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| {{menuNSROS}} | | {{headerNSROS}} |
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| __TOC__ | | __TOC__ |
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| == {{lime24|The system}} ==
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| === Engineered in accord with [[Quantum Emergence.Cover|alternate physics of deterministic-quantum coherence]] ===
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| === The Hexatronic Logic Ring Configuration —a differential logic ring oscillator ===
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| Three latching SR flip-flops, a logic-circuit connection scheme using two inverting gates (2-input each) is one of three inverting sections of a ring of inverting sections.
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| The 74HC00 2-input NAND gate will perfectly exemplify the dual ended ring, where flip-flops are connected outputs to inputs as a ring of three flip flops.
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| [[File:SR Flip-flop Diagram 1280px.svg.png|300px|left|The differential-signal of the NSRO are the Q and Q~ (Q-not) outputs of a common logic circuit flip-flop. |thumb]]
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| [[File:Hexatronic configuration and layout--TTL Prototype.2024.01.30.png|none|600px|The Q and Q~ outputs are connected to the Set and Reset inputs of the simple logic-connection of a 2-input, inverting output NAND gate (active low) as a latching 'flip-flop'.|thumb|right]]
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| == Design points ==
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| The 74HC00 logic chip is a CMOS work-alike, with improvements. The 74HC00 will entertain a wide supply voltage range, and when implemented as a ring oscillator, the supply voltage level will determine the ring oscillation frequency (the average center of time-randomized oscillations from inherent amplified ring noise).
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| Noise is a design requirement, and is inherent in a ring as the triggering of the cycle at the gate is clocked by the ring signal, and all errors of the system within the system environment are accumulated within the ring's amplified level of the recurrent noise.
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| The ring averages noise that is <big>'''aperiodic'''</big> with the ring's natural center-frequency.
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| The ring amplifies <big>'''periodic'''</big> timings within the ring that are harmonic with the ring's natural center-frequency. Peaks are found at heterodyne separation of sub-harmonics.
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| == Design goal of the self-oscillation of a 3-phase ordered-knot power version ==
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| In future versions, the humble signal-level logic chips will be duplicated in discrete components —super-sized to around one kilowatt, as a maximum condition, matching the continuous power rating of common microwave oven transformers ([[MOT]]s) which may number into six-quantity, for a top-end system of six kilowatts, with an MOT per power switch of the hexatronic contiguration.
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| Future NAND gate outputs will be surface-mount enhanced gallium nitride die-mount transistor (EPC2022 e.g.). This power version mounts the liquid-cooled ganged-eGaN switches on the resonant elements at the six bifurcation nodes.
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| This creates a voltage controlled oscillator.
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| The oscillator switch is on/off, rather than positive/negative. When off, the phase element returns to a lower voltage level, termed <big>'''V</big><sub>B0</sub>'''.
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| The phase-rotated voltage pulse, {{vb1}}, creates the traveling surface-wave pattern as a traveling current pulse {{vb1}}, which creates a traveling magnetic density wave. I.e., the copper windings of the knot group are continually electrified with D.C. current, wherein this current level will set the nuclear magnetic precession of the NMR target of the [[Hexatron]]
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| <big>'''Phase rotation —the definition'''</big>
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| Separate elements are activated with a repeating signal.
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| Each element gets the activating signal at a different time, activating the group in sequence at the frequency of any one element. I.e., the signal is phased in time among the electrical 3-group of windings.
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| == Adjusting natural nuclear magnetic self-resonance in the target —tuning a guitar ==
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| The D.C. adjustable operating bias current interacts with the NMR target, which bismuth target has a magnetic handle on the nucleus which affords a natural resonant frequency. This natural nuclear magnetic resonance is adjustable by the {{b0}} flux density. When the external flux density experienced by a bismuth atom is intensified, the natural magnetic-resonant-coupling-frequency of the bismuth atom increases. The analogy is tuning a guitar-string (harmoinic NMR coupling) which increases when the string tension is increased. Increasing {{b0}} flux density increases the center-frequency of the natural bismuth NMR frequency.
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| === Power ===
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| === Telemetry and Control ===
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| === Analysis ===
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| {{footerNSROS}}
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