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Ongoing Work on GTX

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Title: Ongoing Work on GTX


1

Puneet Gupta, Chul-Hong Park and Andrew B.
Kahng Blaze DFM, Inc. UCSD, ECE
Department UCSD, CSE Department
Enhanced Resist and Etch CD Control by Design
Perturbation
Abstract
Etch Dummy Insertion Problem
Technique 1 SAEDM
  • Etch dummy features are used to reduce CD skew
    between resist and etch processes and improve
    printability. However, etch dummy rules conflict
    with SRAF insertion because the two techniques
    each require particular spaces of poly-to-assist,
    active-to-etch dummy, etc.
  • We first present a novel SRAF-Aware Etch Dummy
    Method (SAEDM) which optimizes etch dummy
    insertion to make the layout more conducive to
    assist-feature insertion after etch dummy have
    been inserted.
  • We also describe a novel dynamic
    programming-based technique for etch-dummy
    correctness (EtchCorr) which is used in
    combination with the SAEDM for detailed
    placement.
  • EtchCorr placement with SAEDM can achieve up to
    100 reduction in number of cell border poly
    geometries having forbidden pitch violations.
  • These techniques extend existing RET techniques
    to meet the ITRS CD tolerance spec by
    interactions with design. Hence, our techniques
    can delay the need for radically new RET or
    equipment solutions.

Maximum allowable etch dummy space (MAEDS)
Poly
Active
SRAF
Etch dummy
  • Etch dummy features are placed to the outside of
    active-layer regions
  • Etch dummy features are inserted between primary
    patterns with certain spacing to reduce etch skew
    between resist and etch process
  • Maximum allowable etch dummy space (MAEDS) is
    determined by allowable CD skew of resist and etch

Technique 2 EtchCorr Placement Correctness for
Etch Dummy
Algorithm Approach Dynamic Programming (DP)
Design and Test Flow
  • Key Idea Change whitespace distribution of
    standard-cell placement ? best printability
  • Maximize number of assist features (AFCorr)
  • Optimize location of etch dummies (EtchCorr)
  • AS (ES) sets of feasible spaces between two
    gates that allows insertion of required assist
    features (etch dummies)

Lithography etch model generation
Modified library netlist
  • Etch-Correctness solved by the following DP
    recurrence

Post-placement (AFCorr EtchCorr)
Typical Design Flow
Forbidden pitch, CD slope and skew of resist and
etch
Placement
Route
Route
  • Printability
  • Etch dummy and SB
  • EPEs of resist and etch
  • Performance
  • Delay, OPC run time

Assist and etch dummy corrected GDSII
  • Cost(ab) the cost of placing cell a at
    placement site number b
  • (x_a - b) placement perturbation of cell "a"
  • AFCost, EtchCost printability deterioration of
    resist and etch CDs
  • SRCH Maximum allowable change in location of a
    standard-cell instance
  • ? weight between goals of placement preservation
    and printability benefit
  • a and ß user-defined weights for AFCost and
    EtchCost

Typical GDSII
SB OPC
OPCed GDS
SAEDM
  • SB Insertion
  • Model-based OPC
  • Our novel design flow adds steps of forbidden
    pitch extraction, SAEDM AFCorr and EtchCorr to
    typical design flow
  • Minimize EPE (Edge-Placement Error) and maximize
    dummy and SB

Summary and Ongoing Work
Experimental Results
Optical and Etch Simulation
  • EtchCorr placement perturbation with SAEDM can
    achieve up to 100 reduction in number of cell
    border poly geometries having forbidden pitch
    violations. The corresponding reduction in EPE is
    up to 98 (resist CD) and 97 (etch CD)
  • SB count and etch dummy counts, which indicate
    less through-focus CD variation and etch skew,
    increase up to 10.8 and 18.6, respectively
  • Increases of data size, OPC running time and
    maximum delay due to EtchCorr are within 3, 4
    and 6, respectively
  • Runtime of EtchCorr placement perturbation is
    negligible (5 minutes) compared to running time
    of OPC (2.5 hours)
  • Ongoing research
  • Investigate other perturbation objectives such as
    weighting of perturbation cost by cell timing
    criticality
  • Develop methodologies for correct-by-constructio
    n standard cell layouts that are always
    EtchCorrect and AFCorrect in any placement
    scenario
  • Number of total SRAFs and etch dummies increases
    due to EtchCorr
  • Reduction in Forbidden Pitch Count of resist
    process ? 57-94 with SAEDM and 77-100 with
    SAEDM EtchCorr
  • Reduction in Forbidden Pitch Count of etch
    process ? 73-97 with SAEDM EtchCorr
  • After whitespace adjustment, additional SRAFs can
    be inserted to avoid forbidden pitch ? resist
    image (verifiable by simulation) is better
  • Large resist-to-etch skew in isolated patterns
    necessitates etch dummy insertion
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