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2008; Stanford and Ifju 2009; Guest and Smith Genut. 2010). In Fig. ..... Querin O, Steven G, Xie Y (1998) Evolutionary structural optimisation. (ESO) using a ...
Aug 29, 2013 - ... to indicate material or void in the various elements to independent continuous design variables. ... is successfully applied to optimum material distribution problems for ... parameterization level set method for structural shape a
Keywords: differential evolution, topology optimization, truss design. 1. ... time in finding required data for calculating objective function of optimization problem.
G4 = Ai min ⤠Ai ⤠Ai max. The design variables Ai is the cross-sectional areas of the structural members. The parameter Ïallow and δallow indicate the.
found are related to the piezoresistive load cell design. ... to find optimum load cell dimensions to reduce the coupling problem among the strain-gage responses.
Nov 27, 2014 - 2Department of Mechanical Engineering, University of Michigan, Ann Arbor, MI 48105, USA. 3Beijing Automotive Technology Center, Beijing 100081, China ...... sor products of certain classes of functions,âSoviet Mathematics,.
Mróz [15]. The stress-constrained topology optimization procedure can give premature results when it is stuck in point of high values of the state parameter.
Sep 6, 2017 - We proposed an isogeometric topology optimization approach using moving ...... 19â35. http://dx.doi.org/10.1007/s00466-015-1219-1.
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Topology optimization generates the optimal shape of a mechanical structure. ... layout problem of material distribution by a much easier sizing problem for the density and ... topology design of continuum structures using Performance indices.
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... and vCenter Server 5 Documentation VMware vSphere ESXi and vCenter Server 5 Documentation VMware vSphere Basics VMwa
Jun 3, 2009 - Mechanicial layer: Aluminum, 5cmÃ5 cm, 100 µm thick, no glue layer. Fabian Wein. Acoustic Piezoelectric
... Read Online Topology Optimization Read ebook pdf on ipad with full pages You can ebook read .... the use of mathemat
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Topology optimization is a freeform material distribution design scheme that generates optimal forms for specified targeted performance criteria and problem constraints. The typical ..... Optimal shape design as a material distribution problem.
design. Topology optimization of structures is the most recent branch of structural ..... Bendsoe, M. P. Optimal shape design as a material distribution problem.
constellation through orbital changes and addition of new satellites were studied in order to increase capacity. ... evolve from one stage to the next. In this paper ...
Link aggregation is to represent links connected between .... can derive the following equations that are called partial optimization conditions. l. lllD. lllD. llD s nk.
Jun 2, 2010 - tition, in the context of building layout optimization. By ... High-rise buildings · Material layout · Pattern constraints ... e-mail: [email protected].
Nov 16, 2016 - Weiyang Lin, James C. Newman III, W. Kyle Anderson. Design of Broadband Acoustic Cloak. Using Topology Op
IMECE2016-68135
Design of Broadband Acoustic Cloak Using Topology Optimization Weiyang Lin, James C. Newman III, W. Kyle Anderson
November 16, 2016
IMECE2016-68135
Introduction • Acoustic cloak: conceal an object from detecting waves
[Ref] Schematic diagram of the cloaking device by S. Zhang, et al
IMECE2016-68135
Introduction • Acoustic cloak: conceal an object from detecting waves • Homogenization-based topology optimization
[Ref] Topology optimization of a cantilever beam by O. Sigmund
IMECE2016-68135
Introduction • Acoustic cloak: conceal an object from detecting waves • Homogenization-based topology optimization • Sensitivity analysis and time-dependent adjoint formulation – A lot of design variables – Time-domain methods
IMECE2016-68135
Finite Element Time Domain Formulation (1/2) • Acoustics governing equations – Continuity equation and momentum equations • Non-conservative form 𝜕𝑄 𝜕𝑄 𝜕𝑄 +𝐴 +𝐵 =0 𝜕𝑡 𝜕𝑥 𝜕𝑡 where Q is the primitive variables, and A and B are the material properties. • Streamline Upwind Petrov Galerkin Formulation 𝜕𝑄 𝜕𝑄 𝜕𝑄 𝜙 +𝐴 +𝐵 ⅆΩ = 0 𝜕𝑡 𝜕𝑥 𝜕𝑡 Ω with Riemann solver at the material interfaces.
IMECE2016-68135
Finite Element Time Domain Formulation (2/2) Solver Features • Hybrid continuous/discontinuous Galerkin formulation • Absorbing boundary conditions and Perfectly Matched Layers (PML) • Fully discretized using Newton’s method and BDF temporal scheme • GMRES with ILU(k) • Linearization by operator overloading • Parallel solver (OpenMP and MPI)
IMECE2016-68135
Sensitivity Analysis (1/2) Sensitivity derivatives of a given cost function I can be calculated by • Finite difference (central) ⅆ𝐈 𝐈 𝛽 + Δ𝛽 − 𝐈 𝛽 + Δ𝛽 = + 𝑂 Δ𝛽2 ⅆ𝛽 2Δ𝛽 • Complex Taylor series expansion ⅆ𝐈 Im 𝐈 𝛽 + Δ𝛽𝑖 = + 𝑂 Δ𝛽2 ⅆ𝛽 Δ𝛽 • We want to use a large number of design variables with minimal additional cost
IMECE2016-68135
Sensitivity Analysis (2/2) • Algorithm: A discrete adjoint formulation for time-dependent sensitivity derivatives (1) Set 𝜓1𝑘+1 , 𝜓2𝑘+1 and 𝜓2𝑘+2 to be zero. Set k to be ncyc (reversed time) (2) Solve for the adjoint variable
𝜆𝑘𝑄
=−
𝜕𝑅 𝑘 𝜕𝑄𝑘
−𝑇
𝜕𝐈 𝜕𝑄𝑘
𝑇
+ 𝜓1𝑘+1
𝑇
+ 𝜓2𝑘+2
𝑇
Expensive when nonlinear (3) Set the sensitivity derivatives by 𝑘 𝑘 ⅆ𝐈 ⅆ𝐈 𝜕𝑅 𝜕𝜌 𝜕𝑅 𝜕𝐾𝑒 𝜕𝐈 𝜕𝑋 𝑇 𝑒 𝑘 = + 𝜆𝑄 + + ⅆ𝛽 ⅆ𝛽 𝜕𝜌𝑒 𝜕𝛽 𝜕𝐾𝑒 𝜕𝛽 𝜕𝑋 𝜕𝛽 (4) Set k = k-1 (5) Set 𝜓2𝑘+2 to be 𝜓2𝑘+1 , compute 𝜓1𝑘+1
=
𝜕𝑅 𝑘+1 𝜕𝑄𝑘
𝜆𝑘+1 𝑄 ,
(6) If k = 1, stop; otherwise go to step 2
𝜓2𝑘+1
=
𝜕𝑅 𝑘+1 𝜕𝑄𝑘−1
𝜆𝑘+1 𝑄
IMECE2016-68135
Topology Parameterization • SMI (Scaled Material Interpolation) for a well-scaled design space 𝜌𝑒 =
𝜌𝑒1
+
𝜌𝑒2 − 𝜌𝑒1 𝜌𝑒2 − 𝜌𝑒1
𝑠𝛽 𝑠
−1 −1
𝜕𝜌𝑒 𝑠 log 𝜌𝑒2 − 𝜌𝑒1 𝜌𝑒2 − 𝜌𝑒1 = 2 1 𝑠 𝜕𝛽 𝜌𝑒 − 𝜌𝑒 − 1 where s is a scaling factor.
𝜌𝑒2 − 𝜌𝑒1 𝑠𝛽
𝜌𝑒2 − 𝜌𝑒1
IMECE2016-68135
Design of Acoustic Cloaking Devices (1/6)
𝜔2
𝑝 − 𝑝0
min 𝐈 = 𝜔1
Γ
2
ⅆΓ ⅆ𝜔
IMECE2016-68135
Design of Acoustic Cloaking Devices (1/6) 𝜔2
𝑝 − 𝑝0
min 𝐈 = 𝜔1
1.9 kHz
2
ⅆΓ ⅆ𝜔
Γ
2.0 kHz
2.1 kHz
IMECE2016-68135
Design of Acoustic Cloaking Devices (2/6) 𝜔2
𝑝 − 𝑝0
min 𝐈 = 𝜔1
2
ⅆΓ ⅆ𝜔
Γ
Sample illustration of the topology optimization
IMECE2016-68135
Design of Acoustic Cloaking Devices (3/6) 𝜔2
𝑝 − 𝑝0
min 𝐈 = 𝜔1
Narrow band optimization (2.0 kHz)
2
ⅆΓ ⅆ𝜔
Γ
Broadband optimization (1.9~2.1 kHz)
IMECE2016-68135
Design of Acoustic Cloaking Devices (3/6) 𝜔2
𝑝 − 𝑝0
min 𝐈 = 𝜔1
Narrow band optimization (2.0 kHz)
2
ⅆΓ ⅆ𝜔
Γ
Broadband optimization (1.9~2.1 kHz)
IMECE2016-68135
Design of Acoustic Cloaking Devices (4/6) 𝜔2
𝑝 − 𝑝0
min 𝐈 = 𝜔1
1.9 kHz
2
ⅆΓ ⅆ𝜔
Γ
2.0 kHz
Narrow band optimization (2.0 kHz)
2.1 kHz
IMECE2016-68135
Design of Acoustic Cloaking Devices (5/6) 𝜔2
𝑝 − 𝑝0
min 𝐈 = 𝜔1
1.9 kHz
2
ⅆΓ ⅆ𝜔
Γ
2.0 kHz
Broadband optimization (1.9~2.1 kHz)
2.1 kHz
IMECE2016-68135
Design of Acoustic Cloaking Devices (6/6) 𝜔2
𝑝 − 𝑝0
min 𝐈 = 𝜔1
2
ⅆΓ ⅆ𝜔
Γ
The cost function values
IMECE2016-68135
Conclusions • A procedure of using topology optimization for the design of broadband acoustic cloaking devices has been described • Additional storage cost, but adaptable to broadband designs
IMECE2016-68135
Future Work • Design using a fine mesh, and with penalty to reduce gray area • Sequential topology and shape optimization
IMECE2016-68135
Topology Optimization with Penalty • Use a penalty factor to reduce intermediate states (gray areas) 𝐈 ∗ = 𝛼𝑞 𝐈 𝑛𝑑𝑣
𝛼𝑞 = 1 + 𝑞
𝛽𝑖 − 0.5
2
𝑖=1
Note that the actual cost function value would be changed.
