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Chapter 10

Chapter 10. Timing Issues. Rev.1.0 05/11/2003 Rev. 1.1 05/28/2003 Rev. 1.2 06/05/2003. R. 1. R. 2. R. 3. In. Logic. Logic. Out. D. Q. D. Q. D. Q. Block #. 1. Block #. 2. t. t. t. pd,reg. CLK. pd. 1. pd. 2. Synchronous Pipelined Datapath. Data Register.

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Chapter 10

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  1. Chapter 10 Timing Issues Rev.1.0 05/11/2003 Rev. 1.1 05/28/2003 Rev. 1.2 06/05/2003

  2. R 1 R 2 R 3 In Logic Logic Out D Q D Q D Q Block # 1 Block # 2 t t t pd,reg CLK pd 1 pd 2 Synchronous Pipelined Datapath Data Register Output Register

  3. Self-Timed Logic (Asynchronous Datapath) Check Textbook (Sec. 10.4) for details!

  4. Latch Parameters : Clock-to-Q delay tc-q Positive Latch td-q : Data-to-Q delay D Q : Data hold time thold PW : Pulse Width Clk T Clk PW tsu D thold td-q tc-q Q tc-q Delays can be different for rising and falling data transitions

  5. D Q Clk Register Parameters Positive Edge-Triggered Register : Clock-to-Q delay tc-q tsu : Data Setup time :Data hold time thold T Clk thold D tsu tc-q Q

  6. 2 : Device Variations 5 : Temperature Sources of Clock Uncertainties

  7. Clock Nonidealities • Clock skew • () Spatial variation in temporally equivalent clock edges: deterministic + random values. • Clock jitter • Temporal variations in consecutive edges of the clock signal: modulation + random noise • () Cycle-to-cycle (short-term) tJitter • Long-term tJitter • Variation of the pulse width • Important for level-sensitive (latch) clocking (not discussed)

  8. Clock Skew and Jitter Clk • Both skew and jitter affect the effective cycle time tSK Clk tJS

  9. Clock Skew (Distribution) # of registers Earliest occurrenceof Clk edge Nominal – /2 Latest occurrenceof Clk edge Nominal + /2 Clk delay Insertion delay Max Clk skew 

  10. Positive and Negative Skew

  11. Positive Skew Launching edge arrives before the receiving edge

  12. Negative Skew Receiving edge arrives before the launching edge

  13. Datapath Structure with Feedback

  14. Positive Skew Launching edge arrives before the receiving edge

  15. Timing Constraints Minimum cycle time  fastest clock rate: T +   tc-q + tlogic + tsu T  tc-q + (tlogic -  ) + tsu Eq. (10.3) • Has the potential to improve the performance ( >0)

  16. Timing Constraints Hold time constraint: t(c-q, cd) + t(logic, cd) > thold +   Race between data and clock   should be kept small

  17. T k n CLK t j m l CLK jitter o -t jitter Combinational REGS In Logic CLK t t , t logic t c-q c-q, cd logic, cd t t su, hold t jitter Impact of Clock Jitter T – 2 tjitter >= tc-q + tlogic + tsu Eq. (10.5)

  18. Combined Impact of Skew and Jitter T +  – 2 tjitter >= tc-q + tlogic + tsu Eq. (10.6) thold +  < t(c-q, cd) + t(logic, cd) – 2 tjitter Eq. (10.7)

  19. Latch-based Design L1, L2: Negative Latches (3) : Latch CLB_A (Combinational Block A) (4): Latch CLB_B (Combinational Block B)

  20. Edge-triggered Pipeline Design

  21. Slack-borrowing (Sec. 10.3.4, not covered)

  22. Latch-Based Design for State Machine L1 latch is transparentwhen f = 0 L2 latch is transparent when f = 1 f L1 L2 Logic Latch Latch Logic

  23. Clocking Schemes in VLSI Circuits

  24. Clock Distribution H-tree Clock-distribution Network for 16 leaf nodes Clock is distributed in a tree-like fashion

  25. More realistic H-tree

  26. Grid Structure • No rc-matching • Allow a Low-skew clock distribution and physical design flexibility at the cost of larger power dissipation • Grids are typically used in the final stage of a clock network to distribute the clock to the clocking element loads

  27. Example: DEC Alpha 21164

  28. final drivers pre-driver 21164 Clocking tcycle= 3.3ns • 2 phase single wire clock, distributed globally • 2 distributed driver channels • Reduced RC delay/skew • Improved thermal distribution • 3.75nF clock load • 58 cm final driver width • Local inverters for latching • Conditional clocks in caches to reduce power • More complex race checking • Device variation tskew = 150ps trise = 0.35ns Clock waveform Location of clock driver on die

  29. Clock Skew in Alpha Processor

  30. tcycle= 1.67ns trise = 0.35ns tskew = 50ps EV6 (Alpha 21264) Clocking 600 MHz – 0.35 micron CMOS • 2 Phase, with multiple conditional buffered clocks • 2.8 nF clock load • 40 cm final driver width • Local clocks can be gated “off” to save power • Reduced load/skew • Reduced thermal issues • Multiple clocks complicate race checking Global clock waveform

  31. 21264 Clocking

  32. ps 5 10 15 20 25 30 35 40 45 50 ps 300 305 310 315 320 325 330 335 340 345 EV6 Clock Results GCLK Skew (at Vdd/2 Crossings) GCLK Rise Times (20% to 80% Extrapolated to 0% to 100%)

  33. EV7 Clock Hierarchy Active Skew Management and Multiple Clock Domains • PLL regenerate the on-chip clocks • DLLs compensate static and low-frequency variation • Divides design and verification effort • DLL/PLL designs and verification is added works

  34. Summary • Clocking schemes are very important in synchronous circuit designs  dominated in speed performance and power consumption. • Clock jitter and skews should be considered in early design phase. • Register-based designs are dominated in modern VLSI than latch-based designs. • Phase-locked loop (PLL) and Delay-locked loop (DLL) circuits are used to reduce the clock jitter and skews. • Good clock distribution CAD tools are useful in analyzing the clock performance in modern chips.

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