Acoustically camouflage Discussion and conclusion

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Acoustically camouflage Discussion and conclusion S. Wei, B. Liu, and J. P. Huang Department of Physics, Fudan University, Shanghai 200433, China Motivation Our train of thoughts Conceal an object at one place and emerge at another place Many potential applications. For example, mislead enemy to make a chance to steal with submarines Acoustically conceal the object A with an acoustical cloak [For remote electromagnetic cloaks, see PRL 102, 093901 (2009)] Enhance the acoustically scattering capability of a smaller object B to get the same pressure distribution as A in the absence of the cloak [For electromagnetic superscatterers, see Opt. Express 16, 18545 (2008) ] Rectangular version Simulation results of rectangular version Air {2a4,2b4} {2a5,2b5} Core material {2a1,2b1} Complementary media {2a2,2b2} Air {2a3,2b3} Region size The coordinate transformation from the air layer to core region (yellow) The complementary media region is divided into 4 subdomains to accomplish coordinate transformation. For subdomain I The mass density and bulk modulus obtained by using Snapshots of the pressure fields under an incident acoustic (1a)-(1c) plane wave , (2a) -(2b)cylindrical wave. (1a) and (2a) A rectangular object of size {0.03m,0.04m} . (1b) and (2b) The scattered pressure field distribution of the rectangular object of size {0.0075m,0.01m} is the same as the one of the object of size {0.03m,0.04m} . (1c) and (2c) With a rectangular object on the left, the scattered pressure distribution is same to (1b) and (2b), respectively. All objects have and . The coordinate transformation from the air layer to green layer subdomain I Circular version Simulation results of circular version Snapshots of the distribution of pressure fields under (a) an incident acoustic plane wave , (b) a cylindrical. Distributions of pressure fields of single object are similar to (1a),(1b),(2a) and (2b). R1 R2 R3 (a) “anti-object” The coordinate transformation from the air layer to green layer (b) Discussion and conclusion With our design we can make a feint to the east but attack in the west (“声东击西”). All simulations obtained by using finite-element solver Comsol Multiphysics 3.5. References [1] B. Liu and J. P. Huang,”Acoustically conceal an object with hearing”, European Physical Journal – Applied Physics (in press, 2009) [2] J. B. Pendry, D. Schurig and D. R. Smith. Controlling electromagnetic fields. Science, 312: 1780-1782 (2006) [3] Y. Lai, H. Y. Chen, Z. Zhang, and C. T. Chan. Phys. Rev. Lett., 102: 093901, (2009). [4] S. A. Cummer, D. Schurig. New J. Phys, 9: 45, (2007).