1 / 16

Design and Analysis of an 8-Bit Carry Look-Ahead Adder Operating at 200 MHz

This presentation details the design process and results of an 8-bit carry look-ahead adder optimized for high speed and low power consumption. The adder operates at 200 MHz, consumes only 1mW of power, and occupies a compact area of 400x400 mm². We will discuss the theoretical framework underlying the design, provide a background literature review, and summarize key findings from our experimental results. The presentation is structured to guide the audience through the project phases, methodologies, and analyses performed, while emphasizing the significance of our work in advancing existing concepts.

raziya
Télécharger la présentation

Design and Analysis of an 8-Bit Carry Look-Ahead Adder Operating at 200 MHz

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Advice: Do not read each slide, explain each slide to the audience. Please do not go over 15 slides! Title Do not change the background! Your name goes here. Advisor: Dave Parent DATE

  2. Agenda • Abstract • Introduction • Why • Simple Theory • Back Ground information (Lit Review) • Summary of Results • Project (Experimental) Details • Results • Cost Analysis • Conclusions

  3. Abstract • Summarize the logic, clock frequency, area, and power specs of your final design • We designed an 8-bit carry look ahead adder that operated at 200 MHz and use 1mW of Power and occupied an area of 400x400mm2

  4. Introduction If you need more room use another slide. • You also explain why your project was worthwhile to study. • This is where you describe the essential theory of your project. • If you are going to use equations make them legible ( Insert...object.... MS equation)

  5. Previous Work (not really required for 166) • This is were you talk about what others have done in the field that your work enhances, disproves, or used. • 1987 Parent et al. introduces the XYZ concept. • 1988 Parent et al. expands the XYZ concept. • 1989 Freeman et al. refutes the XYZ concept and introduces the ABC concept. • 1990 Choo et al. links the ABC and XYZ concepts. If you need more room, use another slide.

  6. Project Summary • This is were you show how your work fits in with the previous work • The key thing is to show what you did was an improvement over what has been done in the past.

  7. Project Details • Explain all the details of your project. • Schematics should be legible, and not too busy. • If you did a set of experiments describe the conditions you did them under. • show a table with all hand calculations for your longest path • Show • Final schematic (not test bench) • Final layout • Final simulation

  8. Longest Path Calculations Note: All widths are in microns and capacitances in fF

  9. Schematic

  10. Layout

  11. Verification

  12. Simulations

  13. Cost Analysis • Estimate how much time you spent on each phase of the project • verifying logic • verifying timing • layout • post extracted timing

  14. Lessons Learned • Give advice to future 166 students and professors

  15. Summary • Go over again why your project was worthwhile to study. • Summarize the main result • Make a prediction about the future.

  16. Do not read this slide, just show it. Acknowledgements • Thanks to my wife/husband for putting up with me. • Thanks to Cadence Design Systems for the VLSI lab • Thanks to Synopsys for Software donation • Professors X,Y, and Z • NSF grant #

More Related