Answer:
2.84 g's with the remaining 1 g coming from gravity (3.84 g's)
Explanation:
period of oscillation while waiting (T1) = 2.45 s
period of oscillation at liftoff (T2) = 1.25 s
period of a pendulum (T) =2π. [tex]\sqrt{\frac{L}{a} }[/tex]
where
therefore the ration of the periods while on ground and at take off will be
[tex]\frac{T1}{T2}[/tex] =(2π [tex]\sqrt{\frac{L}{a1} }[/tex] ) / (2π[tex]\sqrt{\frac{L}{a2} }[/tex])
where
[tex]\frac{T1}{T2}[/tex] = [tex]\frac{\sqrt{\frac{L}{a1} }}{\sqrt{\frac{L}{a2} }}[/tex]
squaring both sides we have
[tex](\frac{T1}{T2})^{2}[/tex] = [tex]\frac{\frac{L}{a1} }{\frac{L}{a2} }[/tex]
[tex](\frac{T1}{T2})^{2}[/tex] = [tex]\frac{a2}{a1}[/tex]
assuming that the acceleration on ground a1 = 9.8 m/s^{2}
[tex](\frac{T1}{T2})^{2}[/tex] = [tex]\frac{a2}{9.8}[/tex]
a2 = 9.8 x [tex](\frac{T1}{T2})^{2}[/tex]
substituting the values of T1 and T2 into the above we have
a2 = 9.8 x [tex](\frac{2.45}{1.25})^{2}[/tex]
a2 = 9.8 x 3.84
take note that 1 g = 9.8 m/s^{2} therefore the above becomes
a2 = 3.84 g's
Hence assuming the rock is still close to the ground during lift off, the acceleration of the rocket would be 2.84 g's with the remaining 1 g coming from gravity.
