Answer:
Step-by-step explanation:
In this system we have the force of the spring and the gravitational force. The equation that describes that is
[tex]F_{s}+F{g}=ma\\k(y_0+y)-mg=ma[/tex]
where y0 is the equilibrium position when the string is free and y0+y is the new equilibrium position when the object is hanged of the string. By replacing by derivatives we have
[tex]ky_0+ky-mg=ma\\mg+ky-mg=ky=ma\\\\ky=m\frac{d^2y}{dt^2}\\\\my''+ky=0[/tex]
the solution for this differential equation is (by using the characterisic polynomial)
[tex]y(x)=Acos(kt)+Bsin(kt)\\k=\omega^2m[/tex]
hope this helps!!
Answer:
A) d²x/dt² = -326.67x
At time t = 0,the spring is stretched to 5cm and and released.
Thus, the initial velocity is zero. Thus, the initial condition is;
x(0) = -5 and x'(0) = 0
B) The solution to the equation is;
x(t) = -5cos 18.07t
Step-by-step explanation:
A) Due to stretching, the force due to gravity and that due to stretching of spring will be the same. Thus;
mg = -kx
m = 4kg ; x = -3cm and g=980 cm/s²
Thus,
k = mg/x = 4x980/3 = 1306.67
The motion of mass attached to a spring is given as;
d²x/dt² = -ω²x
Where, ω² = k/m = 1306.67/4 = 326.67
Thus, the differential equation for the problem would be;
d²x/dt² = -326.67x
At time t = 0,the spring is stretched to 5cm and and released.
Thus, the initial velocity is zero. Thus, the initial condition is;
x(0) = -5 and x'(0) = 0
B) The general solution would be given by;
x(t) = C1cos ωt + C2sinωt
From earlier, ω² = 326.67
So, ω = √326.67 = 18.07
Thus,
x(t) = C1cos 18.07t + C2sin 18.07t
Now, applying initial conditions ;
At x(0) = -5;
-5 = C1cos 0 + C2sin 0
C1 = -5
x'(t) = -18.07C1Sin18.07t + 18.07C2Cos18.08t
Thus, at x'(0) = 0
0 = -18.07C1Sin 0 + 18.07C2Cos0
18.07C2 = 0
So,C2 = 0
Thus,the solution to the equation is;
x(t) = -5cos 18.07t
