AN537 Datasheet, PDF(1/9 Page) Microchip Technology – Everything a System Engineer Needs to Know About Serial EEPROM Endurance

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AN537 Datasheet, PDF (1/9 Pages) Microchip Technology – Everything a System Engineer Needs to Know About Serial EEPROM Endurance

Serial EEPROM Endurance

AN537

Everything a System Engineer Needs to Know About Serial EEPROM Endurance

The term âenduranceâ has become a confusing param-

eter for both users and manufacturers of EEPROM

products. This is largely because many semiconductor

vendors treat this important application-dependent reli-

ability 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.

Endurance (the number of times an EEPROM cell can be

erased and rewritten without corrupting data) is a mea-

sure of the deviceâs reliability, not its parametric perfor-

mance. As such, endurance is not achieved by some-

how 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 evaluat-

ing components from various manufacturers. The sys-

tem 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.

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:

â¢ CMOS floating gate memory cell operation and char-

acteristics

EEPROM MEMORY CELL

OPERATION AND

CHARACTERISTICS

In discussing endurance characteristics of EEPROMs,

itâs 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 gener-

ated on chip by a charge pump, with the only external

voltage required being VDD. The only difference be-

tween an ERASE and a WRITE is the direction of the

applied field potential relative to the polysilicon floating

gate.

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 Tun-

nel 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 â1â. 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 â0â.

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 âE/W cycle.â

â¢ Significant process and design interactions and en-

The field (applied voltage to an oxide thickness) across

durance characterization variables

the tunneling path created by the 20V potential is ex-

tremely high in order to transfer the electrons. Over the

â¢ Common misinterpretations of endurance

cellâs âapplication time,â as measured by E/W cycles, the

â¢ Determining some real world application reliability

EEPROM cell begins to wear out due to the field stress.

requirements

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 characteris-

tics) 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.

8-15

DS00537A-page 1

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