A spinning top has an angular retardation of -k-2 in rad-s2- where - is angular velocity of the top and k-1 rad -1- At -0-0 rad- if -0-120 rad-s- then the relation between angular displacement - and angular velocity is

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Radial & Tangential Acceleration for Non Uniform Circular Motion

A spinning to...

Question

A spinning top has an angular retardation of $α = k ω^{2}$ (in ${rad/s}^{2}$ ), where $ω$ is angular velocity of the top and $k = 1 {rad}^{- 1}$ . At $θ_{0} = 0 rad$ , if $ω_{0} = 120 rad/s$ , then the relation between angular displacement ( $θ$ ) and angular velocity is

ω = 120 e^{- θ}

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ω = 120 e^{θ}

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ω = 60 e^{- θ}

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ω = 60 e^{θ}

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Solution

The correct option is A $ω = 120 e^{- θ}$
Initial angular velocity $(ω_{0}) = 120 rad/s$
Angular acceleration, $α = k ω^{2} = ω^{2}$
( $k = 1$ )
To find relation between $ω$ and $θ$ , we use $α = - ω \frac{d ω}{d θ}$ (negative sign due to retardation)
$\Rightarrow - ω \frac{d ω}{d θ} = ω^{2}$
$\Rightarrow - \frac{d ω}{ω} = d θ$
Integrating on both sides
$\int_{ω_{0}}^{ω} \frac{d ω}{ω} = - \int_{θ_{0}}^{θ} d θ$
$\Rightarrow {\begin{matrix} ln ω \end{matrix} |}_{ω_{0}}^{ω} = - (θ - θ_{0})$
$\Rightarrow ln (\frac{ω}{ω_{0}}) = - (θ - θ_{0})$
$\Rightarrow ω = ω_{0} e^{- (θ - θ_{0})}$
$\Rightarrow ω = ω_{0} e^{- θ} = 120 e^{- θ}$
(because $θ_{0} = 0$ )

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A spinning top has an angular retardation of α=kω2 (in rad/s2), where ω is angular velocity of the top and k=1 rad −1. At θ0=0 rad, if ω0=120 rad/s, then the relation between angular displacement (θ) and angular velocity is

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