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A particle of mass (m) is attached to a spring (of spring constant k) and has a narural angular frequency omega_(0). An external force `R(t)` proportional to cos omegat(omega!=omega)(0) is applied to the oscillator. The time displacement of the oscillator will be proprtional to.

A

`(m)/(omega_(0)^(2) - omega^(2))`

B

`(1)/(m(omega_(0)^(2) - omega^(2)))`

C

`(1)/(m(omega_(0)^(2) + omega^(2)))`

D

`(m)/(omega_(0)^(2) + omega_(2))`

Text Solution

Verified by Experts

The correct Answer is:
B
Natural frequency of oscillator `= omega_(0)`
Frequency of the applied force `= omega`
Net force acting on oscillator at a displacement `x`
`= m(omega_(0^(2)) - omega^(2))x"….."(i)`
From eqs. (i) and (ii) we get
`m(omega_(0^(2)) - omega^(2)) x prop cosomegat"......."(ii)`
Also `x = Acosomegat"....."(vi)`
From eqs. (iii) and (iv), we get
`m(omega_(0^(2)) - omega^(2))Acosomegat prop cosomegat rArr A prop (1)/(m(omega_(0)^(2) -omega^(2)))`
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