Spring Mass System
What is a Spring Mass System?
A spring-mass system is a type of system that can be used to calculate the period of an object undergoing simple harmonic motion. Additionally, it can be used for a wide range of applications, such as simulating the motion of human tendons with computer graphics and foot skin deformation.
What is the Relationship Between Mass and the Period of a Spring?
Consider a spring with mass m and spring constant k in a closed environment, which demonstrates Simple Harmonic Motion (SHM).
$$T = \frac{2\pi \sqrt{m}}{k}$$
From the above equation, it is evident that the period of oscillation is independent of both gravitational acceleration and amplitude. Additionally, a constant force cannot affect the period of oscillation. Furthermore, the time period is directly proportional to the mass of the body that is attached to the spring. Therefore, when a heavy object is connected to it, it will oscillate more slowly.
Spring Mass System Arrangements
- Spring mass systems can be arranged in two ways: 1. 2.
The parallel combination of springs
Series Combination of Springs
We will discuss them below;
Parallel Combination of Springs
Fig (a), (b), and (c) are parallel combinations of springs.
Displacement on each spring is equal.
But restoring force is different;
\begin{array}{l}F={{F}_{1}}+{{F}_{2}}\end{array}
Since $$F = -kx$$, the above equation can be written as $$F = -kx$$
\begin{array}{l}-{{k}_{p}}x=-{{k}_{1}}x-{{k}_{2}}x\end{array} \Rightarrow
\Rightarrow -x{{k}_{p}} = -x{{k}_{1}} - x{{k}_{2}}
$$\begin{array}{l} \Rightarrow {{k}_{p}} = {{k}_{1}} \cdot {{k}_{2}} \end{array}$$
Check Out:
Important Concepts of Simple Pendulum
Parallel Combination of Time Periods
(\begin{array}{l}T=2\pi \sqrt{\frac{m}{{{k}_{1}}+{{k}_{2}}}}=2\pi \sqrt{\frac{m}{{{k}_{p}}}}=\frac{2\pi }{\omega }\end{array} )
Springs in Series Combination
The force on each string is the same, but the displacement of each string is different.
(\begin{array}{l}x_{1} + x_{2} = x\end{array})
Since $F=-kx$, the above equation can be written as:
(\begin{array}{l}\frac{F}{k_{s}}= \frac{F}{k_{1}}+\frac{F}{k_{2}}\end{array} )
(\begin{array}{l}k_{s} = k_{1}k_{2} \\ \frac{1}{k_{s}}= \frac{1}{k_{1}}+\frac{1}{k_{2}}\end{array})
$$\Rightarrow k_s = \frac{k_1 \cdot k_2}{k_1 + k_2}$$
Time Period in Series Combination
(\begin{array}{l}T=2\pi \sqrt{\frac{m\left( {{k}_{1}}+{{k}_{2}} \right)}{{{k}_{1}}{{k}_{2}}}}\end{array})
Spring Constant
The relationship between force and displacement described by Hooke’s Law
Young’s Modulus of Elasticity, $$Y = \frac{Stress}{Strain} = \frac{\frac{F}{A}}{\frac{\Delta L}{L}}$$
Here,
F = Force needed to extend or compress the spring
A = Area over which the Force is Applied
L = Nominal Length of the Material
ΔL = change in the length
(\frac{Y\Delta L}{L}=\frac{F}{A})
(\begin{array}{l}F=\frac{Y}{L}\left( \Delta L \right)\end{array})
(\begin{array}{l}K=\frac{Y}{A} \div L\end{array})
(\begin{array}{l}K \propto \frac{1}{L}\end{array})
Therefore, the equation can be rewritten as:
‘(\begin{array}{l}F = K\cdot x\end{array})’
The magnitude of spring constant of the new pieces will be 2K.
(\begin{array}{l}K\propto \frac{1}{L}\end{array} )
so, (K = \frac{2K}{L})
Spring Constant: A Video
Understanding the Spring Constant
How to Find the Time Period of a Spring Mass System?
![Spring Mass System]()
Steps:
- Find the mean position of the SHM (where the net force is equal to 0) in a horizontal spring-mass system.
The natural length of the spring is the position of the equilibrium point.
Displace the object by a small distance (x) from its equilibrium position (or) mean position. The restoring force for the displacement x is given as
F = -kx (1)
The acceleration of the body is given as a = $\frac{F}{m}$
Substituting the value of F from equation (1), we get
(\begin{array}{l}a = \frac{kx}{m}\end{array})
The acceleration of the particle can be expressed as
(\begin{array}{l}a=\frac{d^2x}{dt^2}…(2)\end{array} )
Equating (1) and (2)
(\frac{k}{m} = {{\omega }^{2}})
‘\(\omega = \sqrt{\frac{k}{m}}\)’
Substitute the value of ω in the standard time period expression of Simple Harmonic Motion.
(\begin{array}{l}T=2\pi \sqrt{\frac{m}{k}}\end{array})
$$T = 2\sqrt{\frac{Mass}{Force\,constant}}$$
Problems on Spring-Mass Systems
Q.1: The velocity and displacement of a particle executing linear SHM when its acceleration is half the maximum possible is zero.
Given:
This is a Heading
Solution:
This is a Heading
(\overrightarrow{a} = A \omega^2 \cos(\omega t + \phi))
‘\(\overrightarrow{{{a}_{\max }}} = A{{\omega }^{2}}\)’
(\Rightarrow \frac{{{a}_{\max }}}{2}=A{{\omega }^{2}}\sin \left( \frac{\pi }{6} \right))
Phase $\left( \omega t+\phi \right)=\frac{\pi }{6}$
(\begin{array}{l}\Rightarrow v=A\omega \cos \left( \frac{\pi }{6} \right)=A\omega \frac{\sqrt{3}}{2}\end{array})
(\begin{array}{l} \Rightarrow x = A \sin\left(\frac{\pi}{6}\right) = \frac{A}{2} \end{array})
(\begin{array}{l} \Rightarrow \left( v=\frac{A\omega \sqrt{3}}{2},,and,,x=\frac{A}{2} \right) \end{array})
Q.2: What is the frequency of the oscillation of a particle executing linear SHM, given that it has speeds v1 and v2 at distances y1 and y2 from the equilibrium position?
Given:
Welcome to my website!
Solution:
Welcome to my website!
\(\begin{array}{l}v=\omega \sqrt{{{A}^{2}}-{{y}^{2}}} \end{array}\)
(\begin{array}{l} \Rightarrow {{v}^{2}}={{\omega }^{2}}\left( {{y}^{2}}-{{A}^{2}} \right)\end{array})
(\begin{array}{l} \Rightarrow \frac{{{\omega }^{2}}}{{{v}^{2}}}=\left( {{y}^{2}}-{{A}^{2}} \right) \end{array})
(\begin{array}{l} \frac{{{v}^{2}}}{{{\omega }^{2}}}+{{y}^{2}}={{A}^{2}} \\Rightarrow (1) \end{array})
$$A^2 = \frac{v_1^2}{\omega^2} + y_1^2 = \frac{v_2^2}{\omega^2} + y_2^2$$
(\begin{array}{l}\frac{v_{2}^{2}-v_{1}^{2}}{{{\omega }^{2}}}=y_{1}^{2}-y_{2}^{2}\end{array} )
(\begin{array}{l}\Rightarrow \frac{v_{1}^{2}-v_{2}^{2}}{y_{2}^{2}-y_{1}^{2}}={{\omega }^{2}}\end{array} )
‘\(\omega = 2\pi f\)’
$$f = \frac{\omega}{2\pi} = \frac{1}{2\pi}\left[\frac{v_1^2 - v_2^2}{y_2^2 - y_1^2}\right]^{\frac{1}{2}}$$
Q.3: What is the maximum displacement of the particle?
What fraction of the total energy is kinetic when the displacement is one-fourth of the amplitude?
At what displacement is the energy half kinetic and half potential?
Given:
This is a heading
Solution:
This is a heading
$$KE=\frac{1}{2}m{{\omega }^{2}}\left( {{A}^{2}}-{{y}^{2}} \right)$$
‘(\begin{array}{l}PE = \frac{1}{2}m\omega^2y^2\end{array})’
(\begin{array}{l} \Rightarrow E = \frac{1}{2} m \omega^2 A^2 \end{array})
(a) At $$y=\frac{A}{4},$$ KE becomes
(\begin{array}{l}KE=\frac{1}{2}m{{\omega }^{2}}\left( {{A}^{2}}-{{\left( \frac{A}{4} \right)}^{2}} \right)\end{array})
\(\frac{15}{32}m\omega^2A^2\)
100% of E = [(15/16) x 100]%
93% of total energy is Kinetic Energy
KE = PE
(\frac{1}{2}m{{\omega }^{2}}{{y}^{2}} = \frac{1}{2}m{{\omega }^{2}}\left( {{A}^{2}}-{{y}^{2}} \right))
‘(\begin{align*}y &= \frac{A}{\sqrt{2}}\end{align*})’
Q.4: What is the time period of oscillation of the common mass when it is pulled by one of the three springs, each of which has a force constant k and are connected at equal angles with respect to each other?
\(\begin{array}{l}(a)\ 2\pi \sqrt{\frac{K}{M}}\end{array} \)
\(\displaystyle 2\pi \sqrt{\frac{M}{2K}}\)
\(\displaystyle 2\pi \sqrt{\frac{2M}{3K}}\)
\(\displaystyle 2\pi \sqrt{\frac{2M}{K}}\)
Given:
This is a header
Solution:
This is a header
It is pulled by an upper spring, and each making equal angles.
(\cos 60{}^\circ = \frac{x}{\Delta x})
(\begin{array}{l}\Rightarrow x\cos 60{}^\circ = \frac{\sqrt{3}}{2}\Delta ,x\end{array} )
(\begin{array}{l}\frac{x}{2}=\Delta ,x\end{array})
‘\(\begin{array}{l}{{F}_{net}}=Kx+Kx\cos 60{}^\circ\end{array}\)’
(\begin{array}{l}Kx + \frac{Kx}{2} = \frac{3Kx}{2}\end{array} \Rightarrow 2Kx = 3Kx \Rightarrow Kx = 0\end{array})
(\begin{array}{l}{K_{eqn}}x=\frac{2Kx}{3}\end{array})
(\begin{array}{l} \Rightarrow K_{eqn} = \frac{3K}{2} \end{array})
‘(\begin{array}{l}T=2\pi \sqrt{\frac{2M}{3K}}\end{array} )’
Q.5: The equation of motion of the particle with mass 0.2 kg, executing SHM of amplitude 0.2 m and initial phase of oscillation of 60°, when passing through the mean position, is given by: $E = 4 × 10^{-3} J$ and $x(t) = 0.2 \sin(2\pi ft + 60^{\circ})$
(\begin{array}{l}(a)\ 0.1\sin \left( 2t + \frac{\pi}{4} \right) \end{array})
$0.2\sin\left(\frac{1}{2}t + \frac{\pi}{3}\right)$
\(\sin \left( t+\frac{\pi }{3} \right) = 0.2 \cdot c\)
$$\left(d\right)\ 0.1\cos \left(2t+\frac{\pi}{4}\right)$$
Given:
This is a Heading
Solution:
This is a Heading
Equation of motion for the particle is
(\begin{array}{l}y = A \sin\left(\omega t + \phi\right)\end{array})
A = 0.2 m, (\omega = \frac{ME}{A^2} = \frac{4\times {{10}^{-3}}J}{(0.2 m)^2} ), (\phi = 60{}^\circ ), ME = 4 x 10\textsuperscript{-3} J
To energy
$$E = \frac{1}{2}m\omega^2A^2$$
$$4\times {{10}^{-3}}=\frac{1}{2}\left( 0.2 \right){{\omega }^{2}}{{\left( 0.2 \right)}^{2}}$$
$$\omega^2 = \frac{4 \times 10^{-3} \times 2}{(0.2)(0.2)^2} = \frac{8 \times 10^{-3}}{0.008} = 1 , rad , s^{-1}$$
$y = 0.2 \sin(t + \frac{\pi}{3})$
Q.6: What is the period of oscillation of a 0.1 kg block sliding without friction on a 30° incline, which is connected to the top of the incline by a massless spring of force constant 40 Nm-1, when it is pulled slightly from its mean position?
(a) $\pi$ s
$\frac{\pi}{10}$ s
2π/5 s
(d) $\frac{\pi}{2}$ s
Given:
This is a statement
Solution:
This is a statement
(\begin{array}{l}T=2\pi \sqrt{\frac{0.1}{40}}=0.09817477 \end{array})
\(\frac{\pi}{10}s\)
NEET NCERT Solutions (Physics)
- Acceleration Due To Gravity
- Capacitor And Capacitance
- Center Of Mass
- Combination Of Capacitors
- Conduction
- Conservation Of Momentum
- Coulombs Law
- Elasticity
- Electric Charge
- Electric Field Intensity
- Electric Potential Energy
- Electrostatics
- Energy
- Energy Stored In Capacitor
- Equipotential Surface
- Escape And Orbital Velocity
- Gauss Law
- Gravitation
- Gravitational Field Intensity
- Gravitational Potential Energy
- Keplers Laws
- Moment Of Inertia
- Momentum
- Newtons Law Of Cooling
- Radiation
- Simple Harmonic Motion
- Simple Pendulum
- Sound Waves
- Spring Mass System
- Stefan Boltzmann Law
- Superposition Of Waves
- Units And Dimensions
- Wave Motion
- Wave Optics
- Youngs Double Slit Experiment