Search results for "quant-ph"

showing 10 items of 1378 documents

Toward computability of trace distance discord

2014

It is known that a reliable geometric quantifier of discord-like correlations can be built by employing the so-called trace distance. This is used to measure how far the state under investigation is from the closest "classical-quantum" one. To date, the explicit calculation of this indicator for two qubits was accomplished only for states such that the reduced density matrix of the measured party is maximally mixed, a class that includes Bell-diagonal states. Here, we first reduce the required optimization for a general two-qubit state to the minimization of an explicit two-variable function. Using this framework, we show next that the minimum can be analytically worked out in a number of r…

Discrete mathematicsDYNAMICSBell-diagonal statesquantum statesQuantum Physicse trace distance discordComputabilityPhysicsGeneral Physics and AstronomyFOS: Physical sciencesClass (philosophy)Function (mathematics)State (functional analysis)Expression (computer science)Measure (mathematics)X-STATESX-STATES; QUANTUM; ENTANGLEMENT; DYNAMICSQubitquantum information quantum correlationsTrace distanceQuantum Physics (quant-ph)QUANTUMENTANGLEMENTtrace distanceMathematics

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Understanding Quantum Algorithms via Query Complexity

2017

Query complexity is a model of computation in which we have to compute a function $f(x_1, \ldots, x_N)$ of variables $x_i$ which can be accessed via queries. The complexity of an algorithm is measured by the number of queries that it makes. Query complexity is widely used for studying quantum algorithms, for two reasons. First, it includes many of the known quantum algorithms (including Grover's quantum search and a key subroutine of Shor's factoring algorithm). Second, one can prove lower bounds on the query complexity, bounding the possible quantum advantage. In the last few years, there have been major advances on several longstanding problems in the query complexity. In this talk, we su…

Discrete mathematicsFOS: Computer and information sciencesQuantum PhysicsComputer scienceModel of computationSubroutineComputer Science::Information RetrievalFOS: Physical sciencesFunction (mathematics)Computational Complexity (cs.CC)Symmetric functionComputer Science - Computational ComplexityBounding overwatchPartial functionKey (cryptography)Quantum algorithmQuantum Physics (quant-ph)Computer Science::Databases

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On Physical Problems that are Slightly More Difficult than QMA

2013

We study the complexity of computational problems from quantum physics. Typically, they are studied using the complexity class QMA (quantum counterpart of NP) but some natural computational problems appear to be slightly harder than QMA. We introduce new complexity classes consisting of problems that are solvable with a small number of queries to a QMA oracle and use these complexity classes to quantify the complexity of several natural computational problems (for example, the complexity of estimating the spectral gap of a Hamiltonian).

Discrete mathematicsFOS: Computer and information sciencesQuantum PhysicsTheoretical computer scienceCompleteNP-easyFOS: Physical sciences0102 computer and information sciencesComputer Science::Computational ComplexityComputational Complexity (cs.CC)01 natural sciencesPHStructural complexity theoryComputer Science - Computational Complexity010201 computation theory & mathematics0103 physical sciencesAsymptotic computational complexityComplexity classF.1.2Low010306 general physicsQuantum Physics (quant-ph)Quantum complexity theoryMathematics2014 IEEE 29th Conference on Computational Complexity (CCC)

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Polynomial method to study the entanglement of pure N-qubit states

2009

We present a mapping which associates pure N-qubit states with a polynomial. The roots of the polynomial characterize the state completely. Using the properties of the polynomial we construct a way to determine the separability and the number of unentangled qubits of pure N-qubit states.

Discrete mathematicsPhysicsPolynomialQuantum PhysicsQuantum t-designSettore FIS/02 - Fisica Teorica Modelli E Metodi MatematiciCluster stateFOS: Physical sciencesQuantum entanglementQuantum PhysicsPolinomiMeccanica quantisticaAtomic and Molecular Physics and OpticsSettore FIS/03 - Fisica Della MateriaEntanglementSeparable stateComputer Science::Emerging TechnologiesQubitQuantum mechanicsComputingMethodologies_SYMBOLICANDALGEBRAICMANIPULATIONW stateHardware_ARITHMETICANDLOGICSTRUCTURESQuantum Physics (quant-ph)Quantum teleportation

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Scalable Ellipsoidal Classification for Bipartite Quantum States

2008

The Separability Problem is approached from the perspective of Ellipsoidal Classification. A Density Operator of dimension N can be represented as a vector in a real vector space of dimension $N^{2}- 1$, whose components are the projections of the matrix onto some selected basis. We suggest a method to test separability, based on successive optimization programs. First, we find the Minimum Volume Covering Ellipsoid that encloses a particular set of properly vectorized bipartite separable states, and then we compute the Euclidean distance of an arbitrary vectorized bipartite Density Operator to this ellipsoid. If the vectorized Density Operator falls inside the ellipsoid, it is regarded as s…

Discrete mathematicsPhysicsQuantum PhysicsBasis (linear algebra)Operator (physics)FOS: Physical sciencesEllipsoidAtomic and Molecular Physics and OpticsSeparable spaceEuclidean distanceSeparable stateDimension (vector space)Quantum mechanicsBipartite graphQuantum Physics (quant-ph)

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Quantum walks on two-dimensional grids with multiple marked locations

2015

The running time of a quantum walk search algorithm depends on both the structure of the search space (graph) and the configuration (the placement and the number) of marked locations. While the first dependence has been studied in a number of papers, the second dependence remains mostly unstudied.We study search by quantum walks on the two-dimensional grid using the algorithm of Ambainis, Kempe and Rivosh [3]. The original paper analyses one and two marked locations only. We move beyond two marked locations and study the behaviour of the algorithm for several configurations of multiple marked locations.In this paper, we prove two results showing the importance of how the marked locations ar…

Discrete mathematicsQuantum PhysicsComputer scienceStructure (category theory)FOS: Physical sciences0102 computer and information sciencesSpace (mathematics)01 natural sciencesRunning time010201 computation theory & mathematicsSearch algorithm0103 physical sciencesComputer Science (miscellaneous)Graph (abstract data type)Quantum walk010306 general physicsQuantum Physics (quant-ph)

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Improved constructions of quantum automata

2008

We present a simple construction of quantum automata which achieve an exponential advantage over classical finite automata. Our automata use \frac{4}{\epsilon} \log 2p + O(1) states to recognize a language that requires p states classically. The construction is both substantially simpler and achieves a better constant in the front of \log p than the previously known construction of Ambainis and Freivalds (quant-ph/9802062). Similarly to Ambainis and Freivalds, our construction is by a probabilistic argument. We consider the possibility to derandomize it and present some results in this direction.

Discrete mathematicsQuantum PhysicsFinite-state machineTheoryofComputation_COMPUTATIONBYABSTRACTDEVICESGeneral Computer ScienceFOS: Physical sciencesω-automatonComputer Science::Computational ComplexityNonlinear Sciences::Cellular Automata and Lattice GasesMobile automatonTheoretical Computer ScienceQuantum finite automataQuantum computationAutomata theoryQuantum finite automataNondeterministic finite automatonExponential advantageQuantum Physics (quant-ph)Computer Science::Formal Languages and Automata TheoryMathematicsQuantum computerQuantum cellular automatonComputer Science(all)

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Spatial Search on Grids with Minimum Memory

2015

We study quantum algorithms for spatial search on finite dimensional grids. Patel et al. and Falk have proposed algorithms based on a quantum walk without a coin, with different operators applied at even and odd steps. Until now, such algorithms have been studied only using numerical simulations. In this paper, we present the first rigorous analysis for an algorithm of this type, showing that the optimal number of steps is $O(\sqrt{N\log N})$ and the success probability is $O(1/\log N)$, where $N$ is the number of vertices. This matches the performance achieved by algorithms that use other forms of quantum walks.

Discrete mathematicsQuantum PhysicsNuclear and High Energy PhysicsQuantum sortSpatial searchGeneral Physics and AstronomyFOS: Physical sciencesStatistical and Nonlinear PhysicsType (model theory)Binary logarithmTheoretical Computer ScienceComputational Theory and MathematicsQuantum walkQuantum algorithmQuantum Physics (quant-ph)Mathematical PhysicsQuantum computerMathematics

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Exceptional Quantum Walk Search on the Cycle

2016

Quantum walks are standard tools for searching graphs for marked vertices, and they often yield quadratic speedups over a classical random walk's hitting time. In some exceptional cases, however, the system only evolves by sign flips, staying in a uniform probability distribution for all time. We prove that the one-dimensional periodic lattice or cycle with any arrangement of marked vertices is such an exceptional configuration. Using this discovery, we construct a search problem where the quantum walk's random sampling yields an arbitrary speedup in query complexity over the classical random walk's hitting time. In this context, however, the mixing time to prepare the initial uniform state…

Discrete mathematicsQuantum PhysicsSpeedupHitting timeFOS: Physical sciencesStatistical and Nonlinear PhysicsContext (language use)Random walk01 natural sciences010305 fluids & plasmasTheoretical Computer ScienceElectronic Optical and Magnetic MaterialsQuadratic equationModeling and Simulation0103 physical sciencesSignal ProcessingSearch problemQuantum walkElectrical and Electronic Engineering010306 general physicsQuantum Physics (quant-ph)MathematicsSign (mathematics)

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Nonmalleable encryption of quantum information

2008

We introduce the notion of "non-malleability" of a quantum state encryption scheme (in dimension d): in addition to the requirement that an adversary cannot learn information about the state, here we demand that no controlled modification of the encrypted state can be effected. We show that such a scheme is equivalent to a "unitary 2-design" [Dankert et al.], as opposed to normal encryption which is a unitary 1-design. Our other main results include a new proof of the lower bound of (d^2-1)^2+1 on the number of unitaries in a 2-design [Gross et al.], which lends itself to a generalization to approximate 2-design. Furthermore, while in prime power dimension there is a unitary 2-design with =…

Discrete mathematicsQuantum Physicsbusiness.industryDimension (graph theory)FOS: Physical sciencesStatistical and Nonlinear PhysicsState (functional analysis)Encryption01 natural sciencesUnitary stateUpper and lower bounds010305 fluids & plasmasQuantum state0103 physical sciencesQuantum informationQuantum Physics (quant-ph)010306 general physicsbusinessPrime powerMathematical PhysicsComputer Science::Cryptography and SecurityMathematicsJournal of Mathematical Physics

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