Respuesta :
Answer:
Approximately [tex]1.44\times 10^3 \; \rm N \cdot m^{-1}[/tex] assuming that the spring has zero mass.
Explanation:
Without any external force, a piece of mass connected to an ideal spring (like the chair in this question) will undergo simple harmonic oscillation.
On the other hand, the force constant of a spring (i.e., its stiffness) can be found using Hooke's Law. If the spring exerts a restoring force [tex]\mathbf{F}[/tex] when its displacement is [tex]\mathbf{x}[/tex], then its force constant would be:
[tex]\displaystyle k = -\frac{\mathbf{F}}{\mathbf{x}}[/tex].
The goal here is to find the expressions for [tex]F[/tex] and for [tex]x[/tex]. By Hooke's Law, the spring constant would be ratio of these two expressions.
Let [tex]T[/tex] represent the time period of this oscillation. With the chair alone, the period of oscillation is [tex]T = 1.00\; \rm s[/tex].
For a simple harmonic oscillation, the angular frequency [tex]\omega[/tex] can be found from the period:
[tex]\displaystyle \omega = \frac{2\pi}{T}[/tex].
Let [tex]A[/tex] stands for the amplitude of this oscillation. In a simple harmonic oscillation, both [tex]\mathbf{F}[/tex] and [tex]\mathbf{x}[/tex] are proportional to [tex]A[/tex]. Keep in mind that the spring constant [tex]k[/tex] is simply the opposite of the ratio between [tex]\mathbf{F}[/tex] and [tex]\mathbf{x}[/tex]. Therefore, the exact value of [tex]A[/tex] shouldn't really affect the value of the spring constant.
In a simple harmonic motion (one that starts with maximum displacement and zero velocity,) the displacement (from equilibrium position) at time [tex]t[/tex] would be:
[tex]\displaystyle \mathbf{x}(t) = A \cos(\omega \cdot t)[/tex].
The restoring velocity at time [tex]t[/tex] would be:
[tex]\displaystyle \mathbf{v}(t) = \mathbf{x}^\prime(t) = -A\, \omega \sin(\omega\cdot t)[/tex].
The restoring acceleration at time [tex]t[/tex] would be:
[tex]\displaystyle \mathbf{a}(t) = \mathbf{v}^\prime(t) = -A\, \omega^2 \cos(\omega\cdot t)[/tex].
Assume that the spring has zero mass. By Newton's Second Law of motion, the restoring force at time [tex]t[/tex] would be:
[tex]\begin{aligned}& \mathbf{F}(t) \\ &= m(\text{chair}) \cdot \mathbf{a}(t) \\&= -m(\text{chair}) \, A\, \omega^2 \cos(\omega \cdot t)\end{aligned}[/tex].
Apply Hooke's Law to find the spring constant, [tex]k[/tex]:
[tex]\begin{aligned} k & = -\frac{\mathbf{F}}{\mathbf{x}} \\ &= -\left(\frac{-m(\text{chair}) \, A\, \omega^2 \cos(\omega \cdot t)}{A\cos(\omega \cdot t)}\right) \\ &= \omega^2 \cdot m(\text{chair}) \end{aligned}[/tex].
Again, [tex]\omega[/tex] stands for the angular frequency of this oscillation, where
[tex]\displaystyle \omega = \frac{2\pi}{T}[/tex].
Before proceeding, note how [tex]A[/tex] was eliminated from the ratio (as expected.) Additionally, [tex]t[/tex] is also eliminated from the ratio. In other words, the spring constant is "constant" at all time. That agrees with the assumption that this spring is indeed ideal. Back to [tex]k[/tex]:
[tex]\begin{aligned} k & = -\frac{\mathbf{F}}{\mathbf{x}} \\ &= \cdots \\ &= \omega^2 \cdot m(\text{chair}) \\ &= \left(\frac{2\pi}{T}\right)^2 \cdot m(\text{chair}) \\ &= \left(\frac{2\pi}{1.00\; \rm s}\right)^2 \times 36.4\; \rm kg\end{aligned}[/tex].
Side note on the unit of [tex]k[/tex]:
[tex]\begin{aligned} & 1\; \rm kg \cdot s^{-2} \\ &= 1\rm \; \left(kg \cdot m \cdot s^{-2}\right) \cdot m^{-1} \\ &= 1\; \rm N \cdot m^{-1}\end{aligned}[/tex].
