In their simplified model they are considering the "arm and hand" rod to be a single rod passing through the axis of rotation. The rotation axis is definitely not at the shoulder! It passes vertically though the center of the body.Asad Raza said:
Moments of inertia sum algebraically, so no, if the rod is continuous.
It's the same thing. Each arm (measured from the spine) is length L/2, mass m/2. Applying the 1/3 formula for a rod about its end point that gives 1/3(m/2)(L/2)2 = mL2/24 for each arm, and a total of mL2/12.Asad Raza said:
Moment of inertia is a physical property of an object that describes its resistance to rotational motion. It is a measure of how an object's mass is distributed around its rotational axis.
Moment of inertia is calculated by multiplying the mass of an object by the square of its distance from the rotational axis. This is also known as the moment of inertia equation: I = mr², where I is moment of inertia, m is mass, and r is the distance from the axis of rotation.
The units of moment of inertia depend on the units used for mass and distance. In the SI system, the units are kg·m². In the imperial system, the units are slug·ft².
Moment of inertia is important in understanding the behavior of objects in rotational motion. It affects how quickly or slowly an object will rotate, and how much force is needed to change its rotational motion.
Moment of inertia and mass are two different properties of an object. Mass is a measure of the amount of matter in an object, while moment of inertia is a measure of how that mass is distributed around its rotational axis. In other words, an object with the same mass can have different moments of inertia depending on its shape and distribution of mass.
