| 000 | 05665na a2201141 4500 | ||
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| 001 | 64151 | ||
| 003 | koha_MIRAKIL | ||
| 005 | 20221103135316.0 | ||
| 008 | 180522b tu 000 0 | ||
| 040 |
_aCY-NiCIU _btur _cCY-NiCIU _erda |
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| 041 | _aeng | ||
| 090 |
_aYL 311 _bO84 2012 |
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| 100 | _aOtesile, Oluyinka Abayomi | ||
| 245 |
_aA performance analysis of Ethernet over fibre transmission systems _cOluyinka Abayomi Otesile; Supervisor: Mehmet Toycan |
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| 260 |
_a2012 _bCyprus International University _c2012 |
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| 300 |
_aXII, 128 p. _bcol.tab., ill. _c30.5 cm |
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| 336 |
_2rdacontent _atext _btxt |
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| 337 |
_2rdamedia _aunmediated _bn |
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| 338 |
_2rdacarrier _avolume _bnc |
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| 504 | _aIncludes appendix. | ||
| 520 | _a'This thesis describes the optical network as a reliable network technology used for transmission of large bandwidth to the used with a channel called optical fibre via fibre to the home access network.This fibre has been getting closer to the users through the fibre to the home (FTTH) technology.The capacity of the fibre link ends at 400 metres from user\'s home called the distribution point.From this point,copper is used to connect the customer at a mazimum speed of 20Mbps.Today experienced users begin to notice slow bandwidth connections and start to ask for better quality and faster speed connections.But that can only be obtained by replacing the copper in the last few hundred metres by fibre.In this context,the multimode fibre can be deployed to users home so has to maintain the bandwidth level transmitted from the central office with little or no loss. In this thesis,an experiment was carried for a point link so as to calculate the fibre length,connection loss as well as to determine the attenuation in the optical fibre.In addition,properties of mutimode fibre (MMF),single mode fibre (SMF),optical sources as well as other optical transmission component were discussed and simulated using an educational optical design suite to determine the Bit Error Rate in the transmission signal. Keywords:Fibre-to-the-Home,MMF,SMF,Attenuation,BER ' | ||
| 650 | _aAttenuation | ||
| 650 | _aZayıflama | ||
| 650 | _aEthernet | ||
| 650 | _aİnternet | ||
| 700 |
_aSupervisor: Toycan, Mehmet _91656 |
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| 942 |
_2ddc _cTS |
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| 505 | 1 |
_g1 _tCHAPTER 1 |
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| 505 | 1 |
_g1 _tINTRODUCTION |
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| 505 | 1 |
_g1 _tINTRODUCTION |
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| 505 | 1 |
_g2 _tIMPORTANCE OF OPTICAL COMMUNICATION TECHNOLOGY |
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| 505 | 1 |
_g3 _tMOTIVATION |
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| 505 | 1 |
_g4 _tTHESIS OUTLINE |
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| 505 | 1 |
_g5 _tCHAPTER 2 |
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| 505 | 1 |
_g5 _tOPTICAL TECHNOLOGY AT A GLANCE |
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| 505 | 1 |
_g5 _tEVOLUTION OF OPTICAL COMMUNICATION TECHNOLOGY |
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| 505 | 1 |
_g7 _tOPTICAL FIBRE COMMUNICATION SYSTEMS |
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| 505 | 1 |
_g8 _tMerit and Demerit of Optical Fibre Communication Systems |
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| 505 | 1 |
_g9 _tOPTICAL FIBRE |
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| 505 | 1 |
_g10 _tTypes of Optical Fibre(Constituents) |
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| 505 | 1 |
_g11 _tTypes of Optical Fibre(Propagation) |
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| 505 | 1 |
_g14 _tModes in an Optical Fibre |
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| 505 | 1 |
_g14 _tOptical Fibre Loss(Attenuation) |
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| 505 | 1 |
_g15 _tFibre Attenuation Mechanisms |
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| 505 | 1 |
_g16 _tDispersion |
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| 505 | 1 |
_g21 _tOPTİCAL SOURCES |
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| 505 | 1 |
_g21 _tLıght Emitting Diodes(LEDs) |
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| 505 | 1 |
_g21 _tLight Emitting Diodes (LEDs) |
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| 505 | 1 |
_g24 _tLight Amplification by Stimulated Emmission of Radiation(Laser) Diode |
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| 505 | 1 |
_g25 _tTransmission of Light in and Optical Fibre |
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| 505 | 1 |
_g27 _tOPTICAL RECEIVER |
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| 505 | 1 |
_g28 _tOPTICAL COMPONENTS |
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| 505 | 1 |
_g29 _tOptical Amplifiers |
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| 505 | 1 |
_g32 _tMutiplexers & Demultiplexer |
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| 505 | 1 |
_g36 _tOptical Filter |
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| 505 | 1 |
_g37 _tNETWORK PERSPECTIVE |
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| 505 | 1 |
_g37 _tCORE NETWORK |
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| 505 | 1 |
_g38 _tACCESS NETWORK |
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| 505 | 1 |
_g40 _tARCHITECTURE OF ACCESS NETWORK |
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| 505 | 1 |
_g41 _tDISCUSSION |
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| 505 | 1 |
_g43 _tCHAPTER 3 |
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| 505 | 1 |
_g43 _tOPTICAL ACCESS NETWORK |
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| 505 | 1 |
_g44 _tTHE EVOLUTION OF ACCESS NETWORK |
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| 505 | 1 |
_g55 _tFIBRE TO THE HOME TECHNOLOGIES |
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| 505 | 1 |
_g56 _tFTTH SERVICE REQUIREMENT |
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| 505 | 1 |
_g58 _tDescription of an FTTH Network Infrastructure |
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| 505 | 1 |
_g59 _tFTTH ARCHITECTURE |
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| 505 | 1 |
_g63 _tPASSIVE OPTICAL NETWORK |
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| 505 | 1 |
_g66 _tATM PON |
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| 505 | 1 |
_g67 _tBroadband passive optical network (B-PON) |
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| 505 | 1 |
_g68 _tETHERNET PASSIVE OPTICAL NETWORK (EPON) |
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| 505 | 1 |
_g72 _tWAVELENGTH-DIVISION-MULTIPLEXED (WDN) PON |
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| 505 | 1 |
_g74 _tHYBRID WDM/TDM PON |
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| 505 | 1 |
_g76 _tDiscusssion |
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| 505 | 1 |
_g78 _tCHAPTER 4 |
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| 505 | 1 |
_g78 _tEXPERIMENTAL ANALYSIS ON OPTICAL TRANSMISSION |
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| 505 | 1 |
_g78 _tARCHITECTURAL DESIGN |
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| 505 | 1 |
_g81 _tOperating Instruction |
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| 505 | 1 |
_g83 _tEXPERIMENTAL RESULTS |
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| 505 | 1 |
_g85 _tOptical Fibre Connector Loss |
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| 505 | 1 |
_g86 _tAttenuation of the Optical Signal over the Link Length |
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| 505 | 1 |
_g88 _tDetermination of Fibre Link Length and Fibre Attenuation Coefficient |
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| 505 | 1 |
_g90 _tDetermination of Attenuation Limited link Lengths |
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| 505 | 1 |
_g93 _tDISCUSSION |
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| 505 | 1 |
_g94 _tCHAPTER 5 |
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| 505 | 1 |
_g94 _tOPTICAL SYSTEM DESIGN AND SIMULATION |
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| 505 | 1 |
_g95 _tFTTH NETWORK TOPOLOGY |
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| 505 | 1 |
_g97 _tOPTICAL TRANSMISSION LINK WITH EXTERNAL MODULATION TECHNIQUE |
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| 505 | 1 |
_g101 _tOPTICAL TRANSMISSION LINK WITH DIRECT MODULATION TECHNIQUE |
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| 505 | 1 |
_g105 _tBIDIRECTIONAL OF OPTICAL TRANSMISSION LINK |
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| 505 | 1 |
_g108 _tWDM TECHNOLOGY AT A GLANCE |
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| 505 | 1 |
_g112 _tDISCUSSION |
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| 505 | 1 |
_g114 _tCHAPTER 6 |
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| 505 | 1 |
_g114 _tSUMMARY AND CONCLUSION |
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| 505 | 1 |
_g115 _tFUTURE WORK |
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| 505 | 1 |
_g116 _tREFERENCES |
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| 999 |
_c353 _d353 |
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