MICROCHIP AN537

Serial EEPROM Endurance
AN537
Everything a System Engineer Needs to Know About Serial EEPROM Endurance
The term “endurance” has become a confusing parameter for both users and manufacturers of EEPROM
products. This is largely because many semiconductor
vendors treat this important application-dependent reliability parameter as a vague specmanship topic. As a
result, the system engineer often designs without proper
reliability information or under-utilizes the EEPROM as
an effective solution.
EEPROM MEMORY CELL
OPERATION AND
CHARACTERISTICS
In discussing endurance characteristics of EEPROMs,
it’s important to review how these components operate,
and why and how they fail. Figure 1 illustrates a CMOS
floating gate EEPROM cell, including voltage conditions
for READ, ERASE, and WRITE operations. To erase or
write, the row select transistor must have the relatively
high potential of 20V. This voltage is internally generated on chip by a charge pump, with the only external
voltage required being VDD. The only difference between an ERASE and a WRITE is the direction of the
applied field potential relative to the polysilicon floating
gate.
Endurance (the number of times an EEPROM cell can be
erased and rewritten without corrupting data) is a measure of the device’s reliability, not its parametric performance. As such, endurance is not achieved by somehow making EEPROM devices more durable or robust to
extend the life of the intrinsic erase/write cycle, but rather
by reducing their defect-density failure rates. This has a
direct impact on the design engineer characterizing
EEPROM memory needs for an application and evaluating components from various manufacturers. The system design engineer needs to understand not only the
relationship between the application, expected use and
failure mechanisms, but also how the manufacturer has
arrived at published endurance data for its components.
When 20V is applied to the polysilicon memory cell gate
and 0V is applied to the bit line drain (column), electrons
tunnel from the substrate through the 90-angstrom Tunnel Dielectric (TD) oxide to the polysilicon floating gate
until the polysilicon floating gate is saturated with charge.
The cell is now at an ERASE state of “1”. When 0V is
applied to the polysilicon memory cell gate and 20V is
applied to the bit line drain (column), electrons tunnel
from the polysilicon floating gate through the TD oxide to
the substrate. The cell then is at a WRITE state of “0”.
This sequence of the transfer of charge onto the floating
gate (ERASE) and the electrical removal of that charge
from the floating gate (WRITE) is one ERASE/ WRITE
cycle, or “E/W cycle.”
This tutorial volume is intended to clarify some of the
issues in the industry and provide a tool for the system
design engineer, the system reliability engineer, and the
component engineer to determine EEPROM reliability
and understanding how to apply it to actual application
requirements. It will examine four main areas:
•
CMOS floating gate memory cell operation and characteristics
•
Significant process and design interactions and endurance characterization variables
•
Common misinterpretations of endurance
•
Determining some real world application reliability
requirements
The field (applied voltage to an oxide thickness) across
the tunneling path created by the 20V potential is extremely high in order to transfer the electrons. Over the
cell’s “application time,” as measured by E/W cycles, the
EEPROM cell begins to wear out due to the field stress.
The EEPROM cell wears out as the number of cycles
increase resulting in the voltage margin between the
ERASE and WRITE states decreasing until finally there
is not enough margin for the EEPROM sense amp to
detect a difference in the two states during a READ.
Failure is defined as when the sense amp can no longer
reliably differentiate logic state changes.
Figure 2 (single cell EEPROM endurance characteristics) illustrates that the intrinsic wear out point for a
normal cell with specified dimensions and electrical
characteristics is very acceptable, in excess of 2 million
E/W cycles. Failures at lower cycles are due mostly to
very small defects or imperfections in the oxide or
silicon-to-oxide interface.
© 1992 Microchip Technology Inc.
DS00537A-page 1
8-15
8
Serial EEPROM Endurance
A key point to remember is that most failures occurring
at less than 2 million E/W cycles are due to the number
of defects per a given area (defect density dependent.)
Thus high EEPROM endurance reliability is achieved by
reducing the defect density failure rates, not by increasing the number of intrinsic cycles in the cell’s operational
design.
Error correction circuits are design techniques commonly used by EEPROM manufacturers to increase
endurance by reducing the failure rate caused by single
bit failures. These circuits are transparent to the user.
One typical scheme is using 4 bits of error correction for
every 8 “real” bits (one byte). In this scheme, one bit
failure in the byte is correctable, while if two bits within
the byte fail, the byte is not correctable.
Another error correction scheme is to use one “parity” bit
for every “cell.” Here both EEPROM cells must fail to
result in a bit fail.
FIGURE 1 - CMOS FLOATING GATE EEPROM CELL
Memory Cell Gate
Poly-Silicon, Level 2
Row Select Transistor
Inter-Level Dielectric
Poly-Silicon, Level 1
Poly-Silicon, Level 2
90 ANG Td Oxide
Source
Drain
(Not to scale)
Common Source
Bit Line
Memory
Cell Gate
Bit Line
Row Select Gate
Memory Cell Gate
Common Source
Row
Select
Read
Write
Erase
Standby
1.6 volts
5.0 volts
5.0 volts
0.0 volts
18.0 volts
20.0 volts
0.0 volts
Float
0.0 volts
20.0 volts
20.0 volts
0.0 volts
0.0 volts
0.0 volts
0.0 volts
0.0 volts
DS00537A-page 2
© 1992 Microchip Technology Inc.
8-16
Serial EEPROM Endurance
FIGURE 2 - SINGLE EEPROM CELL ENDURANCE CHARACTERISTICS
Erase
Failure will occur when either the ERASE or WRITE
margin crosses the sense amp level
Sense Amp Level
Cell Margin
(Volts)
Write
1
1,000,000
Erase/Write Cycles
The primary interaction is the amount of TIME at the
HIGH VOLTAGES that is ultimately applied to the cell. A
finite amount of time at finite voltages are required to
achieve “optimal” ERASE and WRITE thresholds. If the
time is too short and the voltage is too low, the EEPROM
will not program to the proper threshold. Also, if the
programming ramp time is too fast and the voltage is too
high, the EEPROM’s endurance will be reduced. Unfortunately, there is most often a trade-off between fast
reliable programming performance or high endurance
reliability. Some of the significant process and design
variables are shown below and their impact on programming performance and endurance performance.
PROCESS AND DESIGN VARIABLES
AFFECTING ENDURANCE
There are many subtle process and design variables
that have a strong impact on endurance. These interacting variables will play very different roles depending on
the different process technologies of various semiconductor manufacturers.
8
PARAMETER
PROGRAMMING
ENDURANCE
Internal High Voltages
HIGHER = Faster Programming
LOWER
= Increased Endurance
= Increased Endurance
Internal High Voltage Ramp Rate
FASTER = Faster Programming
SLOWER
Programming Time
LONGER = Improved Voltage
Margin on the Cell
SHORTER = Less Oxide Stress for
Increased Reliability
TD Oxide thickness
THICKER = Slower Programming
THINNER
= Reduced Endurance
Temperature
LOWER
LOWER
= Increased Endurance
= Faster Programming
© 1992 Microchip Technology Inc.
DS00537A-page 3
8-17
Serial EEPROM Endurance
COMMON MISINTERPRETATIONS
Cycles/Day
In examining industry EEPROM literature on the topic of
endurance, it’s easy to misunderstand or misinterpret
endurance concepts due to incomplete databook statements. The following are clarifications to some of the
common misinterpretations:
In many cases, a serial EEPROM is used for widely
varying functions in an application. These functions
have different E/W usage requirements (cycles/day),
resulting in different endurance requirements and, usually, different reliability results for each function.
For example, assume a given end-product application
will have a 10-year life. For each function within that
application, an assumption must be made for the expected E/W cycles per day for a given segment of bytes.
If a function has a segment of bytes cycled 1 time per
day, then this segment of bytes will have 3,650 cycles in
its lifetime (365 days per year for 10 years at 1 cycle per
day and 7 days per week operation). Any given segment
of bytes would have to cycle 274 times per day everyday
to reach 1,000,000 E/W cycles in its 10-year application
lifetime. Such a frequency is, of course, very rare in
actual applications.
Endurance and Read Cycles
READ operations are unlimited since they impose virtually no stress on the cell. Endurance data apply only to
E/W cycles.
Erase/Write Ratings
E/W ratings are based on each byte in the application,
not on the number of opcodes or control byte commands
utilized. For example, if a part is rated to 100K E/W
cycles, then each individual byte can be erased and
written 100K times. The part is NOT limited to only a total
of 100K E/W opcodes or control bytes. This is probably
the most common misinterpretation made by system
designers. Endurance is thus an interactive applicationspecific reliability parameter. It is not a typical data sheet
specification, such as a parametric AC/DC specification
with benchmark standards for measurement.
For reference purposes, Figure 3 indicates typical cycles
per day for some common applications. Although many
manufacturers routinely discuss very high numbers of E/
W cycles, the amount of applications actually utilizing 1
million cycles is very small.
A further and very important incorrect assumption often
made is that ALL bits in an application need the same
number of cycles and endurance ratings. In most
applications, however, functions that require a high
FIGURE 3 - TYPICAL SERIAL EEPROM E/W CYCLES/DAY BY APPLICATION
Maintenance Log
Last Number Redial
Electronic Lock Access
Power Down Storage
Digital Potentiometer
Look Up Table
Tuner Controls
System Configuration
Anti-Lock Brakes
Speed Dial
Airbag
0.001
0.01
0.1
1
10
100
1000
Cycles/Day
DS00537A-page 4
© 1992 Microchip Technology Inc.
8-18
Serial EEPROM Endurance
number of E/W cycles per day require only a small
number of bits. Last number redial in a telephone, for
example, consumes many E/W cycles per day, but
utilizes only a few bytes for this function. By contrast,
speed dial storage in that same telephone consumes
only a fraction of E/W cycles per day, but requires a
relatively large segment of bits to accommodate the
many speed dial options. In such an application, the
same serial EEPROM normally performs both functions
at different address locations.
First, memory cell failure rates are defect density driven
up to the intrinsic wear out point. Existing defects in a
cell, while not causing failure initially, are stressed
during every transfer of electrons through the TD oxide
until they eventually cause cell failure. Worst case
testing would be to erase and write each bit, which is
what a write all “0”s pattern with an auto-erase of “1”
routine will perform. Indeed, this write all “0”s test
pattern will produce very different results than a checkerboard test pattern of alternating “1”s and “0”s within a
byte, since cells are changed more often writing all “0”s
than in an alternating “1” and “0” write pattern. The
resultant failure rate differences are indicated on the
pattern effect graph in Figure 4.
ENDURANCE DATA FROM THE
CUSTOMER’S PERSPECTIVE
Unfortunately, an industry standard for an endurance
test method has yet to be adopted. Since endurance
data is not baselined, the process of evaluating endurance becomes that much more complicated for the
system designer and reliability engineer.
In actual use, however, a system will experience a
random pattern much more like the alternating “1”s and
“0”s pattern than the more stressful all “0”s pattern. The
key point for system designers is to determine how
accurate a test routine has been used to determine a
particular manufacturer’s endurance data, and make
the appropriate judgement on that part’s expected endurance in the application.
It is not uncommon for customers to request endurance
data from many semiconductor vendors. All vendors
would be expected to comment that they experience a
low failure rate through 100K E/W cycles. While this can
be a true statement, it can also be a very incomplete
statement. It is extremely doubtful that all vendors test
their components to the same conditions. Yet the
variables within endurance testing are extremely significant. Small differences in text protocol can have enormous differences. Pattern, cycling mode, temperature
and array size, for example, are the most significant
testing variables.
FIGURE 4 - PATTERN EFFECT ON ENDURANCE TESTING
8
Byte Write 0
Pattern
Cumulative
Failure Rate
Alternating "1"
and "0" Pattern
Erase/Write Cycles
© 1992 Microchip Technology Inc.
DS00537A-page 5
8-19
Serial EEPROM Endurance
RECOMMENDED EEPROM
ENDURANCE TESTING
Second, the cycling mode graph in Figure 5 indicates
that significantly different results can be achieved in
endurance testing using a block cycle mode than using
a byte cycle mode. The block mode is commonly used
by manufacturers to “speed up” the endurance characterization process. However, endurance results usually
will appear much better for the block mode than the byte
mode, due to the high voltage variables discussed
earlier. The reason is that the voltage ramp rate is
significantly SLOWER, the high voltages are slightly
lower, thus less stressful for block cycling since the
capacitive load of the entire array is on the high voltage
charge pump. The capacitive load is much lower with a
single row or byte, which thus has a significantly faster
ramp rate. Also, there is not a polysilicon to polysilicon
stress for adjacent cells since all cells are at the same
potential. Most often, these factors combine to yield
lower failure rates for block cycling than for byte cycling.
Again, the test conditions must match the system conditions.
Microchip believes that EEPROM components should
be endurance tested to reflect system conditions. Therefore, units are cycled to an alternating ONE and ZERO
pattern (checkerboard), then to an alternating ZERO
and ONE pattern (inverse checkerboard).
Again, since endurance characterization data indicates
that a random single bit fail is the primary first order
failure mode, endurance is defect density (def/cm2 or
segment of bit size) dependent. Therefore an expected
failure rate range by density can be established.
DETERMINING THE RELIABILITY
CALCULATIONS
There are three primary components for the system
design engineers to use in determining the endurance
reliability required for a defect density limited application. These three components are:
Finally, increasing temperature also increases stress on
the cell. Microchip’s endurance characterization data
indicates that increasing temperature adds an activation energy (Ea) of 0.12eV on the cell. From a 25°C to
85°C ambient the acceleration factor is approximately
2.1. Therefore, the higher the temperature, the higher
the stress. These results will vary significantly with each
EEPROM manufacturer.
• Erase/write cycles/day estimated for the function.
• The number of bits in the function (or segment size).
• Case operating temperature of the Serial EEPROM.
Let’s look at three typical examples utilizing the above
information to predict a cumulative failure rate at different points in a system lifetime. Please note that Industry
endurance perceptions have improved from a very high
(> 2%) failure rate expectation to a very low actual PPM
level failure rate in the past few years.
FIGURE 5 - CYCLING MODE EFFECT ON ENDURANCE TESTING
Byte Mode
Block Mode
Cumulative
Failure Rate
Erase/Write Cycles
DS00537A-page 6
© 1992 Microchip Technology Inc.
8-20
Serial EEPROM Endurance
EXAMPLE #1 - AUTOMOBILE
ELECTRONIC COMPASS
EXAMPLE #3 - LASER PRINTER
A serial EEPROM could have many functions in a laser
printer. A function that would likely require the most
cycles/day is the maintenance log storage of the pages
printed (estimated to be 100 cycles/day). Three bytes
are utilized to store this number. The case temperature
environment is estimated to be between 55°C and 85°C
A 16-byte (128-bits) segment from a 2K array stores
data every time the power is turned off in an automobile
electronic compass. The design engineers expect the
system to power down an average of 5 times/day over a
10-year life in an 85°C case temperature environment.
The projected Microchip cumulative failure rate under
these conditions at the 10 year point is less than 8 PPM
or 0.0008% failures in 10 years. The cumulative PPM
failure rate graph is referenced on Figure 6.
The high number of cycles at an extreme temperature of
85°C indicate a failure rate of less than 1200 PPM
through the first 5 years and 2600 PPM through the first
10 years.
This failure rate can be dramatically reduced if the
operating temperature is reduced to 55°C. The same 5
and 10 year PPM levels are reduced to 450 PPM and
1600 PPM at 55°C.
EXAMPLE #2 FULL-FEATURED
TELEPHONE
An 8-byte (64-bit) segment is used to store the last
number redial on a stationary full feature phone operating in a room temperature environment. A 12K bit
(12,288-bits) segment is used for storage of speed dial
numbers on the same phone. This application has two
major functions and therefore it will have two separate
failure rate calculations.
These failure rates are illustrated on Figure 8.
SUMMARY
Microchip Technology Inc. has recognized that increasing reliability in serial EEPROMs through increased
endurance is not a function of extending the life of the
intrinsic erase/write cycle, but depends on reducing
defect-density failure rates. Design engineers characterizing EEPROM memory needs for an application and
evaluating EEPROM components from various manufacturers need to understand not only the relationship
between the application and expected use and failure
mechanisms, but also how the manufacturer has arrived
at published endurance data for its components.
The last number redial function is expected to be utilized
an average of 20 times/day over a 10 year life. Each
speed dial is expected to be updated an average of 0.1
times/day over a 10 year life.
Figure 7, the cumulative failure rate graph for these two
conditions indicates an extremely low failure rate in the
projected 10 year lifetime. The failure rate begins beyond 20 years as shown on the attached cumulative
PPM failure rate graph.
FIGURE 6 - EXAMPLE #1: THE AUTOMOBILE COMPASS
24LC02, 85C, 5V, 16bytes, 5cycles/day, RANDOM, BYTE
8
100
80
60
PPM = 82
40
20
0
0.000
0.005
0.010
, 18,250 Cycles,
© 1992 Microchip Technology Inc.
0.015
10.0 Yrs
0.020
DS00537A-page 7
8-21
Serial EEPROM Endurance
Microchip has developed a program to calculate the
cumulative PPM failure rates for specific system conditions, as shown on the previous pages. This program is
being transferred onto menu driven DOS floppy disks.
These disks will be available in December 1992 to the
system designers, reliability engineers, and component
engineers to project endurance failure rates for specific
system conditions. These disks will be periodically
updated to reflect Microchip's most recent endurance
data.
FIGURE 7 - EXAMPLE #2: THE FULL FEATURED PHONE
400
350
300
250
PPM
200
150
100
2.73E-04
3.02E-04
3.33E-04
3.64E-04
0.006132
0.012264
0.018396
0.024528
0.03066
0.036792
0.042924
0.049056
0.055188
0.06132
0.067452
1.50E-04
1.81E-04
0.0002117
2.42E-04
8.91E-05
1.20E-04
0
2.77E-05
0.0000584
50
24LC16, 22C, 5V, K Cycles, 10 Yrs.
FIGURE 8 - EXAMPLE #3: THE LASER PRINTER
Laser Printer Cumulative 365k Cycles 10 Yrs.
55C
3000
85C
2500
2000
1500
1000
500
Author:
DS00537A-page 8
0.36354
0.29054
0.30514
0.31974
0.33434
0.34894
0.21754
0.23214
0.24674
0.26134
0.27594
0.12994
0.14454
0.15914
0.17374
0.18834
0.20294
0.08614
0.10074
0.11534
0.05694
7.15E-02
8/27/93
0.01314
0.02774
0.04234
0
Steve Drehobl
Memory Products Division
© 1992 Microchip Technology Inc.
8-22
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