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Instrumentation-on-chipBasic considerations
Giorgio FerrariDipartimento di elettronica, informazione e bioingegneria
Politecnico di Milano
Milano, November 24 2016
Electrical characterisation of nanoscale samples & biochemical interfaces: methods and electronic instrumentation
Instrumentation-on-chip - G. Ferrari2
OUTLOOK of the LESSON
Motivations for instrumentation based on CMOS integrated circuits Examples How to reduce 1/f noise How to design high value resistances
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Instrumentation-on-chip - G. Ferrari3
Standard experimental setup
CcableCampCDUT
+
Vbias
Nano/micro sample
Heavy (kg)Bulky (dm3)
Expensive (k€)Multchannel capability is limited
no portability
Long cables
e.m. interference Large capacitancecoax.cable: 80pF/m
Higher noise
Instrumentation-on-chip - G. Ferrari4
Improving the Signal-to-Noise Ratio
100 1k 10k 100k 1M1f
10f
100f
1p
Cur
ren
t no
ise
[A/s
qrt
(Hz)
]
Frequency [Hz]
222ampcableDUTn CCCe
CDUT
+Vbias
CMOS preamplifier
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e.m. interferences
+
Vbias
Nano/micro sample
Power supply:• 50Hz• 50kHz-10MHz
Other experiments
Loop antenna
Ideal solution:• shielding without increasing the capacitance• shorter cables
Instrumentation-on-chip - G. Ferrari6
Reducing the e.m. interferences
+
Vbias
Nano/micro sample
Power supply:• 50Hz• 50kHz-10MHz
Other experiments
Loop antenna
• Faraday cage to shield the smallest signals• Shielded cables for the amplified signals
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Instrument-on-a-chip
• Portable systems: weight: g, size: mm, power: mWor wearable:
C RAC
sample
Instrument on a chip
IntegratorDouble Lock-In amp.& ADC
Poten-tiostat
amp. + processing (analog and/or digital)
Google glass
Instrumentation-on-chip - G. Ferrari8
Instrument-on-a-chip
C RAC
sample
Instrument on a chip
IntegratorDouble Lock-In amp.& ADC
Poten-tiostat
amp. + processing (analog and/or digital)
• Portable systems: weight: g, size: mm, power: mWor implantable
Fully implantable wireless neural recording microsystem (not drawn to scale).
X. Zou et al. IEEE Trans. Circuits Syst. I Regul. Pap., pp. 2584–2596, 2013.
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Instrument-on-a-chip
• Portable systems: weight: g, size: mm, power: mW
… wearable…
… implantable…
C RAC
sample
Instrument on a chip
IntegratorDouble Lock-In amp.& ADC
Poten-tiostat
amp. + processing (analog and/or digital)
• Multichannel capability
Instrumentation-on-chip - G. Ferrari10
Multichannel microsystems
Processing unit
Limited by the number of physical connections ( 64 )
Intan, RHA2000
CMOS chip
• Multi-parameters meas.• Speed-up an experiment
• Multi-point sensing of a complex system
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Multichannel microsystems E.H.M. Heijne,”How Chips Pave the Road to the Higgs Particle and the Attoworld Beyond”, ISSCC 2014
Large Hadron Collider at CERN
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Multichannel microsystems E.H.M. Heijne,”How Chips Pave the Road to the Higgs Particle and the Attoworld Beyond”, ISSCC 2014
The ATLAS experiment has 5x104 of these ICs installed!!!
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Multichannel microsystems E.H.M. Heijne,”How Chips Pave the Road to the Higgs Particle and the AttoworldBeyond”, ISSCC 2014
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A step further…
Better: in a single chip
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A step further…
• Light: CMOS imager• Force: MEMS• Capacitance: touch screen• Magnetic field: compass• …Biosensor ?
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CMOS biochip
CaptureProbe
Target Molecule
CMOS Chip Design(Analog/Mixed‐Mode IC Design)
Post‐CMOSProcessing
(MEMS “Lite”)
2+1 major components in a CMOS biochip
Hassibi, SiNano 2012
Graham et al., Sensors p.4943, 2011
Aluminium
oxide corrosion (Cl−) biocompatibility?
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CMOS biochip
CaptureProbe
Target Molecule
CMOS Chip Design(Analog/Mixed‐Mode IC Design)
Post‐CMOSProcessing
(MEMS “Lite”)
Bio‐functionalization
(Surface Chemistry/Spotting Procedures)
2+1 major components in a CMOS biochip
Hassibi, SiNano 2012
U. Frey, MEMS 2007
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High-density MicroElectrode Array
CMOS chip as active substrate for neural recording and stimulation
M. Ballini, J. Muller, P. Livi, Yihui Chen, U. Frey, A. Stettler, A. Shadmani, V. Viswam, I. Lloyd Jones, D. Jackel, M. Radivojevic, M. K. Lewandowska, Wei Gong, M. Fiscella, D. J. Bakkum, F. Heer, and A. Hierlemann, “A 1024-Channel CMOS Microelectrode Array With 26,400 Electrodes for Recording and Stimulation of Electrogenic Cells In Vitro,” IEEE J. Solid-State Circuits, vol. 49, no. 11, pp. 2705–2719, 2014.
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High-density MicroElectrode ArrayM. Ballini, J. Muller, P. Livi, Yihui Chen, U. Frey, A. Stettler, A. Shadmani, V. Viswam, I. Lloyd Jones, D. Jackel, M. Radivojevic, M. K. Lewandowska, Wei Gong, M. Fiscella, D. J. Bakkum, F. Heer, and A. Hierlemann, “A 1024-Channel CMOS Microelectrode Array With 26,400 Electrodes for Recording and Stimulation of Electrogenic Cells In Vitro,” IEEE J. Solid-State Circuits, vol. 49, no. 11, pp. 2705–2719, 2014.
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High-density MicroElectrode Array
11,011 electrodes,126 recording and stimulation channels, for extracellular bidirectional communication with neurons !26’400 platinum
electrodes!
1024 readout channel (voltage)
ADC
Voltage or current stimulation
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High-density MicroElectrode Array
Chip: 7.6 x 10.1 mm2; sensing area: 2 x 4 mm2; power dissipation: 75mW
9.3 x 5.4 m2
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High-density MicroElectrode Array
A. Hierlemann, Tech. Dig. - Int. Electron Devices Meet. IEDM, 2016
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CMOS nanocapacitor arraysC. Laborde, F. Pittino, H. A. Verhoeven, S. G. Lemay, L. Selmi, M. A. Jongsma, and F. P. Widdershoven, “Real-time imaging of microparticles and living cells with CMOS nanocapacitor arrays.,” Nat. Nanotechnol., vol. 10, no. 9, pp. 791–5, 2015.
Dielectric properties at high-frequency (50MHz)
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CMOS nanocapacitor arrays
256 x 256 gold electrodes!90 nm radius, thickness 25nm,
0.6 m x 0.9 m grid
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CMOS nanocapacitor arrays
• Charge-based measurement• Up to 50MHz• Equivalent capacitance • Nonselected electrodes are CE
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CMOS nanocapacitor arrays
The particles are shielded by the double-layer capacitance at “low” frequency (only particles in direct contact with the electr.)
Microparticle (4.4 m radius) sedimentation
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CMOS nanocapacitor arrays
The particles are shielded by the double-layer capacitance at “low” frequency (only particles in direct contact with the electr.)
Microparticle (4.4 m radius) sedimentationDouble layer
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CMOS nanocapacitor arrays
Dielectric (≈ 2.6) and conductive particles (2.5 m radius)
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Single chip Airborne PM Detector
CMOS Particulate Matter detector:
• Scaled lithography for microelectrodes on chip
• Integrated electronics with ZeptoFarad resolution
• Compactness
• Low cost / mass production
CMOS ASIC
2mmP. Ciccarella, et al., IEEE ISSCC 2016.P. Ciccarella, et al., IEEE JSSC 2016
Next lesson
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OUTLOOK of the LESSON
Motivations for instrumentation based on CMOS integrated circuits Examples How to reduce 1/f noise How to design high value resistances
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Challenges of CMOS integration
• Active devices limited to MOSFET
high 1/f noise
• Capacitors value ~ <100pF (1fF/m2 )
• Resistors value ~ <1M (1k/ high value module)
• 4kT/1M noise of 4pA on BW=1kHz,126pA on BW=1MHz
• RC time constants ~ < 100s, low-pass filters?
A bag of tricks to overcome these limitations!
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1/f noise
Amplifiers have offset and 1/f noise
frequency
Noise power spectral density 1/f
1/f is part of an electronic system (out of equilibrium condition)How to reduce the high 1/f noise of MOS transistors:
• Increase the area of transistor• pMOS better than nMOS• Dynamic reduction techniques
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Chopping principle
LPFVn Vout
Vin
Offset1/f noise
Vch
Signal is modulated, amplified and then demodulatedOutput is continuously available
-1
+1
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Square wave modulation
Square wave is easily generated (digital oscillator)…… and multiplication is easily implemented
(4 switches)
m
m
m
ms(t)
m(t)
out(t)
-1
+1Vin(t)
Vout(t)
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Square wave modulation
m
m
m
ms(t)
m(t)
out(t)
-1
+1Vin(t) Vout(t)=Vin(t)
Square wave is easily generated (digital oscillator)…… and multiplication is easily implemented
(4 switches)
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Square wave modulation
m
m
m
ms(t)
m(t)
out(t)
-1
+1Vin(t) Vout(t)=-Vin(t)
Square wave is easily generated (digital oscillator)…… and multiplication is easily implemented
(4 switches)
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Chopper in the frequency domain
1/f completely removed!
fch> 1/f corner freq.
K. M
akin
wa,
Dyn
amic
Offs
et-C
ance
llatio
n
Tech
niqu
es, S
mar
t Sen
sor
Sys
tem
s ‘0
2
BWLPF< fch
BWamp> fch
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Chopper technique
+ Amplifiers with sub-microvolt offset
+ Eliminates 1/f noise
- Reduction of the bandwidth (LPF required)
- Increases current noise (charge injection of the input switches)
C.C. Enz, G.C.Temes, “Circuit techniques for reducing the effects of op-amp imperfections: autozeroing, correlated double sampling and chopper stabilization,” Proc. of the IEEE, vol. 84, no. 11, Nov. 1996, p. 1584 -1614
J. Xu, Q. Fan, J. H. Huijsing, C. Van Hoof, R. F. Yazicioglu, and K. A. A. Makinwa, “Measurement and Analysis of Current Noise in Chopper Amplifiers,” IEEE J. Solid-State Circuits, vol. 48, no. 7, pp. 1575–1584, Jul. 2013.
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Challenges of CMOS integration
• Active devices limited to MOSFET
high 1/f noise
• Capacitors value ~ <100pF (1fF/m2 )
• Resistors value ~ <1M (1k/ high value module)
• 4kT/1M noise of 4pA on BW=1kHz,126pA on BW=1MHz
• RC time constants ~ < 100s, low-pass filters?
A bag of tricks to overcome these limitations!
Instrumentation-on-chip - G. Ferrari40
High value resistance
High value resistor = small current with large applied voltage
Equivalent resistance: Vin/Iout = N Rf
Output noise = equivalent to N2Rf (+ cur. div. noise)4
⋅1
Rail-to-rail input voltage
Vin
Rf Iin Current divider0V
0V
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>0V 0V
Current divider
in1
2out I
W
WI
IoutVin
VM
T2
T1
+
-Rf Iin
VSD1=VSD2
L1=L2
2
1f
out
ineq W
WR
I
VR
VSD1
VSD2
W1>>W2 High value resistor set by geometry and Rf
p p
n wellp substrate
S DG
p p
n wellp substrate
S DG
N wellP substrate
0V
Bi-directional !
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High value – low noise resistor
IoutVin
VM
T2
T1
+
-Rf Iin
nA driving capability:Rf=300k W1/W2=100
Req=30M, Iout max 30nA
2
1
2
f W
W
R
4kT
Equivalent to a 3G resistor!!!
Rf Output Noise:
T2 Output Noise
In both cases shot noise: 2qIout
Dominant for |Iout|>20pA
Worst case:Iout=10nA Rnoise=5M
F. Gozzini et al., Electronics. Letters 42 (2006) 1069-1070
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Very high value resistor
Vin
+
-
Tb1 Ta1Rin
Ia
Ib
+
-
Tb2 Ta2
+
-
Tb3 Ta3
+
-
Tb4 Ta4
Iout
b1
a1
W
W
La=Lb
Ia= Ib b4
a4
b3
a3
b2
a2
b1
a1
in
inout W
W
W
W
W
W
W
W
R
VI
If Wb/Wa=100 Req=Rin 108 !!
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300GΩ equivalent resistor
-1,5 -1,0 -0,5 0,0 0,5 1,0 1,5-6
-4
-2
0
2
4
6
I ou
t [p
A]
Vin [V]
Req = 300G% 5%
-10m -5m 0 5m 10m-40f
-20f
0
20f
Vin [V]
+ Good linearity, rail-to-rail operation, fA capability- Practical limitations: transistor mismatch and OpAmps offset
Avoid on the signal path!
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H(s)
Ci
-
+ Cd
VAC
Rd
-
+
is
VDC
RDC
Active reset network (see M. Sampietro lesson)
1 10 100 1k 10k 100k 1M 10
10M
100MDC
out
ACout
fm
Frequency [Hz]
80Hz – 5MHz
Frequency response
AC outDC out
RDC = 50M
H(s): ≈ 1s (300G)
G. Ferrari, F. Gozzini, A. Molari, M. Sampietro, JSSC 44 (2009) 1609
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Summary
• CMOS amplifiers / instruments: • Better SNR
• Multichannel applications
• Active substrate of the experiment
• CMOS limitations:• Materials: aluminum pad post-processing for biodevices
• R,C values, 1/f noise
• … it requires custom design!