Demonstration of negative dispersion fibers for DWDM metropolitan area networks

Tomkos, Ioannis; Chowdhury, D.Q.; Conradi, J.; Culverhouse, D.O.; Ennser, K.; Giroux, Cynthia B.; Hallock, Bradley S.; Kennedy, T.; Kruse, A.; Kumar, Shiva; Lascar, N.; Roudas, I.; Sharma, Manish; Vodhanel, R.S.; Wang, C.-C.

doi:10.1109/2944.962268

Cited by 46 publications

(18 citation statements)

References 25 publications

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“…The signal observations at the outputs of the 50 km (MS1) and 99.7 km (cascaded MS1 and MS2) lengths of dispersion-matched fiber indicate good signal recovery at the receiver; clear open eyes and good OSNRs were observed. An improved extinction ratio was observed after the 99.7 km of cascaded fiber: the net negative chromatic dispersion of the link improves the directly modulated optical signal from the laser; this observation agrees well with other reports [17]. The OSNR was, however, degraded by 2.38 dB by transmission along MS1, and a further 0.36 dB by transmission over the second matched span (MS2).…”

Section: Key Resultssupporting

confidence: 81%

“…With the IDF, we were able to recover error-free transmissions for all PRBSs used. The net negative dispersion of the matched transmission spans was observed to improve transmission performance beyond that obtained at the transmitter output; this result does not conflict with previously reported results for transmission of directly modulated laser signals over links with net negative chromatic dispersion [17].…”

Section: Key Resultscontrasting

confidence: 33%

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Free-Running 1550 nm VCSEL for 107 Gb/s Transmission in 997 km PON

Prince¹,

Gibbon

et al. 2011

J. Opt. Commun. Netw.

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Abstract-We present a cooler-less, free-running 1550 nm vertical cavity surface emitting laser (VCSEL) directly modulated at 10.7 Gb/s. We also report on error-free transmission through 40 km of standard single-mode optical fiber, achieved without the use of dispersion-mitigation or mid-span amplification. Inverse-dispersion fiber was utilized to realize a dispersion-matched 99.7 km optical access uplink supporting error-free transmission with 27 dB loss margin. These results indicate the feasibility of implementing cooler-less long-wavelength VCSEL devices in long-reach optical access networks.Index Terms-Passive optical network; Vertical cavity surface emitting laser.

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Section: Key Resultssupporting

confidence: 81%

Section: Key Resultscontrasting

confidence: 33%

Free-Running 1550 nm VCSEL for 107 Gb/s Transmission in 997 km PON

Prince¹,

Gibbon

et al. 2011

J. Opt. Commun. Netw.

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“…Indeed special fiber designs have been developed which have normal dispersion in the 1550-nm region and hence can be used with chirped directly modulated lasers for extended propagation distances without suffering from dispersive effects. Such fibers could be very interesting especially in metro networks [19].…”

Section: Propagation Of Chirped Pulses Through An Optical Fibermentioning

confidence: 99%

“…(19)] by τ rms = τ / √ 2. For a communication system working at a bit rate of B bits per second, the bit period is 1/B s. In order to keep the interference between adjacent bits below a specified level, the rms width of the dispersed pulse needs to be kept below a certain fraction of the bit period B.…”

Section: Maximum Bit Ratementioning

confidence: 99%

Modeling dispersion in optical fibers: applications to dispersion tailoring and dispersion compensation

Thyagarajan

Pal

2007

J Optic Comm Rep

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The phenomenon of temporal pulse dispersion, which is a key characteristic of an optical fiber communication system is described from the first principles. Beginning with the basics of dispersion in a bulk medium, these concepts are then applied to propagation of a pulse in an optical fiber. Details of modeling dispersion are then described in the context of dispersion tailoring and dispersion compensation with a view to form the foundation for subsequent chapters on dispersion compensation that follow in this report. Basic physics behind the design target for dispersion compensating fibers is discussed, which should be useful to fiber designers.

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“…A number of approaches have been used to improve transmission performance using directly modulated lasers, including cutting down the chirp externally using a narrow bandpass filter [Yan 2005] and the deployment of a negative dispersion fiber [Tomkos 2001a, Tomkos 2002. However, typical metro and access networks are made up of a conventional single-mode fiber (SMF) and because of the cost and difficulty (or lack of feasibility) in changing embedded fiber links, a method that enhances system performance requiring only the modification of one or both of the endpoints of a link is a critical requirement.…”

Section: Introductionmentioning

confidence: 99%