Title :
Bit-string physics: a novel “theory of everything”
Author :
Noyes, H. Pierre
Author_Institution :
Stanford Linear Accel. Center, Stanford Univ., CA, USA
Abstract :
Encodes the quantum numbers of the standard model of quarks and leptons using constructed bit-strings of length 256. These label a growing universe of bit-strings of growing length that eventually construct a finite and discrete space-time with reasonable cosmological properties. Coupling constants and mass ratios, computed from closure under XOR and a statistical hypothesis, using only h, c and mp to fix our units of mass, length and time in terms of standard (meter-kilogram-second) metrology, agree with the first four to seven significant figures of accepted experimental results. Finite and discrete conservation laws and commutation relations insure the essential characteristics of relativistic quantum mechanics, including particle-antiparticle pair creation. The correspondence limit in (free space) Maxwell electromagnetism and Einstein gravitation is consistent with the Feynman-Dyson-Tanimura “proof”
Keywords :
discrete symmetries; elementary particles; physics; physics computing; standard model; Einstein gravitation; Feynman-Dyson-Tanimura proof; Maxwell electromagnetism; bit-string physics; commutation relations; cosmological properties; coupling constants; discrete conservation laws; leptons; mass ratios; particle-antiparticle pair creation; quantum numbers; quarks; relativistic quantum mechanics; standard model; statistical hypothesis; theory of everything; Context modeling; Counting circuits; Extraterrestrial measurements; H infinity control; Information theory; Linear accelerators; Metrology; Particle measurements; Physics computing; Relativistic quantum mechanics;
Conference_Titel :
Physics and Computation, 1994. PhysComp '94, Proceedings., Workshop on
Conference_Location :
Dallas, TX
Print_ISBN :
0-8186-6715-X
DOI :
10.1109/PHYCMP.1994.363694
