Storage 'Hypercube' - 3D Volatile Storage

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Hypercube well emerge as the device format for all high-end Information Technology (IT) storage. Hypercube is a permanent magnetic block of metal carbide which is data-encoded by three, orthogonal electromagnetic plates. If the metal is very slowly warm-formed to produce one crystal block of the metal carbide alloy, it will be swift or very volatile in its recording capacity. Information recorded will be stored indefinitely. Magnetic cells will be at the scale of the fundamental units of a monomorphic lattice. The magnetic field strength would be best when the carbon is at a concentration where its behaviour is at the mid spectral position of a metallic analogue.

To completely understand the substrate manufacture, see the Crystal, Warm-Forming for Coherent, Molten Substrate Solidification post.

Warm-forming blocks of metal-carbide, particularly the most thermoelectric, conductive of the affordable metals on the market is the key to manufacturing Hypercube once they are amalgamated with carbon powder, in molten form. That will form one solid and extremely, magnetic flux-change efficient cube. The necessary magnetic cells for differentiation of storage zones are in the geometric, self-similar lattice structure of the alloy.

On any given side of the Hypercube, with a magnetic encoder, the encoder will include a well insulated and high gain solenoid module. To balance the power of each solenoid to be precisely similar, the coils will be slow cast or slowly warm-formed into cylindrically spiralled rods, from the very similar, refined, 3D printed clay moulds. That guarantees near parity of performance.

The three magnetic fields of the solenoids operating, simultaneously, will cumulatively magnetise the metal block, one point dimension (one cell) at a time. Storage will well exceed petabyte capacity for 10 ^-3 m ^ 3, with extraordinary simplicity of physical configuration. Voltage applied to each solenoid will be controlled by a connected computer.

The most ideal storage format is to work with numbers or harmonics in coordinate format. That would be n[a], n[a +1], n[a + 2]. One full array is allocated for each side, field-orientation of the cube from the side-facing solenoid emitters. Each array value will be directly proportional to the electromagnetic flux strength of each solenoid. The array will be similar to the RGB colour array in Windows or operating system.

For results without causing deletion of existing data:

1. Do not use any core material - ambient air only. That will allow agility of solenoid function.

   
   

2. For powerful and agile solenoids the three electromagnetic devices must be have their coordinates preset in the computer array then simultaneously charge the solenoids to emit to the next location in one focused burst, similar to a classic camera flash bulb.

   
   

3. Recording or changing must begin at the vertex diametrically farthest from the most magnetically arrayed vertex. This would form the smallest possible cube of magnetic charge - growing sequentially to the size of the entire cubic mass, while always cub shaped. By the juncture of reaching the nearest and final vertex nearest the array cluster, the cubic field would be charged at lowest combined power.

   
   

4. Reset is to turn all solenoids to full electromagnetic flux strength for at least five seconds of alternating power and alternating magnetic field, at high harmonic or low wavelength (synonymous with UHF), for that full power setting. That is similar to causing vibration in the cube, without trauma. A proficient tester may hold the reset power for significantly less time.

   
   

5. Field collapse will reverse the recently applied, high magnetic charge in the hypercube.

   
   

6. Goto 2.

Gone are the days of tapes and magnetic discs, once the Hypercube is placed on the commercial market. It will be the next format of the Secure Area Network (SAN).

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