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Uncertaintyaware Circuit Optimization

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10 ps. tuned. manufactured. Why optimization is bad. Disadvantages of the 'wall' ... ps. slack. untuned. uncertainty- aware tuning. Estimated manufacturing ... – PowerPoint PPT presentation

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Title: Uncertaintyaware Circuit Optimization


1
Uncertainty-aware Circuit Optimization
  • Xiaoliang Bai, Chandu Visweswariah,
  • Philip N. Strenski, David J. Hathaway
  • University of California, San Diego
  • IBM T. J. Watson Research Center
  • IBM Microelectronics

2
Outline
  • Why optimization is good
  • Why optimization is bad
  • Uncertainty-aware tuning
  • Experimental results
  • Alternative formulations
  • Conclusions

3
Why optimization is good
  • Background EinsTuner automatic transistor
    resizing tool
  • based on static timing all paths implicitly
    considered
  • uses nonlinear optimization optimality
    guaranteed
  • uses fast simulation and sensitivity analysis
  • Benefits
  • better circuits (delay, area, power, noise,
    combinations thereof)
  • enhanced designer productivity

4
Optimizing circuit delay
5
What tuning does the wall
signals
slack
6
What tuning does the wall
signals
untuned
slack
20 ps
-10 ps
7
What tuning does the wall
signals
untuned
slack
20 ps
-10 ps
8
What tuning does the wall
signals
The expected value of the worst slack is
adversely impacted by the height of the wall
untuned
slack
20 ps
-10 ps
9
Why optimization is bad
  • Disadvantages of the wall
  • extreme sensitivity to uncertainties
  • manufacturing
  • environmental
  • inaccuracy in modeling and tools
  • further optimization is very difficult
  • manual
  • automatic
  • high delay-testing cost

10
Key idea
  • The wall is an artifact of mathematical
    optimization the optimizer will increase the
    height of the wall even to save 0.001 ps
  • Define separation of a path as the difference
    between the slack of the path and the slack of
    the most critical path
  • We need to give the optimizer incentives to
    increase separation
  • To accomplish this, we add penalty terms to the
    objective function to avoid the wall
  • The penalty must be in relation to the most
    critical path, which changes dynamically

11
Uncertainty-aware tuning
z
12
In mathematical terms
  • Nominal tuning
  • Uncertainty-aware tuning
  • k is a weight factor the penalty function forces
    separation

13
Observation
  • Optimizers often convert inequalities to
    equalities by introducing a non-negative
    constraint slack variable
  • (z-ATi) is the value of the constraint slack
    introduced by the nonlinear optimizer for the
    inequality z ? ATi
  • We express the penalty in terms of this
    constraint slack

14
Choice of penalty function
Penalty Box
z
15
Choice of parameters
Penalty Box
z
To guarantee the downward pressure on z
16
Uncertainty-aware tuning histogram
17
Estimated manufacturing result
18
Area tradeoff minimization modes
  • Area minimization mode
  • Tradeoff mode

19
Pruning
  • EinsTuner prunes the timing graph
  • reduces problem size
  • reduces degeneracy and redundancy
  • reduces CPU time
  • But a primary output arrival time may be pruned
  • In this case, we add a penalty term corresponding
    to every sub-path that ends at a primary output
  • Again, we re-use the constraint slack variable

20
Experimental results
Similar slacks, better manufacturability
21
Nominal tuning
z
ATi
Arrival time
Delay
22
Nominal tuning with constraint slacks
Constraint Slacks
Critical path
23
Uncertainty-aware tuning
Separation
24
Pruned
25
Internal separation AT/RAT separation
Arrival Time
Required Arrival Time
Delays
Constraint Slacks
Same delay
Separation
Critical Path (shown for AT constraints only)
26
Conclusions
  • Optimizer gratuitously creates a wall of
    equally critical paths
  • Uncertainty-aware tuning reduces the height of
    the wall
  • The resulting design is less susceptible to
    manufacturing and other sources of variation
  • Easier downstream restructuring, delay testing
  • Side benefit optimizer is more efficient by
    eliminating degeneracy
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