(a) Potential energy expression `mgl (1-\cos\theta)`
(b) Expression of torque `mgl\sin\theta`
Solution
In a simple pendulum with no friction,
mechanical energy is conserved. Total mechanical energy is a combination of
kinetic energy and gravitational potential energy. As the pendulum swings back
and forth, there is a constant exchange between kinetic energy and
gravitational potential energy.
(a) For deducing, consider a simple pendulum. Let the bob of mass m be released after being given an angular displacement θ.
Let, Length of the pendulum, OA = OB = `l`.
From the figure we can see, the pendulum has been shifted from point A to B at an angular displacement θ. So, maximum potential energy will be stored in the bob on point B if the velocity reaches zero and kinetic energy is zero at that point.
Though the mass has
been shifted from point A to point B, it has been lifted at a height AC = h
with respect to the datum position A.
We know,
Potential Energy = mass `\times` acceleration due to gravity `\times` height`\therefore E_p=mgh` .......................................... (1)
From figure, `\triangle OCB` is a right angled triangle.
Hence,
`\cos\theta=\frac{OC}{OB}=\frac{OC}l`
`\therefore OC=l\cos\theta` ..................................(2)
Now,
OC = OA – AC
`l\cos\theta=l-h` [From (2)]
`h=l-l\cos\theta`
`h=l(1-\cos\theta)` ................................................(3)
From equation (1) we can write,
`E_p=mgl(1-\cos\theta)`Hence, Potential energy expression `mgl (1-\cos\theta)`
Torque is defined as,
`\vec \tau =\vec r \times \vec F` ........................... (4)
The cross product is defined to satisfy the following property,
`|\vec a\times\vec b|=ab\sin\theta` .....................(5)
Therefore,
`|\vec \tau |= |\vec r \times \vec F|=Fr\sin\theta` ...................... (6)
Where, `\tau` = Torque
F
= Linear force
r = distance measured
from the axis of rotation to where the linear force is applied