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Process & Product checks

Test. Process & Product checks. Introduction. Scope Testing (quality control) is done at various steps Our focus: Only electrical tests Other tests: Defectivity test, etc Electrical Testing Process check (Only overall condition) PARAMETRIC or E-Test

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Process & Product checks

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  1. Test Process & Product checks

  2. Introduction • Scope • Testing (quality control) is done at various steps • Our focus: Only electrical tests • Other tests: Defectivity test, etc • Electrical Testing • Process check (Only overall condition) • PARAMETRIC or E-Test • Product check (Pass/Fail for each chip) • BIN or SORT • RELIABILITY

  3. Process Test (parametric) • Process Check • Simple structures, made between the ‘real’ chips • If the structures are very bad (all shorted, all open/ broken) • Chips are also likely to be ‘dead’ • Not worth processing further (if the wafers are in the midst of processing) • Not worth testing the chips (if the wafers have completed processing) • So, process check is done • in the ‘line’, at some standard steps (after M1 CMP and so on...) • and at the end, just before the chips are tested for pass/fail • The ‘simple structures’ used for process checks are normally called as ‘Scribe line’ or ‘Kerf’ • Process check is called “scribeline test’ or ‘kerf test’

  4. Review from Mask: Basics • A mask may be 100 mm x 100 mm (for example) • So, one ‘print’ will be about 25 mm by 25 mm, on the wafer. • A chip may be only 5 mm by 4 mm • So, one mask will have perhaps 20 chips, if the chip is small • The gaps between the ‘real chips’ are used for • alignment marks (TBD) • test structures (TBD)

  5. Process Test (parametric) • Basic check for shots/opens: • Metal lines: Snakes, Combs • Snake & Comb for both open and shorts • At each layer • Many structures • ==> many tests, time • few structures • ==> lower ability to predict fails • low resolution • if the snake is too long, cannot differentiate between real open vs marginal open vs good structure • if comb is too large, cannot distinguish between leakage vs shorts

  6. Process Test (parametric) • Example of shorts: • What is expected in the electrical test © micro magazine • Very low resistance (or high leakage current) CDF plot Leak between combs Snake resistance

  7. Process Test (parametric) • Plot of leakage current (CDF or QQ-Norm) • sorted values • log scale to identify ppm or ppb level defects • Stop processing the wafers with shorts/opens • Helps isolate problematic modules

  8. Process Test (parametric) • VDP • Proximity structures • Kelvin • Misalign Structures • To find alignment margin • Border structures (via, contact) • Size structures • Capacitor (low-k specific) • intra layer • inter layer • Copper specific (Dishing/Erosion) • Concept of Short Loop, POR, split

  9. Tester ©Advantest Ability to test at high temp some may have low temp capability also Die level vs package level

  10. Probe ©Advantest Tungsten tip (for example) Auto probe vs Manual Probe

  11. Test Program • C or script like • Normally well commented, reasonably readable • information on voltage applied (for example), store the data in test name etc.. • DUT (Device Under Test) • alignment and x,y movement • C-V test (for oxide) OR I-V results • time consuming • usually one result in a DUT in a die • TDDB, NBTI, ESD, EM • Summary file (for water, for lot ...) Temp. Dependent Dielectric Breakdown, Negative Bias Temperature Instability

  12. Pads/Pins: Some examples Pads in product Test Pads in “test chip” and perhaps in scribe line Usually Parametric (analog) tester = slower Digital tester = faster Parallel testing => Faster even for parametric

  13. Pads/Pins: Some examples Too long a pad-group ==> probe alignment/ probe contact issues Pads in “test chip” and perhaps in scribe line

  14. Product Test • Binning • Soft bin, hard bin • initial stages, test the least failing part • some times COF • production stage, test the most failing part • always SOF • Continuity (leakage, open) • Built In Self Test (BIST) • Functional • SCAN • Memory • Repair (yield can improve dramatically) • Fail Bit Map (FBM) • WL ==> M1 short, BL fail ==> via fail (for example)

  15. Product Test • IDDQ test ( Direct Drain Quiescent current) • some devices will pass the logic test, but will degrade in the field • likely to be captured by IDDQ test • Circuit must be CMOS and other parts must be isolated. Tested part should not give significant current, by design • (does not run at the specified frequency, so it won’t replace the function test, for example) • will not detect opens/ high resistance / interconnect capacitance effects • DC, AC, functional IDDQ... • QBD - charge (Q) to break down • Transistor (gate oxide) prob spec i

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