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A Linear Regulator with Fast Digital Control for Biasing of Integrated DC-DC Converters A-VLSI class presentation Adopted from isscc Presented by: Siamak.

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Presentation on theme: "A Linear Regulator with Fast Digital Control for Biasing of Integrated DC-DC Converters A-VLSI class presentation Adopted from isscc Presented by: Siamak."— Presentation transcript:

1 A Linear Regulator with Fast Digital Control for Biasing of Integrated DC-DC Converters A-VLSI class presentation Adopted from isscc Presented by: Siamak Mehrnami

2 2 Outline ●Integrated DC-DC converters ●Linear regulator with digital control ●Implementation details ●measurements ●Conclusions

3 3 Integrated DC-DC Converters ●Demonstrated at 100MHz, η=87.7% Ref.: [3]

4 4 Problem: Low Input Voltage ●The CMOS process limits the DC-DC converter input voltage to 1.2-1.4V Ref: [1]

5 5 Doubling of Input Voltage Range ●V IN is across two transistors in series ●Need a ½-rail linear regulator Ref.: [4]

6 6 High tension power delivery through implicit voltage conversion ref:[2] 2V DD system 3V DD system 

7 7 Auxiliary Regulator Requirements ●Calculate Figure of Merit –single value to measure performance Ref:[1]

8 8 Auxiliary Regulator Figure of Merit ●Best known regulator had FOM=22ps –Rajapandian, et al., 2005 ISSCC, p. 298 ●Need same speed at 3X lower power ref:[1]

9 9 Traditional Linear Regulators ●Class-A buffer has poor slew rate ●Class-AB buffer degrades stability ref:[1]

10 10 Regulator with Digital Control ●Digital buffers (inverters) are perfect class- AB circuits, fast and low power ref:[1]

11 11 Push-Pull ½-Rail Regulator ref:[1]

12 12 Template Cell Design for Matching ref:[1]

13 13 Customized Inverter Cells ref:[1]

14 14 Floorplan of Matched Inverters ref:[1]

15 15 Regulator Test Chip in 90nm CMOS ref:[1]

16 16 Input-Output DC Characteristic ref:[1]

17 17 Output DC Characteristic ref:[1]

18 18 Load Step Response (5ns/div) ref:[1]

19 19 Performance Comparison ref:[1]

20 20 Conclusions ●Digital buffers (inverters) are more power-efficient than analog buffers ●Achieved 3.64X lower quiescent current at 28% slower response –FOM is 2.84X better than the prior art ●The power bottleneck moved from the analog buffer to the error amplifier –matching requirements influence transistor sizes and the quiescent current ref:[1]

21 21 References: ●1-P.Hazucha, “A Linear Regulator With Fast Digital Control For Biasing Integrated DC-DC Converters” ISSCC dig. tech. papers 29.2 feb.2006 ●2-S. Rajapandian, et al., “High-Tension Power Delivery- Operating 0.18µm CMOS Digital Logic at 5.4v,” ISSCC dig. Tech. papers,pp.298299,Feb., 2005 [page 6] ●3- Hazucha, et al., 2004 VLSI Symposium, p. 256. ●4-Xiao, et al., 2004 ISSCC, p. 280.

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