Since inertia is represented numerically by an object's mass.
Unit of inertia in S.I UNIT is Kilogram
The unit of Inertia is kg and the Moment of Inertia is kg*m^2
Is the S.I or metric system the unit of inertia or mass is kilogram.
Moment of inertia has unit kg m2
The word is "unit", not "unot". You can use kilograms (or any other unit of mass) for inertia. The more kilograms an object has, the greater its inertia.
Inertia can be measured by an object's mass. That would make the SI unit the kilogram.
The inertia. This is directly related to the object's mass.
Gravity is related to masses. Inertia is simply another effect of masses. I would say that the mass is the source, both for gravity and for inertia. The basic unit, however, is the mass.Gravity is related to masses. Inertia is simply another effect of masses. I would say that the mass is the source, both for gravity and for inertia. The basic unit, however, is the mass.Gravity is related to masses. Inertia is simply another effect of masses. I would say that the mass is the source, both for gravity and for inertia. The basic unit, however, is the mass.Gravity is related to masses. Inertia is simply another effect of masses. I would say that the mass is the source, both for gravity and for inertia. The basic unit, however, is the mass.
Mass is a measure of a body's inertia in which the SI unit is the kilogram.
inertia?
Polar moment of inertia of an area is a quantity used to predict an object's ability to resist torsion.Moment of inertia, also called mass moment of inertia or the angular mass, (SI units kg m2, Imperial Unit slug ft2) is a measure of an object's resistance to changes in its rotation rate.
The best answer that I could find is that inertia units are the same as mass (kg). Which makes sense, the more mass an object has, the more force it takes to accelerate (get it to move, or move in a different direction). I found this on Physicsforums dot com (it is not letting me post a link at this time)
Comparing linear and circular motion we can see that moment of inertia represents mass and torque represents force. So the product change in the circular momentum per unit time is torque. Circular momentum is the product of moment of inertia and circular velocity.