Movement Path Functions

Movement path functions of objects and the spatial force functions of correlated magnetic structures can be used to precisely define and perform functions (or work).  In other words, the pre-defined movement of two objects can be combined with correlated magnetic structure to produce defined magnetic forces to perform a function (i.e., to do work).  Fig. 1 provides a work example involving a cylinder and a curved object and anti-complementary correlation between their correlated magnetic structures.

Fig. 1 Object Movement Path Functions and Anti-complementary Correlation between their Correlated Magnetic Structures

The cylinder in Fig. 1 has surrounding it a correlated magnetic structure of permanent magnetic sources corresponding to six instances (or code modulos) of a 7x7 code.  It is attached to a shaft that rotates it at a defined rate.  The curved object shown beneath the cylinder has a curvature intended to closely match that of the cylinder and also has a correlated magnetic structure that is anti-complementary coded with the same 7x7 code used to define the correlated magnetic structure surrounding the cylinder.  So, as the cylinder turns, each instance of the 7x7 code of the cylinder correlates with the 7x7 code of the curved object to produce a peak repulsive force that can do work of some kind (e.g., pressing dough into molds).  With, for example, a rotational rate of the cylinder of one rotation per second, the curve object would be repelled six times per second.  Fig. 2 provides a second work example involving two objects and complementary correlation between their correlated magnetic structures.

Fig. 2 Object Movement Path Functions and Complementary Correlation between their Correlated Magnetic Structures

In Fig. 2, a left object having a cutting edge around the outer perimeter of its right side face and is designed to remain in a fixed location while an inner shaft rotates at some rate to turn a correlated magnetic structure mounted in the face of the object.  The right object also has a cutting edge around the outer perimeter of its left side face and is designed not to rotate but to move from right-to-left and vice versa. It also has a correlated magnetic structure that is coded with a code that is complementary to the code used to design the correlated magnetic structure of the left object.   When the correlated magnetic structure mounted in the face of the right object correlates and with the correlated magnetic structure of the left object a peak attractive force is produced causing the object on the right to move to its left such that the two cutting edges cut something passing between them (e.g., cloth).  The right object then moves from left-to-right when the two correlated magnetic structures decorrelate.  As such, as the inner shaft of the left object rotates at N times a second, the two correlated magnetic structures precisely cut N holes per second. 

Generally, all sorts of different object movement path functions and spatial force functions of corresponding correlated magnetic structures can be designed to perform precise, repeatable work.