Answer:
a)[tex] 7.1\frac{m}{s^{2}} [/tex]
b) Yes
Explanation:
a) For an object with constant acceleration we should use the Galileo kinematic equation:
[tex] v^{2}=v_{0}^{2}+2a\varDelta x [/tex] (1)
with v the final velocity vo the initial velocity, a the acceleration and [tex]\varDelta x [/tex] the displacement to change velocity from vo to v at constant acceleration. Solving (1) for a:
[tex]a=\frac{v^{2}-v_{0}^{2}}{2\varDelta x}=\frac{400^{2}-300^{2}}{2(4900)} [/tex]
[tex]a=7.1\frac{m}{s^{2}} [/tex]
That acceleration is lower than acceleration of gravity g= 9.8[tex]\frac{m}{s^{2}} [/tex] and a jet plan is made to support accelerations higher than g and a profesional pilot trained to support it, so 7.1\frac{m}{s^{2}} is a reasonable acceleration for a jet plane.
Answer:
a. 7.14 m/s2
b reasonable
Explanation:
We can use the following equation of motion to find out the distance traveled by the jet:
[tex]v^2 - v_0^2 = 2a\Delta s[/tex]
where v = 400 m/s is the final velocity of the jet, [tex]v_0[/tex] = 300m/s is the initial velocity of the jet, a = acceleration of the jet, which we are looking for, and [tex]\Delta s[/tex] = 4.9km = 4900 m is the distance traveled:
[tex]400^2 - 300^2 = 2a4900[/tex]
[tex]160000 - 90000 = 9800a[/tex]
[tex]9800a = 70000[/tex]
[tex]a = 70000 / 9800 = 7.14 m/s^2[/tex]
b. This answer is reasonable, as the jet rate increases from 300m/s to 400m/s within 4900 m distance. So it requires a fast rate of 7.14 m/s2
