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Engineering, Technology & Applied Science Research Vol. 12, No. 1, 2022, 8017-8022 8017 
 

www.etasr.com Rafi et al.: An Evaluation of the Extreme Rainfall Event of 2010 over the Kabul River Basin using the … 

 

An Evaluation of the Extreme Rainfall Event of 2010 

over the Kabul River Basin using the WRF Model 
 

Fehmida Rafi 

U.S.-Pakistan Center for Advanced Studies in Water Mehran 
University of Engineering and Technology 

Jamshoro, Sindh, Pakistan 

fehmida.rafi850@gmail.com 

Ghulam H. Dars 

U.S.-Pakistan Center for Advanced Studies in Water 
Mehran University of Engineering and Technology 

Jamshoro, Sindh, Pakistan 

ghdars.uspcasw@faculty.muet.edu.pk 

Courtenay Strong  

Department of Atmospheric Sciences 

University of Utah 
Salt Lake City, Utah, USA 

court.strong@utah.edu 

Kamran Ansari 

U.S.-Pakistan Center for Advanced Studies in Water Mehran 

University of Engineering and Technology 

Jamshoro, Sindh, Pakistan 
kansari.uspcasw@faculty.muet.edu.pk 

Syed Hammad Ali  

Glacier Monitoring and Research Center (GMRC) 

Water and Power Development Authority (WAPDA) 

Lahore, Pakistan 
syedhammadali2001@yahoo.com 

 

 

Abstract-Extreme precipitation events are among the most severe 

weather hazards. Knowledge about the spatial patterns 
underlying such events in the Upper Indus Basin is limited 

because estimating precipitation is very challenging due to the 

data scarcity and the complex orography. Numerical weather 

prediction models can be applied at a fine resolution to overcome 

this issue. The Advanced Research Weather Research and 

Forecasting (WRF) model version 3.8.1 was applied over the 

Kabul River Basin to simulate the temperature and precipitation 

of monsoon season 2010, i.e., 1
st
 May to 16

th
 September 2010. We 

considered the May month as a spin-up period. The initial and 

boundary conditions were derived from the National Oceanic and 

Atmospheric Administration, Climate Forecast System 

Reanalysis data. The model was set up by using two-nested 

domains with increasing horizontal resolution moving inward 

from 15km on domain d01 to 5km on domain d02. The 
simulations were compared with TRMM 3B42, and station data 

collected from the Pakistan Meteorological Department and 

Water and the Power Development Authority using bias, 

percentage bias, root mean square error, and Pearson 

correlation. The results revealed that the simulated precipitation 

was improved from d01 to d02. However, the model showed 
mixed results with overestimation of precipitation at some 

stations and underestimations at others. Simulated precipitation 

generally agreed better with TRMM than with station data. 

Overall, the results indicate that the WRF model can be used to 
simulate heavy precipitation in complex terrain. 

Keywords-WRF-ARW model; Upper Indus Basin; Kabul River 

Basin; Pakistan; climate change 

I. INTRODUCTION  

The Indus basin is prone to floods and has been hit by 
massive and destructive flood events in the past. The main 
causes of floods in various regions of Himalayan Karakoram 
and Hindukush (HKH) is the intense monsoon rainfall and the 
rapid snowmelt due to the rising temperatures [1-4]. Pakistan 
faced an unprecedented and most devastating flood in 2010, 
which inundated 100,000km

2
, affecting more than 20 million 

people, with a death toll of 1,980 [5]. Many factors are 
responsible for the 2010 flood occurrence, however the primary 
cause was extreme monsoon precipitation [7, 8]. In the early 
July of 2010, a strong ridge of high pressure was developed 
over Russia, which moved southward and was combined with 
the monsoon track and the Phet cyclone [9, 10]. The 
combination of these three factors caused unprecedented 
rainfall in Pakistan. The northwestern parts of the country, 
especially Kabul River Basin (KRB), were struck first by the 
flooding event of 2010, which then traveled to the south, 
causing severe damage to houses, crops, and livestock [8]. 
Authors in [9] reported that on 29 July 2010, Khyber 
Pakhtunkhwa (KPK) province received more than 200mm of 
rainfall, which caused severe flash floods. Many stations in 
KPK received more than 150% of their climatological monthly 
July rainfall on 29 July. The KRB is a data-scare region, and 
the lack of sufficient meteorological stations makes performing 
climate and hydrological studies very challenging [10]. 

Global Climate Models (GCMs) are basic tools that assess 
climate change, but their coarse resolution limits their utility 

Corresponding author: Fehmida Rafi



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for studying hydrology processes that are sensitive to sub-grid 
scale variations in precipitation. The complex terrain in the 
mountainous areas exhibit variations at much finer scales than 
the grid spacing of GCMs. Therefore, Regional Climate 
Models (RCMs) are used to perform hydro-climate studies in 
complex terrain [11, 12]. Numerical Weather Prediction 
(NWP) models can be applied at higher resolutions to 
overcome the data scarcity issue and enhance the knowledge of 
atmospheric variability. The WRF model has been used 
worldwide for different applications [13, 14], but its application 
to the Indus River Basin (IRB) or even Pakistan is minimal [9, 
15]. 

Pakistan is among the top 10 countries affected by climate 
change. Extreme events due to climate change cannot be 
completely avoided [16, 17], but their impacts can be reduced 
by developing effective and efficient forecasting techniques 
through sophisticated tools. This study has been conducted to 
simulate the flood-producing rainfall event of 2010, which 
occurred in KRB by using the WRF model with a two-nested 
domain with a horizontal resolution of 15km and 5km. The 
event of 2010 is used as a case study to examine the 
applicability of the WRF model to simulate extreme 
precipitation events. The study will help in overcoming the lack 
of gauge data for forecasting heavy precipitation in complex 
terrains, such as KRB. We believe that this study will improve 
the understanding of the flood-producing rainfall event of 2010 
and may serve as a baseline for the authorities to devise better 
strategies to reduce the adverse effects of heavy precipitation 
events. 

II. MATERIALS AND METHODS 

A. Study Area 

The Kabul River is a 700-kilometer long river which is 
located between 33°36’ N - 36°55’ N and 67°36’ E - 73°54’ E. 
The river starts from the Sanglakh Range of Hindukush 
Mountains in Afghanistan and enters Pakistan through 
Mohmand Agency, where it is first gauged at Warsak Dam, 
then passes through Nowshera and finally drains into the Indus 
River near Attock. It contributes about 10% to 20% of its 
annual flows to the Indus river system [17]. The total 
catchment area of the Kabul River Basin (KRB) is about 
76,908km

2
, out of which 14,000km

2
 are located in Pakistan 

(Figure 1). The basin has elevation of 305-7690m [18]. Higher 
discharge in the river is observed in July and August due to the 
heavy rainfall and, due to the higher temperature of these 
months, glacier melting. The main cause of flooding in the 
region is the combination of rainfall and glacier melting [19]. 
The climate of the basin is semi-arid. The maximum 
temperature of 28°C is observed in June-August, whereas the 
mean minimum temperature is -6°C. Due to the complex 
terrain and the variation in elevation, precipitation varies 
throughout the basin. The maximum precipitation occurs 
during winters in the form of snowfall, with an average of 
110mm [20, 21]. Chitral, Swat, and lower parts of the Kabul 
River experience the Indian summer monsoon, On the contrary, 
the Upper Kabul is influenced by western disturbances [17]. 

 

 
Fig. 1.  Map of the two nested domains of WRF simulations at the Kabul 

River Basin (d01 = 6km, d02 = 2km). 

B. WRF Model and Setup 

In this study, the Advanced Research Weather Research & 
Forecasting (WRF) model [21] is used. The WRF model is a 
next-generation mesoscale numerical weather system, which is 
used for short-term weather forecasts and long-term climate 
simulations. The WRF has been developed by the National 
Center for Atmospheric Research (NCAR) in partnership with 
National Oceanic and Atmospheric Administration (NOAA) 
and the US Department of Defense. The WRF model was set 
up by using two nested domains, domain 1 (d01) and domain 2 
(d02) with increasing resolution moving inward from 15km to 
5km grid spacing (Figure 1). The Lambert map projection type 
is chosen for both domains. The inner domain (d02) is centered 
over northwest Pakistan to represent KRB with two-way 
nesting. The simulation started at May, 1 at 00:00 hours and 
ended at September, 16 at 20:00 hours. The hourly simulated 
data were converted into daily data for the validation process. 
Initial and boundary conditions for the simulations were 
derived from the NOAA Climate Forecast System Reanalysis 
(CFSR) data [22], which has a 38km horizontal resolution. The 
research shows that the CFSR dataset performs well in 
simulating atmospheric changes over the HKH region [11, 22].  

The WRF model is a non-hydrostatic model that has many 
options for physical parameterization schemes. The model is 
configured with the Noah Multi-Parameterization (Noah-MP) 
land surface model [23], Yonsei University (YSU) planetary 
boundary layer scheme [24], Thompson microphysics scheme 
[25], Rapid Radiative Transfer Model (RRTM) longwave 
radiation scheme [26], Dudhia shortwave scheme [27], surface 
layer scheme [28], and Betts-Miller-Janjic cumulus scheme 
[29]. All these schemes were applied for both domains, 
however the resolution of the inner domain (d02) is small 
enough to allow switching off the convective parameterization.  

C. Model Validation 

We evaluated the simulations with the station 
meteorological data obtained from the Pakistan Meteorological 
Station (PMD) and Water and Power Development Authority 



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www.etasr.com Rafi et al.: An Evaluation of the Extreme Rainfall Event of 2010 over the Kabul River Basin using the … 

 

(WAPDA). The daily data come from 11 stations, namely 
Balakot, Chitral, Drosh, Dir, Saidu-Sharif, Peshawar, Ushkore, 
Yasin, Phulra, BeshamQila, and Daggar. The WRF 
precipitation output was also assessed with the Tropical 
Rainfall Measuring Mission (TRMM) 3B42 version 7 gridded 
precipitation data at a monthly time scale. TRMM is 
considered a reliable gridded precipitation dataset in the 
Himalayan Karakoram region. The TRMM dataset has the best 
performance among the other remote sensing datasets in the 
Indus basin [30]. Similarly, authors in [31] revealed that 
TRMM 3B42V7 is better than the other products when 
evaluated in the Hunza river. The WRF simulations were 
assessed by the percentage bias (PBIAS), root mean squared 
error (RMSE), and Pearson correlation coefficient (r), and bias.  

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values and N is the number of days.  

III. RESULTS 

In this section, the WRF-simulated precipitation is 
evaluated by using the PMD meteorological data and the 
TRMM dataset.  

A. Precipitation at Specific Location 

This section compares the WRF predicted precipitation to 
values observed by gauges and TRMM. The main results for 
both domains are shown in Figure 2. The WRF and TRMM 
data were bilinearly interpolated to the 11 gauge stations. For 
the WRF data, interpolations were performed separately for the 
15km data from d01 and the 5km data from d02. The WRF 
reproduced the precipitation from May, 1 to September, 16 at 
each station at 22 different resolutions. It was seen that more 
precipitation was simulated by the WRF model on 29 July in 
each station in both domains.  

 

 
Fig. 2.  Time series comparison between the WRF simulated precipitation (blue), observed gauge precipitation (red), and TRMM precipitation (green) for d01 

(left column) and d02 (right column). 

Before presenting the summarized statistics of the WRF 
performance, we begin with the specific results for July, 29, 
2010, which feature exceptionally high precipitation totals as 
discussed in the Introduction. When the simulations of each 
station were compared for d01, the simulated rainfall on July, 
29 was 55mm (Balakot), 65mm (Besham Qila), 27mm 
(Chitral), 47mm (Daggar), 58mm (Dir), 38mm (Drosh), 49mm 
(Phulra), 63mm (Saidu Sharif), 16mm (Ushkore), and 17mm 
(Yasin), with the highest rainfall predicted in Peshawar 
(120mm). Similarly, in domain d02 the rainfall predicted at 
each station was 46mm, 55mm, 22mm, 40mm, 84mm, 30mm, 

53mm, 67mm, 10mm, and 12mm respectively, with the highest 
rainfall again predicted in Peshawar (153mm). On the other 
hand, the observed data show that the maximum precipitation 
recorded on July, 29 was 45mm, 128mm, 41mm, 99mm, 
149mm, 61mm, 90mm, 187mm, 0mm, and 2mm for the same 
stations, with the highest rainfall predicted in Peshawar 
(274mm). In addition, when simulated precipitation and gauge 
data were compared for d01, it was found that the WRF model 
under-predicted the precipitation at all the stations on July, 29, 
whereas there was over-prediction at Balakot, Ushkore, and 
Yasin. 



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For the gauge data, the results showed that the PBIAS 
decreased in magnitude in domain d02 at Balakot, Chitral, 
Daggar, Drosh, Peshawar, Phulra, Saidu Sharif, and Ushkore, 
whereas it increased at Besham Qila, Dir, and Yasin. This 
means that the resolution increase from d01 to d02 lessened the 
bias against the gauge data for 8 stations and worsened the bias 
for 3 stations. On the other hand, when the simulated 
precipitation was compared with the TRMM dataset, it was 
found that there were 4 stations (Balakot, Peshawar, Dir, and 
Yasin) where the bias was decreased in magnitude on d02 and 
7 stations (Chitral, Saidu Sharif, Ushkore, Besham Qila, 
Phulra, Drosh, and Daggar) where the bias was larger in 
magnitude on d02. Overall, the gauge data comparison 
provided a stronger indication of bias reduction on d02 than the 
TRMM data comparison. Similarly, when the WRF predicted 
precipitation was compared with the gauge data, the correlation 
between the simulated and the observed data varied for each 
station. The WRF showed a high correlation (r ≥ 0.5)	to 5 
stations (Balakot, Chitral, Besham Qila, Dir, and Drosh), 
whereas the rest of the WRF results had a lower correlation 
with the station data. The highest correlation was observed in 
Besham Qila (r = 0.8) and the lowest in Phulra (r = 0.2). On the 
other hand, when the correlation was considered for the 
simulation precipitation and TRMM dataset, 8 stations 
(Balakot, Chitral, Yasin, Besham Qila, Dir, Drosh, Saidu 
Shaarif, and Daggar) showed high correlation to the TRMM 
dataset, whereas 3 (Peshawar, Ushkore, and Phulra) did not. 
The highest correlation was observed in Besham Qila and 
Peshawar with r = 0.8, whereas the lowest was observed in 
Phulra with r = 0.3. Overall, at each location, the correlations 
with station data were similar in domains d01 and d02. 

 
 

 

Fig. 3.  WRF precipitation percent bias against gauge data in domain d01 

and domain d02. 

To illustrate how the performance statistics were organized 
on the topography in each domain, Figure 3 shows the PBIAS 
of WRF simulated precipitation relative to gauge data as a 
function of elevation. The shape of the PBIAS graphs as a 
function of elevation was similar on both domains, and the 
largest magnitude biases were positive and occurred at higher-
elevation stations above approximately 1500m. At all but one 
station, as shown in Figure 3, the PBIAS was smaller in d02, 
which shows that at all stations there was a smaller bias 
between modeled and observed precipitation in d02 as 
compared to d01. The PBIAS averaged -9% in d02 and 17% in 

d01. The t-test was used to identify cases where the mean 
precipitation simulated by WRF differed significantly from the 
observed precipitation at the 95% confidence level (p ≤ 0.05). 
For most gauge data, the null hypothesis of no difference in 
mean could not be rejected at the 95% confidence level. 
However, in domain d01, a significant difference in mean was 
found at 3 stations: Chitral, Drosh, and Ushkore. When the 
WRF predicted precipitation was compared with station data in 
domain d02, significant differences were found at Dir and 
Ushkore. For TRMM data, no significant differences were 
found in d01, and only 2 locations (Drosh and Besham Qila) 
had significantly different results in d02. The patchy 
significance of these t-test results indicates the encouraging 
performance of WRF, especially given that we assumed one 
degree of freedom per day (i.e. use of effective degrees of 
freedom reduced to account for autocorrelation would be less 
likely to reject the null). Table I lists the p values associated 
with the t-test comparing the mean WRF precipitation to gauge 
(TRMM) precipitation in d01 and d02. 

TABLE I.  P VALUES FOR D01 AND D02 

Station 
p-value 

d01 (TRMM) 

p-value 

d02 (TRMM) 

Balakot 0.12 (0.14) 0.3 (0.2) 

Chitral 0.004 (0.7) 0.1 (0.3) 

Dir 0.2 (0.2) 0.003 (0.2) 

Drosh 0.002 (0.3) 0.9 (0.02) 

SaiduSharif 0.7 (0.07) 0.8 (0.3) 

Peshawar 0.8 (00.5) 0.6 (0.3) 

Ushkore 0.0005 (0.06) 0.03 (0.6) 

Yasin 0.86 (0.4) 0.4 (0.8) 

Phulra 0.4 (0.5) 0.6 (0.3) 

BeshamQila 0.3 (0.1) 0.1 (0.02) 

Daggar 0.5 (0.6) 0.7 (0.4) 

 

B. Multilocation Mean Precipitation 

This section examines the precipitation averaged across the 
station locations for WRF, TRMM, and gauge data. WRF, 
TRMM, and gauge data were averaged at the 11 gauge 
location. WRF over-predicted the precipitation at some days 
and under-predicted at others (Figure 4). Similarly, it was 
observed that WRF under-predicted the average precipitation 
on July, 29 in both d01 and d02. The TRMM value for this 
extreme event was intermediate between the WRF and the 
station values (the station average precipitation for both 
domains on July 29 was 98mm, and the TRMM dataset 
indicate 76mm in both d01 and d02, whereas the WRF model 
simulated 50mm in d01 and 49 mm in d02). 

IV. DISCUSSION 

In this paper, the WRF model was used to simulate the 
precipitation of the flood-producing rainfall event of 2010. It 
was found that there were 3 heavy precipitation events 
observed during these 5 months, namely May 17, June 3, and 
July 29. The findings of the study revealed that the 
precipitation event of July, 29 was the main cause of the flood 
of 2010, which was consistent with [8, 9]. The results showed 
that the precipitation simulations were improved from d01 
(15km) to d02 (5km), which is attributable to the increased 
resolution or the combination of the parameterization schemes, 



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which is consistent with [32], in which it was found that WRF 
simulates convective precipitation quite effectively using Noah 
LSM, which predicts both soil temperature and moisture. The 
findings are also consistent with [33], the authors of which 
found that at higher resolution the WRF model shows better 
results. The results of the study are similar to that of [34], in 
which it was found that complex terrains need higher resolution 
to accurately forecast precipitation.  

The study showed that the WRF has a weak positive 
correlation (r = 0.3) with the observed data at high-elevation 
stations (Ushkore and Yasin). However, the WRF results tend 
to have a stronger positive correlation with the observed 
datasets at some of the low-elevation stations (e.g. Besham 
Qila and Peshawar). This is consistent with [34-36]. In 
addition, the WRF showed a higher overall correlation with the 
TRMM dataset than with the gauge data. The station-averaged 
precipitation indicated a mix between over-prediction and 
under-prediction. For the extreme event on July, 29, WRF's 
simulated precipitation (~50mm) was smaller than the TRMM 
(76mm) and gauge results (98mm). Discrepancies from 
observations may stem from not resolving subgrid-scale terrain 
effects or limitations of the chosen physical parameterization 
schemes [36]. The high-elevated stations showed more PBIAS 
except for Yasin and Dir station, where the WRF showed a low 
PBIAS of 3.8% in d01 and -18% in d02 in Yasin and -21% in 
d01 and -51% in d02 in Dir. In addition, the WRF showed less 
bias at the low-elevated stations except from SaiduSharif and 
BeshamQila stations where the model showed underestimation 
of precipitation, as large as-34%. 

Overall, it was concluded that the WRF model performed 
well with higher resolution with slightly overestimation at 
some locations and underestimation at others, which is 
consistent with [38]. Hence, it can be said that WRF can be 
used to predict the extreme precipitation events over complex 
regions such as the Upper Indus Basin. 

V. CONCLUSION AND RECOMMENDATIONS 

Kabul River Basin is an integral part of the Indus basin and 
has been frequently hit by massive floods in the past. The worst 
flood in KRB was the flood of 2010. It is expected that due to 
the climate change, the frequency and intensity of floods will 
increase in the future. This study was conducted to simulate the 
flood of 2010 by using the WRF model over the KRB. The 
findings of the study revealed that the WRF model was able to 
predict the extreme precipitation event of 2010. The overall 
favorable performance indicates that the one-month spin-up 
period was sufficient for short-term simulations. Two domains 
were used to simulate the precipitation over the region, and the 
result showed that the WRF model performed better in the 
higher resolution domain. It was concluded that the model 
proved to be useful for precipitation simulations in the HKH 
region. 

Although the WRF model performed well in the KRB, 
substantial biases were found at some of the higher elevation 
stations. Continued work is thus needed on the sensitivity 
analysis of the WRF model, which is important for determining 
the optimal combination of physical parameterization schemes 
over the Upper Indus Basin. In addition, the WRF output 

should be compared with other available satellite and remote 
sensing datasets in addition to TRMM to evaluate the 
effectiveness of the model performance.  

Keeping in view the shortcomings of the GCMs over hilly 
and complex areas such as KRB, the RCMs are the best tools to 
perform modeling climate studies. This study showed that 
WRF was able to simulate extreme events over the KRB. 
Therefore, it could be suggested that the WRF model with the 
right combination of physical parameterization schemes, 
horizontal resolution, and nesting domain can be used to 
forecast similar future events in the complex and rugged terrain 
of the HKH region. 

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