![moment of inertia of a circle derivation moment of inertia of a circle derivation](http://hyperphysics.phy-astr.gsu.edu/hbase/imgmec/sph2.gif)
![moment of inertia of a circle derivation moment of inertia of a circle derivation](http://hyperphysics.phy-astr.gsu.edu/hbase/imgmec/rod6.png)
Thus similarly for the semicircle, the moment of inertia of the x-axis is equal to that of the y-axis. Now we need to pull out the area of a circle which gives us:
![moment of inertia of a circle derivation moment of inertia of a circle derivation](https://thefactfactor.com/wp-content/uploads/2020/03/Expression-02.png)
M.O.I relative to the origin, Jo = Ix + Iy = ¼ πr 4 + ¼ πr 4 = ½ πr 4
#Moment of inertia of a circle derivation full
We know that for a full circle because of complete symmetry and uniform area distribution, the moment of inertia relative to the x-axis is equal to that of the y-axis. Further to determine the moment of inertia of the semi-circle, we will take the sum of both the x and y-axis. The moment of inertia of the semicircle is generally expressed as I = πr 4 / 4.Here in order to find the value of the moment of inertia of a semicircle, we have to first derive the results of the moment of inertia full circle and basically divide it by two to get the required result of that moment of inertia for a semicircle. The moment of inertia of the semicircle is generally expressed as I = πr 4 / 4 Similarly larger the moment of inertia of the body more difficult is to stop its rotational motion. For example, if the body is at rest the larger the moment of inertia of the body the more difficult it is to put the body into the rotational motion. In other words, the moment of inertia is the measurement of resistance of the body to a change in its rotational motion. The moment of inertia plays the same role in rotational motion as the mass does in the translational motion.