Abstract
In this study, satellite-based daily precipitation estimation data from precipitation estimation from remotely sensed information using artificial neural networks (PERSIANN)-climate data record (CDR) are being evaluated in Iran. This dataset (0.25°, daily), which covers over three decades of continuous observation beginning in 1983, is evaluated using rain-gauge data for the period of 1998–2007. In addition to categorical statistics and mean annual amount and number of rainy days, ten standard extreme indices were calculated to observe the behavior of daily extremes. The results show that PERSIANN-CDR exhibits reasonable performance associated with the probability of detection and false-alarm ratio, but it overestimates precipitation in the area. Although PERSIANN-CDR mostly underestimates extreme indices, it shows relatively high correlations (between 0.6316–0.7797) for intensity indices. PERSIANN-CDR data are also used to calculate the trend in annual amounts of precipitation, the number of rainy days, and precipitation extremes over Iran covering the period of 1983–2012. Our analysis shows that, although annual precipitation decreased in the western and eastern regions of Iran, the annual number of rainy days increased in the northern and northwestern areas. Statistically significant negative trends are identified in the 90th percentile daily precipitation, as well as the mean daily precipitation from wet days in the northern part of the study area. The positive trends of the maximum annual number of consecutive dry days in the eastern regions indicate that the dry periods became longer in these arid areas.
Highlights
Precipitation is one of the most important components of the Earth’s hydrologic cycle and the primary contributor to the water cycle
To evaluate the performance of PERSIANN-climate data record (CDR), the categorical statistics are calculated for daily precipitation as a first step
The categorical statistics (Wilks 2006) used in this study are the probability of detection (POD), the false-alarm ratio (FAR), and the bias (BIAS)
Summary
Precipitation is one of the most important components of the Earth’s hydrologic cycle and the primary contributor to the water cycle. Creating a consistent global precipitation dataset using observations obtained from different parts of the world cannot be merged due to the use of different methods (or indices) employed by different services and scientists (Karl et al 1995; Zhai et al 2005; Alexander and Arblaster 2009). The lack of such a longterm, high-resolution, comprehensive precipitation observation record at the global scale limits the ability of the scientific community to study extreme events.
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