Electromagnetic, Advanced Shark Barriers

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Shark Net Technology Upgraded

Electrical shark net technology has been attempted before. There has been no clear success story. Please conduct all testing at scale model and scaled, contained zoning only. Sharks all have similar senses, including those in home aquariums. Avoid cruelty at all costs. Begin tests at well research-backed, low power levels, and increase the power only gradually. It may be slow yet it will save marine life beyond the complete cartilaginous fish life which you may be targeting for zone sequestration.

The technology described can be used for protection of beaches, vessels, diving and swimming locations away from the beach, and even for surfboards, or on human bodies, as wearable technology. In marine environment, shark netting the insulated , mast antenna may be placed laterally for an elliptic or almost egg-like field transmission. Please read further for a thorough briefing.

Induction is the phenomenon which allows for long range communication. Magnetic induction is itself generated and carried by electric fields. Vice versa occurs. That is basic electromagnetic induction theory. It assumes constant, concentrated electric or magnetic components of the electromagnetic field. More complex induction will make use of the whole electromagnetic flux spectrum.

To induce nervous stimulus in a shark’s multiple olfactory senses (especially long range) is a form of signal jamming or noise generation. The correct stimulus to use is white noise with significantly larger spikes or power ratio beats, combined. Noise floor, as seen in the physics article witihin this blog, must be included in the design. That assures that no natural wavelengths are ignored by the technology- possibly allowing a natural threat past the protection.

The disruptive signal is best delivered by the spatial field - the electric field. A disturbance or noise is best carried on the magnetic field. Subsequent and total effect is electromagnetic, rather than simply electrical. Electrical fields in ionised, electrically conductive water will dissipate rapidly when in contact with osmotically affected organic material or living organisms.

The truth is conduction is similarly generated to induction. The signal in the nervous field is electric at any given moment. To shift to the electrical signal state of the next given moment, the signal must rotate from being electrical field propagated to magnetically propagated, then back to electrical field in the following electrical moment. The transition is formulated by the relationship,

A = sin ^ 2 ( ω * t ).

It is also simplified further:

A = sin ^ 2 ( 2 * n * Pi rad * (1 Hz) * t )

For best effect use the whole sinusoidal wave. The best equation the program or build into hardware is the noise floor equation to the second power: sin ^ 2 ( ( ω [i] * t ). The entire wave set is then strengthened as a field by product amplification, only as necessary. The entire amplification must always exceed 1, for animal safety. Quantum signalling must never be attempted. It will distribute through all living organisms which share the wavelengths of the noise, including land-dwelling and and air-dwelling organisms.

The obvious result would be to use one electrically insulated mast antenna to transmit the noise. It will create a circular perimeter. Experiment with down-scaled modelling to begin with. In scale model testing only, use berley to increase the shark attraction to the target location in the shortest timescale.

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