Add to ORKG[1] A new characteristic timescale of a catchment is presented, the response timescale (RTS). It is a range of averaging time intervals which, when applied to catchment rainfall, yield smoothed time series that best approximate that of the resultant runoff. In determining the RTS, nothing is assumed about the nature of the rainfall-runoff transformation. In addition, this new measure is shown to be robust against measurement errors. An objective, automatic, observations-based algorithm is described that introduces the concept of peaks density for the estimation of RTS. Estimation is exemplified for single and multiple rainfall-runoff events through application to small catchments in Panama and Israel. In all cases, relatively stable values ...
A new temporal scaling method applicable to many rainfall-runoff-erosion models is presented. The me...
We present a new modeling approach analyzing and predicting the Transit Time Distribution (TTD) and ...
Abstract: Most catchment-scale rainfall-runoff models represent as time-invariant such features of t...
Published ArticleLarge errors in peak discharge estimates at catchment scales can be ascribed to err...
Methodologies to estimate the response time of a catchment to new rainfall inputs based on rainfall ...
Lagtimes and times of concentration are frequently determined parameters in hydrological design and ...
Sets of flow events from four catchments were selected in order to study how dynamics in the convers...
The Inter-Amount Times (IAT) adaptive sampling technique has been used for the analysis of hydrologi...
Hydrologic catchment response varies in time. The goal of this dissertation is to investigate how an...
Published ArticleIn single‐event deterministic design flood estimation methods, estimates of the pea...
Published ArticleLarge errors in estimates of peak discharge in medium to large catchments in South...
An investigation carried out into the values of lag time for catchment areas as measured from centr...
Inferred rainfall sequences generated by a novel method of inverting a continuous time transfer func...
Hydrological response times are often used to characterise runoff processes. They provide informatio...
Published ArticleCatchment response time parameters are one of the primary inputs required when desi...
A new temporal scaling method applicable to many rainfall-runoff-erosion models is presented. The me...
We present a new modeling approach analyzing and predicting the Transit Time Distribution (TTD) and ...
Abstract: Most catchment-scale rainfall-runoff models represent as time-invariant such features of t...
Published ArticleLarge errors in peak discharge estimates at catchment scales can be ascribed to err...
Methodologies to estimate the response time of a catchment to new rainfall inputs based on rainfall ...
Lagtimes and times of concentration are frequently determined parameters in hydrological design and ...
Sets of flow events from four catchments were selected in order to study how dynamics in the convers...
The Inter-Amount Times (IAT) adaptive sampling technique has been used for the analysis of hydrologi...
Hydrologic catchment response varies in time. The goal of this dissertation is to investigate how an...
Published ArticleIn single‐event deterministic design flood estimation methods, estimates of the pea...
Published ArticleLarge errors in estimates of peak discharge in medium to large catchments in South...
An investigation carried out into the values of lag time for catchment areas as measured from centr...
Inferred rainfall sequences generated by a novel method of inverting a continuous time transfer func...
Hydrological response times are often used to characterise runoff processes. They provide informatio...
Published ArticleCatchment response time parameters are one of the primary inputs required when desi...
A new temporal scaling method applicable to many rainfall-runoff-erosion models is presented. The me...
We present a new modeling approach analyzing and predicting the Transit Time Distribution (TTD) and ...
Abstract: Most catchment-scale rainfall-runoff models represent as time-invariant such features of t...