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quantum automata

(Topic)

Quantum automaton and quantum computation

Definition 0.1 A quantum automaton can be simply defined as an extension of an automaton with quantum states instead of the sequentially determined states, inputs and outputs of a sequential, or state machine. The precise mathematical definitions of quantum automaton*, variable automaton, and quantum computation were first introduced formally in refs. [1] and [2] in relation to relational models in Quantum relational biology (loc.cit).

Note: Quantum computation and quantum `machines' (or nanobots) were much publicized in the early 1980's by Richard Feynman (Nobel Laureate in Physics: QED),and, subsequently, a very large number of papers- too many to cite all of them here- were published on this topic by a rapidly growing number of quantum theoreticians and some applied mathematicians.

Definition 0.2 One obtains a simple definition of quantum automaton by considering instead of the transition function of a classical sequential machine, the (quantum) transitions in a finite quantum system with definite probabilities determined by quantum dynamics. The quantum state space of a quantum automaton is thus defined as a quantum groupoid over a bundle of Hilbert spaces, or over rigged Hilbert spaces. Formally, whereas a sequential machine, or state machine with state space S, input set I and output set O, is defined as a quintuple: $(S, I, O, \delta : S \times S \rightarrow S, \lambda: S \times I\rightarrow O)$ , a quantum automaton is defined by a triple $(\emph{H}, \Delta: \emph{H} \rightarrow \emph{H}, \mu)$ , where H is either a Hilbert space or a rigged Hilbert space of quantum states and operators acting on H, and $\mu$ is a measure related to the quantum logic, LM, and (quantum) transition probabilities of this quantum system.

Remark.

Quantum `computation' becomes possible only when macroscopic blocks of quantum states can be controlled via quantum preparation and subsequent, classical observation. Obstructions to `building', or constructing quantum computers are known to exist in dimensions greater than $2$ as a result of the standard K-S theorem. Subsequent definitions of quantum computers reflect attempts to either avoid or surmount such difficulties often without seeking solutions through quantum operator algebras and their representations related to extended quantum symmetries which define fundamental invariants that are key

Definition 0.3 : Alternatively, as a quantum algebraic topology object, a quantum automaton is defined by the triplet $(\mathsf{G},\emph{H}-\Re_{\mathsf{G}}, Aut(\mathsf{G})$ ), where $\mathsf{G}$ is a locally compact quantum groupoid, H- $\Re_{\mathsf{G}}$ are the unitary representations of $\mathsf{G}$ on rigged Hilbert spaces $\Re_\mathsf{G}$ of quantum states and quantum operators on H, and $Aut(\mathsf{G})$ is the transformation, or automorphism, groupoid of quantum transitions.

Remark. Other definitions of quantum automata and quantum computations have also been reported that are closely related to recent experimental attempts at constructing quantum computing devices.

Two examples of such definitions are briefly considered next.

Definition 0.4 : quantum automata were defined in refs.[1] and [2] as generalized, probabilistic automata with quantum state spaces. Their next-state functions operate through transitions between quantum states defined by the quantum equations of motions in the Schrödinger representation, with both initial and boundary conditions in space-time.

A new theorem was proven which states that the category of quantum automata and automata–homomorphisms has both limits and colimits. Therefore, both categories of quantum automata and classical automata (sequential machines) are bicomplete. A second new theorem established that the standard automata category is a subcategory of the quantum automata category.

Related Results: Quantum Automata Applications to Modeling Complex Systems. The quantum automata category has a faithful representation in the category of Generalized $(M,R)$ -systems which are open, dynamic bio-networks ([]) with defined biological relations that represent physiological functions of primordial(s), single cells and the simpler organisms. A new category of quantum computers is also defined in terms of reversible quantum automata with quantum state spaces represented by topological groupoids that admit a local characterization through unique `quantum' Lie algebroids. On the other hand, the category of $n$ -Łukasiewicz algebras has a subcategory of centered $n$ - Łukasiewicz algebras [15] (which can be employed to design and construct subcategories of quantum automata based on $n$ -Łukasiewicz diagrams of existing VLSI. Furthermore, as shown in ref.([15] the category of centered $n$ -Łukasiewicz algebras and the category of Boolean algebras are naturally equivalent.

Variable machines with a varying transition function were previously discussed informally by Norbert Wiener as a possible model for complex biological systems although how this might be achieved in Biocybernetics has not been specifcally, or mathematically presented by Wiener.

A `no-go' conjecture was also proposed which states that Generalized (M,R)–Systems complexity prevents their complete computability by either standard or quantum automata. The concepts of quantum automata and quantum computation were initially studied and are also currently further investigated in the contexts of quantum genetics, genetic networks with nonlinear dynamics, and bioinformatics. In a previous publication (ICB71a)– after introducing the formal concept of quantum automaton–the possible implications of this concept for correctly modeling genetic and metabolic activities in living cells and organisms were also considered. This was followed by a formal report on quantum and abstract, symbolic computation based on the theory of categories, functors and natural transformations [2]. The notions of topological semigroup, quantum automaton,or quantum computer, were then suggested with a view to their potential applications to the analogous simulation of biological systems, and especially genetic activities and nonlinear dynamics in genetic networks. Further, detailed studies of nonlinear dynamics in genetic networks were carried out in categories of $n$ -valued, Łukasiewicz Logic Algebras that showed significant dissimilarities [] from the widespread Bolean models of human neural networks that may have begun with the early publication of [17]. Molecular models in terms of categories, functors and natural transformations were then formulated for uni-molecular chemical transformations, multi-molecular chemical and biochemical transformations []. Previous applications of computer modeling, classical automata theory, and relational biology to molecular biology, oncogenesis and medicine were extensively reviewed and several important conclusions were reached regarding both the potential and limitations of the computation-assisted modeling of biological systems, and especially complex organisms such as Homo sapiens sapiens []. Novel approaches to solving the realization problems of Relational Biology models in Complex System Biology are introduced in terms of natural transformations between functors of such molecular categories. Several applications of such natural transformations of functors were then presented to protein biosynthesis, embryogenesis and nuclear transplant experiments. Other possible realizations in Molecular Biology and Relational Biology of Organisms were then suggested in terms of quantum automata models of Quantum Genetics and Interactomics. Future developments of this novel approach are likely to also include: Fuzzy Relations in Biology and Epigenomics, Relational Biology modeling of Complex Immunological and Hormonal regulatory systems, $n$ -categories and generalized $LM$ –Topoi of Łukasiewicz Logic Algebras and intuitionistic logic (Heyting) algebras for modeling nonlinear dynamics and cognitive processes in complex neural networks that are present in the human brain, as well as stochastic modeling of genetic networks in Łukasiewicz Logic Algebras (LLA).

Quantum Automata, Quantum Computation and Quantum Dynamics Represented by Categories, Functors and Natural Transformations.

Molecular models were previously defined in terms of categories, functors and natural transformations were formulated for unimolecular chemical transformations, multi-molecular chemical and biochemical transformations [12]. Dynamic similarities or analogies between categories of classical, quantum or complex systems and their transformations were then naturally represented in terms of adjoint functors and the corresponding natural equivalences.

Remark. Previous applications of computer modeling, classical automata theory, and relational biology to molecular biology, neural networks, oncogenesis and medicine were extensively reviewed in a previous monograph and several important conclusions were reached regarding both the potential and the severe limitations of the algorithm driven, recursive computation-assisted modeling of complex biological systems [11].

Bibliography

1: Baianu, I.C.: 1971a, Categories, Functors and Quantum Algebraic Computations, in P. Suppes (ed.), Proceed. Fourth Intl. Congress Logic-Mathematics-Philosophy of Science, September 1–4, 1971, the University of Bucharest.
2: Baianu, I.C.: 1971b, Organismic Supercategories and Qualitative Dynamics of Systems. Bulletin of Mathematical Biophysics, 33 (3): 339–354.
3: I.C. Baianu.: Łukasiewicz-Topos Models of Neural Networks, Cell Genome and Interactome Nonlinear Dynamics). CERN Preprint EXT-2004-059. Health Physics and Radiation Effects (June 29, 2004).
4: I. C. Baianu, J. F. Glazebrook, R. Brown and G. Georgescu.: Complex Nonlinear Biodynamics in Categories, Higher dimensional Algebra and Łukasiewicz-Moisil Topos: Transformation of Neural, Genetic and Neoplastic Networks, Axiomathes, 16: 65–122(2006).
5: Baianu, I.C.: 1970, Organismic Supercategories: II. On Multistable Systems. Bulletin of Mathematical Biophysics, 32: 539-561.
6: Baianu, I.C. and D. Scripcariu: 1973, On Adjoint Dynamical Systems. The Bulletin of Mathematical Biophysics, 35(4), 475–486.
7: Baianu, I.C.: 1973, Some Algebraic Properties of (M,R) – Systems. Bulletin of Mathematical Biophysics 35, 213-217.
8: Baianu, I.C. and M. Marinescu: 1974, A Functorial Construction of (M,R)– Systems. Revue Roumaine de Mathematiques Pures et Appliquees 19: 388–391.
9: Baianu, I.C.: 1977, A Logical Model of Genetic Activities in Łukasiewicz Algebras: The Non-linear Theory. Bulletin of Mathematical Biophysics, 39: 249-258.
10: Baianu, I.C.: 1980, Natural Transformations of Organismic Structures. Bulletin of Mathematical Biophysics, 42: 431-446
11: Baianu, I. C.: 1987, Computer Models and Automata Theory in Biology and Medicine., in M. Witten (ed.), Mathematical Models in Medicine, vol. 7., Pergamon Press, New York, 1513–1577; CERN Preprint No. EXT-2004-072 .
12: Baianu, I.C.: 2004, Quantum Nano–Automata (QNA): Microphysical Measurements with Microphysical QNA Instruments, CERN Preprint EXT–2004–125.
13: Baianu, I. C., Glazebrook, J. F. and G. Georgescu: 2004, Categories of Quantum Automata and N-Valued Łukasiewicz Algebras in Relation to Dynamic Bionetworks, (M,R)–Systems and Their Higher Dimensional Algebra, Abstract and Preprint of Report
14: Baianu I. C., Brown R., Georgescu G. and J. F. Glazebrook: 2006, Complex Nonlinear Biodynamics in Categories, Higher Dimensional Algebra and Łukasiewicz–Moisil Topos: Transformations of Neuronal, Genetic and Neoplastic networks, Axiomathes 16 Nos. 1–2, 65–122.
15: Georgescu, G. and C. Vraciu 1970. On the Characterization of Łukasiewicz Algebras., J Algebra, 16 (4), 486-495.
16: BMB1: Mathematical Biology reports
17: McCullough, E. and M. Pitts.1945. Bull. Math. Biophys. 7, 112-145.
18: MBR2: Eprint at cogprints.org/3674/ Mathematical Biology reports2.
19: A Java quantum circuit simulator: jQuantum; click on the link to download the Java quantum circuit simulator
20: A $C^{++}$ Quantum Library
21: The Haskell Library for Quantum computations
22: A Quasi–Quantum Computer.
23: A Quantum circuit emulator: QCAD
24: An introduction to Quantum Computers

"quantum automata" is owned by bci1.

Other names:

nano-automaton

Also defines:

quantum automaton, quantum computers

Keywords:

quantum computers, quantum groupoids, quantum groups, quantum applications, quantum relational biology

This object's parent.

Cross-references: algorithm, adjoint functors, automata theory, computer, chemical transformations, molecular models, semigroup, topological, natural transformations, functors, genetic networks, concepts, complexity, diagrams, Lie algebroids, topological groupoids, category, category of quantum automata, theorem, space-time, boundary, motions, functions, groupoid, quantum operators, object, quantum algebraic topology, extended quantum symmetries, representations, quantum operator algebras, K-S theorem, quantum logic, operators, state space, rigged Hilbert spaces, Hilbert spaces, quantum groupoid, quantum state space, dynamics, system, sequential machine, transition function, QED, relational biology, relation, computation, automaton
There are 21 references to this object.

This is version 21 of quantum automata, born on 2008-12-15, modified 2009-05-04.
Object id is 328, canonical name is QuantumAutomaton.
Accessed 3353 times total.

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Physics Classification:

03.65.Fd (Algebraic methods )

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