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A 30-GS/sec Track and Hold Amplifier in 0.13-µm CMOS Technology

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Presentation on theme: "A 30-GS/sec Track and Hold Amplifier in 0.13-µm CMOS Technology"— Presentation transcript:

1 A 30-GS/sec Track and Hold Amplifier in 0.13-µm CMOS Technology
Shahriar Shahramian Sorin P. Voinigescu Anthony Chan Carusone Department of Electrical & Computer Eng. University of Toronto Canada

2 Introduction & Motivation I
Equalization required at high bit rates Analog equalization up to 40 Gb/s Digital equalization is more robust and flexible Digital Equalizer Photo Detector T/H ADC Adaptive Equalizer Clock Recovery Equalized Data Require full rate Track & Hold Amplifiers

3 Introduction & Motivation II
Demonstrated 40-GS/sec THA in SiGe BiCMOS fT and fMAX of 160 GHz CMOS technologies scaling to nanometre fT and fMAX exceed 200 GHz for in production CMOS CMOS is a serious contender for implementing DSP based equalizers above 10 Gb/s

4 Switched Emitter Follower
Introduction & Motivation III Diode Sampling Bridge Switched Emitter Follower J. C. Jensen, et. al. CICC 02 S. Shahramian, et. al. CSICS 05 High speed Low dynamic range Requires diodes High speed Lower supply Isolation in hold mode

5 Switched Source Follower
Introduction & Motivation IV Series CMOS Sampler Switched Source Follower I. H. Wang, et. al. Electronic Letters 06 This work CICC 06 Low supply Low speed due to series CMOS RON Take advantage of high speed CMOS source follower

6 0.13-µm CMOS Technology Simulated fT and fMAX of 80 GHz
8 layer metallization back end with thick RF top metal layers Available triple-well CMOS transistors Available low power (high VTH) transistors

7 THA Block Diagram Data Path Output Input T/H Clock Clock Path TIA TIA
DRV CS TIA T/H Diff. Pair Diff. Pair Input Output DRV CS Clock TIA CML INV Clock Path CS

8 Input Stage Design TIA Active loads Improve open loop Gain, T

9 Input Stage Design Eliminating current source transistor reduces power
TIA Eliminating current source transistor reduces power supply voltage

10 Input Stage Design TIA Signal matching through resistive feedback

11 Input Stage Design TIA Noise matching through transistor sizing

12 Input Stage Design Transistors biased at J = 0.25 mA/µm,
TIA Transistors biased at J = 0.25 mA/µm, increased noise figure for higher bandwidth Simulated bandwidth: 30 GHz Simulated input integrated noise over 30 GHz: 0.5 mVrms

13 Input Stage Design Inductors improve bandwidth, input
TIA Inductors improve bandwidth, input matching and filter high frequency noise

14 Input Stage Design TIA CS Transistors Q1 and Q2 are diode-connected at DC and therefore can bias the next CS stage

15 THA Stage Design T/H Switched source follower for maximum bandwidth

16 THA Stage Design T/H During Track, QSF acts as a source follower
with current IT

17 THA Stage Design T/H During Hold, IT flows through RL which turns
QSF off and isolates CH

18 THA Stage Design T/H QT and QH operate in digital mode and
thus are biased at J = 0.15mA/µm

19 used to drive QT further
THA Stage Design T/H High VTH devices are used to drive QT further into “OFF” region and reduce leakage

20 triple well transistor to
THA Stage Design T/H QSF is implemented as a triple well transistor to reduce VEFF and lower power supply voltage

21 THA Stage Design T/H A linear buffer drives the T/H block with 600mVPP
Diff. Pair T/H A linear buffer drives the T/H block with 600mVPP input and output swing

22 THA Stage Design Diff. Pair T/H Capacitor Cfth is used to match QSF-CGS and thus cancel input signal feedthrough during hold mode

23 THA Stage Design Diff. Pair DRV T/H A linear output driver provides signal to external 50Ω resistors and measurement equipment

24 Clock Distribution Converts a single-ended 30-GHz clock signal
CML INV Converts a single-ended 30-GHz clock signal to a differential signal with 750mVPP swing

25 Chip Micrograph Manufactured using IBM’s 0.13µm CMOS technology The circuit operates from a 1.8V supply and consumes 150mA. TIA CS Diff. Pair Diff. Pair DRV THA CML INV CML INV 1mm CML INV TIA CS 1mm

26 Measurement Results: SP

27 Measurement Results: SP II

28 Time Domain

29 Frequency Domain I

30 Frequency Domain II

31 Frequency Domain III

32 Circuit Comparison fsample [GS/s] Track BW [GHz] THD [dB @ fin] Supply
[V] Power [mW] Process [N / fT] This Work 30 7 1GHz 7GHz 1.8 270 CMOS 0.13µm I. H. Wang el. al. Electronic Letters 06 10 N/A 5GHz 200 0.18µm J. Lee et. al. JSSC 03 12 14 12GHz -5.2 390 InP 120 GHz S. Shahramian et al. CSICS 05 40 43 20GHz 10GHz 3.6 540 SiGe 160 GHz Y. Lu et. al. BCTM 05 5.5 1.5GHz 3.5 700 200 GHz

33 Conclusion CMOS emerges as a contender for high speed DSP based equalizers Discussed the design methodology for CMOS switched source follower THA Demonstrated the first 30-GS/sec THA in CMOS

34 Acknowledgement CMC for chip fabrication and providing CAD tools
NSERC for financial support OIT and CFI for equipment ECIT for providing the network analyzer

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