If the car accelerates for time `t_(1)` and decelerates for time `t_(2)` then according to give problem,
`t = t_(1) + t_(2)`.....(i)
If `v_("max")` is the maximum velocity of the car, fron `v//t` curve, we have
`alpha = (v_("max"))/(t_(1))` and `beta = (v_("max"))/(t_(2))` [as slope of `v//t` curve gives acc.] so that `[(1)/(alpha) + (1)/(beta)] = ((t_(1) + t_(2)))/(v_("max"))`
Which in the light of Eqn. (i) gives
`v_("max") = (alpha beta t)/((alpha + beta))`....(ii)
Further as area under `v//t` curve gives the distance covered in a given time so,
`s = (1)/(2) (v_("max")) t = (alpha beta t^(2))/(2 (alpha + beta))`....(iii)
Eqn. (ii) and (iii) are the desired result.
Alternative: From 1 st equation of motion we have :
`v = 0 + alpha t_(1) " and " 0 = v - beta t_(2)`
Which in the light of Eqn. (i) gives
`v = alpha beta t//(alpha + beta)`....(iv) and from II equation of motion we have
`s_(1) = (1)/(2) alpha t_(1)^(2)` and `s_(2) = v t_(2) - (1)/(2) beta t_(2)^(2)` i.e., `s = s_(1) + s_(2) = (1)/(2) alpha t_(1)^(2) + v t_(2) - (1)/(2) beta t_(2)^(2)`
`= (1)/(2) alpha (v^(2))/(alpha^(2)) + v (v)/(beta) - (1)/(2) beta (v^(2))/(beta^(2))`
or `s = (1)/(2) v^(2) [(1)/(alpha) + (1)/(beta)]`
`= (1)/(2) (alpha^(2) beta^(2) t^(2))/((alpha + beta)^(2)) xx [(alpha + beta)/(alpha beta)] = (1)/(2) (alpha beta t^(2))/((alpha + beta))`.....(v)
