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Kejia Li, Yang Fu University of Virginia

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Presentation on theme: "Kejia Li, Yang Fu University of Virginia"— Presentation transcript:

1 Low Power Lookup Table Using Power Gating and Forward Body Biasing Techniques
Kejia Li, Yang Fu University of Virginia Department of Electrical and Computer Engineering Charlottesville, VA 22904

2 Outline Introduction System components Simulation results Summary
Mux structure Well Driver for FBB Power gating circuitry Output buffer Level converter Simulation results High power mode 1 High power mode 2 Low power mode Sleep mode Summary

3 Introduction Low-power design techniques We choose LUT as
Power gating Body biasing Gate biasing Dual-VDD Dual-Vt We choose LUT as the base line device

4 System Components Input Buffer Mux Output Buffer
SRAM configuration bits Level Converter Control Signal Bus Output Well Driver Power Gating Selector

5 System Components

6 Mux Structure We use high Vt devices (NMOS_VTG) in the mux together with forward body biasing.

7 The Well Driver Generate the body bias required for FBB
~0.64V in our design A trade-off between power and delay

8 Power Gating Circuitry
High power mode: both PMOS and NMOS are on Low power mode: PMOS off, NMOS on  reduced VVDD Sleep Mode: PMOS off, NMOS off Header circuit Mode selection circuit

9 Output Driver Use a PMOS keeper to restore the logic level after the mux

10 Level Converter Used in the low power mode operation
Reduced swing signal  Full swing signal Restore logic level to prevent leakage in subsequent stages.

11 High Power Mode 1 FBB on / Power gating: PMOS on, NMOS on
Energy per switch: 148 fJ Static power: 450 nW Delay: 296 ns

12 High Power Mode 2 FBB off / Power gating: PMOS on, NMOS on
Energy per switch: 148 fJ Static power: 370 nW Delay: 311 ns

13 Low Power Mode FBB on / Power gating: PMOS off, NMOS on
Energy per switch: 101 fJ Static power: 280 nW Delay: 556 ns

14 Sleep Mode FBB off / Power gating: PMOS off, NMOS off
Static power: 84 nW

15 Summary We have designed a low power lookup table using power gating and forward body biasing techniques. Four different operation modes are available, depending on the power/delay requirement. Future work needed to optimize the performance (like reducing leakage).

16 The End Thank you!

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