of forced regression in the Pearl River Mouth basin
  19. High-precision remote sensing mapping of aeolian sand landforms based on deep learning algorithms
  20. Experimental study on reservoir characteristics and oil-bearing properties of Chang 7 lacustrine oil shale in Yan’an area, China
  21. Estimating the volume of the 1978 Rissa quick clay landslide in Central Norway using historical aerial imagery
  22. Spatial accessibility between commercial and ecological spaces: A case study in Beijing, China
  23. Curve number estimation using rainfall and runoff data from five catchments in Sudan
  24. Urban green service equity in Xiamen based on network analysis and concentration degree of resources
  25. Spatio-temporal analysis of East Asian seismic zones based on multifractal theory
  26. Delineation of structural lineaments of Southeast Nigeria using high resolution aeromagnetic data
  27. 3D marine controlled-source electromagnetic modeling using an edge-based finite element method with a block Krylov iterative solver
  28. A comprehensive evaluation method for topographic correction model of remote sensing image based on entropy weight method
  29. Quantitative discrimination of the influences of climate change and human activity on rocky desertification based on a novel feature space model
  30. Assessment of climatic conditions for tourism in Xinjiang, China
  31. Attractiveness index of national marine parks: A study on national marine parks in coastal areas of East China Sea
  32. Effect of brackish water irrigation on the movement of water and salt in salinized soil
  33. Mapping paddy rice and rice phenology with Sentinel-1 SAR time series using a unified dynamic programming framework
  34. Analyzing the characteristics of land use distribution in typical village transects at Chinese Loess Plateau based on topographical factors
  35. Management status and policy direction of submerged marine debris for improvement of port environment in Korea
  36. Influence of Three Gorges Dam on earthquakes based on GRACE gravity field
  37. Comparative study of estimating the Curie point depth and heat flow using potential magnetic data
  38. The spatial prediction and optimization of production-living-ecological space based on Markov–PLUS model: A case study of Yunnan Province
  39. Major, trace and platinum-group element geochemistry of harzburgites and chromitites from Fuchuan, China, and its geological significance
  40. Vertical distribution of STN and STP in watershed of loess hilly region
  41. Hyperspectral denoising based on the principal component low-rank tensor decomposition
  42. Evaluation of fractures using conventional and FMI logs, and 3D seismic interpretation in continental tight sandstone reservoir
  43. U–Pb zircon dating of the Paleoproterozoic khondalite series in the northeastern Helanshan region and its geological significance
  44. Quantitatively determine the dominant driving factors of the spatial-temporal changes of vegetation-impacts of global change and human activity
  45. Can cultural tourism resources become a development feature helping rural areas to revitalize the local economy under the epidemic? An exploration of the perspective of attractiveness, satisfaction, and willingness by the revisit of Hakka cultural tourism
  46. A 3D empirical model of standard compaction curve for Thailand shales: Porosity in function of burial depth and geological time
  47. Attribution identification of terrestrial ecosystem evolution in the Yellow River Basin
  48. An intelligent approach for reservoir quality evaluation in tight sandstone reservoir using gradient boosting decision tree algorithm
  49. Detection of sub-surface fractures based on filtering, modeling, and interpreting aeromagnetic data in the Deng Deng – Garga Sarali area, Eastern Cameroon
  50. Influence of heterogeneity on fluid property variations in carbonate reservoirs with multistage hydrocarbon accumulation: A case study of the Khasib formation, Cretaceous, AB oilfield, southern Iraq
  51. Designing teaching materials with disaster maps and evaluating its effectiveness for primary students
  52. Assessment of the bender element sensors to measure seismic wave velocity of soils in the physical model
  53. Appropriated protection time and region for Qinghai–Tibet Plateau grassland
  54. Identification of high-temperature targets in remote sensing based on correspondence analysis
  55. Influence of differential diagenesis on pore evolution of the sandy conglomerate reservoir in different structural units: A case study of the Upper Permian Wutonggou Formation in eastern Junggar Basin, NW China
  56. Planting in ecologically solidified soil and its use
  57. National and regional-scale landslide indicators and indexes: Applications in Italy
  58. Occurrence of yttrium in the Zhijin phosphorus deposit in Guizhou Province, China
  59. The response of Chudao’s beach to typhoon “Lekima” (No. 1909)
  60. Soil wind erosion resistance analysis for soft rock and sand compound soil: A case study for the Mu Us Sandy Land, China
  61. Investigation into the pore structures and CH4 adsorption capacities of clay minerals in coal reservoirs in the Yangquan Mining District, North China
  62. Overview of eco-environmental impact of Xiaolangdi Water Conservancy Hub on the Yellow River
  63. Response of extreme precipitation to climatic warming in the Weihe river basin, China and its mechanism
  64. Analysis of land use change on urban landscape patterns in Northwest China: A case study of Xi’an city
  65. Optimization of interpolation parameters based on statistical experiment
  66. Late Cretaceous adakitic intrusive rocks in the Laimailang area, Gangdese batholith: Implications for the Neo-Tethyan Ocean subduction
  67. Tectonic evolution of the Eocene–Oligocene Lushi Basin in the eastern Qinling belt, Central China: Insights from paleomagnetic constraints
  68. Geographic and cartographic inconsistency factors among different cropland classification datasets: A field validation case in Cambodia
  69. Distribution of large- and medium-scale loess landslides induced by the Haiyuan Earthquake in 1920 based on field investigation and interpretation of satellite images
  70. Numerical simulation of impact and entrainment behaviors of debris flow by using SPH–DEM–FEM coupling method
  71. Study on the evaluation method and application of logging irreducible water saturation in tight sandstone reservoirs
  72. Geochemical characteristics and genesis of natural gas in the Upper Triassic Xujiahe Formation in the Sichuan Basin
  73. Wehrlite xenoliths and petrogenetic implications, Hosséré Do Guessa volcano, Adamawa plateau, Cameroon
  74. Changes in landscape pattern and ecological service value as land use evolves in the Manas River Basin
  75. Spatial structure-preserving and conflict-avoiding methods for point settlement selection
  76. Fission characteristics of heavy metal intrusion into rocks based on hydrolysis
  77. Sequence stratigraphic filling model of the Cretaceous in the western Tabei Uplift, Tarim Basin, NW China
  78. Fractal analysis of structural characteristics and prospecting of the Luanchuan polymetallic mining district, China
  79. Spatial and temporal variations of vegetation coverage and their driving factors following gully control and land consolidation in Loess Plateau, China
  80. Assessing the tourist potential of cultural–historical spatial units of Serbia using comparative application of AHP and mathematical method
  81. Urban black and odorous water body mapping from Gaofen-2 images
  82. Geochronology and geochemistry of Early Cretaceous granitic plutons in northern Great Xing’an Range, NE China, and implications for geodynamic setting
  83. Spatial planning concept for flood prevention in the Kedurus River watershed
  84. Geophysical exploration and geological appraisal of the Siah Diq porphyry Cu–Au prospect: A recent discovery in the Chagai volcano magmatic arc, SW Pakistan
  85. Possibility of using the DInSAR method in the development of vertical crustal movements with Sentinel-1 data
  86. Using modified inverse distance weight and principal component analysis for spatial interpolation of foundation settlement based on geodetic observations
  87. Geochemical properties and heavy metal contents of carbonaceous rocks in the Pliocene siliciclastic rock sequence from southeastern Denizli-Turkey
  88. Study on water regime assessment and prediction of stream flow based on an improved RVA
  89. A new method to explore the abnormal space of urban hidden dangers under epidemic outbreak and its prevention and control: A case study of Jinan City
  90. Milankovitch cycles and the astronomical time scale of the Zhujiang Formation in the Baiyun Sag, Pearl River Mouth Basin, China
  91. Shear strength and meso-pore characteristic of saturated compacted loess
  92. Key point extraction method for spatial objects in high-resolution remote sensing images based on multi-hot cross-entropy loss
  93. Identifying driving factors of the runoff coefficient based on the geographic detector model in the upper reaches of Huaihe River Basin
  94. Study on rainfall early warning model for Xiangmi Lake slope based on unsaturated soil mechanics
  95. Extraction of mineralized indicator minerals using ensemble learning model optimized by SSA based on hyperspectral image
  96. Lithofacies discrimination using seismic anisotropic attributes from logging data in Muglad Basin, South Sudan
  97. Three-dimensional modeling of loose layers based on stratum development law
  98. Occurrence, sources, and potential risk of polycyclic aromatic hydrocarbons in southern Xinjiang, China
  99. Attribution analysis of different driving forces on vegetation and streamflow variation in the Jialing River Basin, China
  100. Slope characteristics of urban construction land and its correlation with ground slope in China
  101. Limitations of the Yang’s breaking wave force formula and its improvement under a wider range of breaker conditions
  102. The spatial-temporal pattern evolution and influencing factors of county-scale tourism efficiency in Xinjiang, China
  103. Evaluation and analysis of observed soil temperature data over Northwest China
  104. Agriculture and aquaculture land-use change prediction in five central coastal provinces of Vietnam using ANN, SVR, and SARIMA models
  105. Leaf color attributes of urban colored-leaf plants
  106. Application of statistical and machine learning techniques for landslide susceptibility mapping in the Himalayan road corridors
  107. Sediment provenance in the Northern South China Sea since the Late Miocene
  108. Drones applications for smart cities: Monitoring palm trees and street lights
  109. Double rupture event in the Tianshan Mountains: A case study of the 2021 Mw 5.3 Baicheng earthquake, NW China
  110. Review Article
  111. Mobile phone indoor scene features recognition localization method based on semantic constraint of building map location anchor
  112. Technical Note
  113. Experimental analysis on creep mechanics of unsaturated soil based on empirical model
  114. Rapid Communications
  115. A protocol for canopy cover monitoring on forest restoration projects using low-cost drones
  116. Landscape tree species recognition using RedEdge-MX: Suitability analysis of two different texture extraction forms under MLC and RF supervision
  117. Special Issue: Geoethics 2022 - Part I
  118. Geomorphological and hydrological heritage of Mt. Stara Planina in SE Serbia: From river protection initiative to potential geotouristic destination
  119. Geotourism and geoethics as support for rural development in the Knjaževac municipality, Serbia
  120. Modeling spa destination choice for leveraging hydrogeothermal potentials in Serbia
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