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DNC, GEC

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A Digitally Enhanced 1.8V 15-bit 40-MSample/s CMOS Pipelined ADC ... Background Digital Calibration Techniques for Pipelined ADC's ... – PowerPoint PPT presentation

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Title: DNC, GEC


1
DNC, GEC Non-linear interpolation
  • A Review of
  • A Digitally Enhanced 1.8V 15-bit 40-MSample/s
    CMOS Pipelined ADC1
  • Background Digital Calibration Techniques for
    Pipelined ADCs2

2
Pipelined ADC review
  • Non-linearities in DAC levels cause harmonic
    distortion
  • Common solution Try to randomly distribute
    non-linearities in DAC so energy is spread out in
    the frequency spectrum
  • Interstage gain errors reduce SNDR/SNR
  • Solution Apply correction gain digitally

3
Detecting a known signal component in the output
of an unknown system
Mean of td 0
  • Td with a mean of zero
  • Periodic signal
  • Pro Can have a small N since power of td is
    evenly distributed in time
  • Con Delta function in the frequency domain
  • White noise signal
  • Pro Flat power density spectrum
  • Con Need large N, ideally N8

4
A Digitally Enhanced 1.8V 15-bit 40-MSample/s
CMOS Pipelined ADC
5
Outline
  • Dynamic Element Matching (DEM)
  • DAC Noise Cancellation (DNC)
  • Gain Error Correction (GEC)
  • Bootstrapped Switches
  • Timing

6
Pipeline ADC from 1
7
Dynamic Element Matching (1)
  • Errors in DAC paths cause signal dependent error
  • Signal dependent error gt Distortion

8
Dynamic Element Matching (2)
  • Scrambler randomly selects a sequence of Sn such
    that Vout equals (1)
  • The error, e, is uncorrelated with the input
    signal if it is done correctly
  • This will effectively spread DAC noise power in
    the frequency spectrum

(1)
9
DEM encoder from 1
  • With DEM encoder from 1 it can be shown that
    DAC noise inherits statistical properties of the
    pseudorandom sequence used in DEM
  • This can be used to estimate the mismatch in the
    DAC paths
  • Each path error is related to a specific
    pseduorandom sequence

DAC path errors
Known sequences
10
DAC Noise Cancellation
  • Detect presence of known pseduorandom signal,
    sn, in output, un esn, by calculating the
    covariance
  • Estimate DAC path error, e, from covariance
  • Multiply psedurandom sequence by path error
    estimate and subtract from output
  • Repeat for all DAC paths

11
Gain Error Calibration (GEC) from 1
  • Estimate gain error from covariance of digitized
    residue and pseudorandom signal
  • Assuming small e gt(1 e ) 1, multiply
    digitized residue by gain estimate and subtract
    from output

12
Bootstrapped switches
  • Used on continous-time input sampling switches
  • Increased linearity
  • Used on switches connected to mid-supply or
    time-constant matching constrains
  • Reduced resistance

13
Timing
  • First stage amplification is most important
  • Steal time for first stage Flash from second stage

14
Results from 1
  • SFDR is improved by 12dB with DNC and GEC enabled
  • SNDR is improved by 20dB with DNC and GEC enabled

Signal
Without calibration
With calibration
15
Background Digital Calibration Techniques for
Pipelined ADCs
16
Outline
  • Error Model
  • Calibration Method
  • Non-linear Interpolation
  • Quantization Effects on Interpolation

17
Error Model
18
Error measurement
  • Measure gain error in each stage by applying
    known calibration voltage, Vcal-i

19
Simulation results
  • Simulated performance (DNL INL) with and
    without gain calibration

20
Non-linear Interpolation
  • Uses fitting of high order polynomials to
    estimate missing sample.
  • Uses causal and noncausal taps

Normalized coefficients
21
Non-linear Interpolation
  • Limits input bandwidth of converter below Nyquist

Fin lt ½ Nyquist
Fin lt Nyquist
22
Non-linear Interpolation
  • Interpolation error depends on the number of taps
  • Achieve higher bandwith with a certain error by
    using more taps

23
Quantization Effects on Interpolation
  • Quantization noise limits performance of
    interpolation
  • Each tap adds quantization noise to total noise
    power
  • Limits the number of taps

Variance vs number of taps
24
References
  1. Eric Siragusa Ian Galton A Digitally Enhanced
    1.8V 15-bit 40-MSample/s CMOS Pipelined ADC
    IEEE Journal of Solid State, Vol. 39, NO. 12,
    December 2004
  2. Un-Ku Moon Bang-Sup Song Background Digital
    Calibration Techniques for Pipelined ADCs IEEE
    Transatctions on Circuits and Systems-II, Vol.
    44, NO. 2, Febuary 1997
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