Respuesta :
Answer:
a) Â K = 0.63 J, b) Â h = 0.153 m
Explanation:
a) In this exercise we have a physical pendulum since the rod is a material object, the angular velocity is
     w² = [tex]\frac{m g d}{I}[/tex]
where d is the distance from the pivot point to the center of mass and I is the moment of inertia.
The rod is a homogeneous body so its center of mass is at the geometric center of the rod.
       d = L / 2
the moment of inertia of the rod is the moment of a rod supported at one end
       I = ⅓ m L²
we substitute
      w = [tex]\sqrt{\frac{mgL}{2} \ \frac{1}{\frac{1}{3} mL^2} }[/tex]
      w = [tex]\sqrt{\frac{3}{2} \ \frac{g}{L} }[/tex]
      w = [tex]\sqrt{ \frac{3}{2} \ \frac{9.8}{0.75} }[/tex]
      w = 4.427 rad / s
an oscillatory system is described by the expression
       θ = θ₀ cos (wt + Φ)
the angular velocity is
       w = dθ /dt
       w = - θ₀ w sin (wt + Ф)
In this exercise, the kinetic energy is requested in the lowest position, in this position the energy is maximum. For this expression to be maximum, the sine function must be equal to ±1
In the exercise it is indicated that at the lowest point the angular velocity is
      w = 4.0 rad / s
the kinetic energy is
      K = ½ I w²
      K = ½ (⅓ m L²) w²
      K = 1/6 m L² w²
      K = 1/6 0.42 0.75² 4.0²
      K = 0.63 J
b) for this part let's use conservation of energy
starting point. Lowest point
       Em₀ = K = ½ I w²
final point. Highest point
       Em_f = U = m g h
energy is conserved
       Em₀ = Em_f
       ½ I w² = m g h
       ½ (⅓ m L²) w² = m g h
       h = 1/6 L² w² / g
       h = 1/6 0.75² 4.0² / 9.8
       h = 0.153 m
