ChipFind - документация

Электронный компонент: MAXIM6061

Скачать:  PDF   ZIP
MAX6100EUR
Rev. A







RELIABILITY REPORT
FOR
MAX6100EUR
PLASTIC ENCAPSULATED DEVICES




February 14, 2003




MAXIM INTEGRATED PRODUCTS
120 SAN GABRIEL DR.
SUNNYVALE, CA 94086











Written by
Reviewed by
Jim Pedicord
Bryan J. Preeshl
Quality Assurance
Quality Assurance
Reliability Lab Manager
Executive Director




Conclusion


The MAX6100 successfully meets the quality and reliability standards required of all Maxim products. In addition,
Maxim's continuous reliability monitoring program ensures that all outgoing product will continue to meet Maxim's quality
and reliability standards.

Table of Contents
I. ........Device Description
V. ........Quality Assurance Information
II. ........Manufacturing Information
VI. .......Reliability Evaluation
III. .......Packaging Information
IV. .......Die Information
.....Attachments

I. Device Description
A. General
The MAX6100 is a low-cost, low-dropout (LDO), micropower voltage references. This three-terminal reference has an
output voltage option of 1.8V. It features a proprietary curvature-correction circuit and laser-trimmed, thin-film
resistors that result in a low temperature coefficient of 75ppm/C (max) and an initial accuracy of 0.4% (max). This
device is specified over the extended temperature range (-40C to +85C).
This series-mode voltage reference draws only 90A of supply current and can source 5mA and sink 2mA of load
current. Unlike conventional shunt-mode (two-terminal) references that waste supply current and require an external
resistor, this device offers a supply current that is virtually independent of the supply voltage (with only a 4A/V
variation with supply voltage) and does not require an external resistor. Additionally, this internally compensated
device does not require an external compensation capacitor and is stable with load capacitance. Eliminating the
external compensation capacitor saves valuable board area in space-critical applications. Low dropout voltage and
supply-independent, ultra-low supply current makes this device ideal for battery-operated, high-performance, low-
voltage systems.
The MAX6100 is available in a tiny 3-pin SOT23 packages.

B. Absolute Maximum Ratings
Item
Rating

(Voltages Referenced to GND)
IN
-0.3V to +13.5V
OUT
-0.3V to (VIN + 0.3V)
Output Short-Circuit to GND or IN (VIN < 6V)
Continuous
Output Short-Circuit to GND or IN (VIN = 6V)
60s
Operating Temperature Range
-40C to +85C
Storage Temperature Range
-65C to +150C
Lead Temperature (soldering, 10s)
+300C
Continuous Power Dissipation (TA = +70C)
3-Pin SOT23
320mW
Derates above +70C
3-Pin SOT23
4.0mW/C


II. Manufacturing Information
A. Description/Function: Low-Cost, Micropower, Low-Dropout, High-Output-Current, SOT23 Voltage References
B. Process:
B12 (Standard 1.2 micron silicon gate CMOS)

C. Number of Device Transistors:
117
D. Fabrication Location: California or Oregon, USA
E. Assembly Location:
Malaysia or Thailand
F. Date of Initial Production:
March, 2001

III. Packaging Information

A. Package Type:
3-Pin SOT23
B. Lead Frame:
Copper or Alloy 42

C. Lead Finish:
Solder Plate

D. Die Attach:
Silver-filled Epoxy
E. Bondwire:
Gold (1.0 mil dia.)

F. Mold Material:
Epoxy with silica filler

G. Assembly Diagram:
# 05-0901-0179
H. Flammability Rating:
Class UL94-V0
I. Classification of Moisture Sensitivity
per JEDEC standard JESD22-112: Level 1

IV. Die Information

A. Dimensions:
44 x 31mils

B. Passivation:
Si
3
N
4
/SiO
2
(Silicon nitride/ Silicon dioxide)

C. Interconnect:
Aluminum/Si (Si = 1%)

D. Backside Metallization:
None

E. Minimum Metal Width:
1.2 microns (as drawn)

F. Minimum Metal Spacing:
1.2 microns (as drawn)

G. Bondpad Dimensions:
5 mil. Sq.

H. Isolation Dielectric:
SiO
2

I. Die Separation Method:
Wafer Saw
V. Quality Assurance Information

A. Quality Assurance Contacts:
Jim Pedicord (Manager, Reliability Operations)
Bryan Preeshl (Executive Director)
Kenneth Huening (Vice President)

B. Outgoing Inspection Level: 0.1% for all electrical parameters guaranteed by the Datasheet.
0.1% For all Visual Defects.

C. Observed Outgoing Defect Rate: < 50 ppm

D. Sampling Plan: Mil-Std-105D

VI. Reliability Evaluation

A. Accelerated Life Test
The results of the 135
C biased (static) life test are shown in Table 1. Using these results, the Failure
Rate (
) is calculated as follows:
= 1 = 1.83 (Chi square value for MTTF upper limit)
MTTF
192 x 4389 x 160 x 2
Temperature Acceleration factor assuming an activation energy of 0.8eV

= 6.79 x 10
-9

= 6.79 F.I.T. (60% confidence level @ 25
C)

This low failure rate represents data collected from Maxim's reliability monitor program. In addition to
routine production Burn-In, Maxim pulls a sample from every fabrication process three times per week and subjects
it to an extended Burn-In prior to shipment to ensure its reliability. The reliability control level for each lot to be
shipped as standard product is 59 F.I.T. at a 60% confidence level, which equates to 3 failures in an 80 piece
sample. Maxim performs failure analysis on any lot that exceeds this reliability control level. Attached Burn-In
Schematic (Spec. # 06-5630) shows the static Burn-In circuit. Maxim also performs quarterly 1000 hour life test
monitors. This data is published in the Product Reliability Report (RR-1M).

B. Moisture Resistance Tests
Maxim pulls pressure pot samples from every assembly process three times per week. Each lot sample
must meet an LTPD = 20 or less before shipment as standard product. Additionally, the industry standard
85
C/85%RH testing is done per generic device/package family once a quarter.
C. E.S.D. and Latch-Up Testing

The RF24-7
die type has been found to have all pins able to withstand a transient pulse of
1500V, per Mil-
Std-883 Method 3015 (reference attached ESD Test Circuit). Latch-Up testing has shown that this device
withstands a current of
250mA.




Table 1
Reliability Evaluation Test Results
MAX6100EUR

TEST ITEM
TEST CONDITION
FAILURE
SAMPLE
NUMBER OF
IDENTIFICATION
PACKAGE
SIZE
FAILURES

Static Life Test (Note 1)
Ta = 135
C
DC Parameters
160
0
Biased
& functionality
Time = 192 hrs.

Moisture Testing (Note 2)

Pressure Pot
Ta = 121
C
DC Parameters
SOT
77
0
P = 15 psi.
& functionality
RH= 100%
Time = 168hrs.

85/85
Ta = 85
C
DC Parameters
77
0
RH = 85%
& functionality
Biased
Time = 1000hrs.

Mechanical Stress (Note 2)

Temperature
-65
C/150
C
DC Parameters
77
0
Cycle
1000 Cycles
& functionality
Method 1010

Note 1: Life Test Data may represent plastic DIP qualification lots.
Note 2: Generic Package/Process data