The objective of the current study is to investigate and evaluate the annual and seasonal rainfall trends and patterns of the Punjab province, Pakistan during the 1981-2015. The spatial patterns and temporal trends were identified through the Modified Mann Kendall test. Finding revealed that 13 weather stations of Punjab province have shown the statistically significant decreasing trend of annual and summer monsoon rainfall during the study period. From further investigation, the rainfall during the summer monsoon period (JJAS) found to be increased by 12.45%, similarly the rainfall during the whole of year be also increased by 18.75%. The significant decreasing trends observed with the higher percentage change in annual and monsoon rainfall for the stations of Sialkot and Lahore in the northern and central Punjab. The empirical evidences suggested that northern Punjab gets more moisture as compared the Southern and Western Punjab. This study suggests intensive empirical research in the future to evolve further spatio-temporal trends in the rainfall pattern of Punjab.
In this study, spatio-temporal patterns of seasonal precipitation and extreme precipitation events around Mt. Halla (1,950m) and their associations with elevation and aspect are examined based on daily precipitation data for the recent decade(2003~2012) observed at 24 weather stations in Jeju Island. Regression analyses show that annul total precipitation and the annual frequency of extreme precipitation events exceeding 80mm of daily precipitation increase with height by approximately 242mm/100m and 1.0day/100m, respectively. Seasonally, extreme precipitation events over the high mountain area mostly occur in summer (June~August) and also appear in other seasons including winter (December~February). The frequency of annual or seasonal extreme precipitation events as well as precipitation is higher in the southeastern or northeastern slope than in the southwestern or northwestern slope of Mt. Halla. These patterns are associated with the flow direction of moist air that ascends the slope of Mt. Halla when anticlockwise circulation of low pressure systems prevails. These findings provide primary information for developing the proactive strategies to mitigate potential flooding in the low-elevated coastal areas by extreme precipitation events over Mt. Halla