Local Optimal Polarization of Piezoelectric Material

Introduction Local Optimal Polarization Numerical Examples Summary
Local Optimal Polarization of Piezoelectric Material
Fabian Wein, M. Stingl
9th Int. Workshop on Direct and Inverse Problems in Piezoelectricity
30.09-02.10.2013

Overview
General
linear continuum model
numerical approach based on ﬁnite element method
PDE based optimization with high number of design variables
Optimization
optimization helps to understand systems better
manufacturability in mind
no real prototypes

Structural Optimization = Topology Optimization + Material Design
Topology optimization
“where to put holes”/ material distribution
design of (piezoelectric) devices
macroscopic view
Material design
“assume you could have arbitrary material, what do you want?”
realization might be another process
realizations might be metamaterials

Motivation
stochastic orientation
Jayachandran, Guedes,
Rodrigues; 2011
Material Design
common homogeneous material seems to
be not optimal
Free Material Optimization → why it does
not work
local optimal material → new approach

Standard Topology Optimization
distributes uniform polarized material/holes
“macroscopic view”
established in 2 1/2 dimensions (single layer)
scalar variable ρe for each design element (= ﬁnite element cell)
SIMP (solid isotropic material with penalization)
piezoelectric topology optimization K¨ogel, Silva; 2005
[cE
e ] = ρe [cE
] [ee] = ρe [e] [εS
e ] = ρe[εS
], ρe ∈ [ρmin,1]

Piezoelectric Free Material Optimization (FMO)
all tensor coefficients of every finite element cell are design variable
[c] =


c11 c12 c13
− c22 c23
− − c33

, [e] =
e11 e13 e15
e31 e33 e35
, [ε] =
ε11 ε12
− ε22
properties
[c] and [ε] need to be symmetric positive definite
[ε] only for sensor case (mechanical excitation) relevant
questions to be answered
[c] orthotropic?
[e] with only standard coefficients?
orientation of [c] and [e] coincides?
something like an optimal oriented polarization?

FMO Problem Formulation (Actor)
min l u maximize compression
s.th. ˜K u = f, coupled state equation
Tr([c]e) ≤ νc, 1 ≤ e ≤ N, bound stiffness
Tr([c]e) ≥ νc, 1 ≤ e ≤ N, enforce material
( [e]e 2)2
≤ νe, 1 ≤ e ≤ N, bound coupling
[c]e −νI 0, 1 ≤ e ≤ N. positive definiteness
realize positive definiteness by feasibility constraints
c11e −ν ≤ ε, 1 ≤ e ≤ N,
det2([c]e −νI) ≤ ε, 1 ≤ e ≤ N,
det3([c]e −νI) ≤ ε, 1 ≤ e ≤ N.

Tensor Visualization similar to [Marmier et al.; 2010]
[c] =


12.6 8.41 0
8.41 11.7 0
0 0 4.6

,[e] =


0 −6.5
0 23.3
17 0

,[ε] =
1.51 0
0 1.27
[c] [e] [ε] [c] “ortho” [e] “zeros” [ε] “ε12”
orientational stiﬀness
σ
[c]
x (θ) =


1
0
0

 [c](θ)


1
0
0

, σ
[e]
x (θ) =


1
0
0

 [e](θ)
1
0
, D
[ε]
x ...

Actuator Model Problem

FMO Results - Elasticity Tensor [c]
orientational stiﬀness
orientational orthotropy norm

FMO Results - Piezoelectric Coupling Tensor [e]
orientational stress coupling
orientational “zero norm”

Discussion of the FMO Results
objective
maximize vertical displacement of top electrode
observations
less vertical stiﬀness to support compression
in coupling tensor e33 is dominant
characteristic orientational polarization
standard material classes (orthotropic)
coinciding orientation for [c] and [e]
ill-posed problem (stiﬀness minimization)
inhomogeneity due to boundary conditions
boundary conditions
deformation
elasticity
coupling

Electrode Design vs. Optimal Polarization
Electrode Design
pseudo polarization K¨ogel, Silva; 2005
[cE
e ] = [cE
], [ee] = [e], [εS
e ] = ρp[εS
] ρp ∈ [−1,1]
(continuous) ﬂipping of polarization (+ topology optimization)
applied on single layer piezoelectric plates
only scales polarization, does not change angle
known to result in -1 and 1 full polarization (static)
erroneously called “optimal polarization”

Optimal Orientation
parametrization by design angle θ
[cE
] = Q(θ) [c]Q(θ) [e] = R(θ) [e]Q(θ) [εS
] = R(θ) [ε]R(θ)
R =
cosθ sinθ
−sinθ cosθ
Q =


R2
11 R2
12 2R11 R12
R2
21 R2
22 2R21 R22
R11 R21 R12 R22 R11 R22 +R12 R21


concurrent orientation of all tensors
corresponds to local polarization

Numerical System
linear FEM system (static)
Kuu Kuφ
Kuφ −Kφφ
u
φ
=
f
¯q
, short ˜Ku = f
K∗ assembled by local ﬁnite element matrices K∗e
K∗e constructed by [cE
e ](θ), [ee](θ) and [εS
e ](θ)
f is discrete force vector, corresponding to mesh nodes.
¯q from applied electric potential (inhomogeneous Dirichlet B.C.)
f = 0 for sensor, ¯q = 0 for actuator

Function
discrete solution vector u = u1x u1y u2x u2y ...φ1 φ2 ...
displacement (each direction) and electric potential at mesh nodes
generic function f identifying solution
f = u l
scalar product of solution with selection vector l = (0 ... 1 ...0)
f can be maximized or used to specify a restriction
vertical displacement of all upper electrode nodes
horizontal displacement of a corner
diagonal displacement of a given region
selection of electric potential at electrode
. . .

Sensitivity Analysis
the gradient vector ∂f
∂θ determines for every θe the impact on f
sensitivity analysis based on adjoint approach
f = uT
l,
∂f
∂θe
= λe
∂Ke
∂ρe
ue with λ solving ˜Kλ = −l
one adjoint system ˜Kλ = −l to be solved for every function f
∂Ke
∂ρe
easily found by product rule
numerically very eﬃcient, independent of number of design variables
iteratively problem solution by ﬁrst order optimizer (SNOPT, MMA)

Problem Formulation
generic problem formulation
min
θ
l u objective function
s.th. ˜K u = f, coupled state equation
lk u ≤ ck, 0 ≤ k ≤ M, arbitrary constraints
θe ∈ [−
π
2
,
π
2
], 1 ≤ θe ≤ N, box constraints
for sensor and actuator problem
full material everywhere
individual polarization angle in every cell

Regularization
orientational optimization in elasticity known to have local optimima
restricts local change of angle
ﬁltering Bruns, Tortorelli; 2001
θe =
∑
Ne
i=1 w(xi )θi
∑
Ne
i=1 w(xi )
w(xi ) = max(0,R −|xe −xi |)
local slope constraints Petersson, Sigmund; 1998
gslope(θ) = |< ei ,∇θ(x) >| ≤ cs i ∈ {1,...,DIM}
gslope(θe,i) = |θe −θi | ≤ c,

Example Problems
A BC
actuator problems
maximize compression C ↓
maximize compression C ↓ and limit A ← and B →
twist A ↓ and B ↑
sensor problem
maximize electric potential at C

maximize compression C ↓
initial |u| optimized |u|
gain: 6.1% of integrated y-displacement of C nodes
C is ﬂattened
probably no global optimum reached

maximize compression C ↓ and limit A ← and B →
loss: 4.9% of integrated y-displacement of C nodes
but A and C bounded to 50 % of initial x-displacement

twist A ↓ and B ↑
note θ ∈ [−π
2 , π
2 ]
electrode design might be more eﬀective for this case

maximize electric potential at C
gain: 0.6 % in diﬀerence of potential
possibly due to poor local optima

Coupling Tensor vs. Stiffness Tensor
what is the impact of the transversal isotropic stiffness tensor?
assume isotropic stiffness tensor
gain: 4.7 % vs. 6.1 % with PZT-5A tensors

Conclusion
General
local polarization works in principle
solutions might be far from global optimium
more feasible than piezoelectric Free Material Optimization
simple support would change everything
Applications
not to improve performance
exact tuning of devices
metamaterial not yet possible (e.g. auxetic material)

Future Work
Examples
dynamic problems, shift of resonance frequencies possible?
metamaterials (e.g. auxetic material)
Mathematical
novel tensor based solver
very promising for elasticity
Technical Realization
polarization by local electric ﬁeld
piezoelectric building blocks
. . . any suggestions?

End
thanks for your patience :)

Local Optimal Polarization of Piezoelectric Material

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