Solution: Oscillation of a Suspended Rope
Equilibrium length in air is \( l_0 \). Mass \( M_0 = \lambda l_0 \). The spring force balances this weight: \( k \Delta_{eq} = \lambda l_0 g \).
Let the rope be pulled down by a small distance \( x \).
- Spring Force: The spring is stretched further. Upward force increases by \( kx \).
- Weight: Since the rope moves down, a length \( x \) settles onto the heap on the floor. The suspended length decreases by \( x \). The suspended weight decreases by \( \lambda x g \).
Let downward forces be positive. $$ F_{net} = W_{new} – F_{spring\_new} $$ $$ F_{net} = (\lambda l_0 g – \lambda x g) – (k \Delta_{eq} + k x) $$ Using the equilibrium condition \( \lambda l_0 g = k \Delta_{eq} \): $$ F_{net} = -\lambda g x – k x = – (k + \lambda g) x $$
Notice that both the spring stiffness and the loss of weight contribute to the restoring force, so they add up.
The effective spring constant is \( K_{eff} = k + \lambda g \). The oscillating mass is approximately \( M \approx \lambda l_0 \).