35,632 research outputs found
An approach to nonstandard quantum mechanics
We use nonstandard analysis to formulate quantum mechanics in
hyperfinite-dimensional spaces. Self-adjoint operators on
hyperfinite-dimensional spaces have complete eigensets, and bound states and
continuum states of a Hamiltonian can thus be treated on an equal footing. We
show that the formalism extends the standard formulation of quantum mechanics.
To this end we develop the Loeb-function calculus in nonstandard hulls. The
idea is to perform calculations in a hyperfinite-dimensional space, but to
interpret expectation values in the corresponding nonstandard hull. We further
apply the framework to non-relativistic quantum scattering theory. For
time-dependent scattering theory, we identify the starting time and the
finishing time of a scattering experiment, and we obtain a natural separation
of time scales on which the preparation process, the interaction process, and
the detection process take place. For time-independent scattering theory, we
derive rigorously explicit formulas for the M{\o}ller wave operators and the
S-Matrix
Pions: Experimental Tests of Chiral Symmetry Breaking
Based on the spontaneous breaking of chiral symmetry, chiral perturbation
theory (ChPT) is believed to approximate confinement scale QCD. Dedicated and
increasingly accurate experiments and improving lattice calculations are
confirming this belief, and we are entering a new era in which we can test
confinement scale QCD in some well chosen reactions. This is demonstrated with
an overview of low energy experimental tests of ChPT predictions of
scattering, pion properties, N scattering and electromagnetic pion
production. These predictions have been shown to be consistent with QCD in the
meson sector by increasingly accurate lattice calculations. At present there is
good agreement between experiment and ChPT calculations, including the
and N s wave scattering lengths and the lifetime. Recent,
accurate pionic atom data are in agreement with chiral calculations once
isospin breaking effects due to the mass difference of the up and down quarks
are taken into account, as was required to extract the scattering
lengths. In addition to tests of the theory, comparisons between and
N interactions based on general chiral principles are discussed. Lattice
calculations are now providing results for the fundamental, long and
inconclusively studied, N term and the contribution of the
strange quark to the mass of the proton. Increasingly accurate experiments in
electromagnetic pion production experiments from the proton which test ChPT
calculations (and their energy region of validity) are presented. These
experiments are also beginning to measure the final state N interaction.
This paper is based on the concluding remarks made at the Chiral Dynamics
Workshop CD12 held at Jefferson Lab in Aug. 2012.Comment: 13 pages, 8 fig
Automatic communication signal monitoring system
A system is presented for automatic monitoring of a communication signal in the RF or IF spectrum utilizing a superheterodyne receiver technique with a VCO to select and sweep the frequency band of interest. A first memory is used to store one band sweep as a reference for continual comparison with subsequent band sweeps. Any deviation of a subsequent band sweep by more than a predetermined tolerance level produces an alarm signal which causes the band sweep data temporarily stored in one of two buffer memories to be transferred to long-term store while the other buffer memory is switched to its store mode to assume the task of temporarily storing subsequent band sweeps
Dynamic Approximate All-Pairs Shortest Paths: Breaking the O(mn) Barrier and Derandomization
We study dynamic -approximation algorithms for the all-pairs
shortest paths problem in unweighted undirected -node -edge graphs under
edge deletions. The fastest algorithm for this problem is a randomized
algorithm with a total update time of and constant
query time by Roditty and Zwick [FOCS 2004]. The fastest deterministic
algorithm is from a 1981 paper by Even and Shiloach [JACM 1981]; it has a total
update time of and constant query time. We improve these results as
follows: (1) We present an algorithm with a total update time of and constant query time that has an additive error of
in addition to the multiplicative error. This beats the previous
time when . Note that the additive
error is unavoidable since, even in the static case, an -time
(a so-called truly subcubic) combinatorial algorithm with
multiplicative error cannot have an additive error less than ,
unless we make a major breakthrough for Boolean matrix multiplication [Dor et
al. FOCS 1996] and many other long-standing problems [Vassilevska Williams and
Williams FOCS 2010]. The algorithm can also be turned into a
-approximation algorithm (without an additive error) with the
same time guarantees, improving the recent -approximation
algorithm with running
time of Bernstein and Roditty [SODA 2011] in terms of both approximation and
time guarantees. (2) We present a deterministic algorithm with a total update
time of and a query time of . The
algorithm has a multiplicative error of and gives the first
improved deterministic algorithm since 1981. It also answers an open question
raised by Bernstein [STOC 2013].Comment: A preliminary version was presented at the 2013 IEEE 54th Annual
Symposium on Foundations of Computer Science (FOCS 2013
The Limit Behavior Of The Trajectories of Dissipative Quadratic Stochastic Operators on Finite Dimensional Simplex
The limit behavior of trajectories of dissipative quadratic stochastic
operators on a finite-dimensional simplex is fully studied. It is shown that
any dissipative quadratic stochastic operator has either unique or infinitely
many fixed points. If dissipative quadratic stochastic operator has a unique
point, it is proven that the operator is regular at this fixed point. If it has
infinitely many fixed points, then it is shown that limit set of the
trajectory is contained in the set of fixed points.Comment: 14 pages, accepted in Difference Eq. App
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