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ISSN 2394-3777 (Print) ISSN 2394-3785 (Online) Available online at www.ijartet.com International Journal of Advanced Research Trends in Engineering and Technology (IJARTET) Vol. II, Special Issue XXIII, March 2015 in association with FRANCIS XAVIER ENGINEERING COLLEGE, TIRUNELVELI DEPARTMENT OF ELECTRONICS AND COMMUNICATION ENGINEERING INTERNATIONAL CONFERENCE ON RECENT ADVANCES IN COMMUNICATION SYSTEMS AND TECHNOLOGIES (ICRACST’15) TH 25 MARCH 2015 Modeling of Twin Core Liquid Filled Photonic Crystal Fiber Coupler with Elliptical Air Holes 1 K.Rohini Priya, 2A.Sivanantha Raja, 3D.Shanmuga sundar, 1 PG Scholar, 2Associate Professor, 3Research Scholar, 1, 2,3 Alagappa Chettiar College of Engineering and Technology, Karaikudi, Abstract— Twin core photonic crystal fiber (PCF) couplers are generally used for dispersion compensation and relatively short coupling length. In this paper, we have theoretically investigated the dispersion and the coupling characteristics of twin-core photonic crystal fiber coupler (PCFC), based on hexagonal-lattice with the elliptical air-holes of uniform dimension and the effective core size are modified with a packing of circular air-holes with liquids. The dependence of the PCFC structural parameters namely air-hole diameter (d) and hole-to-hole distance () along with the liquid packing has been investigated in details. By proper adjustment of the available parameters, a high negative dispersion value of −10,000 ps/nm/km and short coupling length (Lc) of 0.0015m has been achieved with different liquid filling materials. Our proposed fiber will be an excellent device for wavelength division multiplexing, Dispersion compensation applications. Index Terms— Coupling Length (Lc), Dispersion, Effective Refractive Index (neff), Photonic Crystal Fiber Coupler (PCFC), Wavelength Division Multiplexing (WDM). P I. INTRODUCTION hotonic crystal fibers are a new class of optical fibers. They can guide light not only through a well-known modified total internal reflection (MTIR) mechanism, but also using a photonic band gap (PBG) effect [1].Conventional photonic crystal fibers are fibers with an internal periodic structure made of capillaries, which are filled with air, and laid to form a hexagonal lattice. Light can propagate along the fiber in defects of its crystal structure, which are realized by removing one or more central capillaries. Combining the properties of optical fibers and photonic crystals they possess a series of unique properties impossible to achieve in classical step index fibers [2], [3]. Index-guiding PCFs possess the attractive property of great controllability in chromatic dispersion by varying the hole diameter (d) and hole-to-hole spacing (). Control of dispersion in PCFs is very important problem for realistic applications of optical fiber communications. Several designs for the PCF have been proposed to achieve the ultra negative dispersion properties. So far, various PCFs with remarkable dispersion properties such as, zero dispersion wavelengths shifted to the visible and near infrared wavelengths [4], [5], ultra-flattened chromatic dispersion [6], [7] have been reported. A PCF with two adjacent defect areas (serving as two cores) can be used as an optical coupler [8], [9]. These PCF couplers can be realized as a multiplexer-demultiplexer (MUXDEMUX). Only coupling lengths of dual-core PCF couplers were evaluated by using a finite element method [10], [11]. Such photonic crystal fiber couplers (PCFC) favors many of the exciting light guiding features, when compared to that of the fiber namely endless single mode operation over a wide wavelength range, enhanced nonlinearity and desired zero dispersion wavelength, required coupling length and high design flexibility for the desired applications. They present an excellent opportunity to achieve such desired optical characteristics for required applications by suitable adjustment of the PCF structure parameters namely air hole diameter, air hole separation, inter-core separation and core radius. [12],[13]. Dual core PCFC, where light guided through any one of the input cores with inter-core separation is of the order of wavelength, transferred to the neighboring core by the excitation of the evanescent mode as it propagates [14]. In this paper, we have proposed the dispersion along with the coupling length of the twin core liquid filled photonic crystal fiber coupler in which the diameter of air holes is changed by keeping the d/Λ as fixed facilitates the use of PCF coupler for wavelength-selective applications. 186 All Rights Reserved © 2015 IJARTET ISSN 2394-3777 (Print) ISSN 2394-3785 (Online) Available online at www.ijartet.com International Journal of Advanced Research Trends in Engineering and Technology (IJARTET) Vol. II, Special Issue XXIII, March 2015 in association with FRANCIS XAVIER ENGINEERING COLLEGE, TIRUNELVELI DEPARTMENT OF ELECTRONICS AND COMMUNICATION ENGINEERING INTERNATIONAL CONFERENCE ON RECENT ADVANCES IN COMMUNICATION SYSTEMS AND TECHNOLOGIES (ICRACST’15) TH 25 MARCH 2015 II. DESIGN METHODOLOGY A design of high tunable coupler based on silica PCF with elliptical air holes and dual liquid crystal core is presented and analyzed. The suggested design depends on using silica and liquid crystal (LC) of types chloro benzene and benzene respectively and the refractive index of the chloro benzene and benzene is 1.525 and 1.501. In addition, the propagation through the LC-PCF coupler has taken place by the modified total internal reflection mechanism due to the index variation between the core and cladding region. refractive indexes, Dispersion, Coupling length are calculated by using finite element method (FEM) with perfectly matched boundary layers (PML) [15]. The FEM directly solves the Maxwell equations to get an approximate value of the effective refractive index. Once the effective refractive index, neff of the model is obtained by solving Maxwell equations using the software, dispersion and coupling length of PCFCs can be calculated easily. A. Coupling length The coupling length is defined as the minimum longitudinal distance at which maximum power is transferred from the left core to the right core. The coupling length LC can be obtained using the operating wavelength λ, and effective indices of the even and odd modes are neven and nodd as follows. The coupling length is given by Lc 2 n even n odd Fig.1. Schematic diagram of twin core liquid filled PCFC Fig 1 shows cross section of the suggested hexagonal lattice twin core liquid filled PCF coupler. The two identical cores of diameter have been packed with chloro benzene and benzene. All the cladding elliptical air holes have the same diameter d and are arranged with a hole pitch . The separation between the two identical cores is equal to(c= 2) were optimized to obtain the desired values of coupling length and dispersion. The precise coupling length LC of the even and odd stability biased modes and the dispersion value for the proposed model is measured. III. SIMULATION RESULTS AND DISCUSSIONS We have used COMSOL MULTIPHYSICS software to investigate the guiding properties of this PCFC. Effective Fig. 2: Simulation model of twin core liquid filled PCFC The coupling length of the coupler mainly depends upon the inter core separation, core radius and transmitting wavelength. Also the coupling length increases with the increase in the effective core area because of increase in the inner core separation. Thus, for increase in the Λ the coupling length also increases [16]. Increase in coupling length also possesses higher nonlinearity due to its larger effective core area. 187 All Rights Reserved © 2015 IJARTET ISSN 2394-3777 (Print) ISSN 2394-3785 (Online) Available online at www.ijartet.com International Journal of Advanced Research Trends in Engineering and Technology (IJARTET) Vol. II, Special Issue XXIII, March 2015 in association with FRANCIS XAVIER ENGINEERING COLLEGE, TIRUNELVELI DEPARTMENT OF ELECTRONICS AND COMMUNICATION ENGINEERING INTERNATIONAL CONFERENCE ON RECENT ADVANCES IN COMMUNICATION SYSTEMS AND TECHNOLOGIES (ICRACST’15) TH 25 MARCH 2015 Fig.3a. Variation of coupling length for different wavelengths of twin core chlorobenzene filled PCFC Fig. 3a and 3b shows that the coupling length for different wavelengths for both chlorobenzene and benzene filled PCFC and is found to be the maximum for shorter wavelength, due to the decrease in difference between the even and odd modes and minimum for longer wavelengths. Fig.4a. Variation of coupling length with respect to different pitch constants for twin core chlorobenzene filled PCFC Fig. 4a and 4b shows that the coupling length for different pitch constant for both chlorobenzene and benzene filled PCFC. For smaller pitch values the coupling length increases due to larger core area whereas the increase in pitch results in decreased coupling length B. Dispersion To design negative dispersion PCFC for wideband wavelength, we need variable air-hole diameter in the cladding. The same can be achieved with uniform air-hole diameter by filling the cores with liquid of certain refractive indices. Depending on the refractive index of the different liquids such as chlorobenzene and benzene, the effective size of the air-hole diameter can be modified. First the effective indexes neff are solved, and then the dispersion parameter D can be obtained [17] D Fig.3b. Variation of coupling length for different wavelengths of twin core benzene filled PCFC 2 d n eff C .d Where c is the velocity of the light in a vacuum and λ is the operating wavelength [18]. The waveguide dispersion is strongly related to the design parameters of the PCFs and therefore can be optimized to achieve desired dispersion properties. 188 All Rights Reserved © 2015 IJARTET ISSN 2394-3777 (Print) ISSN 2394-3785 (Online) Available online at www.ijartet.com International Journal of Advanced Research Trends in Engineering and Technology (IJARTET) Vol. II, Special Issue XXIII, March 2015 in association with FRANCIS XAVIER ENGINEERING COLLEGE, TIRUNELVELI DEPARTMENT OF ELECTRONICS AND COMMUNICATION ENGINEERING INTERNATIONAL CONFERENCE ON RECENT ADVANCES IN COMMUNICATION SYSTEMS AND TECHNOLOGIES (ICRACST’15) TH 25 MARCH 2015 Fig.4b. Variation of coupling length with respect to different pitch constants for twin core benzene filled PCFC Fig.5b. Variation of dispersion with respect to different wavelengths of twin core benzene filled PCFC Fig 5a and 5b shows dispersion curves. From the figure negative dispersion in the range of -10,000 ps/nm.km to-5000 ps/nm.km for wavelength range of 1000 nm to 1800nm is observed. It is seen that with the structure designed we could achieve a high negative dispersion. For high values of d/, the core becomes small and the dispersion becomes more negative for wavelength between range of 1000nm to 1800nm. IV. CONCLUSION In this paper, a three ring hexagonal lattice PCFC with elliptical air holes having same diameter and the core is filled with chlorobenzene and benzene is proposed. The designed dual core PCFC offers ultra negative dispersion in wide range of wavelength from 1000nm to 1800nm and relatively short coupling length. The proposed PCFC is easy to fabricate due to the same size of air holes. This structure design is more effective and easier because lesser geometrical parameters need to be optimized. Proposed PCF can be suitable for dispersion compensation, coupler and non linear applications. Fig.5a. 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