WAVES AND VIBRATIONS IN INHOMOGENEOUS STRUCTURES ...

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58 References J. Jiang, J. Cai, G. P. Nordin, and L. Li. Parallel microgenetic algorithm design for photonic crystal and waveguide structures. Optics Letters, 28(23):2381–2383, 2003. J. D. Joannopoulos, R. D. Meade, and J. N. Winn. Photonic Crystals. Princeton University Press, New Jersey, 1995. C. S. Jog. Topology design of structures subjected to periodic loading. Journal of Sound and Vibration, 253(3):687–709, 2002. S. John. Strong localization of photons in certain disordered dielectric superlattices. Physical Review Letters, 58(23):2486–2489, 1987. W. J. Kim and J. D. O’Brien. Optimization of a two-dimensional photonic-crystal waveguide branch by simulated annealing and the finite element method. J. Opt. Soc. Am. B, 21(2):289–295, 2004. G. Kiziltas, D. Psychoudakis, J. L. Volakis, and N. Kikuchi. Topology design optimization of dielectric substrates for bandwidth improvement of a patch antenna. International Journal of Modern Physics, 51(10):2732–2743, 2003. M. S. Kushwaha. Classical band structure of periodic elastic composites. International Journal of Modern Physics, 10(9):977–1094, 1996. J. W. LeeandY. Y. Kim. Optimal distribution ofholes inapartitioninterfacing two cavities for controlling the eigenfrequencies by acoustical topology optimization. Computer Methods in Applied Mechanics and Engineering,198(27–29):2175–2189, 2009. Y. Z. Liu, D. L. Yu, L. Li, H. G. Zhao, J. H. Wen, and X. S. Wen. Design guidelines for flexural wave attenuation of slender beams with local resonators. Physics Letters A, 362(5–6):344–347, 2007. Z. Liu, X. Zhang, Y. Mao, Y. Y. Zhu, Z. Yang, C. T. Chan, and P. Sheng. Locally resonant sonic materials. Science, 289:1734–1736, 2000. Z.-D. Ma, N. Kikuchi, and I. Hagiwara. Structural topology and shape optimization for a frequency response problem. Computational Mechanics, 13:157–174, 1993. Z.-D. Ma, H.-C. Cheng, and N. Kikuchi. Structural design for obtaining desired eigenfrequencies by using the topology and shape optimization method. Computing Systems in Engineering, 5(1):77–89, 1994. F. Maestre andP. Pedregal. Dynamicmaterials foranoptimal design problem under the two-dimensional wave eqaution. Discrete and Continuous Dynamical Systems - Series A, 23:973–990, 2009.
References 59 F. Maestre, A. Münch, and P. Pedregal. A spatio-temporal design problem for a damped wave equation. SIAM Journal of Applied Mathematics, 68:109–132, 2007. C. Manolatou, S. G. Johnson, S. Fan, P. R. Villeneuve, H. A. Haus, and J. D. Joannopoulos. High-density integrated optics. Journal of Lightwave Technology, 17(9):1682–1692, 1999. A. Marathe and A. Chatterjee. Wave attenuation in nonlinear periodic structures using harmonic balance and multiple scales. Journal of Sound and Vibration, 289: 871–888, 2006. P. G. Martinsson and A. B. Movchan. Vibrations of lattice structures and phononic band gaps. The Quarterly Journal of Mechanics and Applied Mathematics, 56(1): 45–64, 2003. D. J. Mead. Wave propagation in continuous periodic structures: Research contributions from southampton, 1964–1995. Journal of Sound and Vibration, 190(3): 495–524, 1996. A. Mekis, J. C. Chen, I. Kurland, S. Fan, P. R. Villeneuve, and J. D. Joannopoulos. High transmission through sharp bends in photonic crystal waveguides. Physical Review Letters, 77(18):3787–3790, 1996. B. Miao, C. Chen, S. Shi, J. Murakowski, and D. W. Prather. High-efficiency broad-band transmission through a double-60 0 bend in a planar photonic crystal single-line defect waveguide. IEEE Photonics Technology Letters, 16(11):2469– 2471, 2004. S. Min, N. Kikuchi, Y. C. Park, S. Kim, and S. Chang. Optimal topology design of structures under dynamic loads. Structural Optimization, 17:208–218, 1999. J. Moosburger, M. Kamp, A. Forchel, S. Olivier, H. Benisty, C. Weisbuch, and U. Oesterle. Enhanced transmission through photonic-crystal-based bent waveguides by bend engineering. Applied Physics Letters, 79(22):3579–3581, 2001. T. Nomura, K. Sato, K. Taguchi, T. Kashiwa, and S. Nishiwaki. Structural topology optimization for the design of broadband dielectric resonator antennas using the finite difference time domain technique. Applied Physics Letters, 71(11):1261– 1296, 2007. T. Nomura, S. Nishiwaki, K. Sato, and K. Hirayama. Topology optimization for the design of periodic microstructures composed of electromagnetic materials. Finite Elements In Analysis And Design, 45(3):210–226, 2009. S. Olivier, H. Benisty, C. Weisbuch, C. J. M. Smith, T. F. Krauss, R. Houdré, and U. Oesterle. Improved 60 0 bend transmission of submicron-width waveguides
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WAVES AND VIBRATIONS IN INHOMOGENEO
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Denne afhandling er af Danmarks Tek
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List of Thesis Papers [1] J. S. Jen
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Contents Preface i List of Thesis P
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Chapter 1 Introduction This thesis
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eplacemen Phononic and photonic ban
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Optimal material distribution - top
Page 17 and 18: Chapter 2 The bandgap phenomenon In
Page 19 and 20: 2.1 Band diagram and forced vibrati
Page 21 and 22: 2.3 Experimental demonstration 11 F
Page 23 and 24: y 2.5 Nonlinearities 13 Response in
Page 25 and 26: Relations to recent work 15 Amplitu
Page 27 and 28: Chapter 3 Bandgap structures as opt
Page 29 and 30: 3.1 Vibration-quenching structures
Page 31 and 32: 3.2 Maximizing wave reflection 21 d
Page 33 and 34: 3.4 Maximizing wave dissipation 23
Page 35 and 36: 3.4 Maximizing wave dissipation 25
Page 37 and 38: 3.5 Plate structures 27 a) b) Figur
Page 39 and 40: 3.6 Acoustic design 29 design domai
Page 41 and 42: Chapter 4 Optimization of photonic
Page 43 and 44: 4.1 Waveguide bends and junctions 3
Page 45 and 46: 4.2 Photonic crystal building block
Page 47 and 48: 4.2 Photonic crystal building block
Page 49 and 50: 4.4 Ridge waveguides 39 w ε =1 ?
Page 51 and 52: Relations to recent work 41 wave in
Page 53 and 54: Chapter 5 Advanced optimization pro
Page 55 and 56: 5.1 Padé approximants 45 h 2h A f
Page 57 and 58: 5.3 Space-time topology optimizatio
Page 59 and 60: 5.3 Space-time topology optimizatio
Page 61 and 62: Relations to recent work 51 Figure
Page 63 and 64: Chapter 6 Conclusions In the first
Page 65 and 66: References K. Asakawa, Y. Sugimoto,
Page 67: References 57 W. R. Frei, D. A. Tor
Page 71 and 72: References 61 O. Sigmund, J. S. Jen
Page 73 and 74: References 63 X. M. Zhou and G. K.
Page 75 and 76: Dansk resumé 65 i strukturen. En r
Page 77 and 78: 1054 ARTICLE IN PRESS J.S. Jensen /
Page 81 and 82: 1058 fundamental eigenfrequency o
Page 83 and 84: 1060 ðo 2 y;j;k ARTICLE IN PRESS J
Page 85 and 86: 1062 local resonator and splits up
Page 87 and 88: 1064 3.1. Model equations A finite
Page 89 and 90: 1066 FRF (dB) 150 100 50 0 -50 -100
Page 91 and 92: 1068 3.3. Example 2: a 2-D waveguid
Page 103 and 104: wave-guiding properties show promis
Page 105 and 106: (a) (b) Acceleration response (dB)
Page 107 and 108: B.S. Lazarov, J.S. Jensen / Interna
Page 109 and 110: ω/κ ω/κ 1.5 1.4 1.3 1.2 1.1 1 0
Page 111 and 112: [B 2000 ] [B 2000 ] [B 2000 ] 0.25
Page 113 and 114: [B 400 ] 0.25 0.2 0.15 0.1 0.05 B.S
Page 115 and 116: 1002 (a) (c) (e) 0. Sigmund and J.
Page 117 and 118: 1004 O. Sigmund and J. S. Jensen wh
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1006 (a) - - - - - - _ - - - - I I
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1008 O. Sigmund and J. S. Jensen we
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1010 O. Sigmund and J. S. Jensen Th
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1012 (a) (b) O. Sigmund and J. S. J
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1014 . ct . _ a) Q^ s^c "3
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1016 O. Sigmund and J. S. Jensen (a
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1018 O. Sigmund and J. S. Jensen 4.
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Z. Kristallogr. 220 (2005) 895-905
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Inverse design of phononic crystals
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320 Optimization of the dissipation
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322 The reflection of the wave is f
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324 which averaged over a wave peri
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326 where the modified stress compo
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328 optimization algorithm is enhan
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330 reflectance are also seen (Fig.
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332 It should be emphasized that ot
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334 b Dissipation, D c Dissipation,
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336 7.2. Three-phase design ARTICLE
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338 ARTICLE IN PRESS J.S. Jensen /
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340 ARTICLE IN PRESS J.S. Jensen /
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968 ARTICLE IN PRESS J.S. Jensen, N
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970 To solve the wave equation with
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972 In the following section, we sh
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974 Design variable, t Design varia
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976 Eigenvalue ratio, ω n+1 2 /ωn
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978 to a design parameter te are gi
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980 ARTICLE IN PRESS J.S. Jensen, N
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982 respect to the higher bound C1
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984 instead vary the value of b. Th
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986 References ARTICLE IN PRESS J.S
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a thick solid was considered. A few
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The above expressions provide insta
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In all the examples shown a density
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domain. To the very left the passiv
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Jensen JS, Sigmund O (2005) Topolog
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paper extends on this work. For an
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R 1 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2
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objective 1 0.9 0.8 0.7 0.6 0.5 0.4
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The optimization algorithm employs
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Appl. Phys. Lett., Vol. 84, No. 12,
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J. S. Jensen and O. Sigmund Vol. 22
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Topology optimization and fabricati
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Normalized transmission 1.0 0.8 0.6
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Fig. 4. Scanning electron micrograp
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Broadband photonic crystal waveguid
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2. Design and fabrication Silicon-o
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Fig. 3. Steady-state magnetic field
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Topology optimised broadband photon
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1202 IEEE PHOTONICS TECHNOLOGY LETT
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1204 IEEE PHOTONICS TECHNOLOGY LETT
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11. P. Debackere, S. Scheerlinck, P
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nanoimprinted patterns are transfer
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emoved and the spectra changed dras
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Y-splitter W1 waveguide 60-degree b
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5. Photonic Wire Waveguides Figure
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Figure 5: Optimized designs and cor
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Figure 8: Optimized designs and cor
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[13] Borel P I, Frandsen L H, Harp
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1606 J. S. JENSEN To compute a freq
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1608 J. S. JENSEN Cramer’s rule [
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1610 J. S. JENSEN The following pro
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1612 J. S. JENSEN Table I. Coeffici
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1614 J. S. JENSEN h 2h Α fcos Ωt
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1616 J. S. JENSEN The derivative of
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1618 J. S. JENSEN which is solved f
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1620 J. S. JENSEN Based on the expr
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1622 J. S. JENSEN Response, ln(u ti
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1624 J. S. JENSEN h 2h fcos Ωt Fi
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1626 J. S. JENSEN details and have
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1628 J. S. JENSEN Equation (A10) co
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1630 J. S. JENSEN 7. Coyette J-P, L
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The number of masses in the chain t
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5 Results The optimization algorith
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Figure 9. Response for optimized de
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Space-time topology optimization fo
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good for low to moderate stiffness
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V ¼ 0:3 at a given time instant fo
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The parameters used in this example
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Normalized amplitude 1 0.9 0.8 0.7
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at the Department of Mechanical Eng
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600 J.S. JENSEN techniques for obta
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602 J.S. JENSEN 1 and 2, where the
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604 J.S. JENSEN 4. Numerical analys
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606 J.S. JENSEN Energy, E a) Energy
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608 J.S. JENSEN relaxed somewhat in
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610 J.S. JENSEN when the contrast i
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612 J.S. JENSEN 6. Summary and conc
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614 J.S. JENSEN Sigmund, O. and Jen
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