failure analysis electrical characterization school of microelectronics kukum
TRANSCRIPT
FAILURE ANALYSIS
ELECTRICAL CHARACTERIZATION
SCHOOL OF MICROELECTRONICS
KUKUM
Introduction
• A general approach is recommended for failure analysis electrical testing that will help the failure analyst to electrically characterize the device under analysis (DUA) without causing additional damage that may obscure or obliterate the original cause of failure.
Introduction
• Failure Analysis is performed on a device to determine the root cause of the failure.If, during the analysis electrical testing causes damage to the device or alters the device’s failure mechanism, then wrong conclusions will be made concerning the root cause of failure.
Introduction
• The initial electrical verification process provides a general understanding of how the device is failing electrically (eg. datalog, measured continuity, parametric, functional outputs of the device from production test equipment).
Example
• Electrical leakage identified -> detailed I-V characterization on a curve tracer or parametric analyzer.
• Functional failures -> Schmoo plotting (characterization as a function of temperature, power supply voltage or freq.) or scan testing
BEFORE ALL ELSE
• UPON FAILURE & FA FLOW DOCUMENTATION
• ==>ELECTRICALLY CHARACTERISE DEVICE<====> BENCH TESTS!
BENCH TESTING
• process of characterizing the failure mode of the sample using various bench equipment for exciting the device and measuring its responses
NDT
WHAT TO LOOK FOR?
Electrical Testing = detecting shorts,= opens, = parametric shifts / changes in resistance,= abnormal electrical behavior on the die, between the die and the interconnects, between the interconnects and the circuit card, within the circuit card, and among the various connections between circuit cards.
DO IT RIGHT!
Correct electrical testing
- provides the failure mode (catastrophic, functional, parametric, programming or timing),
- identify the failure site .
ASSUMPTIONS
• During FA- test has to be performed on the assumption that the device is not the same as a standard or “normal” device.– The device may have been electrically overstressed.– The device may have been damaged by ESD (electrostatic discharge).– The device may be altered internally due to chemical
reactions.– The device may have been misassembled.– The device may include a manufacturing defect.
TOOLS FOR ELECTRICAL CHARACTERIZATION
Multimeters, Freq. counters, OSC, Manual curve tracer, Computer controlled curve tracerSemiconductor parametric analyzer TDR,ATEetc…
MULTIMETERS
Basic tests - electrical connection, short, open
--general localization of fault area
==>IFF => PRIOR KNOWLEDGE
FREQ. CNTR. & OSC.
A STEP HIGHER / DEEPER
-TIMING RELATIONS
-FREQ. RESPONSES
-BEHAVIOURS @ DIFFERENT f’s
V-I CHARACTERISTICS
• Curve tracing - current-voltage characteristics of an electrical path using a curve tracer - identify electrical failures that exhibit abnormal V-I relationships between pins - 2pt probe
• objective of curve tracing = open or shorted pins & pins with abnormal I/V characteristics (excessive leakage, abnormal breakdown voltages, etc.).
• FA focused on circuits with anomalous pins.
• Dynamic curve tracing, unit powered, while curve tracing, if static curve tracing does not reveal any anomalies
• Curve tracing can also be done on an electrical path inside the die circuitry itself, where the nodes defining the electrical path are not connected to any external pins.
==>Microprobing - achieve electrical contact with the selected nodes, with the probe needles also attached to the curve tracer.
CURVE TRACER
• Curve tracing = easiest, safest, fastest and most reliable way to gather electrical characteristics information of DUT
• Curve tracer - visual nature easy to spot certain categories of errors (opens, shorts, leakages, etc...) including problems that might not be obvious from a series of single point measurements- CT =continuous
CURVE TRACER
• Continuous "sweep" - possible to plot the reaction of DUT for entire range of conditions.
• Curve tracer - store trace information, operate at low voltage and current levels - allows detection of certain electrical failure mechanisms that would be hidden by the higher voltage and/or current levels generally associated with verification testing.
CURVE TRACER
CURVE TRACER
- graphical representation of electrical characteristics on screen.
- common configuration- apply voltage to DUT pin (series resistor~1) and measure the resulting voltage and current.
- sweeping applied voltage & displaying current versus voltage plot
CURVE TRACER
• Y axis = current & X axis = voltage. • Values on axis increase with distance from
the origin• Two extreme conditions:
– a vertical line crossing origin = short (no voltage measured on the pin), – a flat horizontal line crossing origin = open (no current through the pin).
fundamentally…
• Standard behaviours - V & I– Resistors– Diodes – Transistors – Zener diodes– combinations– etc.
I
V
I
V
I
V
I
V
TDR
• Old principle BUT new application• Good for BGA / high pin count packages uses
electron speed / reflection - pinpoint exact point / layer of defect
• TDR instrument = very wide BW equivalent sampling oscilloscope (18-
20 Ghz) with an internal step generator.= connected to DUT via cables, probes and fixtures
TDR
Due to wide BW of the oscilloscope, and to ensure that this BW and fast rise time can be delivered to the DUT,
- must use high-quality cables, probes, and fixtures, ==>these cables, probes and fixtures can significantly
degrade the rise time of the instrument, reduce the resolution, and decrease the impedance measurement accuracy.
==>In a TDR probe, both a signal and a ground contact are normally required during the measurement.
t
t
T=2t
d = T/v
v
TDR
• impedance profile analysis
-observe open fault occurred, but also to determine the
exact location of the fault in time.
-If velocity of propagation in the given segment is
known, then the physical location of the fault can be
determined easily.
-velocity of propagation - determined using a reference
device with known physical length.
open fault = occurred shortly after the package-to-die bondwire connection
Computer controlled CT
- Overcomes the limitations of the manual curve tracer for high pin count devices and has become standard tool for I/O electrical characterization
- Controls the application of the stimulus to each pin and records the measured
data for display or comparison to previously stored data
SPA
• For characterization diodes, transistors, performing circuit level parametric testing which includes DC functional testing of analog circuits such as voltage references, regulators, and op-amps
• Can measure very low levels of current and voltages
ATE
• Used in production
• For characterization -> high pin count devices & timing complexity
• Provides a software toolkit for debug tools available are wave, vector or pattern, and schmoo tools