• Degrees of freedom—Measure the number of degrees of freedom (DOF) in your mechanism. In most cases, the degrees of freedom does not change during an analysis. An exception is if you are modeling cams with liftoff. In this case, the DOF changes when the cams separate, and you may want to graph the degrees of freedom.

• Redundancies—Measure the number of redundancies your mechanism contains.

• Time—Measure the time at each step of the analysis.

• Kinetic energy—Measure the total kinetic energy for the mechanism. The kinetic energy is a scalar sum of the kinetic energy for each body, relative to the ground body WCS.

• Linear momentum—Measure the total linear momentum of the mechanism. The linear momentum is the sum over all bodies in the mechanism of the global velocity of each body's center of mass multiplied by its mass.

• Angular momentum—Measure the total angular momentum of the mechanism. The angular momentum is the sum over all bodies in the mechanism of the inertial angular momentum for each body. For each body, this is the product of the moment of inertia at the center of mass times the angular velocity of the body. System angular momentum is reported relative to the ground body WCS.

• Total mass—Measure the sum of the masses for all bodies, including the ground body, in your mechanism.

• Center of mass—Measure the distance to the center of mass of the mechanism relative to the ground body WCS.

• Total centroidal inertia—Measure the total centroidal inertia of the mechanism relative to the center of mass of the mechanism. Centroidal inertia is calculated by regarding all bodies, including the ground body, in the mechanism as a single body with the same mass distribution as the mechanism. Inertial properties of this single body are then computed with respect to the mass center of this body, which is the system mass center.