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Journal articles on the topic 'Transparent and translucent optical networks'

Author: Grafiati
Published: 4 June 2021
Last updated: 1 February 2022

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1

Dahan, D., I. Tomkos, U. Mahlab, A. Teixeira, and I. Zacharopoulos. "Optical performance monitoring for translucent/transparent optical networks." IET Optoelectronics 5, no. 1 (February 1, 2011): 1–18. http://dx.doi.org/10.1049/iet-opt.2010.0010.

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2

Azodolmolky, Siamak, Jordi Perello, Marianna Angelou, Fernando Agraz, Luis Velasco, Salvatore Spadaro, Yvan Pointurier, et al. "Experimental Demonstration of an Impairment Aware Network Planning and Operation Tool for Transparent/Translucent Optical Networks." Journal of Lightwave Technology 29, no. 4 (February 2011): 439–48. http://dx.doi.org/10.1109/jlt.2010.2091622.

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3

Martins-Filho, Joaquim F., J. L. de Santana, H. A. Pereira, D. A. R. Chaves, and C. J. A. Bastos-Filho. "Assessment of the Power Series Routing Algorithm in Translucent, Transparent and Opaque Optical Networks." IEEE Communications Letters 16, no. 6 (June 2012): 941–44. http://dx.doi.org/10.1109/lcomm.2012.032612.120232.

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4

Brasileiro, Ítalo, Iallen Santos, André Soares, Ricardo Rabêlo, and Felipe Mazullo. "Ant Colony Optimization Applied to the Problem of Choosing the Best Combination among M Combinations of Shortest Paths in Transparent Optical Networks." Journal of Artificial Intelligence and Soft Computing Research 6, no. 4 (October 1, 2016): 231–42. http://dx.doi.org/10.1515/jaiscr-2016-0017.

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Abstract This paper presents an attempt to solve the problem of choosing the best combination among the M combinations of shortest paths in optical translucent networks. Fixed routing algorithms demands a single route to each pair of nodes. The existence of multiple shortest paths to some pairs of nodes originates the problem of choose the shortest path which fits better the network requests. The algorithm proposed in this paper is an adaptation of Ant Colony Optimization (ACO) metaheuristic and attempt to define the set of routes that fits in an optimized way the network conditions, resulting in reduced number of blocked requests and better adjusted justice in route distribution. A performance evaluation is conducted in real topologies by simulations, and the proposed algorithm shows better performance between the compared algorithms.
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5

Meier, Wolfgang, and Heino Finkelmann. "Liquid Crystal Elastomers with Piezoelectric Properties." MRS Bulletin 16, no. 1 (January 1991): 29–31. http://dx.doi.org/10.1557/s0883769400057870.

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During the last few years, liquid crystalline elastomers (LCEs) have been systematically produced by cross-linking liquid crystalline side-chain polymers. In these networks, a liquid crystalline molecule is fixed at each monomeric unit. LCEs exhibit a novel combination of properties. Due to liquid crystalline groups, they show anisotropic liquid crystalline properties similar to conventional liquid crystals (LCs); but due to the three-dimensional network-structure of the polymer chains, they show typical elastomer properties, such as rubber elasticity or shape stability. One exceptional property of this combination is demonstrated when a mechanical deformation to the LCE causes macroscopically uniform orientation of the long molecular axis of the LC units (the so-called “director”).This response of the LC-phase structure to an applied mechanical field is similar to the effect of electric or magnetic fields on low molecular weight liquid crystals (LMLC), as illustrated in Figure 1. Figure la shows an undeformed LCE. Because of the non-uniform orientation of the director, the sample scatters light strongly so the elastomer is translucent like frosted glass. On the other hand, applying a mechanical field the director becomes uniformly aligned and the sample is transparent (Figure 1b). Such a macroscopically ordered rubber exhibits optical properties very similar to single crystals. These propertie s of LCEs offer new prospects for technical application, e.g., in nonlinear and integrated optics.
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6

Sambo, Nicola, Nicola Andriolli, Alessio Giorgetti, Luca Valcarenghi, Isabella Cerutti, Piero Castoldi, and Filippo Cugini. "GMPLS-controlled dynamic translucent optical networks." IEEE Network 23, no. 3 (May 2009): 34–40. http://dx.doi.org/10.1109/mnet.2009.4939261.

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7

J. Plášil, A. V. Kasatkin, R. Škoda, M. Novák, A. Kallistová, M. Dušek, R. Skála, et al. "Leydetite, Fe(UO2)(SO4)2(H2O)11, a new uranyl sulfate mineral from Mas d’Alary, Lodève, France." Mineralogical Magazine 77, no. 4 (June 2013): 429–41. http://dx.doi.org/10.1180/minmag.2013.077.4.03.

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AbstractLeydetite, monoclinic Fe(UO2)(SO4)2(H2O)11(IMA 2012–065), is a new supergene uranyl sulfate from Mas d'Alary, Lodève, Hérault, France. It forms yellow to greenish, tabular, transparent to translucent crystals up to 2 mm in size. Crystals have a vitreous lustre. Leydetite has a perfect cleavage on (001). The streak is yellowish white. Mohs hardness is ∼2. The mineral does not fluoresce under long- or short-wavelength UV radiation. Leydetite is colourless in transmitted light, non-pleochroic, biaxial, with α = 1.513(2), γ = 1.522(2) (further optical properties could not be measured). The measured chemical composition of leydetite, FeO 9.28, MgO 0.37, Al2O30.26, CuO 0.14, UO340.19, SO321.91, SiO20.18, H2O 27.67, total 100 wt.%, leads to the empirical formula (based on 21 O a.p.f.u.), (Fe0.93Mg0.07Al0.04Cu0.01)Σ1.05(U1.01O2)(S1.96Si0.02)Σ1.98O8(H2O)11. Leydetite is monoclinic, space group C2/c, with a = 11.3203(3), b = 7.7293(2), c = 21.8145(8) Å, β = 102.402(3)°, V = 1864.18(10) Å3, Z = 4, and Dcalc = 2.55 g cm–3. The six strongest reflections in the X-ray powder diffraction pattern are [dobs in Å (I) (hkl)]: 10.625 (100) (002), 6.277 (1) (11), 5.321 (66) (004), 3.549 (5) (006), 2.663 (4) (008), 2.131 (2) (0 0 10). The crystal structure has been refined from single-crystal X-ray diffraction data to R1 = 0.0224 for 5211 observed reflections with [I > 3σ(I)]. Leydetite possesses a sheet structure based upon the protasite anion topology. The sheet consists of UO7 bipyramids, which share four of their equatorial vertices with SO4 tetrahedra. Each SO4 tetrahedron, in turn, shares two of its vertices with UO7 bipyramids. The remaining unshared equatorial vertex of the bipyramid is occupied by H2O, which extends hydrogen bonds within the sheet to one of a free vertex of the SO4 tetrahedron. Sheets are stacked perpendicular to the c direction. In the interlayer, Fe2+ ions and H2O groups link to the sheets on either side via a network of hydrogen bonds. Leydetite is isostructural with the synthetic compound Mg(UO2)(SO4)2(H2O)11. The name of the new mineral honours Jean Claude Leydet (born 1961), an amateur mineralogist from Brest (France), who discovered the new mineral.
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8

Peelen, J. G. J. "Transparent hot-pressed alumina II: Transparent versus translucent alumina." Ceramics International 11, no. 4 (October 1985): 140. http://dx.doi.org/10.1016/0272-8842(85)90152-x.

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9

Gangxiang Shen and R. S. Tucker. "Sparse Traffic Grooming in Translucent Optical Networks." Journal of Lightwave Technology 27, no. 20 (October 2009): 4471–79. http://dx.doi.org/10.1109/jlt.2009.2024174.

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10

Rahman, Quazi, Subir Bandyopadhyay, and Yash Aneja. "Optimal regenerator placement in translucent optical networks." Optical Switching and Networking 15 (January 2015): 134–47. http://dx.doi.org/10.1016/j.osn.2014.09.002.

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11

Ye, Yabin, Tee Cheng, and Chao Lu. "Novel algorithm for upgrading of translucent optical networks." Optics Express 11, no. 23 (November 17, 2003): 3022. http://dx.doi.org/10.1364/oe.11.003022.

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12

Karasan, Ezhan, and Mustafa Arisoylu. "Design of Translucent Optical Networks: Partitioning and Restoration." Photonic Network Communications 8, no. 2 (September 2004): 209–21. http://dx.doi.org/10.1023/b:pnet.0000033979.26662.f4.

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13

Shen, Gangxiang, and Rodney Tucker. "Translucent optical networks: the way forward [Topics in Optical Communications]." IEEE Communications Magazine 45, no. 2 (February 2007): 48–54. http://dx.doi.org/10.1109/mcom.2007.313394.

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14

Fiaschi, Giovanni, and Alfredo Viglienzoni. "Routing Algorithms for Translucent Networks." Fiber and Integrated Optics 27, no. 4 (July 31, 2008): 256–64. http://dx.doi.org/10.1080/01468030802192559.

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15

Ye, Yabin, Teck Chai, Tee Cheng, and Chao Lu. "Algorithms for the design of WDM translucent optical networks." Optics Express 11, no. 22 (November 3, 2003): 2917. http://dx.doi.org/10.1364/oe.11.002917.

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16

Ye, Yabin, Tee Hiang Cheng, and Chao Lu. "Routing and wavelength assignment algorithms for translucent optical networks." Optics Communications 229, no. 1-6 (January 2004): 233–39. http://dx.doi.org/10.1016/j.optcom.2003.11.001.

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17

Wang, Lei, Jie Zhang, Yongli Zhao, and Wanyi Gu. "Study of optical control plane for translucent WDM networks." Photonic Network Communications 20, no. 1 (March 4, 2010): 64–74. http://dx.doi.org/10.1007/s11107-010-0246-2.

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18

Gonzalez-Montoro, Nehuen, Jorge M. Finochietto, and Andrea Bianco. "Resource-aware provisioning strategies in translucent elastic optical networks." Computer Communications 180 (December 2021): 134–45. http://dx.doi.org/10.1016/j.comcom.2021.09.008.

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19

Chekuri, Chandra, Paul Claisse, René-Jean Essiambre, Steven Fortune, Daniel C. Kilper, Wonsuck Lee, Nachi K. Nithi, et al. "Design tools for transparent optical networks." Bell Labs Technical Journal 11, no. 2 (August 4, 2006): 129–43. http://dx.doi.org/10.1002/bltj.20165.

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20

Payne, D., and J. Stern. "Transparent single-mode fiber optical networks." Journal of Lightwave Technology 4, no. 7 (1986): 864–69. http://dx.doi.org/10.1109/jlt.1986.1074812.

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21

Kanj, Matthieu, Esther Le Rouzic, Julien Meuric, and Bernard Cousin. "Optical Power Control in Translucent Flexible Optical Networks With GMPLS Control Plane." Journal of Optical Communications and Networking 10, no. 9 (August 9, 2018): 760. http://dx.doi.org/10.1364/jocn.10.000760.

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22

Sambo, N., N. Andriolli, A. Giorgetti, L. Valcarenghi, F. Cugini, and P. Castoldi. "Accounting for Shared Regenerators in GMPLS-Controlled Translucent Optical Networks." Journal of Lightwave Technology 27, no. 19 (October 2009): 4338–47. http://dx.doi.org/10.1109/jlt.2009.2023812.

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23

Zhao, Juzi, Suresh Subramaniam, and Maite Brandt-Pearce. "Intradomain and Interdomain QoT-Aware RWA for Translucent Optical Networks." Journal of Optical Communications and Networking 6, no. 6 (May 2, 2014): 536. http://dx.doi.org/10.1364/jocn.6.000536.

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24

Coiro, Angelo, Marco Listanti, and Francesco Matera. "Energy-Efficient Routing and Wavelength Assignment in Translucent Optical Networks." Journal of Optical Communications and Networking 6, no. 10 (September 18, 2014): 843. http://dx.doi.org/10.1364/jocn.6.000843.

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25

Zhao, Juzi, Suresh Subramaniam, and Maite Brandt-Pearce. "Efficient and Accurate Analytical Performance Models for Translucent Optical Networks." Journal of Optical Communications and Networking 6, no. 12 (December 1, 2014): 1128. http://dx.doi.org/10.1364/jocn.6.001128.

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26

Zhu, Zuqing, Xiaoliang Chen, Fan Ji, Liang Zhang, Farid Farahmand, and Jason P. Jue. "Energy-Efficient Translucent Optical Transport Networks With Mixed Regenerator Placement." Journal of Lightwave Technology 30, no. 19 (October 2012): 3147–56. http://dx.doi.org/10.1109/jlt.2012.2213296.

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27

Tintor, Vladica, and Jovan Radunović. "Distributed Dijkstra sparse placement routing algorithm for translucent optical networks." Photonic Network Communications 18, no. 1 (August 27, 2008): 55–64. http://dx.doi.org/10.1007/s11107-008-0170-x.

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28

Chaves, Daniel A. R., Renan V. B. Carvalho, Helder A. Pereira, Carmelo J. A. Bastos-Filho, and Joaquim F. Martins-Filho. "Novel strategies for sparse regenerator placement in translucent optical networks." Photonic Network Communications 24, no. 3 (May 11, 2012): 237–51. http://dx.doi.org/10.1007/s11107-012-0384-9.

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29

Xi Yang and B. Ramamurthy. "Dynamic routing in translucent WDM optical networks: the intradomain case." Journal of Lightwave Technology 23, no. 3 (March 2005): 955–71. http://dx.doi.org/10.1109/jlt.2004.841446.

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30

Pointurier, Yvan, Mark Coates, and Michael Rabbat. "Cross-Layer Monitoring in Transparent Optical Networks." Journal of Optical Communications and Networking 3, no. 3 (February 24, 2011): 189. http://dx.doi.org/10.1364/jocn.3.000189.

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31

Chaves, D. A. R., H. A. Pereira, C. J. A. Bastos-Filho, and J. F. Martins-Filho. "SIMTON: A Simulator for Transparent Optical Networks." Journal of Communication and Information Systems 25, no. 1 (April 30, 2010): 1–10. http://dx.doi.org/10.14209/jcis.2010.1.

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32

Mas, C., I. Tomkos, and O. K. Tonguz. "Failure location algorithm for transparent optical networks." IEEE Journal on Selected Areas in Communications 23, no. 8 (August 2005): 1508–19. http://dx.doi.org/10.1109/jsac.2005.852182.

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33

Manousakis, Konstantinos, and Georgios Ellinas. "Attack-aware planning of transparent optical networks." Optical Switching and Networking 19 (January 2016): 97–109. http://dx.doi.org/10.1016/j.osn.2015.03.005.

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34

Morea, Annalisa, Daniel C. Kilper, Dominique Verchere, and Richard Douville. "Wavelength layer recovery in transparent optical networks." Bell Labs Technical Journal 14, no. 4 (February 23, 2010): 193–211. http://dx.doi.org/10.1002/bltj.20411.

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35

Seung-Woo Seo, K. Bergman, and P. R. Prucnal. "Transparent optical networks with time-division multiplexing." IEEE Journal on Selected Areas in Communications 14, no. 5 (June 1996): 1039–51. http://dx.doi.org/10.1109/49.510926.

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36

Maeda, M. W. "Management and control of transparent optical networks." IEEE Journal on Selected Areas in Communications 16, no. 7 (1998): 1008–23. http://dx.doi.org/10.1109/49.725174.

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37

Li, Zhong, and Khiam Aik Khor. "Transparent Hydroxyapatite Obtained through Spark Plasma Sintering: Optical and Mechanical Properties." Key Engineering Materials 631 (November 2014): 51–56. http://dx.doi.org/10.4028/www.scientific.net/kem.631.51.

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Transparent bioceramics have great potential for applications in the biomedical field as they facilitate direct observation of the interactions at biomaterial – cell / tissue interfaces. Thus far, sintering of transparent hydroxyapatite (HA) usually involves application of extraordinarily high pressure and / or long duration. This study attempts to fabricate transparent HA by a direct and fast Spark Plasma Sintering (SPS) process using three different types of raw powder: micro-spheres (MS), nanorods (NR) and nanospheres (NS). The optical and mechanical properties of the sintered pellets were examined and compared. The highest total forward transmittance (TFT) showed by sintered MS pellet (~2 mm thick) was 85% in the visible spectrum, whereas sintered NR and NS pellets were either translucent or opaque. Although lowest degree of transparency was observed for NS pellets, they demonstrated highest Young’s modulus (E), hardness (H) and fracture toughness (KIC). The eminent KIC of NS pellets benefited mainly from its self-toughened microstructure.
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38

WANG, Xin, Tithra CHAP, Sugang XU, and Yoshiaki TANAKA. "Toward Distributed Translucent Wavelength Switched Optical Networks under GMPLS/PCE Architecture." IEICE Transactions on Communications E95-B, no. 3 (2012): 740–51. http://dx.doi.org/10.1587/transcom.e95.b.740.

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39

Garcia-Manrubia, Belen, Pablo Pavon-Marino, Ramon Aparicio-Pardo, Mirosław Klinkowski, and Davide Careglio. "Offline Impairment-Aware RWA and Regenerator Placement in Translucent Optical Networks." Journal of Lightwave Technology 29, no. 3 (February 2011): 265–77. http://dx.doi.org/10.1109/jlt.2010.2098393.

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40

Bao, Ning-Hai. "Impairment aware sharing constraint relaxed path protection in translucent optical networks." Optical Engineering 51, no. 4 (April 6, 2012): 045002. http://dx.doi.org/10.1117/1.oe.51.4.045002.

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41

Pedrola, Oscar, Davide Careglio, Miroslaw Klinkowski, Josep Solé-Pareta, and Keren Bergman. "Cost Feasibility Analysis of Translucent Optical Networks With Shared Wavelength Converters." Journal of Optical Communications and Networking 5, no. 2 (January 7, 2013): 104. http://dx.doi.org/10.1364/jocn.5.000104.

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42

Chen, Xiaoliang, Fan Ji, Yanan Wu, and Zuqing Zhu. "Energy-Efficient Resilience in Translucent Optical Networks With Mixed Regenerator Placement." Journal of Optical Communications and Networking 5, no. 7 (June 28, 2013): 741. http://dx.doi.org/10.1364/jocn.5.000741.

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43

Chen, Ying, Ataul Bari, and Arunita Jaekel. "Optimal regenerator assignment and resource allocation strategies for translucent optical networks." Photonic Network Communications 23, no. 1 (October 11, 2011): 16–24. http://dx.doi.org/10.1007/s11107-011-0331-1.

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44

Iyer, Sridhar, and Shree Prakash Singh. "Performance Analysis of Translucent Space Division Multiplexing Based Elastic Optical Networks." International Journal of Advances in Telecommunications, Electrotechnics, Signals and Systems 8, no. 1 (February 12, 2019): 8. http://dx.doi.org/10.11601/ijates.v8i1.270.

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The required upgradation of the network capacity of the single-mode fiber which is constrained by the non-linear Shannon’s limit, and the capacity provisioning needed by the future diverse Internet traffic can be resolved by the adoption of the Space Division Multiplexing (SDM) based Elastic Optical Networks (EONs) (SDM-b-EONs). In the current work, we focus on the performance analysis of a SDM-b-EON in which translucent lightpaths are routed through the spectral super-channels over the spatial single-mode fiber(s) bundle(s) links. In regard to regeneration, we investigate three scenarios which differ in their regeneration variability level in addition to the adjustment of modulation formats according to transmission route characteristics. We conduct extensive simulations considering an online traffic case and two realistic network topologies with different numbers of (i) fibers in every link, and (ii) transceivers available within SDM-b-EON. The obtained results demonstrate that when regeneration is conducted with complete flexibility and simultaneously the modulation format conversion is also permitted at every SDM-b-EON node both, largest traffic volume amounts can be provisioned, and significant SDM-b-EON performance scaling can be obtained with a corresponding increase in the utilized fibers amount.
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45

Sun, Zeyu. "Propagation of all-optical crosstalk attack in transparent optical networks." Optical Engineering 50, no. 8 (August 1, 2011): 085002. http://dx.doi.org/10.1117/1.3607412.

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46

Teimoori, Hassan, Dimitrios Apostolopoulos, Kyriakos G. Vlachos, CÉdric Ware, Dimitrios Petrantonakis, Leontios Stampoulidis, Hercules Avramopoulos, and Didier Erasme. "Optical-Logic-Gate Aided Packet-Switching in Transparent Optical Networks." Journal of Lightwave Technology 26, no. 16 (August 2008): 2848–56. http://dx.doi.org/10.1109/jlt.2008.925065.

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47

Roudas, I., N. Antoniades, T. Otani, T. E. Stern, R. E. Wagner, and D. Q. Chowdhury. "Error probability of transparent optical networks with optical multiplexers/demultiplexers." IEEE Photonics Technology Letters 13, no. 11 (November 2001): 1254–56. http://dx.doi.org/10.1109/68.959381.

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48

Shen, G., W. V. Sorin, and R. S. Tucker. "Cross-Layer Design of ASE-Noise-Limited Island-Based Translucent Optical Networks." Journal of Lightwave Technology 27, no. 11 (June 2009): 1434–42. http://dx.doi.org/10.1109/jlt.2008.2005509.

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49

Manousakis, K., P. Kokkinos, K. Christodoulopoulos, and E. Varvarigos. "Joint Online Routing, Wavelength Assignment and Regenerator Allocation in Translucent Optical Networks." Journal of Lightwave Technology 28, no. 8 (April 2010): 1152–63. http://dx.doi.org/10.1109/jlt.2010.2041527.

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50

Zou, Rujia, Hiroshi Hasegawa, Masahiko Jinno, and Suresh Subramaniam. "Link-protection and FIPP p-cycle designs in translucent elastic optical networks." Journal of Optical Communications and Networking 12, no. 7 (April 21, 2020): 163. http://dx.doi.org/10.1364/jocn.382561.

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