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Title:
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Oversampling ADC
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Nyquist-Rate ADC
- The black box version of the quantization
process - Digitizes the input signal up to the Nyquist
frequency (fs/2) - Minimum sampling frequency (fs) for a given input
bandwidth - Each sample is digitized to the maximum
resolution of the converter
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Anti-Aliasing Filter (AAF)
- Input signal must be band-limited prior to
sampling - Nyquist sampling places stringent requirement on
the roll-off characteristic of AAF - Often some oversampling is employed to relax the
AAF design (better phase response too) - Decimation filter (digital) can be linear-phase
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Oversampling ADC
- Sample rate is well beyond the signal bandwidth
- Coarse quantization is combined with feedback to
provide an accurate estimate of the input signal
on an average sense - Quantization error in the coarse digital output
can be removed by the digital decimation filter - The resolution/accuracy of oversampling
converters is achieved in a sequence of samples
(average sense) rather than a single sample
the usual concept of DNL and INL of Nyquist
converters are not applicable
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Relaxed AAF Requirement
- Nyquist-rate converters
- Oversampling converters
OSR fs/2fm
Sub-sampling
Band-pass oversampling
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Oversampling ADC
- Predictive type
- Delta modulation
- Noise-shaping type
- Sigma-delta modulation
- Multi-level (quantization) sigma-delta modulation
- Multi-stage (cascaded) sigma-delta modulation
(MASH)
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Oversampling
Nyquist
Oversampled
? OSR M
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Noise Shaping
Push noise out of signal band
?
Large gain _at_ LF, low gain _at_ HF ? Integrator?
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Sigma-Delta (S?) Modulator
First-order S? modulator
- Noise shaping obtained with an integrator
- Output subtracted from input to avoid integrator
saturation
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Linearized Discrete-Time Model
Caveat E(z) may be correlated with X(z) not
white!
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First-Order Noise Shaping
- Doubling OSR (M) increases SQNR by 9 dB (1.5
bit/oct)
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SC Implementation
- SC integrator
- 1-bit ADC ? simple, ZX detector
- 1-bit feedback DAC ? simple, inherently linear
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Second-Order S? Modulator
- Doubling OSR (M) increases SQNR by 15 dB (2.5
bit/oct)
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2nd-Order S? Modulator (1-Bit Quantizer)
- Simple, stable, highly-linear
- Insensitive to component mismatch
- Less correlation b/t E(z) and X(z)
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Generalization (Lth-Order Noise Shaping)
- Doubling OSR (M) increases SQNR by (6L3) dB, or
(L0.5) bit - Potential instability for 3rd- and higher-order
single-loop S? modulators
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S? vs. Nyquist ADCs
S? ADC output (1-bit)
Nyquist ADC output
- S? ADC behaves quite differently from Nyquist
converters - Digital codes only display an average
impression of the input - INL, DNL, monotonicity, missing code, etc. do not
directly apply in S? converters ? use SNR, SNDR,
SFDR instead
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Tones
- The output spectrum corresponding to Vi 0
results in a tone at fs/2, and will get
eliminated by the decimation filter - The 2nd output not only has a tone at fs/2, but
also a low-frequency tone fs/2000 that cannot
be eliminated by the decimation filter
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Tones
- Origin the quantization error spectrum of the
low-resolution ADC (1-bit in the previous
example) in a S? modulator is NOT white, but
correlated with the input signal, especially for
idle (DC) inputs. - (R. Gray, Spectral analysis of sigma-delta
quantization noise) - Approaches to whitening the error spectrum
- Dither high-frequency noise added in the loop
to randomize the quantization error. Drawback is
that large dither consumes the input dynamic
range. - Multi-level quantization. Needs linear
multi-level DAC. - High-order single-loop S? modulator. Potentially
unstable. - Cascaded (MASH) S? modulator. Sensitive to
mismatch.
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Cascaded (MASH) S? Modulator
- Idea to further quantize E(z) and later subtract
out in digital domain - The 2nd quantizer can be a S? modulator as well
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2-1 Cascaded Modulator
DNTF
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2-1 Cascaded Modulator
- E1(z) completely cancelled assuming perfect
matching between the modulator NTF (analog
domain) and the DNTF (digital domain) - A 3rd-order noise shaping on E2(z) obtained
- No potential instability problem
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Integrator Noise
INT1 dominates the overall noise Performance!
Delay ignored
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References
- B. E. Boser and B. A. Wooley, JSSC, pp.
1298-1308, issue 6, 1988. - B. H. Leung et al., JSSC, pp. 1351-1357, issue 6,
1988. - T. C. Leslie and B. Singh, ISCAS, 1990, pp.
372-375. - B. P. Brandt and B. A. Wooley, JSSC, pp.
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4, 1995. - R. T. Baird and T. S. Fiez, TCAS2, pp. 753-762,
issue 12, 1995. - T. L. Brooks et al., JSSC, pp. 1896-1906, issue
12, 1997. - A. K. Ong and B. A. Wooley, JSSC, pp. 1920-1934,
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References
- T. Burger and Q. Huang, JSSC, pp. 1868-1878,
issue 12, 2001. - K. Vleugels, S. Rabii, and B. A. Wooley, JSSC,
pp. 1887-1899, issue 12, 2001. - S. K. Gupta and V. Fong, JSSC, pp. 1653-1661,
issue 12, 2002. - R. Schreier et al., JSSC, pp. 1636-1644, issue
12, 2002. - J. Silva et al., CICC, 2002, pp. 183-190.
- Y.-I. Park et al., CICC, 2003, pp. 115-118.
- L. J. Breems et al., JSSC, pp. 2152-2160, issue
12, 2004. - R. Jiang and T. S. Fiez, JSSC, pp. 63-74, issue
12, 2004. - P. Balmelli and Q. Huang, JSSC, pp. 2161-2169,
issue 12, 2004. - K. Y. Nam et al., CICC, 2004, pp. 515-518.
- X. Wang et al., CICC, 2004, pp. 523-526.
- A. Bosi et al., ISSCC, 2005, pp. 174-175.
- N. Yaghini and D. Johns, ISSCC, 2005, pp.
502-503. - G. Mitteregger et al., JSSC, pp. 2641-2649, issue
12, 2006. - R. Schreier et al., JSSC, pp. 2632-2640, issue
12, 2006.
