## Center of MassThe terms "center of mass" and "center of gravity" are used synonymously in a uniform gravity field to represent the unique point in an object or system which can be used to describe the system's response to external forces and torques. The concept of the center of mass is that of an average of the masses factored by their distances from a reference point. In one plane, that is like the balancing of a seesaw about a pivot point with respect to the torques produced.
| Index Torque concepts | ||||

| Go Back |

## Center of Mass for ParticlesThe center of mass is the point at which all the mass can be considered to be "concentrated" for the purpose for the purpose of calculating the "first moment", i.e., mass times distance. For two masses this distance is calculated from For the more general collection of N particles this becomes and when extended to three dimensions: This approach applies to diccrete masses even if they are not point masses if the position x | Index Torque concepts | ||

| Go Back |

## Center of Mass: ContinuousFor a continuous distribution of mass, the expression for the center of mass of a collection of particles : becomes an infinite sum and is expressed in the form of an integral For the case of a uniform rod this becomes This example of a uniform rod previews some common features about the process of finding the center of mass of a continuous body. Continuous mass distributions require calculus methods involving an integral over the mass of the object. Such integrals are typically transformed into spatial integrals by relating the mass to a distance, as with the linear density M/L of the rod. Exploiting symmetry can give much information: e.g., the center of mass will be on any rotational symmetry axis. The use of symmetry would tell you that the center of mass is at the geometric center of the rod without calculation. | Index Torque concepts | ||

| Go Back |