93 research outputs found
Memory Effects and Scaling Properties of Traffic Flows
Traffic flows are studied in terms of their noise of sound, which is an
easily accessible experimental quantity. The sound noise data is studied making
use of scaling properties of wavelet transforms and Hurst exponents are
extracted. The scaling behavior is used to characterize the traffic flows in
terms of scaling properties of the memory function in Mori-Lee stochastic
differential equations. The results obtained provides for a new theoretical as
well as experimental framework to characterize the large-time behavior of
traffic flows. The present paper outlines the procedure by making use of
one-lane computer simulations as well as sound-data measurements from a real
two-lane traffic flow. We find the presence of conventional diffusion as well
as 1/f-noise in real traffic flows at large time scales.Comment: 3 figure
Rapid Steady State Convergence for Quantum Systems Using Time-Delayed Feedback Control
We propose a time-delayed feedback control scheme for open quantum systems
that can dramatically reduce the time to reach steady state. No measurement is
performed in the feedback loop, and we suggest a simple all-optical
implementation for a cavity QED system. We demonstrate the potential of the
scheme by applying it to a driven and dissipative Dicke model, as recently
realized in a quantum gas experiment. The time to reach steady state can then
reduced by two orders of magnitude for parameters taken from experiment, making
previously inaccessible long time attractors reachable within typical
experimental run times. The scheme also offers the possibility of slowing down
the dynamics, as well as qualitatively changing the phase diagram of the
corresponding physical system.Comment: 25 pages, 9 figures. Invited paper in "Focus on Coherent Control of
Complex Quantum Systems", Eds. B. Whaley and G. Milburn. PS: Preview on OSX
struggles with opening some of the figures with a lot of data in the
Theory of the Microscopic Maser Phase Transitions
Phase diagrams of the micromaser system are mapped out in terms of the physical parameters at hand like the atom cavity transit time, the atom-photon frequency detuning, the number of thermal photons and the probability for a pump atom to be in its excited state. Critical fluctuations are studied in terms of correlation measurements on atoms having passed through the micromaser or on the microcavity photons themselves. At sufficiently large values of the detuning we find a ``twinkling'' mode of the micromaser system. Detailed properties of the trapping states are also presented
Interference of Light in a Michelson-Morley Interferometer: A Quantum Optical Approach
The temporal coherence interference properties of light as revealed by single detector intensity measurements in a Michelson-Morley interferometer (MMI) is often described in terms of classical optics. We show, in a pedagogical manner, how such features of light also can be understood in terms of a more general quantum-optics framework. If a thermal reference source is used in the MMI local oscillator port in combination with a thermal source in the signal port, the interference pattern revealed by single detector intensity measurements shows a distinctive dependence on the differences in the temperature of the two sources. A related method has actually been used to perform high-precision measurements of the cosmic microwave background radiation. The general quantum-optics framework allows us to consider any initial quantum state. As an example, we consider the interference of single photons as a tool to determine the peak angular-frequency of a single-photon pulse interfering with a single-photon reference pulse. A similar consideration for laser pulses, in terms of coherent states, leads to a different response in the detector. The MMI experimental setup is therefore an example of an optical device where one, in terms of intensity measurements, can exhibit the difference between classical and quantum-mechanical light
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