Answer to Question #294771 in Mechanics | Relativity for joy

a) We can calculate the time with the equation

"h= h_0+V_0t-\\frac{gt^2}{2}= 0\n\\\\ t= \\frac{-V_0 \u00b1\\sqrt{V_0^2+2gh_0 }}{-g} \n\\\\ t= \\frac{V_0}{g} \\mp \\sqrt{ (\\frac{V_0}{g})^2+\\frac{2h_0}{g} }\n\\\\ t= (\\frac{V_0}{g})\\Big(1\\mp \\sqrt{ 1+\\frac{2gh_0}{V_0^2} } \\Big)"

We take the positive root and we calculate the total time with V₀ = 15 m/s and h₀ = 50 m:

"t= (\\frac{15\\,m\/s}{9.8\\,m\/s^2})\\Big( \\sqrt{ 1+\\frac{2(9.8\\,m\/s^2)(50\\,m)}{(15\\,m\/s)^2} } +1\\Big)\n\\\\ t= ( 1.53\\,s)(1+\\sqrt{ 1+4.355 })= 5.07\\,s"

b) the total distance along the y axis will be twice the maximum distance reached when the ball goes upwards and then we add it to the height of the cliff h₀ to find the total distance traveled by the ball as D:

"t_{upwards}= \\frac{V_0}{g}\n\\\\ d=V_0t-\\frac{gt^2}{2}=V_0(\\frac{V_0}{g})-\\frac{g}{2}(\\frac{V_0}{g})^2\n\\\\ \\therefore d = \\frac{V_0^2}{g}-\\frac{V_0^2}{2g}=\\frac{V_0^2}{2g}\n\\\\ \\to D = h_0 + 2d = h_0 +\\frac{V_0^2}{g} \n\\\\ D= 50\\,m+\\frac{[15\\frac{m}{s}]^2}{9.8\\frac{m}{s^2}}= 72.96\\,m"

In conclusion, a) it takes 5.07 s for the ball to reach the base of the cliff, and b) the ball covers a total distance of 72.96 m.