[1] ZHANG Jia-long, YAO Hong, DU Jun, et al. The reduction of low-frequency noise in phononic crystal plates with composite locally resonant structures and thin membrane［J］. Acta Photonica Sinica, 2016, 45(7): 0731002.

[2] DU JUN, QI Peng-shan, JIANG Jiu-long, et al. Investigation of sound isolation in composite structure of local resonant phononic crystals［J］. Acta Photonica Sinica, 2016, 45(10): 1016001.

[3] LIU Z Y, ZHANG X X, MAO Y W, et al. Locally resonant sonic materials ［J］. Science, 2000, 289(5485): 1734-1736.

[4] WANG J W, WANG G, CHEN S B, et al. Broadband attenuation in phononic beams induced by periodic arrays of feedback shunted piezoelectric patches［J］. Chinese Physics Letters, 2012, 29(6): 064302.

[5] XIAO Y, WEN J H, WANG G, et al. Theoretical and experimental study of locally resonant and Bragg band gaps in flexural beams carrying periodic arrays of beam-like resonators ［J］. Journal Vibration and Acoustics, 2013, 135(4): 041006.

[6] YU D L, LIU Y Z, WANG G, et al. Flexural vibration band gaps in Timoshenko beams with locally resonant structures ［J］. Journal of Applied Physics, 2006, 100(12): 124901.

[7] HAN L, ZHANG Y, NI Z Q, et al. A modified transfer matrix method for the study of the bending vibration band structure in phononic crystal Euler beams ［J］. Physica B, 2012, 407(23): 4579-4583.

[8] XIANG H J, SHI Z F. Analysis of flexural vibration band gaps in periodic beams using differerntial quadrature method ［J］. Computers and Structures, 2009, 87(23-24): 1559-1566.

[9] LI T J, MA X F, ZHANG Q, et al. Band gap properties of periodic tapered beam structure using travelling wave method ［J］. Journal of Theoretical and Applied Mechanics, 2016, 54(4): 1297-1308.

[10] HUSSEIN M I, EI-BELTAGY M A. Optimization of phononic filters via genetic algorthms［C］. Journal of Physics: Conferernce Series, 2007, 92: 012110.

[11] DONG H W, SU X X, WANG Y S. Topological optimization of two-dimensional phononic crystals based on the finite element method and genetic algorithm［J］. Struct Multidisc Optim, 2014, 50(4): 593-604.

[12] GAZONAS G A, WEILE D S, WILDMAN R,et al. Genetic algorithm optimization of phononic bandgap structures［J］. International Journal of Solids snd Structures, 2006, 43(18): 5851-5866.

[13] WILDMAN R A, GAZONAS G A. Genetic programming-based phononic bandgap structure design［R］. Army Research Lab Aberdeen Proving Ground Md Weapons and Materials Research Directorate, 2011.

[14] ZHONG Hui-lin, WU Fu-gen, YAO Li-ning. Application of genetic algorithm in optimization of band gap of two-dimensional phononic crystals［J］. Acta Physica Sinica, 2006, 55(1): 275-280.

[15] DONG Ya-ke, DU Jun, YAO Hong,et al. Optimal structure design of two-dimensional phononic crystal based on intelligent algorithm［J］. Journal of Synthetic Crystals, 2015, 44(11): 3201-3204.

[16] ROMERO-GARCIA V, FUSTER-GARCIA E, SANCHE-PEREZ J,et al. Genetic algorithm in the optimization of the acoustic attenuation systems［C］. Conference on Artificial Neural Networks, Springer, Berlin, Heidelberg, 2007.

[17] HERRERO J M, GARCIA-NIETO S, BLASCO X, et al. Optimization of sonic crystal attenuation properties by ev-MOGA multiobjective evolutionary algorithm［J］. Structural & Multidisciplinary Optimization, 2009, 39(2): 203-215.

[18] HUSSEIN M I, HAMZA K, HULBERT G M, et al. Multiobjective evolutionary optimization of periodic layered materials for desired wave dispersion characteristics［J］. Structural and Multidisciplinary Optimization, 2006, 31(1): 60-75.