Design and Analysis of MEMS Accelerometers
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Transcript of Design and Analysis of MEMS Accelerometers
Sponsored by the IEEE Sensors Council, www.ieee-sensors.org
SENSORS 2013Tutorials: November 3, 2013 Conference: November 4-6, 2013
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Source: Yole Développement, “Inertial Sensors in Mobile Products”, 2012
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M. Judy, Proc. Solid-State Sensors, Actuators, and Microsystems Workshop, Hilton Head Island, SC, Jun. 2004
Source: Yole Développement, “MEMS Packaging sample report”, 2012
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The Evolution of Compact Three Axis Accelerometers, St.J. Dixon-Warren, Chipworks Inc. Source: www.bosch-sensortec.com
Source: System Plus Consulting – Reverse costing sample reports
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LGM-118 Peacekeeper ICBM IMU
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main = −k x
x
ain= −
m
k
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dC
dx=
ε ⋅w ⋅ t
g0 − x( )2dC
dx=ε ⋅2n ⋅ tg0
l
g0
g0
t: thickness, n: # of fingers
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J. Chae, et. al., Journal of Microelectromechanical Systems, Vol. 14, No 2, Apr. 2005
Electrode fixed to substrate
Electrode fixed to mass
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Parameter Units Expression Description
Resonance Frequency Hz Free-vibration frequency of accelerometer
Scale Factor F/(m/s2) Linear term of the acceleration to capacitance change sensitivity
Quadratic non-linearity F/(m/s2)2 Quadratic term of the acceleration to capacitance change sensitivity
Brownian Noise (m/s2)/√Hz Mechanical noise equivalent acceleration
Pull-in Voltage V Voltage required to snap-down moving device to parallel
Bandwidth Hz Approximate 3 dB Bandwidth in over-damped second-order system
ω0 =k
m
MNEA =4k B ⋅T ⋅ω0
Q ⋅m
ΔCx ≈ Sx ⋅ax + Sx2 ⋅ax2 + Sy ⋅ay + Sz ⋅az +C0SxS ⋅ SxS 2 + Sy ⋅ + SzS +C0CC
Scale Factor Non-linearity Cross-Axis Sensitivity Offset
SF2 ≈1
ω04
ε ⋅Aelec
g03
SF ≈1
ω02
ε ⋅Aelec
g02
Vpi =8ω0
2 ⋅m ⋅ g03
27ε ⋅Aelec
ω3dB ≈Q ⋅ω0
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m = ρ ⋅V = ρ ⋅ h ⋅w ⋅ l( )
k =Cn ⋅E ⋅ Ilt3 I =
1
12b3 ⋅h
l
w
h
lt
lt
ρ E I
Cn ≈ 48 Cn ≈ 384 Cn ≈ 36
lt1
lt2
for: lt1 = 2 lt2
b
h
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X( jω)Ain ( jω)
≈1
ω02=m
k
md 2x
dt2+ b
dx
dt+ k x =main
X(s)
Ain (s)=
1
s2 +ω0
Qs+ω0
2
ω << ω0
Q =km
bω0 =
k
m
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1
Q=
1
QSFD
+1
QTED
+1
Qanchor
+1
Qmaterial
1
Q≈
1
QSFD
Plate
Air flow Air flow
ΔP
x
h: Gap size
P: Pressure
µ: Coefficient of viscosity
∂2P∂x2
+∂2P∂y2
=12μeff
h3dh
dt
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b ≈μeff ⋅ l ⋅ t
3
h3
Plate
λ =μP
2kBT
m
Ks ≈λh
μeff ≈μ0
1+ 9.638Ks1.159
Q∝h3
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b ≈nelec ⋅μeff ⋅ l ⋅ t
3
h3
Q =km
b
⋅ l ⋅ t3
h3nelec nelec
µefflth
Dam
ping
coe
ffici
ent (
Ns/
m)
Electrode area (um2) Gap size (nm)
Gap , Area Larger damping
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Vpull−in ≈8
27
k ⋅ g03
ε ⋅nsens ⋅Aelec
SF =ΔCain
≈1
ω02
ε ⋅Aelec
g02
BW3dB ≈Q ⋅ω0
Felec ≈1
2
ε ⋅Aelecg02
V 2
b = μeff ⋅ l ⋅t
g03
⎛
⎝⎜
⎞
⎠⎟
3
⋅ nsens + ndamp( )+ ndadd mpm )nsens(
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Out
put V
olta
ge (m
V)
Applied acceleration (g) Applied acceleration (g) Applied acceleration (g)
Out
put V
olta
ge (m
V)
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MUX
X
DEMUX
Y
Z
ReferenceCapacitor
Z-AXIS GYRO
Y-AXIS GYRO X-AXIS GYRO
3-AXIS ACCEL
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f0 =1
2πk
meff
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f0 =1
2πk +Δkmeff
f0ff =1
2
k +Δk
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Felec =1
2
∂C∂xV 2 =
1
2
ε A(g0 ∓ x)
2V 2
Felec ≈1
2
ε Ag0V 2 ⋅
1
g0±2
g02x +
3
g03x2 ±...
⎛
⎝⎜
⎞
⎠⎟
FelecTOT = Felec1 − Felec2
FelecTOT ≈ε Ag0
⋅ VAC ⋅VP +2 ⋅VP
2
g02x
⎛
⎝⎜
⎞
⎠⎟+
2 ⋅VPVV2
g02x⎞
⎠
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md 2x
dt2+ b
dx
dt+ k x =main +FelecTOT
Mechanical Transfer Function
Input Acceleration
Electrostatic Force
md 2x
dt2+ b
dx
dt+ k −
2ε Ag3
VP2
⎛
⎝⎜
⎞
⎠⎟x =main +
ε Ag2Vac VP
ωTOT =k − 2
ε Ag3VP2
m
∂ωTOT
∂ain≈ −
3
2
ε Akω0 g
4VDC2
g0 ain
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TCF CTE α TCE
f =1
2πk
meff
∝w
ρ ⋅ l2
E = E0 1+TCE ⋅ ΔT( )
w = w0 1+α ⋅ ΔT( ) l = l0 1+α ⋅ ΔT( ) ρ = ρ0 1−3α ⋅ ΔT( )
TCFα =1
f0
df
dT≈α2
f =1
2πk
meff
∝ E
TCFTCE =1
f0
df
dT≈TCE
2TCF ≈ -30 ppm/ºC SF ≈ 500-1500 ppm/g
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f = f0 1+NL2
EI
SF ≈ 200 Hz/g @ 83 KHz
SF ≈ 7.7 Hz/g @ 2.6 KHz
Differential FM Accelerometer
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proof-mass
Vac
ΔC+ ΔC-
x
ain RF
RF
TIA
ΔC-
ΔC+
Vac
VoutΔC
≈ 2 ⋅RF ⋅ jωac ⋅Vacω3dB ≈Q ⋅ω0 Q <1
ωac >>ω3dB
F ⋅ jωj ac ⋅VaVV c
Mag
nitu
de [d
B]
Frequency [rad/s]
ωac
ω3dB
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Amplifying Phase
OTA OTA
Sampling Phase
proof-mass
Vcm
CP2 CN2
x
ain
CP1 CN1
Vout =1
2
VDDCF
CTOT
(CTOT =CP1 −CN1 +C P2−CN 2 )
CP2
CP1
CN1
CN2
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dC
dx=
ε ⋅A
g0 − x( )2 Feedback electrodes
y =FelecFB
≈FextFB
=m ⋅ainFB
Ferr ∝ x ≈ 0
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atest
aref
Programing Interface
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Amp
x
go
proof-massΔC
Felec
VtestAmp
x
go
proof-mass
ain
ΔC
ΔCain
≈1
ω02
ε ⋅Aelec
g02
ΔCVtest2≈
1
2M ⋅ω02
ε ⋅Aelec( )2
g04
Cha
nge
in
Cap
acita
nce
[F]
Input Stimulus
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SC-AMP
proof-mass
CN1CP1
Integrated Self-Test
Ccal
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Vout =1
2
VDDCF
(CP1 −CN1 +CP2 −CN 2 )
=2VDDCF
ΔC +VDD2CF
(CS.P1 −CS.N1 +CS.P2 −CS.N 2 )
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Ceq ≈b0Cb0 + b1Cb1 + b2Cb2 + b3Cb3
(Cb0 +Cb1 +Cb2 +Cb3)+Ct1
Ct2
Ct2 +Ct3
⎛
⎝⎜
⎞
⎠⎟Ct4
SC-AMPproof-mass
CN1CP1
Ceq
Ceq
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Vout =2VDDCF
ΔC +VDD2CF
Cmismatch +0.5VDD −Vcal
CF
Coffset
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SOUT ≈ FIN1
FB+COFF
k
α ⋅FB+COFF
kmodα ⋅FB
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Sponsored by the IEEE Sensors Council, www.ieee-sensors.org
SENSORS 2013Tutorials: November 3, 2013 Conference: November 4-6, 2013
