Methods and systems for quantum search, computation and memory
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G06F-015/00
G06F-015/18
출원번호
US-0337076
(2008-12-17)
등록번호
US-8190553
(2012-05-29)
발명자
/ 주소
Routt, Thomas J.
출원인 / 주소
Routt, Thomas J.
대리인 / 주소
Edwards Wildman Palmer LLP
인용정보
피인용 횟수 :
9인용 특허 :
5
초록▼
A system for performing multi-dimensional quantum search, quantum computation, quantum memory, quantum storage, and quantum retrieval includes a structure and method for: enabling components and systems for quantum search, and more particularly to improved local and remote quantum computing and sear
A system for performing multi-dimensional quantum search, quantum computation, quantum memory, quantum storage, and quantum retrieval includes a structure and method for: enabling components and systems for quantum search, and more particularly to improved local and remote quantum computing and search components and systems; quantum memory component and systems; quantum storage components and systems; quantum retrieval components and systems; quantum logic gates; classical (non-quantum) search components and systems; integrated quantum-classical search components and systems; and integrated quantum-classical cryptosystems.
대표청구항▼
1. A system for quantum search and retrieval in multiple dimensions in a distributed computing environment having a plurality of users associated with clients comprising: a Quantum search query module configured for: receiving quantum search queries from clients across a Quantum application programm
1. A system for quantum search and retrieval in multiple dimensions in a distributed computing environment having a plurality of users associated with clients comprising: a Quantum search query module configured for: receiving quantum search queries from clients across a Quantum application programming interface in the distributed computing environment; interfacing to classical query and ranking modules within a classical search system across a quantum-classical application programming interface in the distributed computing environment; and interfacing to a Quantum oracle index within an indexes system;the Quantum oracle index in the distributed computing environment;a Mapping index in the distributed computing environment including: a quantum search index with rotation operators and spin matrices components; an addressable absolute memory index with rotation matrices, quantum number, world sheet, root systems, and root memory cells components; and an encryption index with quantum, classical, and steganographic components;a Content mapping module in the distributed computing environment configured for: interfacing to the Mapping index within said indexes system; and generating a quantum search results list in response to the quantum search queries across the Quantum application programming interface; andthe Quantum application programming interface in the distributed computing environment. 2. A system as recited in claim 1, incorporating a classical application programming interface and a quantum-classical application programming interface to a classical (non-quantum) search and retrieval system including: a classical crawler module; a classical page repository; a plurality of classical indexes and modules; and a plurality of classical query and ranking modules. 3. A system as recited in claim 1, wherein the system initializes to a superposition: [(|0+|00+ . . . +|0 . . . 0+|1+|11+ . . . +|1 . . . 1)/n√2],the superposition obtained within an nth root of A number of steps, where A is any complex number of the form a+bi, where a and b are real numbers, and where i is an imaginary unit, with the property i2=−1; where such a superposed intialization provides a basis for massively parallel quantum computation, enabling combined sequential and simultaneous processing, generating a conditional basis for massively parallel calculation of a plurality of computational trajectories, pathways, and outcomes. 4. A system as recited in claim 1 for calculating a quantum addressable absolute memory index (AAMI) in the form: AAMI=∏i=0nYi[∫∫∫…∫Df(x1,x2,…,xn)ⅆx1ⅆx2…ⅆxn]; where: [∏i=0nYi] is the Cartesian product of the set of all (n+1)-tuples (y0, . . . ,yn); [∫∫∫ . . . ∫] is an n-dimensional indefinite/unbounded integral;[(xn−5=c=quantum memory cell)];[(xn−4=s=spin quantum number)];[(xn−3=m=magnetic quantum number)];[(xn−2=l=azimuthal quantum number)];[(xn−1=n=principal quantum number)]; and[(xn=w=E8 quantum number)];and where AAMI comprises an n-level quantum system based upon a plurality of projective space vectors from the Poincaré sphere (quantum photonic expression), and Bloch sphere (quantum electronic expression), operating within n-dimensional Hilbert space. 5. A system as recited in claim 4 for: identifying quantum numbers of spin-polarized electrons;identifying fermionic quantum numbers, where fermions include any of electrons, protons, neutrons, neutrinos, quarks, or certain atomic structures;storing quantum numbers of spin-polarized electrons;storing fermionic quantum numbers, where fermions include any of electrons, protons, neutrons, neutrinos, quarks, or certain atomic structures;associating a plurality of quantum numbers to a plurality of particles, at a plurality of scales, to a plurality of quantum memory cells, where the set of quantum numbers specifies the complete and unique quantum state of each particle functioning as a particular quantum memory cell, and where the combination of any given particle quantum number set is associated with any given unique quantum memory cell; andassociating particle states to wave functions. 6. A system as recited in claim 1, wherein the rotation operators are integer values. 7. A quantum search oracle computer in a distributed computing environment comprising: a processor coupled with memory storage devices and hardware operative to:utilize zero-point quantum computation, search, storage and retrieval logic within a plurality of superposed quantum gaps, or computational singularities in the hardware;perform internally state-continuous quantum computation while stationed between and among any 2-to-n instances of a plurality of observable system states in the hardware;marks, by the processor a plurality of solutions to a plurality of quantum search query requests by phase-shifting search request solutions utilizing zero-point, self-referral computations' in quantum gap logic at hyper-exponentially convergent calculation velocities, where the search problem contains a plurality of N possible items and a plurality of M possible solutions;solves, by the processor, a quantum search problem searching for the N possibilities; andgenerate, by the processor a quantum oracle index upon completion of the quantum search solution mark process. 8. A quantum search, computation, and retrieval system in a distributed computing environment having a plurality of clients, a server and memory devices comprising: a plurality of mapping indices between and among a plurality of real-, complex-, and quaternion-based computations and representations;a Wavefunction Ψ(x) initialization at uniform superposition, stored in the memory devices with equal amplitudes in all basis states and where sums of entries in initialization matrix columns are unity;a plurality of computational and search arguments and parameters stored in the memory devices that propel a quantum, massively parallel search along n-dimensional, massively interlinked computational pathways;a quantum search query module stored as an instruction set in the memory devices that formats and presents a plurality of quantum search query requests to a quantum oracle index;a quantum oracle index stored in the memory devices that invokes a quantum search oracle;a plurality of E8 roots and cells stored in the memory devices and mapped to a plurality of quantum root memory cells stored in the memory devices;a rotation operator module stored as an instruction set in the memory devices to associate a plurality of basis state phase shift rotations by π radians to a plurality of root memory cells; phase-shift marked basis state search matches by rotations of 2π radians; phase-shift unmarked basis state search matches by rotations of 3π/2 radians; phase-shift a plurality of marked and unmarked basis state computational and search matches by a plurality of infinitesimal increments of rotations of [−∞≦π≦∞ radians]; associate a plurality of marked rotations (2π-to-nπ-radians) and unmarked rotations (3π/2-to-nπ/n-radians), with a plurality of quantum search indices utilizing an nth root algorithm, where a plurality of radicands is enabled, approaching an infinite root number of steps at exponentially or hyper-exponentially convergent calculation velocities; associate a plurality of marked rotations (2π-to-nπ-radians) and unmarked rotations (3π/2-to-nπ/n-radians), with a plurality of locations on an absolute addressable memory index; associate a plurality of infinitesimal increments of phase-shifted rotations of [−∞≦π≦∞ radians] to a plurality of locations on an addressable absolute memory index;a method to initialize subsequent named computational search sets [Sn+1→S∞] on E8 roots and cells that are directly mapped to a plurality of root memory cells:,a spin matrices module stored as an instruction set in the memory devices where spin-polarized particle results from marked and unmarked rotations generate and apply n-vector extensions to a plurality of spin matrices;a rotation matrices module stored as an instruction set in the memory devices that generates a plurality of spin-polarized particle rotation matrices;a quantum number module stored as an instruction set in the memory devices that initializes root memory cell map index matrices, calculates a plurality of root system, principal, azimuthal, magnetic, and spin quantum numbers;an integrated world sheet root system and root memory cells module stored as an instruction set in the memory devices that: initializes nth-root search logic approaching infinite root at hyper-exponentially convergent calculation velocities: initializes cartan sub-algebra generators; generates a strong G2 root system; rotates and scales in n-dimensions; matches on parallel world lines; collapses a G2 root system to lower-dimensional embedded space; generates a plurality of graviweak F4 vertices a quantum number; generates a plurality of gravitation and electroweak D2 vertices; calculates a plurality of E8 polytope vertices; calculates an E8 quantum number; combines a plurality of E8 roots in eight dimensions; collapses an E8 root system along matched parallel world lines and lattices to lower-dimensional embedded space; calculates a plurality of E8 root systems along mapped world lines; calculates collapsed n-dimensional E8 root system projections; and maps to a plurality of root memory cells;a quantum encryption module stored as an instruction set in the memory devices that performs quantum encryption and decryption;a content mapping module stored as an instruction set in the memory devices that formats, maps, and returns a plurality of quantum search query request indexes into a quantum search results list across a quantum application programming interface; andan integrated classical crawler module stored as an instruction set in the memory devices, classical page repository, classical search indexes, and classical search query ranking module stored as an instruction set in the memory devices that processes a plurality of search query requests and formats a plurality of search results within a classical search system and via interface to a quantum search system. 9. A quantum search, computation and retrieval system in a distributed computing environment having a plurality of clients, a server and memory devices comprising: a source of spin-polarized particles;a Wavefunction Ψ(x) initialization at uniform superposition, stored in the memory devices with equal amplitudes in all basis states and where sums of entries in initialization matrix columns are unity;a Quantum logic initialization stored in the memory devices for a named search sets wavefunction time to zero, where [(t=0) Ψ(x)] is an eigenstate of a Hamiltonian (H), a self-adjoint operator acting on a state space to initialize computational energy as a physically observable (real number-based) quantity=N which is associated with a named computational search set=Sn;a plurality of computational and search arguments and parameters stored in the memory devices that propel a quantum, massively parallel search along n-dimensional, massively interlinked computational pathways;a quantum search query module stored as an instruction set in the memory devices that formats and presents a plurality of quantum search query requests to a quantum oracle index;a quantum oracle index stored in the memory devices that invokes a quantum search oracle;a plurality of E8 roots and cells stored in the memory devices and mapped to a plurality of quantum root memory cells stored in the memory devices;a rotation operator module stored as an instruction set in the memory devices to associate a plurality of basis state phase shift rotations by π radians to a plurality of root memory cells; phase-shift marked basis state search matches by rotations of 2π radians; phase-shift unmarked basis state search matches by rotations of 3π/2 radians; phase-shift a plurality of marked and unmarked basis state computational and search matches by a plurality of infinitesimal increments of rotations of [−∞≦π≦∞ radians]; associate a plurality of marked rotations (2π-to-nπ-radians) and unmarked rotations (3π/2-to-nπ/n-radians), with a plurality of quantum search indices utilizing an nth root algorithm, where a plurality of radicands is enabled, approaching an infinite root number of steps at exponentially or hyper-exponentially convergent calculation velocities; associate a plurality of marked rotations (2π-to-nπ-radians) and unmarked rotations (3π/2-to-nπ/n-radians), with a plurality of locations on an absolute addressable memory index; associate a plurality of infinitesimal increments of phase-shifted rotations of [−∞≦π≦∞ radians ] to a plurality of locations on an addressable absolute memory index;a method to initialize subsequent named computational search sets [Sn+1→S∞] on E8 roots and cells that are directly mapped to a plurality of root memory cells;a spin matrices module stored as an instruction set in the memory devices where spin-polarized particle results from marked and unmarked rotations generate and apply n-vector extensions to a plurality of spin matrices;a rotation matrices module stored as an instruction set in the memory devices that generates a plurality of spin-polarized particle rotation matrices;a quantum number module stored as an instruction set in the memory devices that initializes root memory cell map index matrices, calculates a plurality of root system, principal, azimuthal, magnetic, and spin quantum numbers;an integrated world sheet root system and root memory cells module stored as an instruction set in the memory devices that: initializes nth-root search logic approaching infinite root at hyper-exponentially convergent calculation velocities; initializes cartan sub-algebra generators; generates a strong G2 root system; rotates and scales in n-dimensions; matches on parallel world line's; collapses a G2 root system to lower dimensional embedded space; generates a plurality of graviweak F4 vertices a quantum number; generates a plurality of gravitation and electroweak D2 vertices; calculates a plurality of E8 polytope vertices; calculates an E8 quantum number; combines a plurality of E8 root in eight dimensions; collapses an E8 root system along matched parallel world lines and lattices to lower-dimensional embedded space; calculates a plurality of E8 root systems along mapped world lines; calculates collapsed n-dimensional E8 root system projections; and maps to a plurality of root memory cells;a quantum encryption module stored as an instruction set in the memory devices that performs quantum encryption and decryption;a classical encryption module stored as an instruction set in the memory devices that performs industry-standard classical (non-quantum) encryption, decryption and interfaces;a steganographic encryption module stored as an instruction set in the memory devices that performs steganographic encoding of a plurality of quantum and classical encryption operations;a content mapping module stored as an instruction set in the memory devices that formats, maps, and returns a plurality of quantum search query request indexes into a quantum search results list across a quantum application programming interface;an integrated classical crawler module stored as an instruction set in the memory devices, classical page repository, classical search indexes, and classical search query ranking module stored as an instruction set in the memory devices that processes a plurality of search query requests and formats a plurality of search results within a classical search system and via interface to a quantum search system. 10. A quantum search, computation, and retrieval system as recited in claim 9 that generates a quantum search index of the form 0≦ element index≦N−1 to N search elements, N=2n; where the quantum search index can be stored in n qubits, an associated quantum search problem has M solutions with 1≦M≦N, the quantum search index obtains a search solution utilizing an exponentially or hyper-exponentially converging nth root algorithm for finding an nth root of A, where A is any complex number of the form a+bi, where a and b are real numbers, where i is an imaginary unit with the property i2=−1, and where a radical or root may be encoded by an infinite series: (1+x)s/t=∑n=0∞(s+t-kt)(s+t)n!tnxnwithx<1. 11. A quantum search, computation, and retrieval system as recited in claim 9 that associates with, and encodes to, a plurality of Lie groups, the Lie groups being differentiable manifolds with the property that group operations are compatible with a continuous-symmetry smooth structure, i.e., continuous symmetries of differential equations; associating a plurality of spin states with local or linearized, versions of a global quantum computational object with its infinitesimal group, based on Lie algebra;comprising a plurality of root vectors and a plurality of Cartan subalgebra generators that span the Lie algebra and, in so doing, can function as generators—the Cartan-Weyl basis of the Lie algebra, where the Lie bracket between root vectors corresponds to vector addition between their roots, and to interactions between quantum memory address locations stored in the memory devices;where eigenvectors function as weight vectors of the Cartan subalgebra, with eigenvalues that correspond to the generalized roots (weights) that describe a plurality of representations; comprising a plurality of canonical forms for the commutation relations of a Lie algebra, where resulting equations are invariant under the nonsingular transformation U, and where the canonical form is a polynomial in λ of order η, with real coefficients φj(ri), depending on the choice of Lie algebra element; and comprising a means to generate and store a plurality of Lie brackets within a plurality of Lie groups as a function of equivalent operators of a subgroup of vectors in fundamental representation spaces, based upon a plurality of superposed quantum gaps, or computational singularities, stationed between and among any 2-to-n instances of a plurality of observable system states. 12. A quantum search, computation, and retrieval system as recited in claim 9 further comprising a means to cross-associate and cross-integrate quantum search and retrieval initialization, time-series evolution, and results, within and among a plurality of classical, non-quantum systems as a function of a plurality of addressable classical memory components existing within a quantum memory system. 13. A quantum search, computation, and retrieval system as recited in claim 9 further comprising: a plurality of spin-polarized electrons or spin-polarized photons generated and expressed as a plurality of spin slopes and spin slope fields;a first means to achieve long storage times of representations of spin polarization, based upon construction of a plurality of slope fields associated with a plurality of spin-polarized states, expressed as differentiable functions computed at n-dimensional cartesian coordinate-based points of spin-polarized near-tangency;a second means to generate autonomous differential equations, yielding horizontal-shift-invariant slope fields;a third means to generate nonautonomous differential equations yielding horizontal- and vertical-shift-variant slope fields;a fourth means to associate a plurality of nonautonomous differential equation-based slope fields to a plurality of spin-poloarized electronic, and to a plurality of spin-polarized photonic states;a fifth means to represent a plurality of spin-polarized electronic and a plurality of spin-polarized photonic states, to a plurality of autonomous and nonautonomous differential equation-based slope fields;a sixth means to generate a plurality of solution curves to a plurality of autonomous and non-autonomous differential equation-based representations of spin-polarized electronic and photonic states, where convergence regions generate addressable and reusable quantum search index identifiers; anda seventh means to associate a plurality of quantum numbers to a plurality of quantum memory cells, where the associated set of quantum numbers specifies the complete and unique quantum state of each particle functioning as a particular quantum memory cell stored in the memory devices. 14. A quantum search, computation, and retrieval system as recited in claim 13, further comprising a plurality of spin state-vectors imparted with n-dimensional components via operators on n-directional photonic oscillating magnetic field and electric field parallel and perpendicular alignments, where spin decoherence is contained by minimizing duration of optical pulse and storage times, and wherein the first through seventh means are a quantum computer. 15. A quantum cryptosystem of the quantum search, computation, and retrieval system as recited in claim 9, wherein qubits are established via the oscillating polarization generated as a function of the time-varying electric field of a light wave where the relationship between the polarization and applied electric field is linear, with the resulting time-varying polarization sinusoidal at frequency ω1 through ωn;wherein sinusoidally-varying fields are generated for any medium in which induced polarization is a nonlinear function of any electric field, inducing polarizations that incorporate frequency components at 1-to-n higher harmonics of the original (first-order, or linear) frequency, generating the basis for 1-to-n qubit encryption; where Σ-frequencies of second-to-nth-order harmonic waves expressing as qubits are calculated using perturbations of Maxwell's equations for static and time-varying electric and magnetic fields, and where computational reversibility may be calculated through an Inverse Fourier Transform on any classical (non-quantum) function ƒ(x). 16. A quantum cryptosystem of the quantum search, computation, and retrieval system as recited in claim 9, wherein computational reversibility can be calculated through a Quantum Fourier Transform as the discrete Fourier transform with a specified decomposition into a product of simpler unitary matrices, and where the decomposition and associated decryption can be implemented as a quantum logic gate. 17. A quantum cryptosystem of the quantum search, computation, and retrieval system as recited in claim 9, wherein the relationship between induced polarization P and the electric field E is not linear; qubits are established as a result of the generated polarization not being the same for a given applied field of magnitude +E0, in the same fashion as for an applied field of magnitude −E0; and the polarization response to any given applied sinusoidal field is not purely sinusoidal, generating a distortion reflecting the presence of polarization components at frequencies ≠ω1, and therefore providing the basis state for a strong component at the second-harmonic frequency 2ω1 or nth-harmonic frequencies 2ωn. 18. A quantum cryptosystem of the quantum search, computation, and retrieval system as recited in claim 9, wherein sender-receiver parties rotate Einstein-Podolsky-Rosen (EPR) quantum key-generating pairs [(|00+|11)√2)] by 1-to-n spin-polarized phase angles (θ) throughout the integer and/or sub-integer range 0≦θ≦360. 19. A quantum cryptosystem of the quantum search, computation, and retrieval system as recited in claim 9, wherein quantum cryptographic algorithms, keys, and references thereto, are steganographically encoded and referenced within classical fields protected by n-bit keys, and references thereto, based on steganographically embedding 1-to-n quantum cryptographic algorithms, keys, and references thereto, within 1-to-n classical fields, and references thereto, comprising the following steps: (1) Initializing the sequence by encoded reference to quantum computational results, resulting in generation of non-orthogonal qubits;(2) Generating a non-orthogonal qubit result reference field comprising 1-to-n classical bits;(3) Generating a pseudo-random key sequence using a classical (non-quantum) XOR operation;(4) Encrypting the XOR pseudo-random result employing a commutative one-way accumulator;(5) Pseudo-randomly interspersing check bits among (classical) data bits;(6) Embedding reference (classical) check bits to calculated non-orthogonal qubits and references thereto; and(7) embedding classical data referenced by classical check bits into variable-length message data and overhead fields. 20. A quantum cryptosystem as recited in claim 19 that employs a reversible computational method to the method for retrieving 1-to-n embedded quantum cryptographic algorithms, keys, and references thereto, from 1-to-n classically encrypted fields, and references thereto. 21. A quantum cryptosystem as recited in claim 19 wherein classical (non-quantum) data fields protected by n-bit keys, and references thereto, are steganographically encoded and referenced within quantum cryptographic algorithms, keys, and references thereto. 22. An integrated classical (non-quantum)-quantum cryptosystem of the quantum search, computation, and retrieval system recited in claim 19 that steganographically embeds 1-to-n classical (non-quantum) cryptographic algorithms, keys, and references thereto, within 1-to-n quantum cryptographic algorithms, keys, and references thereto, comprising the following steps: (1) Initializing the sequence by encoded reference to classical (non-quantum) encryption algorithms and keys;(2) Generating a random quantum key sequence resulting in non-orthogonal qubits;(3) Calculating a spin-polarized phase angle pointer to 1-to-w classical (non-quantum) cryptographic algorithms and keys;(4) Calculating the associated inner product φ|Ψ between the vectors |φ and |Ψ;(5) Calculating the associated tensor product |φ{circumflex over (×)}|Ψ of |φ and |Ψ;(6) Embedding reference quantum check qubits to calculated classical (non-quantum) cryptographic algorithms, keys, and references thereto; and(7) Embedding the quantum computational result into the transmitted quantum message. 23. An integrated classical (non-quantum)-quantum cryptosystem as recited in claim 22 that employs a reversible computational method to the method for retrieving 1-to-n embedded classical (non-quantum) cryptographic algorithms, keys, and references thereto, from 1-to-n quantum encrypted fields, and references thereto.
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이 특허에 인용된 특허 (5)
Grover Lov K., Fast quantum mechanical algorithms.
Mower, Jacob C.; Harris, Nicholas C.; Englund, Dirk R.; Steinbrecher, Greg, Methods, systems, and apparatus for programmable quantum photonic processing.
Mower, Jacob C.; Harris, Nicholas C.; Englund, Dirk R.; Steinbrecher, Greg, Methods, systems, and apparatus for programmable quantum photonic processing.
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