Feynman R., Simulating Physics with Computers, Intern. Journal of Theoretical Physics, vol.21, no.6/7, 1982, 467-488. Home/Search Document Details and Download
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....random access machines, circuits, or cellular automata are all universal in the sense that they can simulate each other with only polynomial overhead. These models are based on classical physics, whereas physicists believe that the universe is better described by quantum mechanics. Feynman [8, 9] pointed out first that there might be a substantial gap between computational models based on classical physics and those based on quantum mechanics. The quantum Turing machine (QTM) the first model of quantum computation, was introduced by Benioff [1, 2] Deutsch in [5] described a universal ....
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....fluid regime, there is excellent agreement between the theoretical prediction and the numerical data for the single particle occupation probability. 2 Review There are new possibilities and limitations that arise in computing if we use the principle of quantum mechanical superposition of states [4, 5, 6, 7, 8, 9]. In quantum computing a two level quantum bit represents the smallest unit of information which may be in a superposition of the discrete states 0# 1#. An example of the physical embodiment of a qubit is the z component of A qubit, # 0# # 1#, has an amplitude, #, of it being in ....
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R. Feynman (1982): Simulating physics with computers. Int. J. Theor. Phys. 21, 467--488.
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Feynman R., Simulating Physics with Computers, Intern. Journal of Theoretical Physics, vol.21, no.6/7, 1982, 467-488.
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