WAVES AND VIBRATIONS IN INHOMOGENEOUS STRUCTURES ...

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at the Department of Mechanical Engineering at the Technical university of Denmark) for inspiring discussions. References [1] M.P. Bendsøe, Optimal shape design as a material distribution method, Struct. Optim. 10 (1989) 193–202. [2] M.P. Bendsøe, N. Kikuchi, Generating optimal topologies in structural design using a homogenization method, Comput. Methods Appl. Mech. Engrg. 71 (1988) 197–224. [3] M.P. Bendsøe, O. Sigmund, Material interpolations in topology optimization, Arch. Appl. Mech. 69 (1999) 635–654. [4] M.P. Bendsøe, O. Sigmund, Topology Optimization – Theory, Methods and Applications, Springer-Verlag, Berlin, 2003. [5] I.I. Blekhman, K.A. Lurie, On dynamic materials, Proc. Russian Acad. Sci. (Doklady) 37 (2000) 182–185. [6] I.I. Blekhman, Vibrational dynamic materials and composites, J. Sound Vib. 317 (2008) 657–663. [7] M. Bruggi, P. Venini, Topology optimization of incompressible media using mixed finite elements, Comput. Methods Appl. Mech. Engrg. 196 (2007) 3151– 3164. [8] L. Brillouin, Wave Propagation in Periodic Structures, second ed., Dover Publications, 1953. [9] J.S. Choi, J. Yoo, Structural optimization of ferromagnetic materials based on the magnetic reluctivity for magnetic field problems, Comput. Methods Appl. Mech. Engrg. 197 (2008) 4193–4206. [10] Y.-S. Chung, C. Cheon, S.-Y. Hahn, Reconstruction of dielectric cylinders using FDTD and topology optimization technique, IEEE Trans. Magnetics 36 (2000) 956–959. [11] W.W. Clark, Vibration control with state-switched piezoelectric materials, J. Intel. Mater. Syst. Struct. 11 (2000) 263–271. [12] R.D. Cook, D.S. Malkus, M.E. Plesha, R.J. Witt, Concepts and Applications of Finite Element Analysis, fourth ed., Wiley, New York, 2002. [13] J. Dahl, J.S. Jensen, O. Sigmund, Topology optimization for transient wave propagation problems in one dimension, Struct. Multidiscipl. Optim. 36 (2008) 585–595. [14] D. Holtz, J.S. Arora, An efficient implementation of adjoint sensitivity analysis for optimal control problems, Struct. Optim. 13 (1997) 223–229. [15] G.M. Hulbert, Time finite element methods for structural dynamics, Int. J. Numer. Methods Engrg. 33 (1992) 307–331. [16] J. Issa, R. Mukherjee, A.R. Diaz, S.W. Shaw, Modal disparity and its experimental verification, J. Sound Vib. 311 (2008) 1465–1475. [17] B.-S. Kang, G.-J. Park, J.S. Arora, A review of optimization of structures subjected to transient loads, Struct. Multidiscipl. Optim. 31 (2006) 81–95. [18] D.E. Kirk, Optimal Control Theory: An Introduction, Prentice-Hall, New Jersey, 1970. [19] V. Krylov, S.V. Sorokin, Dynamics of elastic beams with controlled distributed stiffness parameters, Smart Mater. Struct. 6 (1997) 573–582. J.S. Jensen / Comput. Methods Appl. Mech. Engrg. 198 (2009) 705–715 715 [20] J.S. Lee, J.E. Kim, Y.Y. Kim, Damage detection by the topology design formulation using modal parameters, Int. J. Numer. Methods Engrg. 69 (2007) 1480–1498. [21] Y. Li, K. Saitou, N. Kikuchi, Topology optimization of thermally actuated compliant mechanisms considering time-transient effect, Finite Elem. Anal. Des. 11 (2004) 1317–1331. [22] K.A. Lurie, Effective properties of smart elastic laminates and the screening phenomenon, Int. J. Solids Struct. 34 (1997) 1633–1643. [23] K.A. Lurie, S.L. Weekes, Wave propagation and energy exchange in a spatiotemporal material composite with rectangular microstructure, J. Math. Anal. Appl. 314 (2006) 286–310. [24] K.A. Lurie, An Introduction to Mathematical Theory of Dynamic Materials, Springer-Verlag, 2007. [25] F. Maestre, A. Münch, P. Pedregal, A spatio-temporal design problem for a damped wave equation, SIAM J. Appl. Math. 68 (2007) 109–132. [26] F. Maestre, P. Pedregal, Dynamic materials for an optimal design problem under the two-dimensional wave eqaution, Discrete Contin. Dyn. Syst. – Ser. A, in press. [27] S. Min, N. Kikuchi, Y.C. Park, S. Kim, S. Chang, Optimal topology design of structures under dynamic loads, Struct. Optim. 17 (1999) 208–218. [28] T. Nomura, K. Sato, K. Taguchi, T. Kashiwa, S. Nishiwaki, Structural topology optimization for the design of broadband dielectric resonator antennas using the finite difference time domain technique, Int. J. Numer. Methods Engrg. 71 (2007) 1261–1296. [29] C.L.W. Pedersen, Crashworthiness design of transient frame structures using topology optimization, Comput. Methods Appl. Mech. Engrg. 193 (2004) 653– 678. [30] A. Ramaratnam, N. Jalili, A swithched stiffness approach for structural vibration control: theory and real-time implementation, J. Sound Vib. 291 (2006) 258–274. [31] S.V. Sorokin, O.A. Ershova, S.V. Grishina, The active control of vibrations of composite beams by parametric stiffness modulation, Eur. J. Mech. A – Solids 19 (2000) 873–890. [32] K. Svanberg, The method of moving asymptotes – a new method for structural optimization, Int. J. Numer. Methods Engrg. 24 (1987) 359–373. [33] S. Turteltaub, Optimal material properties for transient problems, Struct. Multidiscipl. Optim. 22 (2001) 157–166. [34] S. Turteltaub, Optimal non-homogeneous composites for dynamic loading, Struct. Multidiscipl. Optim. 30 (2005) 101–112. [35] S.L. Weekes, Numerical computation of wave propagation in dynamic materials, Appl. Numer. Math. 37 (2001) 417–440. [36] S.L. Weekes, A stable scheme for the numerical computation of long wave propagation in temporal laminates, J. Comput. Phys. 176 (2002) 345–362. [37] G.H. Yoon, J.S. Jensen, O. Sigmund, Topology optimization of acoustic– structure interaction problems using a mixed finite element formulation, Int. J. Numer. Methods Engrg. 70 (2007) 1049–1075. [38] G.H. Yoon, O. Sigmund, A monolithic approach for topology optimization of electrostatically actuated devices, Comput. Methods Appl. Mech. Engrg. 197 (2008) 4062–4075.
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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
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Chapter 2 The bandgap phenomenon In
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2.1 Band diagram and forced vibrati
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2.3 Experimental demonstration 11 F
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y 2.5 Nonlinearities 13 Response in
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Relations to recent work 15 Amplitu
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Chapter 3 Bandgap structures as opt
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3.1 Vibration-quenching structures
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3.2 Maximizing wave reflection 21 d
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3.4 Maximizing wave dissipation 23
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3.4 Maximizing wave dissipation 25
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3.5 Plate structures 27 a) b) Figur
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3.6 Acoustic design 29 design domai
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Chapter 4 Optimization of photonic
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4.1 Waveguide bends and junctions 3
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4.2 Photonic crystal building block
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4.2 Photonic crystal building block
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4.4 Ridge waveguides 39 w ε =1 ?
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Relations to recent work 41 wave in
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Chapter 5 Advanced optimization pro
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5.1 Padé approximants 45 h 2h A f
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5.3 Space-time topology optimizatio
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5.3 Space-time topology optimizatio
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Relations to recent work 51 Figure
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Chapter 6 Conclusions In the first
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References K. Asakawa, Y. Sugimoto,
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References 57 W. R. Frei, D. A. Tor
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References 59 F. Maestre, A. Münch
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References 61 O. Sigmund, J. S. Jen
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References 63 X. M. Zhou and G. K.
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Dansk resumé 65 i strukturen. En r
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1054 ARTICLE IN PRESS J.S. Jensen /
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1058 fundamental eigenfrequency o
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1060 ðo 2 y;j;k ARTICLE IN PRESS J
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1062 local resonator and splits up
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1064 3.1. Model equations A finite
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1066 FRF (dB) 150 100 50 0 -50 -100
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1068 3.3. Example 2: a 2-D waveguid
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wave-guiding properties show promis
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(a) (b) Acceleration response (dB)
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B.S. Lazarov, J.S. Jensen / Interna
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ω/κ ω/κ 1.5 1.4 1.3 1.2 1.1 1 0
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[B 2000 ] [B 2000 ] [B 2000 ] 0.25
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[B 400 ] 0.25 0.2 0.15 0.1 0.05 B.S
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1002 (a) (c) (e) 0. Sigmund and J.
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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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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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Page 251 and 252: [13] Borel P I, Frandsen L H, Harp
Page 253 and 254: 1606 J. S. JENSEN To compute a freq
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Page 257 and 258: 1610 J. S. JENSEN The following pro
Page 259 and 260: 1612 J. S. JENSEN Table I. Coeffici
Page 261 and 262: 1614 J. S. JENSEN h 2h Α fcos Ωt
Page 263 and 264: 1616 J. S. JENSEN The derivative of
Page 265 and 266: 1618 J. S. JENSEN which is solved f
Page 267 and 268: 1620 J. S. JENSEN Based on the expr
Page 269 and 270: 1622 J. S. JENSEN Response, ln(u ti
Page 271 and 272: 1624 J. S. JENSEN h 2h fcos Ωt Fi
Page 273 and 274: 1626 J. S. JENSEN details and have
Page 275 and 276: 1628 J. S. JENSEN Equation (A10) co
Page 277 and 278: 1630 J. S. JENSEN 7. Coyette J-P, L
Page 279 and 280: The number of masses in the chain t
Page 281 and 282: 5 Results The optimization algorith
Page 283 and 284: Figure 9. Response for optimized de
Page 286 and 287: Space-time topology optimization fo
Page 288 and 289: good for low to moderate stiffness
Page 290 and 291: V ¼ 0:3 at a given time instant fo
Page 292 and 293: The parameters used in this example
Page 294 and 295: Normalized amplitude 1 0.9 0.8 0.7
Page 298 and 299: Control and Cybernetics vol. 39 (20
Page 300 and 301: Optimization of space-time material
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