Mixed signal systems and integrated circuits signal... · 2010. 4. 2. · quantizer and dynamic...

2008/1/18 A. Matsuzawa 1

Mixed signal systems and integrated circuits

Akira Matsuzawa

Tokyo Institute of Technology

2008/1/18 A. Matsuzawa 2

Over sampling ADC and DAC

Sigma-delta modulation

1. Z transform2. Noise shaping3. Sigma-delta modulation4. SNR5. Hider order system6. Multi-stage Sigma-delta modulation7. Recent important developments8. Design example

2008/1/18 A. Matsuzawa 3

Higher order sigma-delta modulation

Higher order sigma-delta modulator becomes unstable easily.

Cascade connection of the integrators Quantizer

111

−− z 111

−− z 1−z... Q

( ) ( ) ( ) ( )

( ) )z(Ez)z(X)z(Y

QYz

z.....YzzY

zzX

zY

k

kkk

1

1

1

11

1

1

1

1

1

11111

−

−

−

−−

−

−

−

−

−+=

∴

+−

−−−

−−

−−

=

111

−− z

OutHIn

The feed back loop becomes unstabledue to large phase delay,When the order is larger than 2.

Increase the resolution of the quantizerfor stabilization

3rd-- >10 steps 4 th ---- >30

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Actual 4th order Sigma-delta ADC

+X +1

1

1 −

−

− zz

a2a1

+1

1

1 −

−

− zz

1

1

1 −

−

− zz

nQ Y+

a3 a4

1

1

1 −

−

− zz

( )( ) ( ) ( ) ( ) 4

1311

2221

3131

441

41

11111

−−−−−−−−

−

+−+−+−+−

−

zazzazzazzazzNTF :

Needs adjustment coefficients for system stabilization.

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Feed forward type

( ) ( )

( ) ( )

( ) ( )N

kikk

ii

ikk

ii

k

N

k

ii

i

QAzXa

A

zaY

zazzA

QYzXaz

aY

1

0

1

1

1

1

11

10

11

11

11

1

−

−−

=

−−

=

−−

−

=−

−+

−=

−+−≡

+−⎪⎭

⎪⎬⎫

⎪⎩

⎪⎨⎧

−=

∑

∑

∑

( )N

k

kkc

QazXaY

aAffz1

0

1

1

1−

−

−+≅∴

≅∴<<≅ )(

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Feed forward technique

Feed forward technique is effective to stabilize the feed back loop.

111

−− z+ 111

−− z +1−z

...Quantization

QOut

a1a2 ak-1

111

−− z

H

In

Adjust the coefficients to satisfy the feed back stability.

( ) ( )

( ) ( )

( ) ( )N

kikk

ii

ikk

ii

k

N

k

ii

i

QAzXa

A

zaY

zazzA

QYzXaz

aY

1

0

1

1

1

1

11

10

11

11

11

1

−

−−

=

−−

=

−−

−

=−

−+

−=

−+−≡

+−⎪⎭

⎪⎬⎫

⎪⎩

⎪⎨⎧

−=

∑

∑

∑( )

Nk

kkc

QazXaY

aAffz1

0

1

1

1−

−

−+≅∴

≅∴<<≅ )(

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General expression of ΣΔ modulator

Quantizer Output signalInput signal

+ )(zH

)(zF

nQX Y

nQzFzH

XzFzH

zHY)()()()(

)(+

++

=1

11

)()()(

zFzHzH

+1STF: Signal Transfer Function

)()( zFzH+11

NTF: Noise Transfer Function

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Actual SNR of Sigma delta ADC

M 阪大 谷口教授より

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Pole, zero, and frequency characteristics

Unit circle

Zeros: Z=1Quadrature

Poles

阪大 谷口教授より

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Design for position of zeros

Deeper blacking for noise in signal-band

1=z

Spiting zeros on the unit circle

阪大 谷口教授より

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Local resonators

Local resonator can form the zeros

)()(:

zFzHNTF

+11

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Effect of zero-spreading

阪大 谷口教授より

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MASH (Multi-stage noise shaping)

111

−− z+

1−z

Q1

+

+

11 −− z

111

−− z+

1−z

Q2

+

+

11 −− z

111

−− z+

1−z

Q3

X

-Q1

-Q2

1st

quantization noise

Y1Y

Y2

Y3

2nd

quantization noise

( )( )( ) 3

123

21

12

11

1

11

1

QZQYQZQY

QZXY

−

−

−

−+−=

−+−=

−+=

( ) ( )( ) 3

31

321

21

1

1

11

QZXY

YZYZYY−

−−

−+=∴

−+−+=

Feed forwarded multi-stage noise shaping architecture is free from instability,however requires good matching.

Realizing the stable 3rd order sigma delta modulation.

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Continuous time ΣΔADC

We can make sigma delta ADC with CT filter.

L. Breems and J.H. Huijsing,”Continuous-time sigma-delta modulation for A/D conversion in radio Receivers”Kluwer

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Effect of clock jitter

SNR of CT ΣΔADC is very sensitive to the clock jitter.In contrast, DT type is not so.

DAC Pulse

2281

Tbwit Mf

SNR∆

≈σlim_

Ts

SNR=85dB, M=32, fbw=1.25MHz, 2.8psfbw=12.5MHz, 0.028ps

T∆σ

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High dynamic range design

Sigma delta method with multi-bit quantizer and dynamic element matching technique realized 25MS/s, 80dB ADC.

P. Balmelli, et al., ISSCC 2004

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Add new functionSigma-delta ADC can change the performance by changing over sampling ratio and filter characteristics. High DR and narrow BW

Low DR and wide BW Compatible:

T. Burger and Q. Huang, ISSCC 2001

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Add new functionDelta-sigma ADC can use complex band-pass filter.Analog filter and VGA can be removed from IF stage.

gm-C filter

K. Philips, ISSCC 2003

Complex band-pass sigma-delta

5th order complex sigma-delta 1b, @64MHz

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LV and LP design0.8V 1.5mW CT sigma-delta modulator attained 50dB at 2MHz in.

Low voltage OTA

Conventional SC integrator

2nd order, 16x over sampling ADC

Simple low voltage OTA enabled itT. Ueno, et al., ISSCC 2004

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Design example of ΣΔ型ADC

Matsuzawa Lab. Now designing high speed sigma delta ADC

Signal bandwidth：10MHzDynamic range： >80dB

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Design issuesフィルタ・ 高次の方が量子化ノイズ抑制大・ しかし安定性確保が困難

サンプリング容量・ 小さいと高スルーレート・ しかしｋＴ/Ｃノイズ大

量子化ノイズ・ 量子化器が高分解能だと少ない・ しかし限界や非理想性がある

オペアンプ・ 初段の入力換算ノイズは抑制がきかない・ 実際のゲインは有限

近似

＋

量子化ノイズ QN

＋

クロック

フィルタ

DAC

量子化器入力 Ｘ（アナログ）

出力 Ｙ（デジタル）

＋－

量子化器・ 積分非直線誤差（ＩＮＬ）や微分非直線性誤差（ＤＮＬ）がある

クロックジッター・ サンプリング時間のずれが雑音を生じる

ＤＡＣ素子のばらつき・ フィードバック抑制がきかない

MATLAB/Simulink の可変パラメータモデルによるシミュレーション

どこがどの程度性能に影響するのか？

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Architecture

シミュレーションの概要

１、上図のフィルタの係数を決定する

２、以下の可変パラメータ・ノイズ・非理想性を加えたモデルの作成振幅・周波数等 量子化器積分非直線性誤差オーバーサンプリング率 ＤＡＣ素子ばらつき量子化分解能 オペアンプノイズジッター オペアンプゲインスルーイング 振幅範囲

サンプリング容量（ｋＴ/Ｃノイズ）

３、各パラメータを変化させてシミュレーションを行いＳＮＲをグラフ化、考察

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Transfer function, pole and zero location for stability

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Simulation model with Simulink

積分器係数0.75 0.40 0.30 0.15 0.15ローカルフィードバック係数0.05 0.25（比較用に 0.0 0.0 も）

信号帯域 10MHzサンプリング周波数 640MHz（オーバーサンプリング率32）量子化器分解能 4bit

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SNR vs. Input signal intensity

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SNR vs. M

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SNR vs. Quantizing level

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SNR vs. Jitter

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SNR vs. Capacitor

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SNR vs. quantizer INL

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SNR vs. DAC nonlinearity

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SNR vs. gain of OP amp

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References

• J.C. Candy and G.C. Tems, “Oversampling Delta-Sigma Converters,” IEEE Press, 1992.

• Rudy van de Plassche, “ CMOS Integrated Analog to Digital and Digital to Analog Converters,” Kluwer.

• F. Medeiro, A. Perez-Verdu and A. Rodriguez-Vazquez, “Top-Down Design of High-Performance Sigma-Delta Modulators,”, Kluwer.

• C. Toumanzou, G. Moschytz, and B. Bilbert, “Trade-offs in Analog Circuit Design,” Kluwer.

• 岩田 「CMOSアナログ回路設計技術」 トリケップス