Oscillator-shuttle-circuit (OSC) networks for conditioning energy in higher-order symmetry algebraic topological forms and RF phase conjugation

The present invention provides passive networks which act as the host to nonlinear and parametric interactions, with energy inputs to said networks being caused to "bleed off" auxiliary, and time-delayed conditioning flows resulting in phase modulations to the main input and which achieve, e.g., RF phase conjugation with cancellation of the noise modulation after two-way passage of beams between transmitter and receiver and when used in duplex arrangements. Also, passive networks for noise reduction in communications transmission due to conditioning of electromagnetic fields in higher order group symmetry form. Because a transmitted wave from a network of the present invention is in higher-order group symmetry form, and fields of such higher-order symmetry have a low probability of occurrence naturally, then environmental noise, which is of lower group symmetry form (usually, U(1) symmetry) and has a high probably of natural occurrence, will be excluded from a receiver matched to higher-order symmetry waves. Therefore in the case of communications, less noise will be processed statistically at a receiver designed for SU(2) or higher group symmetry operation, resulting in enhanced signal-to-noise. Also disclosed are passive networks for power transmission resulting in decreased loss in transmission. Higher-order group symmetry matched "receivers" will have enhanced signal-to-noise reception over lower-order symmetry receivers, i.e., leakage to ground will be less.