90- 
gol A s» Distributed 
d 
m m À € Lumped 
Es i 
$ so i * À Observed 
X brinda 
O 4 fig 
5 30 | a 
1 
TR, A 
104 | A sr 
  
cou TY T T T T Y. T T T T T T T T 1 
Q0 20 40 60 80 1C0 120 14C i50 180 280 
Time (3-h interval) 
  
Figure 2. Simulated runoff hydrograph for the rainfall 
event on 21-6-96 
approach gave good results in respect of watershed response 
against rainfall as compared to the lumped approach. The model 
simulated the heterogeneity of catchment characteristics and 
provided reasonable prediction, although the spatial distribution 
of rainfall is only given by five recording raingauge stations. 
Further, degree of spatial variability in a watershed can be 
represented by number of unique combinations of soil type and 
land use in the watershed but this methodology may fail if 
different combinations of soil and land use result in virtually 
equivalent curve numbers (Manguerra and Engel, 1998). 
However, this problem can be eliminated by using the curve 
number as the final measure of the watershed's spatial 
variability. 
For evaluation of grid size on the runoff depth, spatially 
distributed curve numbers were generated for different grid 
sizes of 23, 46, 92, 184, 368, 736 and 1472 m. and the resulting 
runoff for these grid resolutions was shown as figure 3. From 
the figure it is observed that the difference between simulated 
and observed runoff increases with the increase of grid size 
beyond 184 m. It may be observed that with increased grid 
resolution, response of watershed to hydrological process tend 
to be lumped. However, simulation of watershed with small grid 
size is more complex as spatial variation of hydrological 
parameters is high. Increasing grid size helps in simpler analysis 
with increased assumptions at the cost of accuracy in the results. 
Hence, sensitivity analysis of effect of grid size on runoff depth 
is a complex phenomenon and needs to make balance between 
computational time and accuracy. An analysis more detailed 
than manual methods is possible using a GIS integrated with 
distributed hydrological model offering crucial insight into 
effects of cell size. Thus, the grid cell size should be chosen 
such that the flow-path lengths in the drainage network are 
closely approximated. The modelling approach is capable of 
continuously simulating flow in distributed fashion for 
analyzing the impact of land use changes and as well as climate 
variability. Further, this model can be used to evaluate a 
futuristic water availability scenario for an agricultural 
watershed in eastern India. 
     
   
     
  
   
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B8, 2012 
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia 
  
    
  
  
  
  
0s 
055 - 
OB. a 
045 or 
E os Resolution(m) 
2 035 ay 
$ o3. PU 
5 225 une OY) 
z 02 ma 184 | 
0.15 + 388 : 
od 788 
di m 1472 
Od : ' 
2 so 100 150 
Rainfall depth (mm) 
  
  
Figure 3. Effect of grid resolution on runoff coefficient 
5. CONCLUSIONS 
The main advantage of distributed modeling is that the spatial 
variation of parameters is incorporated into the model response. 
Runoff prediction is a major component of watershed 
hydrologic modelling whether for resource conservation or 
environmental protection. In the present study, the distributed 
hydrological modelling approach considered the heterogeneity 
of catchment characteristics and provided reasonable prediction, 
although the spatial distribution of rainfall is only given by five 
recording raingauge stations. Advances in continuous time, 
distributed parameter hydrologic modeling as well as its 
integration with Geographical Information Systems (GIS) have 
led to the development of powerful tools for predicting runoff 
from watersheds. Particularly, GIS allowed the combination of 
remotely sensed data with spatial data forms such as 
topography, soil maps, and hydrologic variables such as rainfall 
distribution and soil moisture. This study has described the 
importance of parameterization issues involved when predicting 
watershed stream runoff. 
6. REFERENCES 
Abbott, MB, Bathurst, JC, Cung JA., O’Connell, PE, 
Rasmusses, J., 1986. An introduction to the European 
Hydrological System-Systeme. Hydrologique European SHE 2: 
Structure of a physically based distributed modelling system. J. 
Hydrolo, 87, 61-77. 
Beven, KJ. 1985. Distributed Model, In: MG Anderson and TP 
Burt (eds.), Hydrological Forecasting, Wiley 
Beven, KJ,, Kirby, MJ., Schofield, N., Tagg AF., 1984. Testing 
a physically based flood forecasting model (TOPMOEL) for 
three UK catchments, J Hydrol. 69:119-143. 
Arnold, JG., Williams, JR., Srinivasan, R., and King, KW., 
1995. SWAT: Soil Water Assessment Tool, Texas A&M 
University, Texas Agricultural Experimental Station, Blackland 
Research Center, 808 East Blackland Road, Temple, Texas. 
Beasley, DB., Huggins, LF., and Monke, EJ., 1980. 
ANSWERS: A Model for watershed planning. Transactions of 
the ASAE. 23(4):938-944. 
   
Intern: 
Chow, ' 
Newyork 
Chowdar 
Modellin 
Sensing. 
Cunge, 
computa 
7(2):209 
Diskin, | 
model tc 
Diskin, 
distribut 
Resourc 
Dooge, . 
Agric. B 
Foster, ‘ 
Water | 
No.1, 1 
Lafayett 
Greene, 
using g 
Manag, 
Maidme 
Proceed 
Integrat 
Environ 
1991. 0 
Morris, 
forecast 
mathen 
Natural 
Report. 
Londor 
Pandey 
and se 
waters} 
348:30: 
Ponce, 
reachec 
Ponce, 
methoc 
104(H) 
SCS, 1 
soil co: 
Stuebe 
using ( 
US Ar 
packag 
Engine