Deriving the moment of inertia of a thin hoop

Learning about linear motion

Understanding the concept of rotational inertia

Calculating the mass of a solid cylinder

The cylinder has a constant temperature

The cylinder has a uniform volumetric mass density

The cylinder has a uniform surface texture

The cylinder has a uniform color

To reduce the complexity of the problem

To make the cylinder lighter

To ensure every part of DM is the same distance from the axis

To simplify the calculation of volume

2π times capital R times Dr

π times capital R-squared times Dr

2π times lowercase R times capital L times Dr

π times lowercase R-squared times capital L

Volumetric mass density

Lowercase R

Capital L

2π

From lowercase R to capital R

From 0 to capital R

From 0 to capital L

From lowercase R to capital L

2 times the mass of the cylinder times the radius squared

1/4 the mass of the cylinder times the radius squared

π times the mass of the cylinder times the radius squared

1/2 the mass of the cylinder times the radius squared

Mass

Radius

Length

Density

Density and radius of the cylinder

Mass and length of the cylinder

Length and density of the cylinder

Mass and radius of the cylinder

It is the axis perpendicular to the cylinder's length

It is the axis parallel to the cylinder's radius

It is the axis about which the cylinder rotates

It is the axis along which the cylinder is cut