Abstract :
It is well known that quantum mechanics is explained in quantum logic and orthomodular lattices. However, these logic and algebraic structure have not always succeeded in explaining behavior of quantum information systems. A qubit |Ψ>=α|0>+β|1> in quantum information systems is extension of classical concept "bit", where |0> and |1> are basis of a two dimensional quantum system, α and β are probabilistic amplitudes in C (complex numbers). Then, one qubit can have infinite number of values in contrast with classical one bit. In this paper, to analyze various infinite number of quantum states, we establish a discrete algebraic structure as a model of qubit space, which is isomorphic to Kleene algebra 3=< {0, 1/2, 1}, ∼, ∧, ∨ >. Furthermore, we propose weak Kleenean non-additive measures and weak Kleene-Choquet integrals. Then, we show that we can analyze quantum communication channels effectively by the proposed framework.
Keywords :
algebra; quantum cryptography; quantum theory; algebraic structure; complex numbers; orthomodular lattices; probabilistic amplitudes; quantum communication channels; quantum cryptosystems; quantum information systems; quantum logic; quantum mechanics; quantum states; two dimensional quantum system; weak Kleene-Choquet integrals; weak Kleenean nonadditive measures; Algebra; Cryptography; Detectors; Error correction; Information analysis; Information systems; Noise figure; Noise measurement; Quantum mechanics; State estimation;
