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Question: A particle starts from rest and its angular displacement (in radians) is given by \(\theta =\dfrac{{...

A particle starts from rest and its angular displacement (in radians) is given by θ=t220+t5\theta =\dfrac{{{t}^{2}}}{20}+\dfrac{t}{5}. If the angular velocity at the end of t=4st=4s is k'k'. Then, what will be the value of 5k'5k' ?

Explanation

Solution

Hint: The angular velocity as a function of time can be found out by differentiating angular displacement θ\theta with respect to time.

Before proceeding with the question, we must know that the angular velocity (which is generally denoted by ω\omega ) as a function of time can be found by simply differentiating the angular displacement θ\theta with respect to time. Mathematically, we get,
ω=dθdt............(1)\omega =\dfrac{d\theta }{dt}............\left( 1 \right)
Here, in this formula, θ\theta should be a function of time tt.
In this question, it is given that θ=t220+t5\theta =\dfrac{{{t}^{2}}}{20}+\dfrac{t}{5}. Substituting θ=t220+t5\theta =\dfrac{{{t}^{2}}}{20}+\dfrac{t}{5} in equation (1)\left( 1 \right), we can find angular velocity as a function of time.
ω=d(t220+t5)dt ω=d(t220)dt+d(t5)dt ω=120d(t2)dt+15d(t)dt...............(2) \begin{aligned} & \omega =\dfrac{d\left( \dfrac{{{t}^{2}}}{20}+\dfrac{t}{5} \right)}{dt} \\\ & \Rightarrow \omega =\dfrac{d\left( \dfrac{{{t}^{2}}}{20} \right)}{dt}+\dfrac{d\left( \dfrac{t}{5} \right)}{dt} \\\ & \Rightarrow \omega =\dfrac{1}{20}\dfrac{d\left( {{t}^{2}} \right)}{dt}+\dfrac{1}{5}\dfrac{d\left( t \right)}{dt}...............\left( 2 \right) \\\ \end{aligned}
In differentiation, we have a formula,
d(t2)dt=2t...........(3)\dfrac{d\left( {{t}^{2}} \right)}{dt}=2t...........\left( 3 \right)
Substituting d(t2)dt=2t\dfrac{d\left( {{t}^{2}} \right)}{dt}=2t from equation(3)\left( 3 \right) in equation (2)\left( 2 \right), we get,
ω=120(2t)+15 ω=t10+15...........(4) \begin{aligned} & \omega =\dfrac{1}{20}\left( 2t \right)+\dfrac{1}{5} \\\ & \Rightarrow \omega =\dfrac{t}{10}+\dfrac{1}{5}...........\left( 4 \right) \\\ \end{aligned}
In the question, it is given that the angular velocity ω\omega at t=4st=4s is equal to kk. Substituting t=4st=4sin equation (4)\left( 4 \right), we get,
ω=410+15 ω=25+15 ω=35 \begin{aligned} & \omega =\dfrac{4}{10}+\dfrac{1}{5} \\\ & \Rightarrow \omega =\dfrac{2}{5}+\dfrac{1}{5} \\\ & \Rightarrow \omega =\dfrac{3}{5} \\\ \end{aligned}
This angular velocity which we got in the above equation is equal to kk, so, we can say,
k=35..........(5)k=\dfrac{3}{5}..........\left( 5 \right)
In the question, we are asked to find out the value of 5k5k. So, using equation (5)\left( 5 \right), the value of 5k5k is equal to,
5k=5(35) 5k=3 \begin{aligned} & 5k=5\left( \dfrac{3}{5} \right) \\\ & \Rightarrow 5k=3 \\\ \end{aligned}
Hence, the answer is 33.

Note: There is a possibility that one may commit a mistake while finding the angular velocity ω\omega as a function of time. Sometimes, we integrate the angular displacement θ\theta with respect to time to find the angular velocity instead of differentiating the angular displacement. So one must remember that angular velocity is found by differentiating the angular displacement function with respect to time