Answer:
[tex]s = 21\ ft\\\\a = -6\ \frac{ft}{s^2}[/tex]
Step-by-step explanation:
To find the changes in the slope of the function s(t) we find its derivative
[tex]\frac{ds(t)}{dt} = 3t^2 - 18t +24\\[/tex]
Now we make [tex]\frac{ds(t)}{dt} = 0[/tex]
[tex]3t^2 - 18t +24 = 0[/tex]
[tex]3t^2 - 18t +24\\\\3(t^2-6t + 8)\\\\3(t-4)(t-2)\\\\t_1 =4\\t_2=2\\[/tex]
The particle changes direction for the first time at t = 2 sec
The position at t = 2 sec is:
[tex]s(t=2) = (2)^3 - 9(2)^2 + 24(2) + 1\\\\\s(2) = 21\ ft[/tex]
The acceleration after t = 2 sec is the second derivative of s(t), evaluated at t = 2:
[tex]\frac{d^2s(t)}{d^2t} = 6t -18\\\\\frac{d^2s(t)}{d^2t}(2) = 6(2) -18\\\\ a = 12-18\\\\a = -6\ \frac{ft}{s^2}[/tex]
Answer:
The position is 21 feet
The acceleration is -6 ft/sec²
Step-by-step explanation:
∵ s(t) = t³ - 9t² + 24t + 1
- where s is the displacement in feet and t is the time in second
∵ v(t) = ds/dt ⇒ velocity is the differentiation of s(t)
∵ a(t) = d²s/dt² = dv/dt ⇒ acceleration is the differentiation of v(t)
∴ v(t) = 3t² - 18t + 24
∵ When the particle reverses means v(t) = 0
∴ 3t² - 18t + 24 = 0 ⇒ ÷ 3
∴ t² - 6t + 8 = 0
∴ (t - 2)(t - 4) = 0
∴ t - 2 = 0 ⇒ t = 2 seconds
∴ t - 4 = 0 ⇒ t = 4 seconds
- That means the particle will change its direction first after 2 seconds
and again after 4 seconds
∵ a(t) = dv/dt
∴ a(t) = 6t - 18
∵ t = 2
∴ a(2) = 6(2) - 18 = 12 - 18 = -6 ft/sec²
∵ s(t) = t³ - 9t² + 24t + 1
∴ s(2) = 2³ - 9(2)² + 24(2) + 1 = 21 feet
