完整後設資料紀錄
DC 欄位語言
dc.contributor.author江文智en_US
dc.contributor.authorJiang. Wen-Jren_US
dc.contributor.author陳智弘en_US
dc.contributor.author林俊廷en_US
dc.contributor.authorChen, Jyehongen_US
dc.contributor.authorLin, Chun-Tingen_US
dc.date.accessioned2014-12-12T01:40:48Z-
dc.date.available2014-12-12T01:40:48Z-
dc.date.issued2011en_US
dc.identifier.urihttp://140.113.39.130/cdrfb3/record/nctu/#GT079724804en_US
dc.identifier.urihttp://hdl.handle.net/11536/45140-
dc.description.abstractThe increasing demand for wireless video-based interactive and multimedia data services explains why 60-GHz wireless system is a promising candidate to provide multi-gigabit-per-second services. While attempting to generate and transmit 60-GHz signals in a wireless system cost effectively and increase the spectral efficiency to facilitate multi-gigabit-per-second services, this work presents four novel RoF systems based on optical frequency multiplication to reduce the bandwidth requirement of optical transmitters. In this thesis, the performances of RoF systems are investigated by theoretical analysis, VPI WDM-TransmissionMaker simulation, and experimental demonstration. Additionally, we employ RoF systems with OFDM modulation, single carrier modulation, adaptive bit-loading algorithm, I/Q imbalance compensation algorithm, and pre-coded method to successfully circumvent multiple system impairments resulting in significant system performance improvement. Optical I/Q up-conversion system with frequency quadrupling technique for 60-GHz RoF system are proposed. The advantage of the proposed transmitter is that no electrical mixer is needed to generate RF signal. Therefore, I/Q data of RF signals are processed at baseband at the transmitter, which is independent of the carrier frequency of the generated RF signal. Negligible power penalty following 25-km standard single-mode fiber transmission is observed, capable of significantly extending the service range to various applications within a building or campus. Electrical I/Q up-conversion RoF system which is a simple architecture for 60-GHz application are proposed. This system can achieve fiber transmission distances exceeding 3-km and 10-m wireless transmission distance without any chromatic dispersion compensation. Fiber links of 3km are sufficient for most short-range RoF applications such as in-building systems, where low system complexity is very critical. This work also demonstrates the 2×2 MIMO technique for capacity improvement of the proposed system. Both SISO and MIMO systems are achieved record data-rate within 7-GHz license-free band at 60 GHz and BER measurement results are below the FEC limit of 1x10−3. Hybrid access network which support both 60-GHz RoF and FTTx systems using a frequency multiplication technique are presented. One of architectures uses single-electrode MZM with frequency doubling technology. The other architecture uses dual parallel MZM with frequency quadrupling technology. Furthermore, wavelength reuse for uplink data transmission via a RSOA is also demonstrated. Two proposed hybrid access network systems exhibit no RF fading, no narrow-band optical filter is required at the remote node to separate the RF and BB signals, and vector signals are carried. Therefore, the proposed systems are compatible with the current PON system.zh_TW
dc.description.abstractThe increasing demand for wireless video-based interactive and multimedia data services explains why 60-GHz wireless system is a promising candidate to provide multi-gigabit-per-second services. While attempting to generate and transmit 60-GHz signals in a wireless system cost effectively and increase the spectral efficiency to facilitate multi-gigabit-per-second services, this work presents four novel RoF systems based on optical frequency multiplication to reduce the bandwidth requirement of optical transmitters. In this thesis, the performances of RoF systems are investigated by theoretical analysis, VPI WDM-TransmissionMaker simulation, and experimental demonstration. Additionally, we employ RoF systems with OFDM modulation, single carrier modulation, adaptive bit-loading algorithm, I/Q imbalance compensation algorithm, and pre-coded method to successfully circumvent multiple system impairments resulting in significant system performance improvement. Optical I/Q up-conversion system with frequency quadrupling technique for 60-GHz RoF system are proposed. The advantage of the proposed transmitter is that no electrical mixer is needed to generate RF signal. Therefore, I/Q data of RF signals are processed at baseband at the transmitter, which is independent of the carrier frequency of the generated RF signal. Negligible power penalty following 25-km standard single-mode fiber transmission is observed, capable of significantly extending the service range to various applications within a building or campus. Electrical I/Q up-conversion RoF system which is a simple architecture for 60-GHz application are proposed. This system can achieve fiber transmission distances exceeding 3-km and 10-m wireless transmission distance without any chromatic dispersion compensation. Fiber links of 3km are sufficient for most short-range RoF applications such as in-building systems, where low system complexity is very critical. This work also demonstrates the 2×2 MIMO technique for capacity improvement of the proposed system. Both SISO and MIMO systems are achieved record data-rate within 7-GHz license-free band at 60 GHz and BER measurement results are below the FEC limit of 1x10−3. Hybrid access network which support both 60-GHz RoF and FTTx systems using a frequency multiplication technique are presented. One of architectures uses single-electrode MZM with frequency doubling technology. The other architecture uses dual parallel MZM with frequency quadrupling technology. Furthermore, wavelength reuse for uplink data transmission via a RSOA is also demonstrated. Two proposed hybrid access network systems exhibit no RF fading, no narrow-band optical filter is required at the remote node to separate the RF and BB signals, and vector signals are carried. Therefore, the proposed systems are compatible with the current PON system.en_US
dc.language.isoen_USen_US
dc.subject光載微波無線訊號系統zh_TW
dc.subject光纖通訊zh_TW
dc.subject無線通訊zh_TW
dc.subject正交分頻多工系統zh_TW
dc.subject數位訊號zh_TW
dc.subject光纖到府zh_TW
dc.subject多輸出多輸入zh_TW
dc.subject混合式光纖網路zh_TW
dc.subjectRadio-over-Fiberen_US
dc.subjectFiber communicationen_US
dc.subjectWireless communicationen_US
dc.subjectDigital Signal Processingen_US
dc.subject60 GHzen_US
dc.subjectOFDMen_US
dc.subjectSC-FDEen_US
dc.subjectSC-FDMAen_US
dc.subjectHybrid Access Networken_US
dc.subjectMIMOen_US
dc.title超高速60GHz光載微波無線訊號系統zh_TW
dc.titleExtremely High-Capacity 60 GHz Radio-over-Fiber Systemsen_US
dc.typeThesisen_US
dc.contributor.department光電工程學系zh_TW
顯示於類別:畢業論文


文件中的檔案:

  1. 480401.pdf

若為 zip 檔案,請下載檔案解壓縮後,用瀏覽器開啟資料夾中的 index.html 瀏覽全文。