nach oben

Erschienen in:

26.08.2016 | Paper

Evaluation of the Soil Conservation Service curve number methodology using data from agricultural plots

verfasst von: Mohan Lal, S. K. Mishra, Ashish Pandey, R. P. Pandey, P. K. Meena, Anubhav Chaudhary, Ranjit Kumar Jha, Ajit Kumar Shreevastava, Yogendra Kumar

Erschienen in: Hydrogeology Journal | Ausgabe 1/2017

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

The Soil Conservation Service curve number (SCS-CN) method, also known as the Natural Resources Conservation Service curve number (NRCS-CN) method, is popular for computing the volume of direct surface runoff for a given rainfall event. The performance of the SCS-CN method, based on large rainfall (P) and runoff (Q) datasets of United States watersheds, is evaluated using a large dataset of natural storm events from 27 agricultural plots in India. On the whole, the CN estimates from the National Engineering Handbook (chapter 4) tables do not match those derived from the observed P and Q datasets. As a result, the runoff prediction using former CNs was poor for the data of 22 (out of 24) plots. However, the match was little better for higher CN values, consistent with the general notion that the existing SCS-CN method performs better for high rainfall–runoff (high CN) events. Infiltration capacity (fc) was the main explanatory variable for runoff (or CN) production in study plots as it exhibited the expected inverse relationship between CN and fc. The plot-data optimization yielded initial abstraction coefficient (λ) values from 0 to 0.659 for the ordered dataset and 0 to 0.208 for the natural dataset (with 0 as the most frequent value). Mean and median λ values were, respectively, 0.030 and 0 for the natural rainfall–runoff dataset and 0.108 and 0 for the ordered rainfall–runoff dataset. Runoff estimation was very sensitive to λ and it improved consistently as λ changed from 0.2 to 0.03.

Vorheriger Artikel Estimating groundwater inflow and leakage outflow for an intermontane lake with a structurally complex geology: Georgetown Lake in Montana, USA

Nächster Artikel Evaluation of four supervised learning methods for groundwater spring potential mapping in Khalkhal region (Iran) using GIS-based features

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Nur mit Berechtigung zugänglich

Ajmal M, Moon G, Ahn J, Kim T (2015a) Quantifying excess storm water using SCS-CN-based rainfall runoff models and different curve number determination methods. J Irrig Drain Eng 141(3):04014058CrossRef

Ajmal M, Moon G, Ahn J, Kim T (2015b) Investigation of SCS and its inspired modified models for runoff estimation in South Korean watersheds. J Hydro Environ Res 9(4):592–603CrossRef

Ajmal M, Waseem M, Ahn J, Kim T (2015c) Improved runoff estimation using event-based rainfall–runoff models. Water Resour Manag 29:1995–2010CrossRef

Ajmal M, Waseem M, Wi S, Kim T (2015d) Evolution of a parsimonious rainfall–runoff model using soil moisture proxies. J Hydrol 530:623–633CrossRef

Ajmal M, Waseem M, Kim HS, Kim T (2016) Potential implications of pre-storm soil moisture on hydrological prediction. J Hydro Environ Res 11:1–15CrossRef

Ali S, Sharda VN (2008) A comparison of curve number based methods for runoff estimation from small watersheds in a semi-arid region of India. Hydrol Res 39(3):191–200CrossRef

Archibald JA, Buchanan B, Fuka DR, Georgakakos CB, Lyon SW, Walter MT (2014) A simple, regionally parameterized model for predicting nonpoint source areas in the northeastern US. J Hydrol Reg Stud 1:74–91CrossRef

Aron G, Miller AC, Lakatos DF (1977) Infiltration formula based on SCS curve number. J Irrig Drain Div 103(4):419–427

Baltas EA, Dervos NA, Mimikou MA (2007) Determination of the SCS initial abstraction ratio in an experimental watershed in Greece. Hydrol Earth Syst Sci 11:1825–1829CrossRef

Bonta JV (1997) Determination of watershed curve number using derived distributions. J Irrig Drain Div 123(1):28–36CrossRef

Cazier DJ, Hawkins RH (1984) Regional application of the curve number method, Proc., Water Today and Tomorrow, ASCE Irrigation and Drainage Division Special Conf. ASCE, Reston, VA

D’Asaro F, Grillone G (2012) Empirical investigation of curve number method parameters in the Mediterranean area. J Hydrol Eng 17:1141–1152CrossRef

D’Asaro F, Grillone G, Hawkins RH (2014) Curve number: empirical evaluation and comparison with curve number handbook tables in Sicily. J Hydrol Eng 19(12):04014035, pp 1–13CrossRef

Deshmukh DS, Chaube UC, Hailu AE, Gudeta AA, Kassa MT (2013) Estimation and comparison of curve numbers based on dynamic land use land cover change, observed rainfall–runoff data and land slope. J Hydrol 492:89–101CrossRef

Donigian AS, Imhoff JC, Bicknell BR (1983) Predicting water quality resulting from agricultural nonpoint-source pollution via simulation: HSPF. In: Agricultural management and water quality. Iowa State University Press, Ames, IA, pp 200–249

Durbude DG, Jain MK, Mishra SK (2011) Long-term hydrologic simulation using SCS-CN-based improved soil moisture accounting procedure. Hydrol Process 25:561–579CrossRef

EI-Sadek A, Feyen J, Berlamont J (2001) Comparison of models for computing drainage discharge. J Irrig Drain Eng ASCE 127(6):363–369CrossRef

Elhakeem M, Papanicolaou AN (2009) Estimation of the runoff curve number via direct rainfall simulator measurements in the state of Iowa, USA. Water Resour Manag 23(12):2455–2473CrossRef

Fennessey LA (2000) The effect of inflection angle, soil proximity and location on runoff. PhD Thesis, Pennsylvania State University, State College, PA, USA

Fentie B, Yu B, Silburn MD, Ciesiolka CAA (2002) Evaluation of eight different methods to predict hill-slope runoff rates for a grazing catchment in Australia. J Hydrol 261:102–114CrossRef

Feyereisen GW, Strickland TC, Bosch DD, Truman CC, Sheridan JM, Potter TL (2008) Curve number estimates for conventional and conservation tillages in the southeast Coastal Plain. J Soil Water Conserv 63(3):120–128CrossRef

Fu S, Zhang G, Wang N, Luo L (2011) Initial abstraction ratio in the SCS-CN method in the Loess Plateau of China. Trans ASABE 54(1):163–169CrossRef

Garg V, Nikarn BR, Thakur PK, Aggarwal SP (2013) Assessment of the effect of slope on runoff potential of a watershed using NRCS-CN method. Int J Hydrol Sci Technol 3(2):l41–l159CrossRef

Gupta HV, Sorooshian S, Yapo PO (1999) Status of automatic calibration for hydrologic models: comparison with multilevel expert calibration. J Hydrol Eng 4(2):135–143CrossRef

Hauser VL, Jones OR (1991) Runoff curve numbers for the Southern High Plains. Trans Am Soc Agric Eng 34:142–148CrossRef

Hawkins RH (1973) Improved prediction of storm runoff in mountain watershed. Irrig Drain Div ASCE 99:519–523

Hawkins RH (1984) A comparison of predicted and observed runoff curve numbers. Symposium proceedings, Water Today and Tomorrow. ASCE, Reston, VA, pp 702–709

Hawkins RH (1993) Asymptotic determination of runoff curve numbers from data. J Irrig Drain Eng 119(2):334–345CrossRef

Hawkins RH, Khojeini AV (2000) Initial abstraction and loss in the curve number method. Hydrol Water Resour Arizona Southwest http://arizona.openrepository.com/arizona/handle/10150/296552. Accessed August 2016

Hawkins RH, Ward TJ (1998) Site and cover effects on event runoff, Jornada experimental range, New Mexico, Symp. Proc., Conf. on Rangeland Management and Water Resources. American Water Resources Associations, Middleburg, VA, pp 361–370

Hawkins RH, Hjelmfelt AT, Zevenbergen AW (1985) Runoff probability, storm depth, and curve numbers. J Irrig Drain Eng 111(4):330–340CrossRef

Hawkins RH, Jiang R, Woodward DE, Hjelmfelt AT, van Mulle, JA, Quan QD (2002) Runoff curve number method: examination of the initial abstraction ratio In: Proceedings of the Second Federal Interagency Hydrologic Modeling Conference. ASCE, Las Vegas, NV

Hawkins RH, Ward TJ, Woodward DE, Van Mullem JA (2009) Curve number hydrology: state of practice. ASCE, Reston, VA, 106 pp

Hjelmfelt AT (1980) Empirical-investigation of curve number techniques. J Hydraul Eng Div 106(9):1471–1476

Hjelmfelt AT, Kramer KA, Burwell RE (1982) Curve numbers as random variables, Proc. Int. Symp. on Rainfall–Runoff Modeling. Water Resources, Littleton, CO, pp 365–373

Huang M, Jacgues G, Wang Z, Monique G (2006) A modification to the soil conservation service curve number method for steep slopes in the loess plateau of China. Hydrol Process 20(3):579–589CrossRef

IBM (2011) IBM SPSS Statistics for Windows, version 20.0. IBM, Armonk, NY

Jain MK, Mishra SK, Suresh Babu P, Venugopal K, Singh VP (2006a) An enhanced runoff curve number model incorporating storm duration and non-linear I_a–S relation. J Hydrol Eng 11(6):631–635CrossRef

Jain MK, Mishra SK, Suresh Babu P, Venugopal K (2006b) On the I_a–S relation of the SCS-CN method. Nord Hydrol 37(3):261–275CrossRef

Jiang R (2001) Investigation of runoff curve number initial abstraction ratio. MSc Thesis, University of Arizona, Tucson, AZ, 120 pp

Kumar K, Hari Prasad KS, Arora MK (2012) Estimation of water cloud model vegetation parameters using a genetic algorithm. Hydrol Sci J 57(4):776–789CrossRef

Lal M, Mishra SK, Pandey A (2015) Physical verification of the effect of land features and antecedent moisture on runoff curve number. Catena 133:318–327CrossRef

Lim KJ, Engel BA, Tang Z, Muthukrishnan S, Choi J, Kim K (2006) Effects of calibration on L-THIA GIS runoff and pollutant estimation. J Environ Manag 78(1):35–43CrossRef

Mays LW (2005) Water resources engineering, 2nd edn. Willey, Chichester, UK

McCuen RH (2002) Approach to confidence interval estimation for curve numbers. J Hydrol Eng 7(1):43–48CrossRef

Menberu MW, Haghighi AT, Ronkanen AK, Kværner J, Kløve B (2015) Runoff curve numbers for peat-dominated watersheds. J Hydraul Eng 20(4):04014058

Michel C, Vazken A, Perrin C (2005) Soil conservation service curve number method: how to mend a wrong soil moisture accounting procedure. Water Resour Res 41(W02011):1–6

Mishra SK, Singh VP (2002) SCS-CN-based hydrologic simulation package, chapt. 13. In: Singh VP, Frevert DK (eds) Mathematical models in small watershed hydrology and applications. Water Resources, Littleton, CO, pp 391–464

Mishra SK, Singh VP (2003) Soil Conservation Service curve number (SCS-CN) methodology. Kluwer, Dordrecht, The NetherlandsCrossRef

Mishra SK, Singh VP (2004) Long-term hydrological simulation based on the Soil Conservation Service curve number. Hydrol Process 18:1291–1313CrossRef

Mishra SK, Jain MK, Singh VP (2004) Evaluation of SCS-CN-based model incorporating antecedent moisture. Water Resour Manag 18(6):567–589CrossRef

Mishra SK, Sahu RK, Eldho TI, Jain MK (2006a) A generalized relation between initial abstraction and potential maximum retention in SCS-CN-based model. J River Basin Manag 4(4):245–253CrossRef

Mishra SK, Sahu RK, Eldho TI, Jain MK (2006b) An improved I_a–S relation incorporating antecedent moisture in SCS-CN methodology. Water Resour Manag 20(5):643–660CrossRef

Moriasi DN, Arnold JG, Van Liew MW, Bingner RL, Harmel RD, Veith TL (2007) Model evaluation guidelines for systematic quantification of accuracy in watershed simulations. Trans ASABE 50(3):885–900CrossRef

Motovilov YG, Gottschalk L, England K, Rodhe A (1999) Agric For Meteorol 98(99):257–277CrossRef

Nadal-Romero E, Latron J, Lana-Renault N, Serrano-Muela P, Martí-Bono C, David Regüés D (2008) Temporal variability in hydrological response within a small catchment with badland areas, central Pyrenees. Hydrol Sci J 53:629–639CrossRef

Nash JE, Sutcliffe JV (1970) River flow forecasting through conceptual models. Part I: a discussion of principles. J Hydrol 10:282–290

NRCS (1997) ‘Hydrology’ national engineering handbook, supplement A, section 4. Soil Conservation Service, USDA, Washington, DC

Parajuli P, Mankin KR, Barnes PL (2007) New methods in modeling source specific bacteria at watershed scale using SWAT. In: Watershed management to meet water quality standards and TMDLs (total maximum daily load), Proceedings. ASABE Publ. No. 701P0207, ASABE, St. Joseph, MI

Parajuli PB, Mankin KR, Barnes PL (2009) Source specific fecal bacteria modeling using soil and water assessment tool model. Bioresour Technol 100(2):953–963CrossRef

Ponce VM, Hawkins RH (1996) Runoff curve number: has it reached maturity? J Hydrol Eng 1(1):11–19CrossRef

Ritter A, Muñoz-Carpena R (2013) Performance evaluation of hydrological models: statistical significance for reducing subjectivity in goodness-of-fit assessments. J Hydrol 480:33–45CrossRef

Rodríguez-Blanco ML, Taboada-Castro MM, Taboada-Castro MT (2012) Rainfall–runoff response and event-based runoff coefficients in a humid area (northwest Spain). Hydrol Sci J 57(3):445–459CrossRef

Sahu RK (2007) Modifications to SCS-CN technique for rainfall–runoff modelling. PhD Thesis, Indian Institute of Technology, Bombay

Sahu RK, Mishra SK, Eldho TI, Jain MK (2007) An advanced soil moisture accounting procedure for SCS curve number method. J Hydrol Process 21(21):2872–2881CrossRef

Sahu RK, Mishra SK, Eldho TI (2010a) An improved AMC-coupled runoff curve number model. Hydrol Process 24:2834–2839CrossRef

Sahu RK, Mishra SK, Eldho TI (2010b) Comparative evaluation of SCS-CN-inspired models in applications to classified datasets. Agric Water Manag 97(5):749–756CrossRef

Sahu RK, Mishra SK, Eldho TI (2012) An improved storm duration and AMC coupled SCS-CN concept-based model. J Hydrol Eng 17(11):1173–1179CrossRef

Santhi C, Arnold JG, Williams JR, Dugas WA, Srinivasan R, Hauck LM (2001) Validation of the SWAT model on a large river basin with point and nonpoint sources. J Am Water Resour Assoc 37(5):1169–1188CrossRef

Sartori A, Hawkins R, Genovez A (2011) Reference curve numbers and behavior for sugarcane on highly weathered tropical soils. J Irrig Drain Eng 137(11):705–711CrossRef

Scherrer SF, Naef F, Faeh AO, Cordery I (2007) Formation of runoff at the hillslope scale during intense rainfall. Hydrol Earth Syst Sci 11:907–922CrossRef

Schneider LE, McCuen RH (2005) Statistical guidelines for curve number generation. J Irrig Drain Eng 131(3):282–290CrossRef

SCS (1972) ‘Hydrology’ national engineering handbook, supplement A, section 4. Soil Conservation Service, USDA, Washington, DC

Senbeta DA, Shamseldin AY, O’Connor KM (1999) Modification of the probability-distributed interacting storage capacity model. J Hydrol 224:149–168CrossRef

Sharpley AN, Williams JR (1990) Epic-erosion/productivity impact calculator: 1. model determination, USDA technical bulletin, no. 1768, USDA, Washington, DC

Shi ZH, Chen LD, Fang NF, Qin DF, Cai CF (2009) Research on the SCS-CN initial abstraction ratio using rainfall–runoff event analysis in the Three Gorges Area, China. Catena 77:1–7CrossRef

Singh J, Knapp HV, Arnald JG, Demissie M (2004) Hydrologic modeling of the Iroquois River watershed using HSPF and SWAT. J Am Water Resour Assoc 41(2):343–360CrossRef

Singh PK, Mishra SK, Berndtsson R, Jain MK, Pandey RP (2015) Development of a modified SMA based MSCS-CN model for runoff estimation. Water Resour Manag 29(11):4111–4127CrossRef

Sneller JA (1985) Computation of runoff curve numbers for rangelands from Landsat data. Technical report HL85-2, Agricultural Research Service, Hydrology Laboratory, Beltsville, MD

Soulis KX, Valiantzas JD (2013) Identification of the SCS-CN parameter spatial distribution using rainfall–runoff data in heterogeneous watersheds. Water Resour Manag 27(6):1737–1749CrossRef

Stewart D, Canfield E, Hawkins RH (2012) Curve number determination methods and uncertainty in hydrologic soil groups from semiarid watershed data. J Hydrol Eng 17:1180–1187CrossRef

Suresh Babu P, Mishra SK (2012) Improved SCS-CN-inspired model. J Hydrol Eng 17:1164–1172CrossRef

Taguas E, Yuan Y, Licciardello F, Gómez J (2015) Curve numbers for olive orchard catchments: case study in southern Spain. J Irrig Drain Eng. doi:10.1061/(ASCE)IR.1943-4774.0000892

Tedela NH, McCutcheon SC, Rasmussen TC, Tollner EW (2008) Evaluation and improvement of the curve number method of hydrological analysis on selected forested watersheds of Georgia. Project report submitted to Georgia Water Resources Institute, Supported by the US Geological Survey, Reston, VA, 40 pp

Tedela NH, McCutcheon SC, Rasmussen TC, Hawkins RH, Swank WT, Campbell JL, Adams MB, Jackson CR, Tollner EW (2012) Runoff curve numbers for 10 small forested watersheds in the mountains of the eastern United States. J Hydrol Eng 17(11):1188–1198CrossRef

Titmarsh GW, Pilgrim DH, Cordery I, Hossein AA (1989) An examination of design flood estimations using the U.S. soil conservation services method. Hydrology and Water Resources Symposium. The Institution of Engineers, Barton, Australia

Titmarsh GW, Cordery I, Pilgrim DH (1995) Calibration procedures for rational and USSCS design hydrographs. J Hydraul Eng 121(1):61–70CrossRef

Titmarsh GW, Cordery I, Pilgrim DH (1996) Closure of calibration procedures for rational and USSCS design flood methods. J Hydraul Eng 122(3):177CrossRef

Van Liew MW, Arnold JG, Garbrecht JD (2003) Hydrologic simulation on agricultural watersheds: choosing between two models. Trans ASAE 46(6):1539–1551CrossRef

Van Mullem JA, Woodward DE, Hawkins RH, Hjelmfelt AT, Quan QD (2002) Runoff curve number method: beyond the handbook. Proc., 2nd Federal Interagency Hydrologic Modeling Conf., Advisory Committee on Water Information (ACWI), Washington, DC

Woodward DE, Hawkins RH, Quan QD (2002) Curve number method: origins, applications and limitations. Proc., Second Federal Interagency Hydrologic Modeling Conference: Hydrologic Modeling for the 21st Century, Subcommittee on Hydrology of the Advisory Committee on Water Information, Las Vegas, NV

Woodward DE, Hawkins RH, Jiang R, Hjelmfelt AT, Van Mullem JA, Quan QD (2004) Runoff curve number method: examination of the initial abstraction ratio In: Proceedings of the World Water and Environmental Resources Congress and Related Symposiums. ASCE, Philadelphia, PA

Woodward DE, Scheer CC, Hawkins RH (2006) Curve number update used for runoff calculation. Ann Warsaw Agric Univ Land Reclam Land Reclam 37:33–42

Yuan PT (1933) Logarithmic frequency distribution. Ann Math Stat 4(1):30–74CrossRef

Yuan Y, Nie J, McCutcheon SC, Taguas EV (2014) Initial abstraction and curve numbers for semiarid watersheds in south eastern Arizona. Hydrol Process 28:774–783CrossRef

Zhang Y, Wei H, Nearing MA (2011) Effects of antecedent soil moisture on runoff modeling in small semiarid watersheds of southeastern Arizona. Hydrol Earth Syst Sci 15:3171–3179CrossRef

Zhou SM, Lei TW (2011) Calibration of SCS-CN initial abstraction ratio of a typical small watershed in the Loess Hilly-Gully region. China Agric Sci 44:4240–4247

Titel: Evaluation of the Soil Conservation Service curve number methodology using data from agricultural plots
verfasst von: Mohan Lal
S. K. Mishra
Ashish Pandey
R. P. Pandey
P. K. Meena
Anubhav Chaudhary
Ranjit Kumar Jha
Ajit Kumar Shreevastava
Yogendra Kumar
Publikationsdatum: 26.08.2016
Verlag: Springer Berlin Heidelberg
Erschienen in: Hydrogeology Journal / Ausgabe 1/2017
Print ISSN: 1431-2174
Elektronische ISSN: 1435-0157
DOI: https://doi.org/10.1007/s10040-016-1460-5

Springer Professional

Abstract

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Weitere Artikel der Ausgabe 1/2017

The first field-based descriptions of pumping-induced saltwater intrusion and upconing

Editors’ Message: The 2016 Editors’ Choice articles

Review: Current and emerging methods for catchment-scale modelling of recharge and evapotranspiration from shallow groundwater

Groundwater depth prediction in a shallow aquifer in north China by a quantile regression model

Development of unconfined conditions in multi-aquifer flow systems: a case study in the Rajshahi Barind, Bangladesh

Groundwater age, mixing and flow rates in the vicinity of large open pit mines, Pilbara region, northwestern Australia