WAVES AND VIBRATIONS IN INHOMOGENEOUS STRUCTURES ...

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TOPOLOGY OPTIMIZATION WITH PADÉ APPROXIMANTS 1629 ˜Q T j = N Q j,N+1−ku k=1 ∗ k Equation (A16) is inserted into Equation (A10) Bu ′ = Bu ′ 0 − N ũ ju j=1 + j + N ˜biI + u + i=1 u ′ N+1 N+1−i uN+1 j=1 N ũ j ˜Q T j u ′ i − N Q j,N+1−iũj j=1 in which it has been used that ˜b0 = B. Equation (A19) can now be used to identify the components of the matrices Di and Ei and for i = 1, N. h T ū ′ i (A18) (A19) D0 = I, E0 = 0 (A20) DN+1 =− 1 B N ũ ju + j , EN+1 = 0 (A21) j=1 Di = 1 ˜biI + u B + N+1−i uN+1 j=1 Ei =− 1 N Q j,N+1−iũj B j=1 N ũ j ˜Q T j h T ACKNOWLEDGEMENTS (A22) (A23) The author wishes to thank Professors M. P. Bendsøe, Department of Mathematics and P. C. Madsen, Department of Informatics and Mathematical Modelling at the Technical University of Denmark for helpful suggestions and discussions. REFERENCES 1. Tcherniak D. Topology optimization of resonating structures using SIMP method. International Journal for Numerical Methods in Engineering 2002; 54:1605–1622. 2. Baker GA, Graves-Morris P. Padé Approximants (2nd edn). Cambridge University Press: Cambridge, 1996. 3. Pillage LT, Rohrer RA. Asymptotic waveform evaluation for timing analysis. IEEE Transactions on Computer- Aided Design 1990; 9:352–366. 4. Gong J, Volakis L. Awe implementation for electromagnetic fem analysis. Electronics Letters 1996; 32:2216–2217. 5. Zhang J-P, Jin J-M. Preliminary study of awe method for fem analysis of scattering problems. Microwave and Optical Technology Letters 1998; 17:7–12. 6. Kuzuoglu M, Mittra R. Finite element solution of electromagnetic problems over a wide frequency range via the Padé approximation. Computer Methods in Applied Mechanics and Engineering 1999; 169:263–277. Copyright q 2007 John Wiley & Sons, Ltd. Int. J. Numer. Meth. Engng 2007; 72:1605–1630 DOI: 10.1002/nme
1630 J. S. JENSEN 7. Coyette J-P, Lecomte C, Migeot J-L. Calculation of vibro-acoustic frequency response functions using a single frequency boundary element solution and a Padé expansion. Acta Acoustica 1999; 85:371–377. 8. Djellouli R, Farhat C, Tezaur R. A fast method for solving acoustic scattering problems in frequency bands. Journal of Computational Physics 2001; 168:412–432. 9. Malhotra M, Pinsky PM. Efficient computation of multi-frequency far-field solutions of the Helmholtz equation using Padé approximation. Journal of Computational Acoustics 2000; 8:223–240. 10. Wagner MM, Pinsky PM, Oberai AA, Malhotra M. A Krylov subspace projection method for simultaneous solution of Helmholtz problems at multiple frequencies. Computer Methods in Applied Mechanics and Engineering 2003; 192:4609–4640. 11. Xu GL, Bultheel A. Matrix Padé-approximation—definitions and properties. Linear Algebra and its Applications 1990; 137:67–136. 12. Freund RW. Computation of matrix Padé approximations of transfer functions via a Lanczos-type process. Approximation and Interpolation of Approximation Theory VIII, vol. 1. World Scientific: Singapore, 1995; 215–222. 13. Jensen JS, Sigmund O. Topology optimization of photonic crystal structures: a high-bandwidth low-loss T-junction waveguide. Journal of the Optical Society of America B 2005; 22(6):1191–1198. 14. Kwon SK, Bernard JE. Design optimization based on Padé expansions. Finite Elements in Analysis and Design 1992; 11:235–246. 15. Webb JP. Design sensitivity of frequency response in 3-d finite-element analysis of microwave devices. IEEE Transactions on Magnetics 2002; 38:1109–1112. 16. Nair D, Webb JP. Optimization of microwave devices using 3-D finite elements and the design sensitivity of the frequency response. IEEE Transactions on Magnetics 2003; 39:1325–1328. 17. Strang G. Linear Algebra and its Applications (3rd edn). Hartcourt Brace Jovanovich: Orlando, FL, 1986. 18. Tortorelli DA, Michaleris P. Design sensitivity analysis: overview and review. Inverse Problems in Engineering 1994; 1:71–105. 19. Bendsøe MP, Sigmund O. Topology Optimization—Theory, Methods and Applications. Springer: Berlin, Heidelberg, 2003. 20. Ma Z-D, Kikuchi N, Hagiwara I. Structural topology and shape optimization for a frequency response problem. Computational Mechanics 1993; 13:157–174. 21. Jog CS. Topology design of structures subjected to periodic loading. Journal of Sound and Vibration 2002; 253(3):687–709. 22. Olhoff N, Du J. Topological design for minimum dynamic compliance of continuum structures subjected to forced vibration. Structural and Multidisciplinary Optimization 2007, to appear. 23. Sigmund O. A 99 line topology optimization code written in matlab. Structural and Multidisciplinary Optimization 2001; 21:120–127. 24. Svanberg K. The method of moving asymptotes—a new method for structural optimization. International Journal for Numerical Methods in Engineering 1987; 24:359–373. 25. Stolpe M, Svanberg K. An alternative interpolation scheme for minimum compliance optimization. Structural and Multidisciplinary Optimization 2001; 22:116–124. Copyright q 2007 John Wiley & Sons, Ltd. Int. J. Numer. Meth. Engng 2007; 72:1605–1630 DOI: 10.1002/nme
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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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