Quantum stochastic communication with photon-number squeezed light

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Quantum stochastic communication with photon-number squeezed light

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Descriptive

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Title

Quantum stochastic communication with photon-number squeezed light

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Paramanandam

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Joshua

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Joshua Paramanandam

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Michael

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Michael A Parker

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Cheung

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Advisory Committee

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Kin P Cheung

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Zoran

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Zoran Gajic

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Rutgers University

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Graduate School - New Brunswick

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Text

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theses

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2007

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2007

Language

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English

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electronic

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xviii, 264 pages

Abstract

Squeezed states of light have found importance in quantum cryptography due to the no-cloning theorem which prevents two states from being identical to each other. The quantum state with quadrature operators X1 and X2 can be visualized as a point in phase space with the center being l angle X1 r angle, l angle X2 r angle surrounded by an error region which satisfies the minimum uncertainty product l angle Delta X [1 over 2] r angle l angle Delta X [2 over2] r angle=1/16. These states are intrinsically secure since one needs to know which quadrature the measurement is to be made and any attempt to measure the wrong quadratures with arbitrary accuracy would disturb the message. Of course, the eavesdropper cannot simultaneously measure both quadratures with infinite precision for each. This thesis describes a method that not only encodes information in the amplitudes of the quadratures alone but also in the uncertainty of those states. One example of squeezed light is the number-phase squeezed state which satisfying the uncertainity relation l angle Delta n [superscript] 2 r angle l angle Delta phi [superscript] 2 r angle=1/4. An implementation is demonstrated where the information is encoded only in the photon number uncertainity and the phase variable is ignored.
The barrier regulation mechanisms such as macroscopic coulomb blockade in semiconductor junction diodes are responsible for generating photon fluxes with penetration below the standard quantum limit(shot noise level). The thesis describes a comprehensive quantum mechanical Langevin model which details the various mechanisms responsible for producing photon number squeezing from the thermionic emission to the diffusion current limits. Quantities such as the pump fluctuations and cross correlation spectral densities are studied under constant current and constant voltage conditions. The research investigates the generation of photon number squeezed light from high efficiency light emitting diodes. A measurement setup for subshot noise is constructed and each stage is properly calibrated. Experiments were performed to determine the squeezing spectra and Fanofactors for the L2656 and the L9337 high efficiency LEDs. The L9337 produces a squeezing of 1.5dB below the shot noise level over a bandwidth of 25Mhz, the largest known penetration at room temperature. The quantum stochastic communicator is also demonstrated. The research shows that the switching elements used in the modulation of the electrical bias which in turn affect the regulation mechanisms do not affect the statistics of the emitted light under certain conditions. The decoding of the time varying variances is achieved by using time frequency analysis with the aid of the spectrum analyzer.

Note (type = degree)

M.S.

Note (type = bibliography)

Includes bibliographical references (p. 259-263).

Subject (ID = SUBJ1); (authority = RUETD)

Topic

Electrical and Computer Engineering

Subject (ID = SUBJ2); (authority = ETD-LCSH)

Topic

Telecommunication

Subject (ID = SUBJ3); (authority = ETD-LCSH)

Topic

Stochastic processes

Subject (ID = SUBJ4); (authority = ETD-LCSH)

Topic

Squeezed light

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Graduate School - New Brunswick Electronic Theses and Dissertations

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http://hdl.rutgers.edu/1782.2/rucore10001600001.ETD.16755

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ETD_294

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doi:10.7282/T3KP82J9

Genre (authority = ExL-Esploro)

ETD graduate

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The author owns the copyright to this work.

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Joshua Paramanandam

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Rutgers University. Graduate School - New Brunswick

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Non-exclusive ETD license

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I hereby grant to the Rutgers University Libraries and to my school the non-exclusive right to archive, reproduce and distribute my thesis or dissertation, in whole or in part, and/or my abstract, in whole or in part, in and from an electronic format, subject to the release date subsequently stipulated in this submittal form and approved by my school. I represent and stipulate that the thesis or dissertation and its abstract are my original work, that they do not infringe or violate any rights of others, and that I make these grants as the sole owner of the rights to my thesis or dissertation and its abstract. I represent that I have obtained written permissions, when necessary, from the owner(s) of each third party copyrighted matter to be included in my thesis or dissertation and will supply copies of such upon request by my school. I acknowledge that RU ETD and my school will not distribute my thesis or dissertation or its abstract if, in their reasonable judgment, they believe all such rights have not been secured. I acknowledge that I retain ownership rights to the copyright of my work. I also retain the right to use all or part of this thesis or dissertation in future works, such as articles or books.

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