Non-entanglement physical shared ad-hoc randomness (NEPSAR)

What is claimed is: 1. A system used by k mutually remote parties to share a random bit string by using each a duplicate of a non-entanglement, physical, shared Ad-Hoc randomness (NEPSAR) apparatus; the parties conduct a round of operation wherein; each NEPSAR duplicate is comprising: (a) a conductive fluid, (b) a fluid container, serving as a measurement chamber, (c) two electrodes, (d) a power source, (e) an electric current meter, (f) an electronic circuitry, (g) a pump, (h) air pathways; the conductive fluid (a) is placed in the fluid container (b), which is fitted with the two electrodes (c), which are connected to the power source (d) that generates electrical current that flows through the conductive fluid (a) and is also connected to the electric current meter (e) and to the electronic circuitry (f) that transforms the fluctuating electrical current (e) to a corresponding bit string; the pump (g) blows air through the air pathways (h) into the conductive fluid (a) generating air bubbles of a pattern determined by settings adjusted over the pump (g) and the air pathways (h); wherein each NEPSAR duplicate is activated through openly shared activation settings, operating in the following sequence: (i) each NEPSAR duplicate activates the electrically powered pump (g), that blows air bubbles into the fluid container (b), where the conductive fluid (a) is set to conduct electrical current: the bubbles change in size, and flow rate according to the activation settings, and since the air bubbles are insulators, the electrical current (e) that flows through the conductive fluid (a) when the bubbles rise through it, is changing in magnitude according to the flow pattern of the air bubbles, and to the extent that the bubbles are in a chaotic pattern, so does the electrical current in the conductive fluid (a) appear in random fluctuations; the fluctuating current is measured by the electric current meter (e), these measurements are expressed as a bit series (R*) where the bits appear randomized, R* is a ‘raw randomness bit series’; the k NEPSAR duplicate apparatuses thereby generate in the privacy of each party the raw bit series (R* 1 , R* 2 , . . . R* k ); (ii) the parties then randomly designate t test bits from the n bits of each series, n=|R* i | for i=1, 2, . . . k and mutually expose the values of the test bits; (iii) if all k parties agree on all the values of the t test bits then they conclude that with a probability, Pr, where Pr→1 for t→n, the untested (n−t) bits are equal in value for all k parties, thereby defining a trusted shared bit series: R 1 , R 2 , . . . R k where |R i |=(n−t); (iv) and if any test bits as mutually disclosed by any party are different than the value claimed by other parties, then, this round of operation is regarded as failure, and the sequence (i, ii, iii, iv) restarts again using different activation settings. 2. The apparatus in claim 1 where the apparatus generates a randomized mix of two fluids, L, and H, where (i) fluid H has a greater specific gravity than fluid L, and where (ii) L and H are not mutually soluble, and where (iii) L and H have a different electrical conductivity; and where the measurement chamber (b) contains fluid H before the round of operation and after the round of operation; and where the round of operation is carried out by creating a randomized flow of fluid L into the chamber, so that the measurement of the effective electrical resistance within the measurement chamber is recorded as a resistance-curve-over-time which reflects the randomness of the flow of fluid L, into the chamber; this curve is then digitized to extract the raw randomness, which subsequently is converted to the trusted shared bit series. 3. The apparatus of claim 2 where the flow of fluid L into the measurement chamber is being carried out by applying either buoyancy, or positive pumping pressure on L towards a stack of center-axis sharing discs, abreast one next to the other, where the discs are drilled with randomized holes, and where during the round of operation the discs are rotated in a randomized fashion as to direction and as to angular speed, thereby creating circumstances where holes in the discs are aligned to allow fluid L to flow from behind the stack into the measurement chamber; this alignment changes with the randomized rotation of the discs, so that the flow of fluid L under buoyancy or through positive pumping pressure from behind the stack into the measurement chamber is also randomized, and hence the resistance-over-time-curve is also randomized; the round of operation terminates when the discs stop rotating and rest in a mutual alignment where there is no sufficient overlap among the holes of the various discs to allow for fluid L to keep flowing into the measurement chamber, and fluid L being lighter than fluid H, rises above the measurement chamber, which is filled with fluid H; and where the apparatus features a second fluid container, an L-reservoir, above the fluid container (b) where the lighter fluid L rises to, to clear the fluid container from any leftover fluid L, ensuring the fluid container (b) is filled with fluid H, ready for the next round of operation, and where fluids L and H are kept in a closed system where a pump moves fluid L from the L-reservoir towards the disc pack to carry out the next round of operation. 4. The apparatus in claim 3 where fluid L is atmospheric air, and fluid H is an electrically conductive liquid, and where a pump sucks open air through the discs pack, and the air emerges from the measurement chamber (b) back into the open. 5. The apparatus in claim 3 where the discs are welded each into concentric cylinders around the axis perpendicular to the surface of the discs, and each cylinder is rotated independently. 6. The apparatus in claim 3 where the discs are manufactured as cogwheels, and are rotated by a smaller driver cogwheel which is rotated by an electric motor. 7. The apparatus in claim 3 where the circumference of the discs is fitted with magnets, and surrounded by a larger circular structure abreast with the circumference of each disc, and where this structure is fitted with electromagnets that rotate the disc like with an electric motor. 8. The apparatus in claim 3 where the surfaces of the discs are divided to d*s polar elements, defined by dividing each disc to d angular divisions of 2π/d angles each, and dividing each division to s sections through concentric arcs, the concentric arcs are placed so that the polar elements are set to be of the same area, and where each disc is associated with a number h≤d*s of polar elements to be drilled as holes, and where a randomization process selects which of the d*s polar elements will become holes. 9. The apparatus of claim 8 where the discs come to rest at d spots with 2π/d angular intervals such that a stack of w discs can be placed in d w states, and where a valve placed before the stack is initially in a ‘closed’ position, barring fluid L from flowing to the measurement chamber, and where the stack is put in one of the d w states, followed by opening of the valve for an interval of time Δt, “shot”, then closing it again; allowing for an amount of fluid L, “bubble”, to flow through the stack into the measurement chamber, the bubble then rising to the L-reservoir; the quantity of fluid L passing through the stack during the shot depends on how much fluid passage area is available to the moving fluid L, as determined by the mutual alignment of the w discs, and corresponding to the pressure that moves fluid L through the stack into the measurement chamber; the extent to which the holes in the discs are randomized, the selection of the state