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A low-power delta-sigma modulator using dynamic-source-follower integrators

A low-power delta-sigma modulator using dynamic-source-follower integrators. Ryoto Yaguchi, Fumiyuki Adachi, Waho Takao. Department of Information and Communication Sciences Sophia University. Outline. Introduction Background & Motivation Our Approach Proposed Integrator (DSFI)

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A low-power delta-sigma modulator using dynamic-source-follower integrators

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  1. A low-power delta-sigma modulatorusing dynamic-source-follower integrators Ryoto Yaguchi, Fumiyuki Adachi, Waho Takao Department of Information and Communication Sciences Sophia University

  2. Outline • Introduction • Background & Motivation • Our Approach • Proposed Integrator (DSFI) • Output Sampling • Circuit Simulation • DS Modulators • 1st-Order DS Modulator • 2nd-Order DS Modulator • Performance Comparison • Conclusion

  3. Outline • Introduction • Background & Motivation • Our Approach • Proposed Integrator (DSFI) • OutputSampling • Circuit Simulation • DSModulators • 1st-Order DSModulator • 2nd-Order DSModulator • Performance Comparison • Conclusion

  4. Background & Motivation Future communication applications need low power and high resolution ADCs. • SAR ADC • Low power operation • Limited resolution • DS ADC • High resolution • Higher power DSADC (Opamp) Resolution SAR ADC (Opamp-less) 1/Power

  5. Approach DS Modulator Analog IN Digital Out Opamp-less Integrator Low Power DS Modulator We proposed a Dynamic Source Follower Integrator

  6. Outline • Introduction • Background & Motivation • Our Approach • Proposed Integrator (DSFI) • OutputSampling • Circuit Simulation • DSModulators • 1st-Order DSModulator • 2nd-Order DSModulator • Performance Comparison • Conclusion 6

  7. Dynamic Source-Follower Amplifier (MDAC) J. Hu, et al., JSSC ‘09 1.Sampling Phase Sampling Vin and Vref 2.Amplification Phase Redistributing charges

  8. Proposed Integrator Previous work Dynamic Source-Follower Amplifier(MDAC) Dynamic Source-FollowerIntegrator Proposed Input Sampling 8

  9. Proposed Integrator Previous work Dynamic Source-Follower Amplifier(MDAC) Dynamic Source-FollowerIntegrator Proposed Feedback path

  10. Output Sampling C2a C2b Output Sampling Charge Redistributing Feedback path Feedback path Two capacitors for charge redistributing and output sampling,indepandently.

  11. Whole Circuit of DSFI

  12. Simulation of DSFI Input Frequency = 20kHz Sampling Frequency = 0.5MHz Bode Plot 30 0.2 20 10 Gain [dB] 0 Input [V] 0 -10 0.1k 1k 10k 100k -0.2 Input Frequency[Hz] 1.0 0 Output [V] Phase [deg] -45 0 -90 -1.0 0.1k 1k 10k 100k 800 950 850 900 1000 Input Frequency[Hz] Time [ms] Successful integratoroperation

  13. Outline • Introduction • Background & Motivation • Our Approach • Proposed Integrator (DSFI) • OutputSampling • Circuit Simulation • DSModulators • 1st-Order DSModulator • 2nd-Order DSModulator • Performance Comparison • Conclusion 13

  14. 1st-Order DS Modulator Vinp Voutp 0.3 Vinn Voutn Input [V] 0 Vdacp Vdacn -0.3 VDD Voutp 2 1 Vdacn Output [V] Vinp 0 Voutn 800 950 850 900 1000 Vdacp Time [ms] Vinn

  15. 1st-Order DS Modulator Spectrum 0 -20 -40 PSD[dB] -60 -80 20dB/dec -100 1k 1M 10k 100k 10M Frequency [Hz] 1st-order noise shaping characteristics are obtained!!

  16. 2nd DSFI 2nd-Order DS Modulator Charging Time Vinp 1st DSFI Charging capacitors before comparator decision Comparator decision Vinn Charging Redistribution To 1st DFSI Voutp To 1st DFSI Voutn

  17. 2nd-Order DS Modulator Spectrum 0 -20 -40 PSD[dB] -60 40dB/dec -80 -100 1k 1M 10k 100k 10M Frequency [Hz] 2nd-order noise shaping characteristics are obtained!!

  18. Performance Comparison 2009 2009 2009 2009 2008 Proposed 0.18-mm, 2nd-order DS modulator has a good power efficiency comparable with those obtained by using 0.13-mm technologies.

  19. Conclusion We proposed a dynamic source-follower integrator (DSFI), and applied it to opamp-less DS modulators. Operation of proposed 1st and 2nd order DS modulatorsdesigned by using a 0.18-mm CMOS technology successfully was confirmed by transistor-level circuit simulation. The designed 20-kHz BW, 73.8dB SNR, 2nd-order DS modulator has a good power efficiency comparable with those obtained by using 0.13-mm technologies.

  20. Output Common-mode Voltage

  21. CMRR at DSFI ・Output equation of typical differential amplifier: CMRR is very good!! ・CMRR: V++V-=0 V+-V-=0 Input p [V] Input p [V] Input n [V] Input n [V] Output [V] Output [V] Time [s] Time [s]

  22. Clock Generators Q:For example, what about any digital circuits you needed to control switches? Non-overlap clock generator TFF-clock generator Input Input Output Output Time Time Generate φ2a,φ2b Generate φ1,φ2

  23. DS modulator power consumption Q:In your power consumption estimation, what kinds of circuits are included? Others 0.5% Comparator 3.7% Clock Generators 7.1% 2nd DSFI 1st DSFI 47.1% 41.6% *)Without the referential voltage generators

  24. Comparison Fairness Q: You compared your simulation results with the experimental results. Is this a fair comparison? We have to examine the comparison on experimental measurement, hereafter!! 2.5mm Clock Generator Comparator 2nd-order DSM 1st-DSFI 2nd-DSFI

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