July, 2002 CMS Tracker Electronics 1
APV25 wafer testing
Outline
Mark Raymond, Imperial [email protected]
Wafer test procedure speed improvements feedback from hybrid tests
Wafer test results update on results/problems with production lots received so far summary of current position on yield investigations
July, 2002 CMS Tracker Electronics 2
Wafer test speed improvements
Wafer probe test speed now optimised at ~ 70 sec./site (~ 6 hrs/wafer)allows 2 wafers/day throughput
Speed improvements achieved by:reducing any excessive averagingutilising on-chip CM correction to speed up pulse shape mapping
=>pulse shapes for all channels can be acquired in two cal runs/mode only
64 chans withcal pulse
64 chans withoutcal pulse
use average of 64 chans withoutCal pulse to calculate CM correction
July, 2002 CMS Tracker Electronics 3
Feedback from hybrid tests
M.Poettgens
few chips showing large pedestal variation with pipeline location
e.g. chip #1614 from wafer JRCSA0T
why not showing up during wafer probe?
July, 2002 CMS Tracker Electronics 4
Wafer test probe data for suspect chip
wafer test data for chip #1614, wafer JRCSA0T
no obvious problem, pipeline scan flat (rms pipeline peds/channel low)
but CM subtraction applied during pipeline scan, so any effect which mimicscommon mode will not be picked up (appears to be case here)
test designed to be sensitive to individualpipeline cell pedestals stuck high/low
July, 2002 CMS Tracker Electronics 5
chip 1614
Histogram average channel noise for allgood chips on this wafer -> single channelsticks out
channel noise acquired while triggering singlepipeline column => not sensitive to large pipeline CM effects
solution modify wafer test to include cut on excessive CM baseline shifts during pipeline scan
can apply test to all future wafer tests and can re-scanany uncut wafers – should be quick if run just this testonly (~10 secs/site => 1hr/wafer)
average channel noise
compare suspect with other chips on same wafer
JRCSA0T
July, 2002 CMS Tracker Electronics 6
APV25 wafer testing status
Update on previous info presented in May CMS electronics week see http://www.hep.ph.ic.ac.uk/~dmray/pptfiles/CMS_elec_wk_2002.ppt
first 10 engineering wafers (September, 2000) all diced, ~1300 KGD still available at IC
2 production wafer lots delivered January: 48 ordered, 24 + 21 = 45 delivered shortfall of 3 (rejected by manufacturer QA) processing problem – these 2 lots returned to manufacturer
3rd full lot launched to provide remaining shortfall of 3 (25 wafers/lot) 3 wafers delivered mid Feb., remaining 22 requested and delivered in March
3 further lots launched to investigate process problems (75 wafers in total) 45 replacement wafers (from 2 lots) now received
July, 2002 CMS Tracker Electronics 7
Results from 1st 2 production lots
Lot 1 -> low yield (17 – 36 %) some good chips around periphery circular area of good chips in centre ~ even split between digital and analogue failure modes
Lot 2 -> lower yield (1 – 21 %) similar circular pattern but no good chips in centre
manufacturer notified via CERN (F.Faccio) investigation launched early acknowledgement of likely process problem example wafers returned and investigated a problem identified with silicide layer
(gate/source/drain contact layer) these lots now replaced
July, 2002 CMS Tracker Electronics 8
Results from 3rd production lot
average yield 79%
some wafers -> v. high yield
others good but still show pattern
36 chips in incomplete reticles now excluded from yield calculation (previously not the case)
94%
73%
July, 2002 CMS Tracker Electronics 9
Results from replacement lots
Lot A2C17000N5 Lot A2C19Q00N5
33% 47%
maps here for waferswith average yields
failure patterns and types of failure generally similar within a particular lot
some lot-to-lot differences
July, 2002 CMS Tracker Electronics 10
Results from all lots so far
82%
27%
10%
79%
33%
47%
1st 2 “silicide” lots
3rd lot
replacements for “silicide” lots
Yield histograms/lot for all wafers tested so far (average yields in green)
clear lot to lot differences ~ consistent picture within lots
replacement lots processed with extra checkingafter silicide steps – no problems observed
but these lots not giving highest yield circular symmetry to failure patterns => processing problems still present and silicide defects not whole story
eng. lot
July, 2002 CMS Tracker Electronics 11
Yield investigations/discussions with manufacturer
brief summary of discussion during 0.25m User Group Meeting – June 17th
problem not confined to APV wafers, 3 other HEP designs have also seen similar effects but manufacturer’s volume production not affected
any common features in HEP designs? not obvious but long metal lines are possible common feature -> antenna effect (ESD sensitivity) although we are well within design rules
v.large”handcrafted” layouts unusual in industry, metal layers auto-filled to higher density our metal layers less densely filled (still within design rules) -> possible under-etching?
general conclusion exact cause of problem still unclear
work in progress CERN test structure to investigate above theories in preparation examine test results in conjunction with layout looking for evidence to validate theories
– inconclusive so far, but still ongoing
July, 2002 CMS Tracker Electronics 12
Tested chip availability
present chip (KGD) availability
1300 remaining chips from engineering run3800 13 wafers diced from 3rd lot
5100 in waffle packs now
+ 3300 KGD on remaining uncut 3rd lot wafers + 6300 KGD on replacement 45 wafers (assuming we keep)
16800 currently in-hand
3 wafer lots launched to replace 1st two and investigate problems so more available
July, 2002 CMS Tracker Electronics 13
Conclusions
Wafer test protocol speed improvements now allow 2 wafers /day feedback from hybrid tests will allow any loopholes to be plugged
Wafer probing process problems with first two production lots – attributed to silicide problem wafers returned and replaced communication channel (via CERN) to manufacturer effective manufacturer’s response very constructive and helpful throughout 3rd lot yield back at expected high level (average 79%) replacement lots not maintaining high yield (33% and 47%) and not silicide reasons for low yield not fully understood – more work in progress
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