Development and Evaluation of a Gis-Based Spatially Distributed Unit Hydrograph Model

Kilgore, Jennifer Leigh

23 December 1997

Synthetic unit hydrographs, which assume uniform rainfall excess distribution and static watershed conditions, are frequently used to estimate hydrograph characteristics when observed data are unavailable. The objective of this research was to develop a spatially distributed unit hydrograph (SDUH) model that directly reflects spatial variation in the watershed in generating runoff hydrographs. The SDUH model is a time-area unit hydrograph technique that uses a geographic information system (GIS) to develop a cumulative travel time map of the watershed based on cell by cell estimates of overland and channel flow velocities. The model considers slope, land use, watershed position, channel characteristics, and rainfall excess intensity in determining flow velocities. The cumulative travel time map is divided into isochrones which are used to generate a time-area curve and the resulting unit hydrograph. Predictions of the SDUH model along with the Snyder, SCS, and Clark synthetic unit hydrographs were compared with forty observed storm events from an 1153-ha Virginia Piedmont watershed. The SDUH model predictions were comparable or slightly better than those from the other models, with the lowest relative error in the peak flow rate prediction for 12 of the 40 storms, and a model efficiency of at least 0.90 for 21 of the storms. Despite the good predictions of the hydrograph peak flow rate and shape, the time to peak was underpredicted for 34 of the 40 storms. Runoff from the 40 storms was also generated for two subwatersheds (C: 462 ha; D: 328 ha) in Owl Run to assess the effect of scale on the SDUH model. Peak flow rate predictions were more accurate for the entire watershed than for either subwatershed. The time to peak prediction and model efficiency statistics were comparable for the entire watershed and subwatershed D. Subwatershed C had poorer predictions, which were attributed to a large pond in the main channel, rather than to scale effects. The SDUH model provides a framework for predicting runoff hydrographs for ungauged watersheds that can reflect the spatially distributed nature of the rainfall-runoff process. Predictions were comparable to the other synthetic unit hydrograph techniques. Because the time to peak and model efficiency statistics were similar for the 1153-ha watershed and a 328-ha subwatershed, scale does not have a major impact on the accuracy of the SDUH model. / Master of Science

GIS

unit hydrograph

hydrologic modeling

spatial modeling

Peligrosidad de las aguas de avenidas en los cruces de carreteras con ramblas. Estudio aplicado a la franja costera meridional de la región de Murcia

García Lorenzo, Rafael

17 December 2010

Los objetivos de la presente tesis son la identificación de la peligrosidad en las intersecciones de ramblas con carreteras, y la aplicación de diferentes índices, producto de análisis cuantitativos y valoraciones cualitativas basadas en un extenso trabajo de campo reunido en fichas descriptivas. Se analizan las diferentes obras de drenaje que afectan al área de estudio, sus funciones y requerimientos para optimizar el tipo de diseño, la ubicación y la eficiencia de las obras de drenaje transversales a los flujos de avenida. Ello sirve de base para conocer la peligrosidad de los cruces de carreteras con ramblas que depende del nivel de exposición de las infraestructuras viarias y del tipo de cruce de carretera.Para la obtención de datos de caudal se ha empleado el método del hidrograma unitario (MHU) y el método racional modificado (MRM), así como la integración de métodos de geometría hidráulica y técnicas de teledetección. Complementariamente, se ha realizado una modelización hidráulica y la aplicación de modelos empíricos para la estimación de la erosión del lecho y transporte de fondo.Otro objetivo del estudio es la definición de propuestas de gestión de los datos sobre peligrosidad orientadas a estrategias y planes de protección civil. El uso de visores por parte de las autoridades competentes, la integración, mantenimiento y manejo de los datos, así como la creación de un Atlas interactivo de peligrosidad hidrológica e hidromorfológica en carreteras son aplicaciones prácticas concretas de la tesis. / The objectives of this thesis are the identification of the hazard at intersections between ephemeral channels and roads, and the application of different rates, resulting from quantitative and qualitative assessments based on important fieldwork stored in descriptive sheets.Different drainage affecting the study area are analyzed, their functions and requirements to optimize the design type, the location and the efficiency of cross drainage works to flood flows. This serves as a starting point to learn about the dangerous road junctions to ephemeral channels depending on the level of exposure of road infrastructure and the type of road crossing.To obtain flow data has been used the unit hydrograph method (UHM) and the modified rational method (MRM) and the integration of hydraulic geometry methods and techniques of remote sensing. Additionally, a hydraulic modeling has been run and the application of empirical models for estimating the bed erosion and bedload transport.Another objective of the study is define proposals for data management about hazard focused to strategies and plans for protection of citizens. The use of web viewers by the competent authorities, integration, maintenance and management of data and the creation of an interactive atlas and hydrological and hydromorphological hazards on roads are actual practical applications of the thesis.

interactive atlas

hazard

unit hydrograph method

ephemeral channels

atlas interactivo

peligrosidad

hidrograma unitario

rambla

Geografía Física

504

55

626/627

9

A GIS-Based Method of Deriving Spatially Distributed Unit Hydrographs / En GIS-baserad metod för att beräkna  spatialt fördelade enhetshydrografer

Lenander, Ann-Sofi

January 2021

Prior to using hydraulic and spatially distributed modelling softwares, the theory of the unit hydrograph was a commonly used tool for modelling of surface and runoff water. While distributed models often provide detailed results from extensive calculation durations, the unit hydrograph have been questioned for simplifying the physical characteristics of the watershed modelled. Typically, the unit hydrograph theory does not explicitly take the flow paths of the watershed in consideration during calculation. With the rise of geographical information systems, methods of deriving spatially distributed unit hydrographs have been developed. The aim of these have commonly been to find a spatially varied form of hydrological modelling, while still keeping the computation times low. The method is commonly built by calculating the travel time to the watershed outlet along the flow path. In this study, spatially distributed unit hydrographs are derived separately for the watershed’s pervious and impervious surfaces in a Python script using map algebra and the Esri’s Python wrapper module Arcpy. The travel times are generated from a velocity field calculated using Maidment and Olivera’s velocity equation. The velocity equation contains three unknown parameters; one for an average velocity and two calibration parameters. The excess precipitation is calculated of a 100 year return period Chicago Design Storm hyetograph using the SCS-CN method. The direct runoff hydrographs are calculated over three semi-urban watersheds in Smedby in southern Sweden, and the results are compared to MIKE 21 hydrograph data of each corresponding watershed and rain input. The result obtained showed to replicate the hydrograph response quite well, but only if the unknown parameters in the velocity equation were calibrated to match the MIKE 21 data. The unknown parameters of the velocity equations produces uncertainties of using the method without calibration data, which implies that the script is not well adapted to use for modelling predictions. It may be of interest to calculate the travel times of the locations within the watershed using a different formula. The script tool could be tested using different design storms as input, and areas of different characteristics compared to Smedby could be tested. / Innan det blev vanligt att använda hydrauliska och rumsliga modellerings- mjukvaror användes ofta teorin bakom enhetshydrografen för modellering av avrinning. Medan de rumsliga mjukvarorna ofta erbjuder detaljerade resultat till priset av långa beräkningstider, har enhetshydrografen ifrågasatts för att förenkla den fysiska karaktären av avrinningsområdet. Typiskt sett tar inte enhetshydrografen avrinningsområdets flödesvägar direkt i hänseende vid beräkning. Utveckling och ökad tillgänglighet av geografiska informations- system förenklade möjligheterna att utveckla beräkning av enhetshydrografer som tar hänsyn till avrinningsområdets karaktär, typiskt sett genom att beräkna rinntiden från varje läge i avrinningsområdet, längs rinnvägarna och till utloppet. I den här studien beräknas spatiala enhetshydrografer separat för avrinningsområdets hårdgjorda och icke hårdgjorda ytor, genom att utveckla ett Python skript med hjälp av karalgebra och Esri’s wrapper modul ArcPy. Rinntiderna från olika lägen i avrinningsområdet beräknas med Maidments och Oliveras formel för hastighet, vilken innehåller okända parametrar för en uppskattad medelhastighet samt två kalibreringsparametrar. Effektivt regn från ett Chicago Design Storm regn med en återkomsttid på 100 år beräknas med hjälp av SCS-CN metoden. Hydrograferna för direkt avrinning faltas för tre semi-urbana avrinningsområden i Smedby i södra Sverige för att sedan jämföras mot MIKE 21 genererad hydrograf data för respektive motsvarade avrinningsområde. Hydrografdata producerat av MIKE 21 har tagits fram med lika CDS-regn data som input. Resultatet visar att hydrografer snarlika MIKE 21 hydrograferna kan tas fram med Maidments spatialt fördelade enhetshydrograf, om de okända parametrarna i Maidments formel kalibrerades mot MIKE 21 data. Utan kalibreringsdata för att bestämma de okända parametrarna kan resultatet anses vara mycket osäkert, vilket antyder att Python skriptet ej bör användas för använda metoden för att förutspå responser av regnevent. Andra beräkningar än Maidments ekvation kan vara av intresse att implementera. Olika typer av regninput samt spatial data över andra platser än Smedby kan vara av intresse att testa Python skriptet för.

the unit hydrograph

GIS

ArcPy

design storm

SCS-CN method

spatial data

excess rainfall

enhetshydrografen

GIS

Arcpy

design regn

SCS-CN metoden

geodata

effektivt regn

Engineering and Technology

Teknik och teknologier

Hydrological Impacts of Urbanization: White Rock Creek, Dallas Texas

Vicars, Julie Anne Groening

12 1900

This research project concerns changes in hydrology resulting from urbanization of the upper sub-basin of the White Rock Creek Watershed in Collin and Dallas Counties, Texas. The objectives of this study are: to calculate the percent watershed urbanized for the period of 1961 through 1968 and the period of 2000 through 2005; to derive a 1960s average unit hydrograph and a 2000s average unit hydrograph; and, to use the two averaged hydrographs to develop a range of hypothetical storm scenarios to evaluate how the storm response of the watershed has changed between these two periods. Results of this study show that stormflow occurs under lower intensity precipitation in the post-urbanized period and that stormflow peaks and volumes are substantially larger compared to the pre-urbanized period. It is concluded that changes in watershed surface conditions resulting from urbanization have lowered the precipitation-intensity threshold that must be surpassed before storm run-off is generated.

White Rock Creek Watershed (Tex.)

urbanization

hydrology

unit hydrograph