67 research outputs found
Convergence of continuous-time quantum walks on the line
The position density of a "particle" performing a continuous-time quantum
walk on the integer lattice, viewed on length scales inversely proportional to
the time t, converges (as t tends to infinity) to a probability distribution
that depends on the initial state of the particle. This convergence behavior
has recently been demonstrated for the simplest continuous-time random walk
[see quant-ph/0408140]. In this brief report, we use a different technique to
establish the same convergence for a very large class of continuous-time
quantum walks, and we identify the limit distribution in the general case.Comment: Version to appear in Phys. Rev.
On active and passive testing
Given a property of Boolean functions, what is the minimum number of queries
required to determine with high probability if an input function satisfies this
property or is "far" from satisfying it? This is a fundamental question in
Property Testing, where traditionally the testing algorithm is allowed to pick
its queries among the entire set of inputs. Balcan, Blais, Blum and Yang have
recently suggested to restrict the tester to take its queries from a smaller
random subset of polynomial size of the inputs. This model is called active
testing, and in the extreme case when the size of the set we can query from is
exactly the number of queries performed it is known as passive testing.
We prove that passive or active testing of k-linear functions (that is, sums
of k variables among n over Z_2) requires Theta(k*log n) queries, assuming k is
not too large. This extends the case k=1, (that is, dictator functions),
analyzed by Balcan et. al.
We also consider other classes of functions including low degree polynomials,
juntas, and partially symmetric functions. Our methods combine algebraic,
combinatorial, and probabilistic techniques, including the Talagrand
concentration inequality and the Erdos--Rado theorem on Delta-systems.Comment: 16 page
Quantum walks with infinite hitting times
Hitting times are the average time it takes a walk to reach a given final
vertex from a given starting vertex. The hitting time for a classical random
walk on a connected graph will always be finite. We show that, by contrast,
quantum walks can have infinite hitting times for some initial states. We seek
criteria to determine if a given walk on a graph will have infinite hitting
times, and find a sufficient condition, which for discrete time quantum walks
is that the degeneracy of the evolution operator be greater than the degree of
the graph. The set of initial states which give an infinite hitting time form a
subspace. The phenomenon of infinite hitting times is in general a consequence
of the symmetry of the graph and its automorphism group. Using the irreducible
representations of the automorphism group, we derive conditions such that
quantum walks defined on this graph must have infinite hitting times for some
initial states. In the case of the discrete walk, if this condition is
satisfied the walk will have infinite hitting times for any choice of a coin
operator, and we give a class of graphs with infinite hitting times for any
choice of coin. Hitting times are not very well-defined for continuous time
quantum walks, but we show that the idea of infinite hitting-time walks
naturally extends to the continuous time case as well.Comment: 28 pages, 3 figures in EPS forma
Methods and problems of wavelength-routing in all-optical networks
We give a survey of recent theoretical results obtained for wavelength-routing in all-optical networks. The survey is based on the previous survey in [Beauquier, B., Bermond, J-C., Gargano, L., Hell, P., Perennes, S., Vaccaro, U.: Graph problems arising from wavelength-routing in all-optical networks. In: Proc. of the 2nd Workshop on Optics and Computer Science, part of IPPS'97, 1997]. We focus our survey on the current research directions and on the used methods. We also state several open problems connected with this line of research, and give an overview of several related research directions
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