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A 14-b 100-MS/s Pipelined ADC With a
Merged SHA and First MDAC
Byung-Geun Lee, Member, IEEE, Byung-Moo Min, Senior Member, IEEE,
Gabriele Manganaro, Senior Member, IEEE, and Jonathan W. Valvano, Member, IEEE
Adviser : Hwi-Ming Wang
Student : Wei-Guo Zhang
Date : 2009/10/28
Outline
 Abstract
 Introduction
 Low-Power Techniques In Pipeline ADC
 Proposed Opamp And Capacitor Sharing Technique
 Circuit Implementation
 Measurement Results
 Conclusion
 References
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Abstract
 This paper presents low-power 14-bit 100-MS/s ADC
 Further reduction of power and area is achieved by
completely merging the front-end sample-and-hold amplifier
(SHA) into the first multiplying digital-to-analog converter
(MDAC) using the proposed opamp and capacitor sharing
technique
 The ADC, implemented in a 0.18-um dual-gate-oxide(DGO)
CMOS technology
 72.4-dB SNDR, 88.5-dB SFDR
 11.7 effective number of bits at full sampling rate
 46-MHz input While consuming 230-mW from a 3-V
supply
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Introduction
 Mobile wireless communication systems are major
applications of recent analog-to-digital converters (ADCs). In
these applications, the specifications of the ADC vary
significantly across different receiver architectures
 IF-sampling superheterodyne receivers require high-speed
high-resolution ADCs, because intermediate frequency (IF)
signals are directly converted to digital codes.
 Regardless of the receiver architectures, low-power
consumption, and small die area are key specifications
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Introduction
 Among various ADC architectures, a pipelined ADC is
suitable for high-speed, high-resolution, and low-power
operation.
 In low or medium speed and resolution pipelined
ADCs,opamp-sharing and switched-opamp techniques are
widely used to reduce power consumption.
 However, these techniques are rarely used for high-speed
high-resolution ADCs because of some drawbacks, such as
memory effects and limited sampling-rate .
 Further power and area savings can be achieved by
removing the front-end SHA .However, maximum input and
sampling frequencies of the ADC without a SHA can be
limited due to aperture error between different input sampling
networks
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Introduction
 In this paper, the opamp-sharing technique is chosen for lowpower and small area. A discharge phase is added to
suppress memory effects. In addition, instead of removing the
SHA, it is merged with the first MDAC. Thus, the ADC
achieves low-power operation without compromising speed
or accuracy
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Low-Power Techniques In Pipeline ADC
 A. Opamp-Sharing Technique(A conventional pipeline stage
operates with a two-phase nonoverlapping clock)
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Low-Power Techniques In Pipeline ADC
 Thus, significant power and area can be saved by reducing
the number of opamps.
 It also has two drawbacks
 since the opamp is always active, there is no time to reset
the opamp and the previous sample stored on the opamp
input capacitance affects the current output
• This can be relaxed by using a feedback signal polarity
inverting (FSPI) technique
 Is that it requires additional switches at the opamp input
node to disconnect the opamp when it is not needed.
• These switches introduce series resistance and
degrade the settling behavior
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Low-Power Techniques In Pipeline ADC
 B. Switched-Opamp Technique
 Switched-opamp was first invented for low-supply operation
 Since the opamp does not need to be active during the
sampling phase, it can be turned off. However, this requires
the opamp to be turned on and off at each clock which limits
the operating speed
 Recently, a partially switched-opamp technique was
proposed to improve the settling behavior at the cost of
power consumption.
 Unlike a conventional switched-opamp technique, the second
stage of the two-stage opamp is turned off during the
sampling phase(when the opamp is not needed).
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Low-Power Techniques In Pipeline ADC
 C. Removing Front-End SHA
 In a typical pipelined ADC with opamp-sharing, the front-end
SHA consumes about 20% to 30% of the total ADC power
and often limits the linearity and dynamic range of the ADC.
 The concept of completely removing the SHA was first
published for low-power operation in
 It has two drawbacks
 it requires a short comparison phase between the
sampling and amplification phases of the first stage and
an additional feedback capacitor decreases the feedback
factor.
 Is an aperture error caused by resistance–capacitance
(RC) delay mismatch between the input networks for the
first multiplying digital to analog converter (MDAC) and the
flash ADC
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Proposed Opamp And Capacitor Sharing Technique
 Further power and area savings can be achieved by sharing
both the opamp and the capacitors
 The idea behind the opamp and capacitor-sharing technique
is that after the current stage generates the output, the
charge on the feedback capacitor is reused for the following
stage instead of being thrown away
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Proposed Opamp And Capacitor Sharing Technique
 Opamp and capacitor-sharing technique.
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Proposed Opamp And Capacitor Sharing Technique
 Two important facts need to be noted on this technique. First,
the amplification phase is about 20% to 30% shorter than that
of a conventional due to the addition of the discharge phase
 Using this technique, the total opamp load in amplification
phase is reduced by about 40% to 60% depending on the
architecture of the stage compared to that of a conventional
one. The reduced output load allows the opamp output to
settle faster to the required accuracy without increasing
power.
 The second important fact relates to the memory effect
 However, since there is no reset phase between1 and2 ,
the stage i+1 has the memory effect. Thus,it is important to
keep the error voltage caused by the memory effect small
such that it does not affect the output of the stage i+1
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Circuit Implementation
 In this prototype design, the SHA is completely merged with
the first MDAC (SMDAC)
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Circuit Implementation
 SMDAC works with three clock phases: sample/amplification
(S/A), discharge and hold phases
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Circuit Implementation
Qtota1  4  CF [Vin ( N ) 
(Vin ( N ))
(Vin ( N ))
]  CP  [0 
]
Ao
Ao
 4  CF  Vin ( N )  (1   )  (1)
Q 'tota1  CF  [Vres1 ( N ) 
 CF  Vres1 ( N )  [1 
(Vres1 ( N ))
(Vres1 ( N ))
]  (3CF  CP )  [0 
]
Ao
Ao
C
1
 (4  P )]  (2)
Ao
CF
 Since the total charge should be
conserved on both phases
4  CF  Vin ( N )  (1   )  CF Vres1 ( N )  [1 
Vres1 ( N ) 
C
1
 (4  P )]  (3)
Ao
CF
4  Vin ( N )  (1   )
 4  Vin ( N )  (1  3 )  (4)
1  4
3  (1/ Ao )(3 / 4)(4  (CP / CF ))
1/   Ao  (1/ Ao )  (4  (CP / CF ))    CF / 4  CF  CP
 The error is even 25% smaller than
that of a conventional SC amplifier.
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Circuit Implementation
The telescopic amplifier with
gain boosting is chosen for high
DC gain and power efficiency.
The opamp achieves more
than 90-dB gain in all corner
simulations. The SMDAC
opamp consumes about 32 mA,
the second stage opamp
consumes about 10 mA, and
the opamps in the rest of the
pipeline stages consume about
8 mA.
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Measurement Results
 The prototype ADC is implemented in 0.18- m DGO CMOS
2
2
mm
mm
technology and occupies a die area of 7.28
(2.8*2.6
).
 This includes the ADC core and the peripheral circuits such
as bandgap, reference buffers,clock,SMDAC,digital error
correction,5 opamp sharing stage&fadc.
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Measurement Results
 The measured differential nonlinearity (DNL) and integral
nonlinearity (INL) are less than 0.8 and 2.1 LSB, respectively
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Measurement Results
 Typical measured FFT plots for the inputs frequencies 46 and
135 MHz
 ENOB=SNDR-1.762/6.02
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 ENOB=11.4dB
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Measurement Results
 Measured dynamic performance versus input and sampling
frequency
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Measurement Results
 The comparison of figure of merit (FOM). FOM  Power
2 ENOB  Fs
 The ADC performance is summarized in Table I.
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Conclusion
 A 14-b 100-MS/s ADC with low power consumption and small
die area has been described
 In addition to sharing an opamp between two successive
pipeline stages, the front-end SHA are completely merged
into the first MDAC by using the proposed opamp and
capacitor sharing technique
 The ADC achieves low power consumption and small die
area while maintaining high-speed high-resolution operation
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References
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[2] K. Nagaraj, H. S. Fetterman, J. Anidjar, S. H. Lewis, and R. G. Renninger,“A 250-mW, 8-b, 52
Msamples/s parallel-pipelined A/D converter with reduced number of amplifiers,” IEEE J.
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[3] B.-M.Min, P. Kim, F. W. Bowman, D. M. Boisvert, and A. J. Aude, “A 69-mW 10-bit 80MSample/s pipelined CMOS ADC,” IEEE J. Solid-State Circuits, vol. 38, no. 12, pp. 2031–
2039, Dec. 2003.
[4] J. Arias, V. Boccuzzi, L. Quintanilla, L. Enriquez, D. Bisbal, M. Banu,and J. Barbolla, “Lowpower pipeline ADC for wireless LANs,” IEEEJ. Solid-State Circuits, vol. 39, no. 8, pp. 1338–
1340, Aug. 2004.
[5] J. Crols and M. Steyaert, “Switched-opamp: An approach to realize full CMOS switchedcapacitor circuits at very low power supply voltages,”IEEE J. Solid-State Circuits, vol. 29, no.
8, pp. 936–942, Aug. 1994.
[6] M.Waltari and K. A. I. Halonen, “1-V 9-Bit pipelined switched-opamp ADC,” IEEE J. SolidState Circuits, vol. 36, no. 1, pp. 129–134, Jan.2001.
[7] D.-Y. Chang and U.-K. Moon, “A 1.4-V 10-bit 25-MS/s pipelined ADC using opamp-reset
switching technique,” IEEE J. Solid-State Circuits,vol. 38, no. 8, pp. 1401–1404, Aug. 2003.
[8] H. C. Kim and D. K. J. Kim, “A partially switched-opamp technique for high-speed low-power
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