Substituting eq. (8) back into eq. (5). gives an expression for the minimum initial velocity consistent with the ball reaching the hoop. The result is ¹0 = 8√ H+ √H² + x²) where = H-h (9)

Can someone explain this why the answer became like this? And show me the step-by-step solution please

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Here g is acceleration due to gravity at the earth's surface. t, and t₂ are time interval when the ball is released from the player to the maximum height (Y) and the time interval from the maximum height to the hoop respectively. To find the minimum initial velocity of the ball, the relationship between release angle and initial velocity for a given range must be considered. From eq. (3), we can be rewritten as H = (₁ +₂126₁-(₁+₂)]. 2 Substituting eq. (1) and eq. (2) in eq. (4) we got X X 21, V cos H-B.. 2 v cos We can rearrange eq. (4) as gX² (tan²0+1) 2(X tano - K) The trigonometric identities sec² 0 = (5) To solve the problem, we need to differentiate vo with respect to and set the derivative equal to zero. Then, we got dv dvo d0 where H = H-h. X tan X =(Xtano-H)tano- 2 tan²0+1 enable us to write eq. (6) more simply as 8X² 2v cos²0 cos²0 10 (4) sec² 0 = 0. -=X tan²0-21 tane - X=0. (6) - B± √B²-4AC From quadratic equation Ax² + Bx+C =0, x=- where AB and Care 2 A constant. We choose appropriate solution as positive solution, then we get optimal angle as H+√√H² + X² 0= tan (7) (8) Substituting eq. (8) back into eq. (5). gives an expression for the minimum initial velocity consistent with the ball reaching the hoop. The result is -√H²+ (9)