Two cubes with masses m(1) and m(2) were...

Two cubes with masses `m_(1)` and `m_(2)` were interconnected by a weightless spring of stiffness `x` and placed on a smooth horizontal surface. Then the cubes were drawn closer to each other and released simultaneously. Find the natural oscillation frequency of the system.

Text Solution

Verified by Experts

In the `C.M. ` frame `(` which is rigidly attached with the centre of mass of the two cubres `)` the cubes oscillates. We know that the kinetic energy of two body system equals `(1)/(2) mu v_(rel)^(2)`, where `mu` is the reduced mass and `v_(rel)` is the modulus of velocity of any one body particle relative to other . From the conservation of mechanical energy of the oscialltion `:`
`(1)/(2) kx^(2)+ (1)/(2) mu{ (d)/(dt)(l_(0)+x)}^(2)=` constant
Here `l_(0)` is the natural length of the spring.
Differenting the above equation w.r.t. time, we get `:`
`(1)/(2) k 2 x dot(x)+(1)/(2) mu2 dot (x) ddot (x)=0[` becomes`(d(l_(0)+x))/(dt)=dot(x)]`
Thus `ddot(x)=-(k)/(mu)x(`where` mu=(m_(1)m_(2))/(m_(1)+m_(2)))`
Hence the natural frequency of oscillation `: omega_(0)=sqrt((k)/(mu))`where` mu=(m_(1)m_(2))/(m_(1)+m_(2))`

Topper's Solved these Questions

OSCILLATIONS AND WAVES
IE IRODOV, LA SENA & SS KROTOV|Exercise Electric Oscillations|56 Videos
OSCILLATIONS AND WAVES
IE IRODOV, LA SENA & SS KROTOV|Exercise Elastic Waves|39 Videos
OPTICS
IE IRODOV, LA SENA & SS KROTOV|Exercise Exercise|2 Videos
PHYSICAL FUNDAMENTALS OF MECHANICS
IE IRODOV, LA SENA & SS KROTOV|Exercise Relativistic Mechanics|49 Videos

Similar Questions

Explore conceptually related problems

Two cubes of mass m_(1) and m_(2) are interconnected by a weightless spring of stiffness k and placed on a smooth horizontal table. Then the cubes are drawn closer to each other and released. Find the frequency of oscillation.

Two blocks of masses m_(1) and m_(2) being connected with a light spring of stiffness k are driven with forces F_(1) and F_(2) on a smooth horizontal plane.

Two blocks of masses m_(1) and m_(2) are connected by a massless spring and placed on smooth surface. The spring initially stretched and released. Then :

Two bars of masses m_1 and m_2 connected by a weightless spring of stiffness ϰ (figure) rest on a smooth horizontal plane. Bar 2 is shifted a small distance x to the left and then released. Find the velocity of the centre of inertia of the system after bar 1 breaks off the wall.

Two bars of masses m_1 and m_2 connected by a weightless spring of stiffness k , rest on a smooth horizontal plane. Bar 2 is shifted by a small distance x_0 to the left and released. The veloicyt of the centre of mass of the system when bar 1 breaks off the wall is

Two blocks A and B of masses m and 2m respectively are connected together by a light spring of stiffness k and then placed on a smooth horizontal surface. The blocks are pushed towards each other such that spring gets compressed by a length x_(0) and then released from rest. Find the work done on the block A by the spring, by the time the spring acquires its natural length.

Two blocks A and B of mass m and 2m respectively are connected by a light spring of force constant k. They are placed on a smooth horizontal surface. Spring is stretched by a length x and then released. Find the relative velocity of the blocks when the spring comes to its natural length

Two blocks of masses m_(1) and m_(2) interconnect with a spring of stiffness K , are kept on as smooth horizontal surface. Find out the ratio of velocity, displacement, kinetic energy and acceleration block with mass m_(1) of block with mass m_(2) .

IE IRODOV, LA SENA & SS KROTOV-OSCILLATIONS AND WAVES-Electromagnetic Waves, Radiation

Two cubes with masses m(1) and m(2) were interconnected by a weightles...
Text Solution
|
An electromagnetic wave of frequency v=3.0 MHz passes from vacuum into...
Text Solution
|
A plane electromagnetic wave falls at right angles to the surface of a...
Text Solution
|
A plane electromagnetic wave of frequency v=10 MHz propagates in a poo...
Text Solution
|
A plane electromagentic wave E=E(m) cos ( omegat - kr) propagates in ...
Text Solution
|
A plane electromagentic wave E=E(m)cos ( omegat-kr) where E(m) E(m) e(...
Text Solution
|
A plane electromagnetic wave E=E(m) cos ( omega t-kx) propagating in v...
Text Solution
|
Proceeding from Maxwell's equation shown that in the case of a plane e...
Text Solution
|
Find the mean Plynting vector ( : S: ) of a plane electromagnetice wa...
Text Solution
|
A plane harmonic electromagnetic wave with plane polarization propagat...
Text Solution
|
A ball of radius R=50 cm is located in a non- magnetic medium with per...
Text Solution
|
A standing electromagnetic wave with electric component E=E(m) cos kx....
Text Solution
|
A standing electromagnetic wave E=E(m) cos kx. Cosomegat is sustained ...
Text Solution
|
A parallel - plate air capacitor whose electrodes are shaped as dis...
Text Solution
|
An alternating sinusoidal current of frequency omega=1000s^(-1) flows ...
Text Solution
|
A parellel-plate capacity whose electrodes are shaped as round disc is...
Text Solution
|
A current I flows along a straight conductor with round cross-section....
Text Solution
|
Non-relativistic protons accelerated by a potential difference U from ...
Text Solution
|
A current flowing in the winding of a long straight solenoid is increa...
Text Solution
|
Fig. illustrates a segment of a double line carrying direct current wh...
Text Solution
|
The enegry is transferred form a source of constant voltage V to a con...
Text Solution
|