1 / 21

Signal Integrity Introduction Class 1

Signal Integrity Introduction Class 1. Reduction To Practice for High Speed Digital Design Reading assignment: CH8 to 9.3. What is Signal Integrity (SI)?. An Engineering Practice That ensures all signals transmitted are received correctly

obert
Download Presentation

Signal Integrity Introduction Class 1

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. Signal Integrity IntroductionClass 1 Reduction To Practice for High Speed Digital Design Reading assignment: CH8 to 9.3 Richard Mellitz

  2. What is Signal Integrity (SI)? • An Engineering Practice • That ensures all signals transmitted are received correctly • That ensures signals don’t interfere with one another in a way to degrade reception. • That ensures signal don’t damage any device • That ensures signal don’t pollute the electromagnetic spectrum Introduction – Richard Mellitz

  3. What’s this all about? $ Introduction – Richard Mellitz

  4. The Business • Determine design parameters for successful signaling • Design parameters are ranges for design variables within which a product can be reliably built • “One in row” is not good enough • New Terms • General Solution • Point Solution • Specific Solution Introduction – Richard Mellitz

  5. Levels of SI Spheres of Influence Specific Solution One Box – End User Point Solution Boxed ProductProviders General Solution Silicon Providers Introduction – Richard Mellitz

  6. SI Paradigms • Specific Solution • Applies to a given instance of a product or specimen • Point Solution • Applies to any single given product • Encompasses a locus of specific solutions. • Example: Any board that comes off a production line • General Solution • Applies to many products of a given type • Encompasses a locus of point solutions • The locus of all solutions for a specific standard (like SCSI) is an example. Introduction – Richard Mellitz

  7. Effective SI is Pre-Product Release. • It costs less here. • Why? • Time = $ Introduction – Richard Mellitz

  8. Signal Integrity Paced by Silicon Advances • “Moore’s Law” • Still true • Silicon densitydoubles every18 months • “Core” frequency increase roughly follows density • Data transfer rate of connected I/O • Used to lag by about generation Introduction – Richard Mellitz

  9. What About Design Functionality? • Normally not the domain of SI • Often qualifies legal operation • For most computers I/O signals are v(t) • Transmitter • Receiver • Interconnect Core: IC logic Introduction – Richard Mellitz

  10. Components of High Speed Design • Competitive performance goals challenge each generation of technology (higher frequencies) • SI encompasses a conglomerate of electrical engineering disciplines • Transmitter • Receiver • Interconnect • Transistors • Passives • Algorithms • Memory • Transistors • Sources • Algorithms • Passives • Memory • Circuit elements • Transmission lines • S – parameter blocks (advanced topic) Introduction – Richard Mellitz

  11. SI Work • Modeling • Simulation • Measurement • Validation • What is good enough? • Sufficient to operate at desired frequency with required fidelity • Risk Assessment Introduction – Richard Mellitz

  12. SI in Computers – The 60’s and 70’s • 7400 Class TTL • Several MHz operation and 5ns edges • Transistor -Transistor Logic • Logic design with “jelly bean” ICs • Using loading rules from spec books • Lots of combinational and asynchronous one-shot designs. • Bipolar and CMOS Introduction – Richard Mellitz

  13. The 60’s and 70’s - Continued • ECL • Emitter Coupled Logic • Tens of MHz and 2-3ns edge rates • MECL hand book – One of the first books on SI • Introduced concept of termination and transmission lines • Still used spec books for rules • A few engineers evaluated termination schemes but no SI engineering per se • Common SI problems were deglitching switches and specifying clamping diodes on relay drivers. Introduction – Richard Mellitz

  14. The 80’s • Hi Speed CMOS and open drain buses • 100+ MHz operation and 1ns edges • Clocking issues start to creep in here • Ringing becomes a problem • Timing simulators emerge for SI Introduction – Richard Mellitz

  15. The 90’s • Early in the decade extracted board simulators are popular. • Chip I/V and edge V(t) info simulated with transmission lines whose characteristics are extracted directly from PWB layout information • IBIS becomes popular • Edge rates move toward 300ps at launch. • Memory and I/O buses require early SI analysis • SSTL – series stub terminated • AGTL – Advanced Gunning Transistor Logic • Open collector busing • Differential signaling emerges • Late in the decade we start to hear terms like return path, I/O power delivery, ISI, and source-synch • Extracted board simulators don’t account for these Introduction – Richard Mellitz

  16. The 00’s • GHz operation and 50ps launch edges • SI Engineers using spice and modeling with Maxwell 2½D/3-D field solvers. • Emerging technologies • High Speed Serial Differential • De/Pre emphasis • Embedded clocking • Data encoding • Pulse Amplitude Modulation (PAM) • Simultaneous Bi-Directional (SBD) Introduction – Richard Mellitz

  17. Assignment • Assignment: How much electrical transmission length does a 5ns, 2.5ns, 1ns, 300ps, 50ps edge occupy? Assume propagation velocity is half that free of space. • Determine a rationale for specifying physical wiring length in computer printed wiring boards. This is an exercise in engineering judgment. • Plot the ratio of electrical edge length to board trace length (by decade) in previous slide. Use range plots. Introduction – Richard Mellitz

  18. SI Directions Today • SI is starting to borrow from the communications industry • We are starting to hear terms like • Vector Network Analyzer (VNA) • S-parameters • Return and insertion loss • Eye diagram Introduction – Richard Mellitz

  19. SI Roles • Convert product parts and design features into models and parameters • Use models to simulate performance • Perform measurements to validate product • Determine how parameters limit performance • Use cost and simulated or measured performance to determine rules for design • Use margin budgets to manage designs Introduction – Richard Mellitz

  20. SI Deliverables Assignment: Fill in the above 6 boxes with hypothetical examples based on your present knowledge of the computer engineering field. Introduction – Richard Mellitz

  21. Future of SI • Rules of thumb get “old” quick • Old assumptions not good enough – fascinating topics • Can we still use transmission line models? • What is the role of ground? • Higher and higher frequency • Underscores the need to understand 2nd and 3rd order effects. • List examples • Many EE disciplines play together • Plethora of new signal analysis and measurement methods • Need to simplify designs to efficiently turn a profit. Introduction – Richard Mellitz

More Related