Global environmental challenges, particularly those driven by climate change, have disrupted precipitation patterns, causing irregular  rainfall distribution and water stress in agricultural systems. This study investigates the effects of varying watering regimes on the  growth, yield, and photosynthetic ability of two mungbean (Vigna radiata) cultivars, IC-39409 and SWETA. Conducted using a randomized  complete block design (RCBD) in a split-plot layout, the experiment included five watering intervals: control (2-day interval), 4-day, 6-day,  8-day, and 10-day intervals. Growth parameters such as plant height, leaf area index, were measured alongside yield and photosynthetic  efficiency. Data were analyzed using a two-way analysis of variance. The results revealed that both cultivars exhibited consistent  responses across all watering regimes. Maximum growth and yield were observed at the 4- day interval (WR2), with significant  improvements in plant height. Both cultivars demonstrated tolerance to water stress up to a threshold of 4 to 6 days without significant  reductions in yield or growth. Photosynthetic ability remained unaffected even under drought conditions up to a 10-day interval,  highlighting the resilience of mungbean to moderate water stress. However, extended watering intervals beyond six days led to a decline  in yield stability and overall plant performance. This research addresses critical gaps in understanding how intermediate  watering intervals affect mungbean growth parameters, including and photosynthesis, under water-limited conditions. Unlike prior  studies that focused on extreme drought or well-watered regimes, this work uniquely explores the balance between water stress  tolerance and optimal resource utilization. The novelty lies in its holistic approach to evaluating drought thresholds for mungbean  cultivars while providing practical insights into irrigation strategies for sustainable productivity amidst changing climatic conditions.