Answer:
the equation of motion is
[tex]x(t) =-\frac{1}{6} \cos4\sqrt{6} t[/tex]
Explanation:
Given that,
The weight attached to the spring is 24pounds
Acceleration due to gravity is 32ft/s²
Assume x is the string length, 4inches
convert the length inches to to feet = 4/12 = 1/3feet
From Hookes law , we calculate the spring constant k
k = W / x
k = 24 / (1/3)
k = 24 / 0.33
k = 72lb/ft
If the mass is displace from its equilibrium position by amount x
the differential equation is
[tex]m\frac{d^2x}{dt^2} + kx=0\\\\\frac{3}{4 } \frac{d^2x}{dt^2}+72x=0\\[/tex]
[tex]\frac{d^2x}{dt^2} +96x=0[/tex]
Auxiliary equation is
[tex]m^2+96=0\\m=\sqrt{-96} \\m=\_ ^+4\sqrt{6}[/tex]
Thus the solution is,
[tex]x(t) = c_1cos4\sqrt{6t} +c_2sin\sqrt{6t}[/tex]
[tex]x'(t) =-4\sqrt{6c_1} sin4\sqrt{6t} +c_24\sqrt{6} cos4\sqrt{6t}[/tex]
The mass is release from rest
x'(0) = 0
[tex]-4\sqrt{6c_1 } \sin4\sqrt{6} (0)+c_24\sqrt{6} \cos4\sqrt{6} (0)=0\\c_24\sqrt{6} =0\\\\c_2=0[/tex]
Therefore
x(t) = c₁ cos4 √6t
x(0) = -2inches
c₁ cos4 √6(0) = 2/12feet
c₁= 1/6feet
There fore, the equation of motion is
[tex]x(t) =-\frac{1}{6} \cos4\sqrt{6} t[/tex]
