Fibre optic interferometric thermometers and multiplexed systems

Farahi, F.

January 1988

No description available.

535

Fibre optic temperature sensor

Spread spectrum techniques for multiplexing and ranging applications

Street, Andrew M.

January 1994

No description available.

621.382

Fibre optic sensor networks

Fibre optic microsensors for intracellular chemical measurements

McCulloch, Scott

January 2000

No description available.

621.381045

Miniaturised fibre optic sensor

Acoustic penetration of the seabed, with particular application to the detection of non- metallic buried cables

Evans, Ruthven Clive Philip

January 1999

No description available.

621.3895

Fibre optic; Acousto-optic; Geoacoustics

Photoacoustic and photothermal detection of trace compounds in water

Hodgkinson, Jane

January 1998

No description available.

621.381045

Laser cooling in the condensed phase

Clark, Joanne Louise

January 1997

No description available.

535

Theoretical database for the prediction of rime-ice and wet-snow overload on overhead transmission lines

Bibby, Ian Paul

January 1995

No description available.

658.05

OHLC; Accretion; Fibre optic cable

Thermal fibre sensors for aerodynamic measurements

Kidd, Stephen Robert

January 1994

No description available.

621.381045

A high-flux solar concentrating system

Mouzouris, Michael

07 1900

Thesis (MScEng)--University of Kwa-Zulu Natal, 2011. / ENGLISH ABSTRACT: This research investigates the collection of concentrating solar energy and its transmission through optical fibres for use in high temperature applications such as lunar in-situ resource utilisation (ISRU) programmes, solar power generation and solar surgery. A prototype collector, known as the Fibre Optic Concentrating Utilisation System (FOCUS), has been developed and is capable of delivering high energy fluxes to a remote target. Salient performance results include flux concentrations approaching 1000 suns with an overall optical efficiency of 13%, measured from the inlet of the collector to the fibre outlet. The system comprises a novel solar concentrator designed to inject solar energy into a four metre long fibre optic cable for the transmission of light to the target. A nonimaging reflective lens in the form of a 600 mm diameter ring array concentrator was chosen for the collection of solar energy. Advantageous characteristics over the more common parabolic dish are its rearward focusing capacity and single stage reflection. The ring array comprises a nested set of paraboloidal elements constructed using composite material techniques to demonstrate a low-cost, effective fabrication process. At concentrator focus, a fibre optic cable of numerical aperture 0.37 is positioned to transport the highly concentrated energy away from the collector. The cable is treated to withstand UV exposure and high solar energy flux, and allows flexibility for target positioning. A computational analysis of the optical system was performed using ray tracing software, from which a predictive model of concentrator performance was developed to compare with experimental results. Performance testing of FOCUS was conducted using energy balance principles in conjunction with a flat plate calorimeter. Temperatures approaching 1500°C and flux levels in the region of 1800 suns were achieved before injection to the cable, demonstrating the optical system‟s suitability for use in high flux applications. During testing, peak temperatures exceeding 900°C were achieved at the remote target with a measured flux of 104 W/cm2 at the cable outlet. The predicted optical efficiency was 22%, indicating that further refinements to the ray trace model are necessary, specifically with regard to losses at the inlet to the cable. FOCUS was able to demonstrate its usefulness as a test bed for lunar in-situ resource utilisation technologies by successfully melting a lunar soil simulant. The system permits further terrestrial-based ISRU research, such as oxygen production from regolith and the fabrication of structural elements from lunar soil. / Sponsored by the Centre for Renewable and Sustainable Energy Studies

Fibre Optic

Solar

Energy

Lunar

Generation

Determining Optimal Fibre-optic Network Architecture using Bandwidth Forecast, Competitve Market, and Infrastructure-efficienct Models used to Study Last Mile Economics

Saeed, Muhammad

20 December 2011

The study focuses on building a financial model for a telecommunications carrier to guide it towards profitable network investments. The model shows optimal access-network topography by comparing two broadband delivery techniques over fibre technology. The study is a scenario exploration of how a large telecommunication company deploying fibre will see its investment pay off in a Canadian residential market where cable operators are using competing technology serving the same bandwidth hungry consumers. The comparison is made at the last mile by studying how household densities, bandwidth demand, competition, geographic and deployment considerations affect the economics of fibre technology investment. Case comparisons are made using custom models that extend market forecasts to estimate future bandwidth demand. Market uptake is forecasted using sigmoid curves in an environment where competing and older technologies exist. Sensitivity analyses are performed on each fibre technology to assess venture profitability under different scenarios.

FTTx

Fibre Optic

Last Mile

Bandwidth

0796