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16 Bit Logarithmic Converter

16 Bit Logarithmic Converter. Tinghao Liang and Sara Nadeau. 16 Bit Logarithmic Converter. Introduction Motivation Algorithm Explanation High level description Block diagram Design strategy Baseline performance Performance goals Improvement strategy Improved performance Layout

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16 Bit Logarithmic Converter

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  1. 16 Bit Logarithmic Converter Tinghao Liang and Sara Nadeau

  2. 16 Bit Logarithmic Converter • Introduction • Motivation • Algorithm Explanation • High level description • Block diagram • Design strategy • Baseline performance • Performance goals • Improvement strategy • Improved performance • Layout • Conclusions and Future Work

  3. Project Motivation • Logarithmic converters simplify computational needs • Multiplication/Division -> Addition/Subtraction • Power/Root -> Multiplication/Division • Real time DSP becoming more and more in demand, increased need for log converters to simplify computation demands • Explore interesting circuitry

  4. Algorithm • Whole number portion of base two logarithm of binary input acquired by detecting leading 1 • Decimal portion of base two logarithm of binary input approximated by mantissa • Ex: Input -> 2910 or 111012 Binary answer -> 100.1101 Decimal answer -> 4.8579 Error -> 0.0454, or 0.9%

  5. Implementation – Block Diagram

  6. Baseline Design Strategy • Direct CMOS implementation of all circuit blocks • Use gates sized for matching rise and fall times from lab 2 • Goal – functional circuitry

  7. Implementation – Leading One Detector Functionality LOD4 LOD16

  8. Implementation – ROM Functionality

  9. Implementation – Barrel Shifter Functionality

  10. Baseline Design Results • 50 MHz operation speed • 5 mW power consumption

  11. Improvement Strategy - Speed • Critical path • MSB’s pass through LOD and ROM prior to output • LSB’s need valid ROM output before barrel shifter output is valid • Critical block – 2:1 MUX • Appears in LOD as well as barrel shifter, often cascaded • Sized with logical effort • 4-Input NOR also resized for minimum average delay

  12. Improvement Strategy - Power • Power supply reduced to 2 V • Circuitry simplified • ROM circuit activated only when clock is low

  13. Improvement Strategy - Functionality • Expanded from 8 bits to 16 bits • Added a flag to indicate zero input

  14. Schematic Changes - MUX

  15. Improved Design Results • 77 MHz operation speed • 1.7 mW power consumption

  16. Layout – Register

  17. Layout – Leading One Detector

  18. Layout - ROM

  19. Layout – Barrel Shifter

  20. Improved Design Layout

  21. Improved Design Layout

  22. Conclusions and Future Work • Conclusions • Functional base two log converter designed and simulated successfully • Speed and power consumption were both improved by design modifications • Improvements • Size ROM cell for better speed • Further optimize layout organization • Add error compensation circuitry • Build anti-logarithmic converter

  23. Thank you! • Questions?

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