NucleoSonic Ring Oscillator System

The Phased Magnetic Nucleosonic Field Array

The Nucleosonic Ring Oscillating System is a

 ring-configuration of high-power, 2-input, inverting NAND gates —clicking in at under one kilowatt output current rating —and very, very fast.

In as much as the nuclear magnetic moment is actively coupled with the ring oscillator system near field, and becomes a dominant load on the system frequency as the system frequency approaches nuclear magnetic resonance (continuous wave [CW] NMR), the operation of the system in an NMR state is essentially then an NMR-Controlled-Oscillator.

The configuration schematic pictures as three logic flip-flops connected in a ring, with the X-crossover typical of the flip-flop latching signal conductors —with said circuits activating as heavy-current sinks with very fast slew rates of modern power transistors (eGaN, e.g., EPC2022).  

The configuration is a ring of SR logic latches with certain segmentation interconnections of inputs to outputs, forming a differential ring oscillator (at power levels oscillating through short inductors entangled on a donut).

The latch outputs activate power-transistors, which switches are activated sequentially, and the sequential signal is the activating signal traveling the ring... a ring of inductors sequentially activating the next segment to invert it's output.  The ring signal propagation is akin to dominoes falling.

As the timing signal 'falls' around the ring, the up or down position of the 'fall' is not the operation of significance.  The 'fall' is a switching moment that passes the voltage pattern of the oscillator section to the next section.  This pattern is algorithmically created in logic circuitry, and appears first in the pattern-input-gate.  As the pattern is serially inserted into one ring-amp section, the pattern of on/off is shifted around the ring when each section completes its ring activation, in the X-Configuration. 
The delay in switching the pattern, waiting for each inductive knot winding copper segment, is the very small delay, but a real physical delay which sets the ring oscillation frequency, as the reciprocal of the total of all the delays incurred per one oscillating cycle.

This ring oscillator scheme is named a Resonant-X ring configuration.  The ring's resonant frequency is self-tuned by the inductive parameters of the fast-switching square wave, as the sum-total of all inductive related physical delays, plus the propagation delays, and circuitry delays of each resonant element combined.

The NucleoSonic Ring Oscillator System

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