Situation 01. In a survey within the catchment area of a lake, Thiessen polygons were established by setting up a transit at Point Z, which is the inner portion of a four-sided lake MNOP. The readings are as follow: LINE ZM ZN ZO Z.P 0.211 Outflow Seepage Loss Precipitation Evaporation Area RAINFALL, ft 8.23 cms 68 mm 0.26 If the rainfall from the area of bounded by ZMP is the Arithmetic Mean of the other rainfalls, compute the average precipitation (in cm) by Thiessen Polygon Method. 12 cm 2.45 in 21.21 sq.mi. 0.239 Situation 02. Given the following data gathered on December 4-23, 2011, compute for the required. inflow (in cu.ft/hr) in order to have an increase in storage of 14cm. BEARING N 40°30' W N 38° E $70° E S 60° 15' W DISTANCE 420.35km 530.15km 480.75km 695.10km Situation 03. Given the following rainfall data, draw the hyetograph, and determine at what time is the highest intensity of the rainfall.

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Situation 01. In a survey within the catchment area of a lake, Thiessen polygons were established by setting up a transit at Point Z, which is the inner portion of a four-sided lake MNOP. The readings are as follow: BEARING N 40°30' W N 38° E S 70° E | S 60° 15' W | 695.10km RAINFALL, ft DISTANCE 420.35km LINE ZM 0.211 ZN 530.15km 0.26 zo 480.75km 0.239 ZP If the rainfall from the area of bounded by ZMP is the Arithmetic Mean of the other rainfalls, compute the average precipitation (in cm) by Thiessen Polygon Method. Situation 02. Given the following data gathered on December 4-23, 2011, compute for the required inflow (in cu.ft/hr) in order to have an increase in storage of 14cm. Outflow 8.23 cms Seepage Loss 68 mm Precipitation Evaporation 12 cm 2.45 in Area 21.21 sq.mi. Situation 03. Given the following rainfall data, draw the hyetograph, and determine at what time is the highest intensity of the rainfall. Time Rainfall, mm 7:40 2 7:40-7:48 43 7:48-7:56 67 7:56-8:04 87 8:04-8:12 44 8:12-8:20 21 8:20-8:28 13 8:28-8:36 6.