On optimal FEM and impedance conditions for thin electromagnetic - - PowerPoint PPT Presentation

On optimal FEM and impedance conditions for thin electromagnetic shielding sheets

Kersten Schmidt Research Center Matheon, Berlin, Germany, Institut f¨ ur Mathematik, Technische Universit¨ at Berlin, Germany Institut f¨ ur Mathematik, BTU Cottbus-Senftenberg, Germany

Research Center MATHEON Mathematics for key technologies

RICAM SpecSem – Workshop on Analysis and Numerics of Acoustic and Electromagnetic Problems 2016, Linz, Oct 18th 2016

Thin conducting shielding sheets

Maxwell equations in eddy current approximation curl curl E +iµσω E = −iωµ0 J Thin conducting sheets shields electric and magnetic fields Challenges: ⊲ high gradients in thickness directions ⊲ high aspect ratio of the sheets

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 2 / 29

Thin conducting shielding sheets

Maxwell equations in eddy current approximation curl curl E +iµσω E = −iωµ0 J Remedies ⊲ thin sheet basis ⊲ approximate transmission conditions ⊲ boundary integral formulation

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 2 / 29

Thin conducting shielding sheets

Maxwell equations in eddy current approximation curl curl E = J [E × n]Γ = 0 [curl E × n]Γ = Z(ω, σ, d) ET Remedies ⊲ thin sheet basis ⊲ approximate transmission conditions ⊲ boundary integral formulation

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 2 / 29

Thin conducting shielding sheets

Maxwell equations in eddy current approximation curl curl E = J [E × n]Γ = 0 [curl E × n]Γ = Z(ω, σ, d) ET Remedies ⊲ thin sheet basis ⊲ approximate transmission conditions ⊲ boundary integral formulation

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 2 / 29

Thin conducting shielding sheets

b a f = −iωµ0j0 ε Ωε

ext

Ωε

int

Eddy current model curl curl E +iµσω E = −iωµ0 J

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 3 / 29

Thin conducting shielding sheets

b a f = −iωµ0j0 ε Ωε

ext

Ωε

int

Eddy current model curl curl E +iµσω E = −iωµ0 J Two important effects of the thin sheet (of thickness ε) ⊲ Shielding effect – in conductors induced currents diminish electromagnetic fields (behind the conductor) ⊲ Skin effect – major current flow in a boundary layer (skins of the conductor)

◮ Skin depth in solid body δ =

• 2

µ0σω

◮ Copper at 50 Hz → δ ≈ 8mm

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 3 / 29

Thin conducting shielding sheets

ε ∼ δ ε ≪ δ ε ≫ δ Eddy current model curl curl E +iµσω E = −iωµ0 J Two important effects of the thin sheet (of thickness ε) ⊲ Shielding effect – in conductors induced currents diminish electromagnetic fields (behind the conductor) ⊲ Skin effect – major current flow in a boundary layer (skins of the conductor)

◮ Skin depth in solid body δ =

• 2

µ0σω

◮ Copper at 50 Hz → δ ≈ 8mm

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 3 / 29

Outline

1 Optimal basis inside the sheet 2 Impedance transmission conditions (ITCs) 3 Boundary integral equations for impedance transmission conditions

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 4 / 29

Optimal basis inside the sheet

Eddy current model in 2D (TM polarisation) −∆uε(x) + iωµ0σ(x) uε(x) = −iωµ0j0(x) Approximation of higher order without reduction to an interface Ansatz for the solution inside the sheet uε

int(t, s) ≈ uε int,N(t, s) =

N−1

i=0 φε i (s, t) uε int,i(t).

inspired by: Vogelius, M. and Babuˇ ska, I., Math. Comp. 37, 1981.

with N ≥ 2 linear independent basis functions φε

i

spanning V ε

N, and uε int,i ∈ H1(

Γ).

ε n s t ε

ext

ε

ext

ε

int

∂

Basis functions φε

0, φε 1 in the kernel of −∂2 s − κ 1+sκ ∂s + iωµ0σ + κ2 4(1+sκ)2 ,

φε

0(s, κ) =

1 √1 + sκ cosh(√iωµ0σs) cosh(√iωµ0σ ε

2 ),

{φε

,0}κ = 1, [φε ,0]κ = 0,

φε

1(s, κ) =

1 √1 + sκ sinh(√iωµ0σs) 2 sinh(√iωµ0σ ε

2 ),

{φε

,1}κ = 0, [φε ,1]κ = 1, K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 5 / 29

Optimal basis inside the sheet

Eddy current model in 2D (TM polarisation) −∆uε(x) + iωµ0σ(x) uε(x) = −iωµ0j0(x) Approximation of higher order without reduction to an interface Ansatz for the solution inside the sheet uε

int(t, s) ≈ uε int,N(t, s) =

N−1

i=0 φε i (s, t) uε int,i(t).

inspired by: Vogelius, M. and Babuˇ ska, I., Math. Comp. 37, 1981.

with N ≥ 2 linear independent basis functions φε

i

spanning V ε

N, and uε int,i ∈ H1(

Γ).

ε n s t ε

ext

ε

ext

ε

int

∂

Basis functions φε

2j, φε 2j+1,j ∈ N0 in the kernel of (−∂2 s − κ 1+sκ ∂s + iωµ0σ + κ2 4(1+sκ)2 )j+1,

φε

2j(s, κ) =

Pj(s) √1 + sκ cosh(

• iωµ0σs),

{φε

,2j}κ = δj,0, [φε ,2j]κ = 0

φε

2j+1(s, κ) =

Pj(s) √1 + sκ sinh(

• iωµ0σs),

{φε

,2j+1}κ = 0,

[φε

,2j+1]κ = δj,0 K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 5 / 29

Optimal basis inside the sheet

Basis functions φε

i , i ∈ N0 such that (−∂2 s − κ 1+sκ∂s + iωµ0σ + κ2 4(1+sκ)2 )φε i = ε−2φε i−2

φε

2j(s, κ) =

Pj(s) √1 + sκ cosh(

• iωµ0σs),

{φε

,2j}κ = δj,0, [φε ,2j]κ = 0

φε

2j+1(s, κ) =

Pj(s) √1 + sκ sinh(

• iωµ0σs),

{φε

,2j+1}κ = 0,

[φε

,2j+1]κ = δj,0

s φε

int,0

φε

int,1

κ = +8 κ = −8

• ε

2 ε 2

• 0.5

0.5 1 s φε

int,2

φε

int,3

• ε

2 ε 2

• 0.5

0.5 1 s φε

int,4

φε

int,5

• ε

2 ε 2

• 0.5

0.5 1

iωµ0σ = 1000, ε = 0.1

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 6 / 29

Optimal basis inside the sheet

Basis functions φε

i , i ∈ N0 such that (−∂2 s − κ 1+sκ∂s + iωµ0σ + κ2 4(1+sκ)2 )φε i = ε−2φε i−2

φε

2j(s, κ) =

Pj(s) √1 + sκ cosh(

• iωµ0σs),

{φε

,2j}κ = δj,0, [φε ,2j]κ = 0

φε

2j+1(s, κ) =

Pj(s) √1 + sκ sinh(

• iωµ0σs),

{φε

,2j+1}κ = 0,

[φε

,2j+1]κ = δj,0

Decomposition −∆ + iωµ0σ =

• − ∂2

s −

κ 1 + sκ∂s + iωµ0σ + κ2 4(1 + sκ)2

• scales with ε, depends on σ

+ A(s, κ) with regular pertubation, independent of σ A(s, κ) = − 1 1 + sκ∂t

• 1

1 + sκ∂t

• −

κ2 4(1 + sκ)2

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 6 / 29

Optimal basis inside the sheet

Basis functions φε

i , i ∈ N0 such that (−∂2 s − κ 1+sκ∂s + iωµ0σ + κ2 4(1+sκ)2 )φε i = ε−2φε i−2

φε

2j(s, κ) =

Pj(s) √1 + sκ cosh(

• iωµ0σs),

{φε

,2j}κ = δj,0, [φε ,2j]κ = 0

φε

2j+1(s, κ) =

Pj(s) √1 + sκ sinh(

• iωµ0σs),

{φε

,2j+1}κ = 0,

[φε

,2j+1]κ = δj,0

Decomposition −∆ + iωµ0σ =

• − ∂2

s −

κ 1 + sκ∂s + iωµ0σ + κ2 4(1 + sκ)2

• scales with ε, depends on σ

+ A(s, κ) with regular pertubation, independent of σ A(s, κ) = − 1 1 + sκ∂t

• 1

1 + sκ∂t

• −

κ2 4(1 + sκ)2 Interpolation Iε

Nuε for uε smooth enough

Iε

Nuε(s, t) = ⌊ N

2 ⌋

• j=0

ε2jφε

2j(s, κ)AN,j(s, κ){uε}κ + ⌊ N−1

2

⌋

• j=0

ε2jφε

2j+1(s, κ)AN,j(s, κ)[uε]κ K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 6 / 29

Optimal basis inside the sheet

Lemma (Best-approximation error)

For any even N (curved sheet) any N (straight sheet or curved sheet N ≤ 4) and uε smooth enough there exists a constant C independent of σ such that inf

wε

N∈V ε N ⊗H1(

Γ)

|w ε

N − uε|H1(Ωε

int) ≤ CεN− 1 2 ,

inf

wε

N∈V ε N ⊗H1(

Γ)

w ε

N − uεL2(Ωε

int) ≤ CεN+ 1 2 .

Interpolation Iε

Nuε for uε smooth enough

Iε

Nuε(s, t) =

⌊ N

2 ⌋

j=0 ε2jφε 2j(s)AN,j(s, κ){uε}κ +

⌊ N−1

2

⌋ j=0

ε2jφε

2j+1(s)AN,j(s, κ)[uε]κ K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 7 / 29

Optimal basis inside the sheet

Eddy current model in 2D (TM polarisation) −∆uε(x) + iωµ0σ(x) uε(x) = −iωµ0j0(x) Semi-discretization W ε

N :=

• u ∈ H1(Ω) : u|Ωε

ext ∈ H1(Ωε

ext), u|Ωε

int ∈ V ε

N ⊗ H1(

Γ)

• Seek uε

N ∈ W ε N such that

• Ω

∇uε

N · ∇vN dx +

• Ωε

int

iωµ0σuε

NvN dx = −

• Ω

iωµ0j0vN dx ∀vN ∈ W ε

N

Lemma (Semi-discretization error)

For any even N (curved sheet) any N (straight sheet or curved sheet N ≤ 4) and uε smooth enough it holds for uε

N ∈ W ε N

|uε

N − uε|H1(Ωε

int) ≤ CεN− 1 2 ,

uε

N − uεL2(Ωε

int) ≤ CεN+ 1 2 ,

uε

N − uεH1(Ωε

ext) ≤ Cε2N−1.

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 8 / 29

Optimal basis inside the sheet

Semianalytical study for circular arc with κ = 1

2, iωµ0σ = 1 ε.

|uε

N − uε|H1(Ωε

int) ≤ CεN− 1 2 ,

uε

N − uεH1(Ωε

ext) ≤ Cε2N−1.

⊲ e.g., four functions ⇒ sixth-order scheme O(ε7) (outside the sheet) ⊲ easily increasing order by enrichment with higher optimal basis functions ⊲ pre-computation of integrals in s ⇒ surface variables Error in the H1-seminorm inside the sheet. Error in H1-seminorm outside the sheet.

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 9 / 29

Content

1 Optimal basis inside the sheet 2 Impedance transmission conditions (ITCs) 3 Boundary integral equations for impedance transmission conditions

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 10 / 29

Impedance transmission conditions (ITCs)

− ε 2 ε 2

Ωε

ext

Ωε

ext

Ωε

int Γ x y

Original problem curl curl E = −iωµ0 J in Ωε

ext

curl curl E +iωµ0σ E = 0 in Ωε

int

(1)

− ε 2 ε 2

Ω0

ext

Ω0

ext

Γ x y

Reduced problem with ITC-1-0 (Levi-Civita’1902) curl curl E0 = −iωµ0 J in Ω0

ext

[E0 × n] = 0

• n Γ

[curl E0 × n] − iωµ0σε{E0,T} = 0

• n Γ

(2) ⊲ E0 defined Ω0

ext approximates E in Ωε ext

⊲ layer correction inside Ωε

int can be computed a-posteriori

⊲ limit for ε → 0 for σ = σ(ε) ∼ ε−1

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 11 / 29

Impedance transmission conditions (ITCs)

− ε 2 ε 2

Ωε

ext

Ωε

ext

Ωε

int Γ x y

Original problem (TM mode) −∆u = f in Ωε

ext

−∆u + α δ2 u = 0 in Ωε

int

(1) ⊲ Skin depth δ serves as a parameter

− ε 2 ε 2

Ω0

ext

Ω0

ext

Γ x y

Reduced problem with ITC-1-0 (Levi-Civita’1902) −∆u0 = f in Ω0

ext

[u0] = 0

• n Γ

[∂nu0] − αε δ2 {u0} = 0

• n Γ

(2) ⊲ u0 defined in Ω0

ext approximates u in Ωε ext

⊲ layer correction inside Ωε

int can be computed a-posteriori

⊲ limit for ε → 0 for δ(ε) ∼ √ε

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 11 / 29

Impedance transmission conditions (ITCs)

− ε 2 ε 2

Ωε

ext

Ωε

ext

Ωε

int Γ x y

Asymptotic problem (TM mode) −∆uε = f in Ωε

ext

−∆uε + α δ2(ε)uε = 0 in Ωε

int

(1) ⊲ Skin depth δ serves as a parameter

− ε 2 ε 2

Ω0

ext

Ω0

ext

Γ x y

Reduced problem with ITC-1-0 (Levi-Civita’1902) −∆u0 = f in Ω0

ext

[u0] = 0

• n Γ

[∂nu0] − αε δ2 {u0} = 0

• n Γ

(2) ⊲ u0 defined in Ω0

ext approximates u in Ωε ext

⊲ layer correction inside Ωε

int can be computed a-posteriori

⊲ family ITC-1-N of transmission conditions derived by asymptotic expansion with δ → δ(ε) ∼ √ε, and

K.S. and S. Tordeux, ESAIM: M2AN, 45(6): 1115–1140, 2011.

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 11 / 29

Impedance transmission conditions (ITCs)

Reduced problem with transmission conditions ITC-1-0 (Levi-Cevita’1902) −∆u0 = f in Ω0

ext

[u0] = 0

• n Γ

[∂nu0] − αε δ2 {u0} = 0

• n Γ

⊲ O(ε) : error in exterior decreases linearly with ε along δ(ε) ∼ √ε (proven) ⊲ surprise : even if ε ≫ δ → 0 ⊲ extra accuracy for ε ≪ δ → ∞ u − u0H1(Ωε

ext)

0.1 mm 1 mm 10 mm 0.1 mm 1 mm 10 mm Sheet thickness ε Skin depth δ

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 12 / 29

Impedance transmission conditions (ITCs)

Reduced problem with transmission conditions ITC-1-1 −∆uε,1 = f in Ω0

ext

[uε,1] = 0

• n Γ

[∂nuε,1] − αε δ2

• 1 − αε2

6δ2

• {uε,1}

= 0

• n Γ

⊲ O(ε2) : error in exterior decreases like ε2 along δ(ε) ∼ √ε (proven) ⊲ but only O(ε) in case of ε ≫ δ → 0, no improvement when increasing order N from 0 to 1 ITC-1-0 ITC-1-1

0.1 mm 1 mm 10 mm 0.1 mm 1 mm 10 mm Sheet thickness ε Skin depth δ 0.1 mm 1 mm 10 mm 0.1 mm 1 mm 10 mm Sheet thickness ε Skin depth δ

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 13 / 29

Impedance transmission conditions (ITCs)

Reduced problem with transmission conditions ITC-1-2 −∆uε,2 = f in Ω0

ext

[uε,2] + αε3

12δ2 {∂nuε,2} = 0

• n Γ

[∂nuε,2] − αε δ2

• 1 − αε2

6δ2 + ε2 12

7α2ε2

20δ4 + ∂2 Γ

• {uε,2} = 0
• n Γ

⊲ O(ε3) : error in exterior decreases like ε3 along δ(ε) ∼ √ε (proven) ⊲ but convergence to wrong solution in case of ε ≫ δ → 0, not robust in δ anymore, worse than for low orders N = 0, 1 ITC-1-0 ITC-1-1 ITC-1-2

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 14 / 29

Impedance transmission conditions (ITCs)

Reduced problem with transmission conditions ITC-1-2 −∆uε,2 = f in Ω0

ext

[uε,2] + αε3

12δ2 {∂nuε,2} = 0

• n Γ

[∂nuε,2] − αε δ2

• 1 − αε2

6δ2 + ε2 12

7α2ε2

20δ4 + ∂2 Γ

• {uε,2} = 0
• n Γ

⊲ O(ε3) : error in exterior decreases like ε3 along δ(ε) ∼ √ε (proven) ⊲ but convergence to wrong solution in case of ε ≫ δ → 0, not robust in δ anymore, worse than for low orders N = 0, 1 Let ε fixed and ⊲ δ → ∞ : [uε,2] → 0, [∂nuε,2] → 0 on Γ → no shielding ⊲ δ → 0 : {∂nuε,2} → 0, {uε,2} → 0 on Γ → perfect electric b.c. (PEC) ⇒ only valid results for large enough skin depth δ

0.1 mm 1 mm 10 mm 0.1 mm 1 mm 10 mm Sheet thickness ε Skin depth δ

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 14 / 29

Impedance transmission conditions (ITCs)

Reduced problem with transmission conditions ITC-2-1 (derived for δ(ε) ∼ ε)

K.S. and A. Chernov, SIAM J. Appl. Math., 73(6): 1980–2003, 2013.

−∆uε,1 = f in Ω0

ext

[uε,1] + ε

• 1 −

2δ √αε tanh( √αε 2δ

• {∂nuε,1} = 0
• n Γ

[∂nuε,1] − 2√α tanh(

√αε 2δ )

δ − 1

2

√αε tanh(

√αε 2δ )

{uε,1} = 0

• n Γ

⊲ O(ε2) : error in exterior decreases like ε2 along δ(ε) ∼ ε (proven) ⊲ we observe (numerically) O(ε2) independent of δ(ε) Let ε fixed and ⊲ δ → ∞ : [uε,1] → 0, [∂nuε,1] → 0 on Γ → no shielding ⊲ δ → 0 : [uε,1] + ε{∂nuε,1} → 0 {uε,1} + ε

4 [∂nuε,1] → 0 on Γ

→ perfect electric b.c. (PEC) at Γε ⇒ robust results w.r.t. skin depth δ / conductivity σ

0.1 mm 1 mm 10 mm 0.1 mm 1 mm 10 mm Sheet thickness ε Skin depth δ

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 15 / 29

Impedance transmission conditions (ITCs)

Electromagnetic scattering by thin shielding sheet of thickness ε curl curl Eε −(kε)2 Eε = 0 + Silver-M¨ uller b.c. ⊲ with complex wave-number kε =    kext = ω2µext

• ǫext + i σext(ε)

ω

• ,

in Ωε

ext,

kε

int = ω2µint

• ǫint + i σint(ε)

ω

• ,

in Ωε

int.

Reduced problem with transmission conditions ITC-2-1 (derived for σint(ε) ∼ ε−2)

• V. P´

eron, K.S. and M. Durufle, SIAM J. Appl. Math., 76(3): 1031–1052, 2016.

curl curl Eε,1 −k2

ext Eε,1 = 0

in Ω0

ext

Eε,1 × n

• Γ
• Eε,1 × n
• Γ
• = ε

L1 L3 L3 L2  

• 1

µext (curl Eε,1)T

• Γ
• (

1 µext curl Eε,1)T

• Γ

  + Silver-M¨ uller b.c. ⊲ with the operators Li = Ai curlΓ curlΓ −BiId and constants Ai, Bi ⊲ decoupling of ITCs if material parameters are the same on both sides of Γ ⇒ L3 = 0

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 16 / 29

Impedance transmission conditions (ITCs)

Electromagnetic scattering by thin shielding sheet of thickness ε Variational formulation for reduced problem with transmission conditions ITC-2-1 where V =

• v ∈ H(curl, Ω0

ext), v × n ∈ L2 t (∂Ω)

• ,

W = {v ∈ L2

t (Γ), curlΓ v ∈ L2(Γ)} .

Find (Eε,1, λε, µε) ∈ V × W × W such that for all (E′, λ′, µ′) ∈ V × W × W

• Ω+∪Ω−

1 µext curl Eε,1 · curl E′ − κ2

ext

µext Eε,1 ·E′ dx−

• ∂Ω

iκext µext Eε,1 × n ·E′ × n dS −

• Γ

n ×λε n ×µε

• ·
• [E′

T]

{E′

T}

• dS = r.h.s. ,
• Γ
• [n × Eε,1]

{n × Eε,1}

• ·
• λ′

µ′

• + ε A
• curlΓ λε

curlΓ µε

• ·
• curlΓ λ′

curlΓ µ′

• − ε B
• λε

µε

• ·
• λ′

µ′

• dS = 0 .

⊲ with A = A1 A3 A3 A2

• , B =

B1 B3 B3 B2

• K.Schmidt

RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 17 / 29

Impedance transmission conditions (ITCs)

Electromagnetic scattering by thin shielding sheet of thickness ε Impedance transmission conditions ITC-2-1 for spherical sheet ⊲ Discretization with N´ ed´ elec’s elements of the first kind on hexahedral curved elements and its tangential traces

x1 = 0 x2 = 0 x3 = 0

10−6 10−4 10−2 100 102 10−4 10−3 10−2 10−1 100

÷ 2.02 ÷ 4.07 ÷ 1.05 ÷ 2.01

σε2 Relative L2 error

PEC, ε = 0.02 PEC, ε = 0.01 ITC-2-1, ε = 0.02 ITC-2-1, ε = 0.01

⊲ Impedance transmission conditions are robust w.r.t. skin depth δ / conductivity σ

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 18 / 29

Content

1 Optimal basis inside the sheet 2 Impedance transmission conditions (ITCs) 3 Boundary integral equations for impedance transmission conditions

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 19 / 29

Boundary integral equations for impedance transmission conditions

Reduced problem with transmission conditions on a closed Lipschitz curve/surface Γ −∆U = F in Rd\Γ [γ1U] − β {γ0U} = 0

• n Γ

[γ0U] = 0

• n Γ

(3) γ0, γ1 ... Dirichlet, Neumann traces on Γ, β ... impedance parameter BVP is singularly perturbed for large β (homogeneous Dirichlet b.c. in the limit |β| → ∞) Γ supp(F)

Mathematical model for thin conducting sheets in electromagnetics (d = 2)

→ K.S. and S. Tordeux, ESAIM: M2AN, 2011 → K.S. and A. Chernov, SIAM J. Appl. Math., 2013 and references therein.

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 20 / 29

Boundary integral equations for impedance transmission conditions

Reduced problem with transmission conditions on a closed Lipschitz curve/surface Γ −∆U = F in Rd\Γ [γ1U] − β {γ0U} = 0

• n Γ

[γ0U] = 0

• n Γ

(3) γ0, γ1 ... Dirichlet, Neumann traces on Γ, β ... impedance parameter BVP is singularly perturbed for large β (homogeneous Dirichlet b.c. in the limit |β| → ∞)

Mathematical model for thin conducting sheets in electromagnetics (d = 2)

→ K.S. and S. Tordeux, ESAIM: M2AN, 2011 → K.S. and A. Chernov, SIAM J. Appl. Math., 2013 and references therein.

Boundary integral equations and BEM for impedance boundary conditions

→ A. Bendali and L. Vernhet, CRAS, 1995, L. Vernhet, M2AS, 1999, A. Bendali, 2000.

Boundary integral equations and BEM for several kind of transmission conditions

→ K.S. and R. Hiptmair, Discrete Contin. Dyn. Syst. Ser. S, 2015 and references therein. Aim: Numerical analysis of BEM on uniform meshes in dependence of large parameter β,

• r small parameter ε := β−1, and the smoothness of Γ

When is BEM on uniform meshes ε-robust ?

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 20 / 29

Boundary integral equations for impedance transmission conditions

2nd order elliptic BVP with transmission conditions on a closed Lipschitz curve/surface Γ −∆U = F in Rd\Γ (3a) [γ0U] = 0

• n Γ

(3c) Representation formula U = −S [γ1U] + D [γ0U]

=0

+N F with single layer potential S and Newton potential NF (S φ)(x) :=

• Γ

G(x − y)φ(y)dy (N F)(x) :=

• R2 G(x − y)F(y)dy

G(x − y) =

• − 1

2π log(|x − y|),

d = 2,

1 4π|x−y|,

d = 3. Mean of Dirichlet traces gives the single layer operator V := {γ0S ·} : H−1/2+s(Γ) → H

1/2+s(Γ),

Taking mean traces on Γ {γ0U} = −V [γ1U] + γ0NF (5)

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 21 / 29

Boundary integral equations for impedance transmission conditions

2nd order elliptic BVP with transmission conditions on a closed Lipschitz curve/surface Γ −∆U = F in Rd\Γ (3a) [γ0U] = 0

• n Γ

(3c) Representation formula U = −S [γ1U] + D [γ0U]

=0

+N F with single layer potential S and Newton potential NF (S φ)(x) :=

• Γ

G(x − y)φ(y)dy (N F)(x) :=

• R2 G(x − y)F(y)dy

G(x − y) =

• − 1

2π log(|x − y|),

d = 2,

1 4π|x−y|,

d = 3. Mean of Dirichlet traces gives the single layer operator V := {γ0S ·} : H−1/2+s(Γ) → H

1/2+s(Γ),

Taking mean traces on Γ {γ0U} = −V [γ1U] + γ0NF (5) First transmission condition {γ0U} = ε [γ1U] (3b)

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 21 / 29

Boundary integral equations for impedance transmission conditions

2nd order elliptic BVP with transmission conditions on a closed Lipschitz curve/surface Γ −∆U = F in Rd\Γ (3a) ε [γ1U] − {γ0U} = 0

• n Γ

(3b) [γ0U] = 0

• n Γ

(3c) Single layer operator V := {γ0S ·} : H−1/2+s(Γ) → H

1/2+s(Γ).

Mean Dirichlet trace of representation formulation {γ0U} = −V [γ1U] + γ0NF (5) Boundary integral equations for φ = [γ1U] (insert (3b) in (5)) (εId + V )φ = γ0NF ⊲ Singularly perturbed for ε → 0 (|β| → ∞) ⊲ expect internal layers at corners of Γ

(or points of lower smoothness)

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 22 / 29

Boundary integral equations for impedance transmission conditions

Singularly perturbed boundary integral equations for φ = [γ1U] (ε Id + V )φ = γ0NF Variational formulation: Seek φ ∈ L2(Γ) such that for all φ′ ∈ L2(Γ) bε(φ, φ′) := ε

• φ, φ′

+

• V φ, φ′

=

• γ0NF, φ′

Bilinear form bε is L2(Γ)-elliptic bε(φ, φ) ≥ εφ2

L2(Γ)

⇒ φL2(Γ) ≤ ε−1γ0NFL2(Γ) and H−1/2(Γ)-elliptic since

• V φ, φ′

φ2

H−1

/2(Γ)

(with a constant indep. of ε)

⇒ φ2

H−1

/2(Γ) bε(φ, φ) = γ0NF, φ ≤ γ0NFH1 /2(Γ)φH−1 /2(Γ)

⇒ φH−1

/2(Γ) γ0NFH1 /2(Γ).

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 23 / 29

Boundary integral equations for impedance transmission conditions

Variational formulation: Seek φ ∈ L2(Γ) such that for all φ′ ∈ L2(Γ) bε(φ, φ′) := ε

• φ, φ′

+

• V φ, φ′

=

• γ0NF, φ′

(??) BEM discretization: Seek φ ∈ Vh such that for all φ′ ∈ Vh bε(φh, φ′

h) := ε

• φh, φ′

h

• +
• V φh, φ′

h

• =
• γ0NF, φ′

h

• (7)

where Vh is defined on mesh Th of (curved) panels K as

S−1 (Γh) :=

• vh ∈ L2(Γ) : vh ∈ P0(K) ∀K ∈ Th
• ,

ℓ = 0 S0

1 (Γh) :=

• vh ∈ L2(Γ) ∩ C(Γ) : vh ∈ P1(K) ∀K ∈ Th
• ,

ℓ = 1

Γh n K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 24 / 29

Boundary integral equations for impedance transmission conditions

Variational formulation: Seek φ ∈ L2(Γ) such that for all φ′ ∈ L2(Γ) bε(φ, φ′) := ε

• φ, φ′

+

• V φ, φ′

=

• γ0NF, φ′

(??) BEM discretization: Seek φ ∈ Vh such that for all φ′ ∈ Vh bε(φh, φ′

h) := ε

• φh, φ′

h

• +
• V φh, φ′

h

• =
• γ0NF, φ′

h

• (7)

where Vh is defined on mesh Th of (curved) panels K as

S−1 (Γh) :=

• vh ∈ L2(Γ) : vh ∈ P0(K) ∀K ∈ Th
• ,

ℓ = 0 S0

1 (Γh) :=

• vh ∈ L2(Γ) ∩ C(Γ) : vh ∈ P1(K) ∀K ∈ Th
• ,

ℓ = 1

Theorem (Stability and a-priori error estimates)

Let Th be a mesh of Γ with mesh width h. Then, φh ∈ Vh ⊂ L2(Γ) solution of (7) satisfies φhL2(Γ) ≤ ε−1γ0NFL2(Γ) φhH−1

/2(Γ) γ0NFH1 /2(Γ).

For Vh = S−1

0 (Γh) (ℓ = 0) or Vh = S0 1(Γh) (ℓ = 1) and Γ ∈ C ℓ+1,1 it holds

φ − φhL2(Γ) ε−ℓ−5/2hℓ+1γ0NFHℓ+1

/2(Γ).

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 24 / 29

Boundary integral equations for impedance transmission conditions

Variational formulation: Seek φ ∈ L2(Γ) such that for all φ′ ∈ L2(Γ) bε(φ, φ′) := ε

• φ, φ′

+

• V φ, φ′

=

• γ0NF, φ′

(??) BEM discretization: Seek φ ∈ Vh such that for all φ′ ∈ Vh bε(φh, φ′

h) := ε

• φh, φ′

h

• +
• V φh, φ′

h

• =
• γ0NF, φ′

h

• (7)

Theorem (Stability and a-priori error estimates)

[...] For Vh = S−1

0 (Γh) (ℓ = 0) or Vh = S0 1(Γh) (ℓ = 1) and Γ ∈ C ℓ+1,1 it holds

φ − φhL2(Γ) ε−ℓ−5/2hℓ+1γ0NFHℓ+1(Γ).

Theorem (Higher order regularity estimates)

For Γ ∈ C s+j+1,1 with 0 ≤ j ≤ s it holds φHs+1

/2(Γ) εj−sγ0NFHs+j+3 /2(Γ).

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 25 / 29

Boundary integral equations for impedance transmission conditions

Variational formulation: Seek φ ∈ L2(Γ) such that for all φ′ ∈ L2(Γ) bε(φ, φ′) := ε

• φ, φ′

+

• V φ, φ′

=

• γ0NF, φ′

(??) BEM discretization: Seek φ ∈ Vh such that for all φ′ ∈ Vh bε(φh, φ′

h) := ε

• φh, φ′

h

• +
• V φh, φ′

h

• =
• γ0NF, φ′

h

• (7)

Theorem (Higher order regularity estimates)

For Γ ∈ C s+j+1,1 with 0 ≤ j ≤ s it holds φHs+1

/2(Γ) εj−sγ0NFHs+j+3 /2(Γ).

Theorem (Improved a-priori error estimates)

For Vh = S−1

0 (Γh) (ℓ = 0) or Vh = S0 1(Γh) (ℓ = 1) and Γ ∈ C 2ℓ+3,1 it holds

φ − φhL2(Γ) hℓ+1γ0NFH2ℓ+7

/2(Γ).

Proof: Asymptotic expansion of BEM solution φh = φ0,h + δφ0,h.

Theorem (ε-robust stability estimates)

For Γ ∈ C 2,1 it holds φhL2(Γ) γ0NFH5

/2(Γ).

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 25 / 29

Boundary integral equations for impedance transmission conditions

“Stadium” interface Γ ∈ C 1,1

× ×

R R

Γh

1.0 10−5 10−4 10−3 10−2 10−1 10−8 10−7 10−6 10−5 10−4 10−3 10−2 10−1 mesh-width h φh − φL2(Γ) ℓ = 0 β = 70i β = 5600i β = 448000i 2.0 1.5 10−5 10−4 10−3 10−2 10−1 10−8 10−7 10−6 10−5 10−4 10−3 10−2 10−1 mesh-width h φh − φL2(Γ) ℓ = 1 β = 70i β = 5600i β = 448000i

Solution φ computed w. hp-adaptive FEM using the C++ library Concepts (www.tu-berlin.de/?concepts)

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 26 / 29

Boundary integral equations for impedance transmission conditions

Rectangular interface Γ ∈ C 0,1

×

m Rm b a

Γh

1.0 10−5 10−4 10−3 10−2 10−1 10−6 10−5 10−4 10−3 10−2 10−1 mesh-width h φh − φL2(Γ) ℓ = 0 β = 70i β = 5600i β = 448000i 1.52 1.47 0.5 10−5 10−4 10−3 10−2 10−1 10−6 10−5 10−4 10−3 10−2 10−1 mesh-width h φh − φL2(Γ) ℓ = 1 β = 70i β = 5600i β = 448000i

Solution φ computed w. hp-adaptive FEM using the C++ library Concepts (www.tu-berlin.de/?concepts)

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 27 / 29

Boundary integral equations for impedance transmission conditions

⊲ Transmission conditions of Type II have form (e. g., shielding element by Nakata et.al.) [γ1U] − (β1 − β2∂2

Γ) {γ0U} = 0

• n Γ,

[γ0U] = 0

• n Γ

Boundary integral equation as mixed formulation (1st kind) for φ := [γ1U] ∈ H−1/2(Γ), u := {γ0U} ∈ H1(Γ) V Id −Id β1Id − β2∂2

Γ

φ u

• =

γ0N f

• Variational formulation
• V φ, φ′

Γ

+

• u, φ′

Γ

=

• γ0N f , φ′

Γ

−

• φ, u′

Γ + β1

• u, u′

Γ + β2

• ∂Γu, ∂Γu′

Γ = 0

⊲ singularly pertubed BIE for β1 ≫ 1 (high frequency) or β2 ≪ 1 (always)

K.S. and R. Hiptmair, Discrete Contin. Dyn. Syst. Ser. S, 2015

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 28 / 29

Summary – Impedance conditions for thin electromagnetic shielding sheets

FEM with optimal basis inside the sheet ⊲ σ-robust convergence of high order in thickness ε Impedance transmission conditions ⊲ families ITC-1-N and ITC-2-N of transmission conditions derived by asymptotic expansion with δ(ε) ∼ √ε or δ(ε) ∼ ε ⊲ σ-robust convergence for ITC-1-0 (Levi-Civita), ITC-1-1, ITC-2-1 (also in 3D for Maxwell scattering, NtD operators → mixed formulation) Singularly perturbed boundary integral equation (second kind) (β−1 Id + V )U = γ0NF ⊲ β-robust stability and a-priori error estimates for Γ smooth enough Outlook ⊲ convolution quadrature for impedance transmission conditions in time-domain ⊲ Impedance transmission conditions for eddy current model in 3D ⊲ thin electromagnetic sheets with corners (boundary layer + singularities)

K.Schmidt RICAM SpecSem W1, 18.10.2016 FEM + impedance conditions for thin electromagnetic shielding sheets 29 / 29