SPX3819M5-L-1.5 - Exar Corporation

1

DESCRIPTION

FEATURES

■Low Noise: 40µV Possible

■High Accuracy: 1%

■Reverse Battery Protection

■Low Dropout: 340mV at Full Load

■Low Quiescent Current: 90µA

■Zero Off-Mode Current

■Fixed Output: 1.2V, 1.5V, 1.8V, 2.5V, 3.0V,

3.1V, 3.3V, 5.0V. Adj. Output also available.

■Available in RoHS Compliant, Lead Free

Packages: 5 Pin SOT-23, 8 Pin Narrow

SOIC and 8 pin 2X3 DFN

The SPX3819 is a positive voltage regulator with a low dropout voltage and low noise output. In

addition, this device offers a very low ground current of 800µA at 100mA output. The SPX3819 has

an initial tolerance of less than 1% max and a logic compatible ON/OFF switched input. When

disabled, power consumption drops to nearly zero. Other key features include reverse battery

protection, current limit, and thermal shutdown. The SPX3819 includes a reference bypass pin for

optimal low noise output performance. With its very low output temperature coefficient, this device

also makes a superior low power voltage reference.

The SPX3819 is an excellent choice for use in battery-powered applications such as cordless

telephones, radio control systems, and portable computers. It is available in several fixed voltages

-- 1.2V, 1.5V, 1.8V, 2.5V, 3.0V, 3.1V, 3.3V, 5.0V -- or with an adjustable output. This device is offered

in 8 pin NSOIC, 8 pin DFN and 5-pin SOT-23 packages.

APPLICATIONS

■Battery Powered Systems

■Cordless Phones

■Radio Control Systems

■Portable/Palm Top/Notebook Computers

TYPICAL APPLICATION CIRCUIT

+

GND

EN BYP

(Opt.)

ENABLE may be tied directly to V

IN

SPX3819

1

2

3 4

5

V

IN

V

OUT

TOP View

■Portable Consumer Equipment

■Portable Instrumentation

■Bar Code Scanners

■SMPS Post Regulators

SPX3819

8 Pin DFN

EN

NC

VIN

ADJ/BYP

VOUT

GND

5

6

7

81

2

3

4

500mA, Low-Noise LDO Voltage Regulator

SPX3819

2

Power Dissipation ...................................................... Internally Limited

Lead Temp. (Soldering, 5 Seconds) ........................................... 260°C

Operating Junction Temperature Range ................... -40°C to +125°C

Input Supply Voltage ........................................................ -20V to +20V

Enable Input Voltage ........................................................ -20V to +20V

PARAMETER MIN TYP MAX UNITS ♦ CONDITIONS

Output Voltage Tolerance -1 +1 %

-2 +2 ♦

Output Voltage Temperature Coef. 57 ppm/°C

Line Regulation 0.04 0.1 %/V V

IN

=V

OUT

+ 1V to 16V

Load Regulation 0.05 0.4 % I

L

= 0.1mA to 500mA

Dropout Voltage 10 60 mV I

L

= 100µA

(V

IN

-V

O

)(Note 2) 80 ♦

125 175 mV I

L

= 50mA

250 ♦

180 350 mV I

L

= 150mA

450 ♦

340 550 mV IL = 500mA

700 ♦

Quiescent Current (I

GND

) 0.05 3 µA V

ENABLE

≤0.4V

8 ♦ V

ENABLE

≤0.25V

Ground Pin Current (I

GND

) 90 150 µA I

L

= 100µA

190 ♦

250 650 µA I

L

= 50mA

900 ♦

1.0 2.0 mA I

L

= 150mA

2.5 ♦

6.5 25.0 mA I

L

= 500mA

30.0 ♦

Ripple Rejection (PSRR) 70 dB

Current Limit (I

LIMIT

) 800 mA V

OUT

= 0.0V

950 ♦

Output Noise (e

NO

) 300 µV

RMS

I

L

=10mA, C

L

=1.0µF, C

IN

=1µF,

(10Hz-100kHz)

40 µV

RMS

I

L

=10mA, C

L

=10µF, C

BYP

=1µF,

C

IN

=1µF, (10Hz-100kHz)

Input Voltage Level Logic Low (V

IL

) 0.4 V OFF

Input Voltage Level Logic High (V

IH

) 2 V ON

ENABLE Input Current 0.01 2 µA V

IL

≤0.4V

3 20 V

IH

≥2.0V

Thermal Resistance (Note 1) 191 °C/W ♦ SOT-23-5 / Junction to Ambient

128.4 °C/W ♦ NSOIC-8 / Junction to Ambient

59 °C/W ♦ DFN-8 / Junction to Ambient

ELECTRICAL CHARACTERISTICS

TJ=25°C, VOUT + 1V, for 1.2V Option VIN=VOUT + 1.2V IL=100µA, CL=1µF, and VENABLE ≥2.4V. The

♦

denotes the

specifications which apply over full operating temperature range -40°C to +85°C, unless otherwise specified.

ABSOLUTE MAXIMUM RATINGS

NOTES

Note 1: The maximum allowable power dissipation is a function of maximum operating junction temperature, TJ(max) the junction to ambient thermal

resistance, and the ambient θJA, and the ambient temperature TA. The maximum allowable power dissipation at any ambient temperature is

given: PD(max) = (TJ(max)-TA)/θJA, exceeding the maximum allowable power limit will result in excessive die temperature; thus, the regulator will

go into thermal shutdown. The θJA of the SPX3819 is 220°C/W mounted on a PC board.

Note 2: Not applicable to output voltage 2V or less.

Input Voltage ................................................................... +2.5V to+16V

Operating Junction Temperature Range ................... -40°C to +125°C

Enable Input Voltage ........................................................... 0.0V to VIN

RECOMMENDED OPERATING CONDITIONS

3

TYPICAL PERFORMANCE CHARACTERISTICS

Ground Current vs Load Current Ground Current vs Input Voltage

7.0

6.0

5.0

4.0

3.0

2.0

1.0

0.0

0 100 200 300 400 500

I

L

(mA)

I

GN D

( m A )

3.3V Device

V

IN

= 4.3V

C

L

= 1.0µF

160

150

140

130

120

100

90

80

70

60

4

8 10 12 14 16

V

IN

(V)

I

G N D

( µ A )

3.3V Device

C

L

= 1.0µF

I

L

= 100µA

Ground Current vs Load Current in Dropout Output Voltage vs Input Voltage

14.0

12.0

10.0

8.0

6.0

4.0

2.0

0.0

0 100 200 300 400 500

I

L

(mA)

I

G N D

( m A)

3.3V Device

V

IN

= 4.3V

C

L

= 1.0µF

3.350

3.345

3.340

3.335

3.330

3.325

3.320

3.315

3.305

3.300

3.295

3.290

4 6 8 10 12 14 16

V

IN

(V)

V

OU T

(V)

3.3V Device

C

L

= 1.0µF

I

L

= 100µA

3.310

6

4

Dropout Voltage vs Load Current Output Voltage vs Load Current

Ground Current vs Temperature with 100µA Load Ground Current vs Temperature with 50mA Load

350

300

250

200

150

100

50

0

0 100 200 300 400 500

I

L

(mA)

D r o p o u t ( m V )

3.3V Device

C

L

= 1.0µF

0 100 200 300 400 500

I

L

(mA)

V

OUT

(V )

3.3V Device

VIN= 4.3V

CL = 1.0µF

130

120

110

100

90

80

70

-40 -20 0 20 40 60 80 100 120

Temperature (°C)

I

G ND

(µA)

3.3V Device

VIN= 4.3µF

CL= 1.0µF

IL = 100µA

360

340

320

300

280

260

240

220

200

-40 -20 0 20 40 60 80 100 120

Temperature (°C)

I

GN D (µA)

3.3V Device

VIN = 4.3

CL= 1.0µF

IL = 50mA

TYPICAL PERFORMANCE CHARACTERISTICS: Continued

3

.316

3

.314

3.312

3

.310

3

.308

3

.304

3

.302

3

.300

3

.306

5

Ground Current vs Temperature with 500mA Load Ground Current vs Temperature in Dropout

ENABLE Voltage, ON threshold, vs Input Voltage Output Voltage vs Temperature

8.0

7.5

7.0

6.5

6.0

-40 -20 0 20 40 60 80 100 120

Temperature (°C)

I

GND

(mA)

3.3V Device

V

IN

= 4.3µF

C

L

= 1.0µF

I

L

= 500mA

14.0

13.5

13.0

12.5

12.0

11.5

11.0

10.5

-40 -20 0 20 40 60 80 100 120

Temperature (°C)

I

GND (mA)

3.3V Device

VIN= 4.3µF

CL= 1.0µF

IL = 500mA

1.30

1.25

1.20

1.15

1.10

1.05

1.00

4 6 8 10 12 14 16

V

IN

(V)

V

EN,

On Thr eshol d

(V )

3.3V Device

C

L

= 1.0µF

I

L

= 100µA

3.400

3.380

3.360

3.340

3.320

3.300

2.280

2.260

2.240

2.220

2.200

-40 -20 0 20 40 60 80 100 120

Temperature (°C)

V

OUT (V)

3.3V Device

VIN= 4.3µF

CL= 1.0µF

IL = 500mA

TYPICAL PERFORMANCE CHARACTERISTICS: Continued

6

Output Noise vs Bypass Capacitor Value IL = 10mA,

10Hz - 100kHz

Line Transient Response for 3.3V Device

Load Transient Response for 3.3V Device

TYPICAL PERFORMANCE CHARACTERISTICS: Continued

0

50

100

150

200

250

300

350

1 10 100 1000 10000 100000 1000000

Bypass Cap (pF)

uV RMS

Cin = 1uFT,

Cout = 1uFT

Cin = 1uFT,

Cout = 2.2uFT

Cin = 1uFT

Cout = 10uFT

7

The SPX3819 requires an output capacitor for

device stability. Its value depends upon the

application circuit. In general, linear regulator

stability decreases with higher output currents.

In applications where the SPX3819 is sourcing

less current, a lower output capacitance may be

sufficient. For example, a regulator outputting

only 10mA, requires approximately half the

capacitance as the same regulator sourcing

150mA.

Bench testing is the best method for determining

the proper type and value of the capacitor since

the high frequency characteristics of electro-

lytic capacitors vary widely, depending on type

and manufacturer. A high quality 2.2µF alumi-

num electrolytic capacitor works in most appli-

cation circuits, but the same stability often can

be obtained with a 1µF tantalum electrolytic.

With the SPX3819 adjustable version, the mini-

mum value of output capacitance is a function of

the output voltage. The value decreases with

higher output voltages, since closed loop gain is

increased.

Typical Applications Circuits

A 10nF capacitor on the BYP pin will signifi-

cantly reduce output noise, but it may be left

unconnected if the output noise is not a major

concern. The SPX3819 start-up speed is in-

versely proportional to the size of the BYP

capacitor. Applications requiring a slow ramp-

up of the output voltage should use a larger

CBYP. However, if a rapid turn-on is necessary,

the BYP capacitor can be omitted.

The SPX3819’s internal reference is available

through the BYP pin.

Figure 1 represents a SPX3819 standard appli-

cation circuit. The EN (enable) pin is pulled

high (>2.0V) to enable the regulator.

To disable the regulator, EN < 0.4V.

The SPX3819 in Figure 2 illustrates a typical

adjustable output voltage configuration. Two

resistors (R1 and R2) set the output voltage. The

output voltage is calculated using the formula:

VOUT = 1.235V x [ 1 + R1/R2]

R2 must be > 10 kΩand for best results, R2

should be between 22 kΩ and 47kΩ.

APPLICATION INFORMATION

+

GND

EN BYP

(Opt.)

ENABLE may be tied directly to V

IN

SPX3819

1

2

3 4

5

V

IN

V

OUT

TOP View

+

GND

EN

Hi-ON

Lo-OFF

SPX3819

SOT-23

1

2

3 4

5

V

IN

V

OUT

R1

R2

TOP View

Figure 1. Standard Application Circuit Figure 2. Typical Adjustable Output Voltage Configuration

8

PACKAGE: PINOUTS

PACKAGE: PIN DESCRIPTION

#niP

CIOSn

#niP

NFD

#niP

3-TOS emaNniP noitpircseD

2 3 1 V

NI

t u p n I y l p p u S

8 -5 7 2 D N G d n u o r G

3 5 5 V

TU O

t u p t u O r o t a l u g e R

1 1 3 N E e l b i t a p m o c S O M C . ) t u p n i ( e l b a n E

; e l b a n e = h g i h c i g o L . t u p n i l o r t n o c

n w o d t u h s = n e p o r o w o l c i g o l

4 8 4 P Y B /J D A . t u p n i k c a b d e e F . ) t u p n i ( t s u j d A

r e d i v i d -e g a t l o v e v i t s i s e r o t t c e n n o C

k r o w t e n

- 6 , 4 - C N t c e n n o C o N

SPX3819

8 Pin DFN

EN

NC

VIN

ADJ/BYP

VOUT

GND

5

6

7

81

2

3

4

1

2

3

45

6

7

8

EN

ADJ/BYP GND

VOUT

VIN

GND

SPX3819

8 Pin nSOIC

EN GND VIN

ADJ/BYP

VOUT

SPX3819

5 Pin SOT-23

1 2

4

5

3

Note: The bottom exposed pad for the SPX3819

DFN package is connected to GND.

For further assistance:

Email: Sipexsupport@sipex.com

WWW Support page: http://www.sipex.com/content.aspx?p=support

Sipex Application Notes: http://www.sipex.com/applicationNotes.aspx

Product Change Notices: http://www.sipex.com/content.aspx?p=pcn

Sipex Corporation

Headquarters and

Sales Office

233 South Hillview Drive

Milpitas, CA95035

tel: (408) 934-7500

faX: (408) 935-7600

Sipex Corporation reserves the right to make changes to any products described herein. Sipex does not assume any liability arising out of the application or use of

any product or circuit described herein; neither does it convey any license under its patent rights nor the rights of others.

The following sections contain information which is more

changeable in nature and is therefore generated as appendices.

1) Package Outline Drawings

2) Ordering Information

If Available:

3) Frequently Asked Questions

4) Evaluation Board Manuals

5) Reliability Reports

6) Product Characterization Reports

7) Application Notes for this product

8) Design Solutions for this product

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Appendix and Web Link Information

ORDERING INFORMATION

Part Number Accuracy MSL Level Status Package Pack Type Quantity RoHS

SPX3819S-L/TR 0.01 L1 @ 260ºC Active NSOIC8 Tape & Reel 2500 Yes

SPX3819S-L-1-8/TR 0.01 L1 @ 260ºC Active NSOIC8 Tape & Reel 2500 Yes

SPX3819S-L-2-5/TR 0.01 L1 @ 260ºC Active NSOIC8 Tape & Reel 2500 Yes

SPX3819S-L-3-0/TR 0.01 L1 @ 260ºC Active NSOIC8 Tape & Reel 2500 Yes

SPX3819S-L-3-1/TR 0.01 L1 @ 260ºC Active NSOIC8 Tape & Reel 2500 Yes

SPX3819S-L-3-3/TR 0.01 L1 @ 260ºC Active NSOIC8 Tape & Reel 2500 Yes

SPX3819S-L-5-0/TR 0.01 L1 @ 260ºC Active NSOIC8 Tape & Reel 2500 Yes

SPX3819S-L 0.01 L1 @ 260ºC Active NSOIC8 TUBE 98 Yes

SPX3819S-L-1-8 0.01 L1 @ 260ºC Active NSOIC8 TUBE 98 Yes

SPX3819S-L-2-5 0.01 L1 @ 260ºC Active NSOIC8 TUBE 98 Yes

SPX3819S-L-3-0 0.01 L1 @ 260ºC Active NSOIC8 TUBE 98 Yes

SPX3819S-L-3-1 0.01 L1 @ 260ºC Active NSOIC8 TUBE 98 Yes

SPX3819S-L-3-3 0.01 L1 @ 260ºC Active NSOIC8 TUBE 98 Yes

SPX3819S-L-5-0 0.01 L1 @ 260ºC Active NSOIC8 TUBE 98 Yes

SPX3819M5-L 0.01 L1 @ 260ºC Active SOT-23-5 Not in Bulk 2500 Yes

SPX3819M5-L-1-2 0.01 L1 @ 260ºC Active SOT-23-5 Not in Bulk 2500 Yes

SPX3819M5-L-1-5 0.01 L1 @ 260ºC Active SOT-23-5 Not in Bulk 2500 Yes

SPX3819M5-L-1-8 0.01 L1 @ 260ºC Active SOT-23-5 Not in Bulk 2500 Yes

SPX3819M5-L-2-5 0.01 L1 @ 260ºC Active SOT-23-5 Not in Bulk 2500 Yes

SPX3819M5-L-3-0 0.01 L1 @ 260ºC Active SOT-23-5 Not in Bulk 2500 Yes

SPX3819M5-L-3-1 0.01 L1 @ 260ºC Active SOT-23-5 Not in Bulk 2500 Yes

SPX3819M5-L-3-3 0.01 L1 @ 260ºC Active SOT-23-5 Not in Bulk 2500 Yes

SPX3819M5-L-5-0 0.01 L1 @ 260ºC Active SOT-23-5 Not in Bulk 2500 Yes

SPX3819M5-L/TR 0.01 L1 @ 260ºC Active SOT-23-5 Tape & Reel 2500 Yes

SPX3819M5-L-1-2/TR 0.01 L1 @ 260ºC Active SOT-23-5 Tape & Reel 2500 Yes

SPX3819M5-L-1-5/TR 0.01 L1 @ 260ºC Active SOT-23-5 Tape & Reel 2500 Yes

SPX3819M5-L-1-8/TR 0.01 L1 @ 260ºC Active SOT-23-5 Tape & Reel 2500 Yes

SPX3819M5-L-2-5/TR 0.01 L1 @ 260ºC Active SOT-23-5 Tape & Reel 2500 Yes

SPX3819M5-L-3-0/TR 0.01 L1 @ 260ºC Active SOT-23-5 Tape & Reel 2500 Yes

SPX3819M5-L-3-1/TR 0.01 L1 @ 260ºC Active SOT-23-5 Tape & Reel 2500 Yes

SPX3819M5-L-3-3/TR 0.01 L1 @ 260ºC Active SOT-23-5 Tape & Reel 2500 Yes

SPX3819M5-L-5-0/TR 0.01 L1 @ 260ºC Active SOT-23-5 Tape & Reel 2500 Yes

SPX3819R2-L-1-2 0.01 L1 @ 250ºC CF DFN8 Not in Bulk 3000 Yes

SPX3819R2-L-1-2/TR 0.01 L1 @ 250ºC CF DFN8 Tape & Reel 3000 Yes

SPX3819S-L-1-2/TR 0.01 L1 @ 260ºC CF SOIC-8 Tape & Reel 2500 Yes

SPX3819S-L-1-5/TR 0.01 L1 @ 260ºC CF SOIC-8 Tape & Reel 2500 Yes

SPX3819S-L-1-2 0.01 L1 @ 260ºC CF SOIC-8 TUBE 98 Yes

SPX3819S-L-1-5 0.01 L1 @ 260ºC CF SOIC-8 TUBE 98 Yes

ORDERING INFORMATION

Part Number Accuracy MSL Level Status Package Pack Type Quantity RoHS

SPX3819R2-L 0.01 L1 @ 250ºC EOL DFN8 Not in Bulk 3000 Yes

SPX3819R2-L-1-5 0.01 L1 @ 250ºC EOL DFN8 Not in Bulk 3000 Yes

SPX3819R2-L-1-8 0.01 L1 @ 250ºC EOL DFN8 Not in Bulk 3000 Yes

SPX3819R2-L-3-3 0.01 L1 @ 250ºC EOL DFN8 Not in Bulk 3000 Yes

SPX3819R2-L-5-0 0.01 L1 @ 250ºC EOL DFN8 Not in Bulk 3000 Yes

SPX3819R2-1-2 0.01 L1 @ 240ºC EOL DFN8 Not in Bulk 3000 No

SPX3819R2-3-3 0.01 L1 @ 240ºC EOL DFN8 Not in Bulk 3000 No

SPX3819R2-1-2/TR 0.01 L1 @ 240ºC EOL DFN8 Tape & Reel 3000 No

SPX3819S/TR 0.01 L1 @ 240ºC EOL NSOIC8 Tape & Reel 2500 No

SPX3819S-2-5/TR 0.01 L1 @ 240ºC EOL NSOIC8 Tape & Reel 2500 No

SPX3819S 0.01 L1 @ 240ºC EOL NSOIC8 TUBE 98 No

SPX3819S-2-5 0.01 L1 @ 240ºC EOL NSOIC8 TUBE 98 No

SPX3819S-3-3/TR 0.01 L1 @ 240ºC EOL SOIC-8 Tape & Reel 2500 No

SPX3819S-1-8 0.01 L1 @ 240ºC EOL SOIC-8 TUBE 98 No

SPX3819S-3-3 0.01 L1 @ 240ºC EOL SOIC-8 TUBE 98 No

SPX3819S-5-0 0.01 L1 @ 240ºC EOL SOIC-8 TUBE 98 No

SPX3819M5 0.01 L1 @ 240ºC EOL SOT-23-5 Not in Bulk 2500 No

SPX3819M5-1-2 0.01 L1 @ 240ºC EOL SOT-23-5 Not in Bulk 2500 No

SPX3819M5-1-5 0.01 L1 @ 240ºC EOL SOT-23-5 Not in Bulk 2500 No

SPX3819M5-1-8 0.01 L1 @ 240ºC EOL SOT-23-5 Not in Bulk 2500 No

SPX3819M5-2-5 0.01 L1 @ 240ºC EOL SOT-23-5 Not in Bulk 2500 No

SPX3819M5-3-0 0.01 L1 @ 240ºC EOL SOT-23-5 Not in Bulk 2500 No

SPX3819M5-3-1 0.01 L1 @ 240ºC EOL SOT-23-5 Not in Bulk 2500 No

SPX3819M5-3-3 0.01 L1 @ 240ºC EOL SOT-23-5 Not in Bulk 2500 No

SPX3819M5-5-0 0.01 L1 @ 240ºC EOL SOT-23-5 Not in Bulk 2500 No

SPX3819M5/TR 0.01 L1 @ 240ºC EOL SOT-23-5 Tape & Reel 2500 No

SPX3819M5-1-2/TR 0.01 L1 @ 240ºC EOL SOT-23-5 Tape & Reel 2500 No

SPX3819M5-1-5/TR 0.01 L1 @ 240ºC EOL SOT-23-5 Tape & Reel 2500 No

SPX3819M5-1-8/TR 0.01 L1 @ 240ºC EOL SOT-23-5 Tape & Reel 2500 No

SPX3819M5-2-5/TR 0.01 L1 @ 240ºC EOL SOT-23-5 Tape & Reel 2500 No

SPX3819M5-3-0/TR 0.01 L1 @ 240ºC EOL SOT-23-5 Tape & Reel 2500 No

SPX3819M5-3-3/TR 0.01 L1 @ 240ºC EOL SOT-23-5 Tape & Reel 2500 No

SPX3819M5-5-0/TR 0.01 L1 @ 240ºC EOL SOT-23-5 Tape & Reel 2500 No

Solved by

TM

For further assistance:

Email: Sipexsupport@sipex.com

WWW Support page: http://www.sipex.com/content.aspx?p=support

Sipex Application Notes: http://www.sipex.com/applicationNotes.aspx

Sipex Corporation

Headquarters and

Sales Office

233 South Hillview Drive

Milpitas, CA 95035

tel: (408) 934-7500

fax: (408) 935-7600

Sipex Corporation reserves the right to make changes to any products described herein. Sipex does not

assume any liability arising out of the application or use of any product or circuit described herein; neither

does it convey any license under its patent rights nor the rights of others.

For further assistance, contact Sipex Technical Support:

Sipexsupport@sipex.com

Solved by

TM

SPX3819: FAQ

Part Number: SPX3819

Date: Sept14-06

Question:

Assuming a nominal load of 250mA @ 3V DC, how much ground current will be consumed? With a 6V input, will

the part even get warm? How about with a 12V input?

Answer:

The SPX3819 data sheet contains a graph of ground current vs load current for your review.

Also we suggest that you download the Thermal Considerations application note which includes a few example

calculations from the SPX3819:

http://www.sipex.com/les/ApplicationNotes/LDOThermal.pdf

The Linear Regulator Heat Calculator could also prove helpful:

http://www.sipex.com/les/ApplicationNotes/ThermalCalculator.xls

Customer bench testing is strongly recommended using intended application circuit to ensure proper operation.

Question:

Is this part similar to your SP6203 CMOS part in the above regard? Or, is it like a conventional regulator (LM7805)

where the excess voltage turns into heat?

Answer:

All LDO’s will transfer most of its energy to heat. To minimize this temperature rise keep the input to output voltage

difference slightly above dropout voltage. See the applications note mentioned above.

Question:

Can ceramic capacitors be used on the output?

Answer:

Ceramic capacitors may be used for this part. For Tantalum or Aluminum Electrolytic types, keep the Equivalent

Series Resistance (ESR) as small as possible.

Question:

Considering the PSRR is 70db, what is a better strategy for ltering the 60Hz ripple from the wall cube? A big high

voltage electrolytic on the input or a smaller, low voltage ceramic on the output? Or, a combination of both?

Answer:

A small common mode choke would be best for ltering this ripple. Variations / combinations of input capacitance

might also help but bench testing would be required.

For further assistance, contact Sipex Technical Support:

Sipexsupport@sipex.com

Question:

Is there any practical limit to how much capacitance is used on the input or output?

Answer:

Input and output capacitance may be increased without limit.

Question:

It would appear, from the data sheet, increasing the Bypass capacitor above 0.01uF has little improvement in

terms of noise. We use a special low ESL/ESR 0.1uF ceramic as standard for RF bypassing. Any concerns

about using these on your Bypass pin as well?

Answer:

If the bypass pin is to be used a 10nF ceramic capacitor is suggested. You may also use the value / type

mentioned. The only concern with the bypass feature is that startup time is increased. If startup time is a

concern then the bypass pin should be kept open. Different values of bypass capacitor will result in different

startup times.

Question:

A portion of this application involves modulating a IR LED with a 400KHz signal having a 50% duty cycle or less.

Assumming a drive level of 1 AMP per 25µS pulse, will your device even see this as an overload and go into

current limiting? If so, should a large electrolytic be employed on the output?

Answer:

This is a little difcult to answer not knowing how you plan on modulating the LED. If the enable input is used for

modulation it is possible that the device may not react fast enough to provide an output. This is very much true

if the Bypass pin is used. If the output load exceeds the current limit trip point then the output will be turned off

to protect the device. However. if the output is always on and modulation is done with some external circuitry,

then adding extra capacitance to the output could satisfy the current demand of the LED so as not to cause

current limit activation.

Question:

This part is quite attractive in terms of its Reverse Battery Protection feature. Do you have any other more

current/better alternatives?

Answer:

For a 500mA output current device this is the best Sipex offers for package size and performance. Check our

LDO products page for all of Sipex LDO offerings.

http://www.sipex.com/productselector.aspx?family=LowDropOut

For further assistance, contact Sipex Technical Support:

Sipexsupport@sipex.com

Question:

If a 3V battery pack was connected to the output, without a “wall wart” connected to the input, would any

current ow back through the device?

Answer:

The datasheet does not state that this device is operable in a pre-biased output condition; therefore, leakage

may occur.

Question:

If the 3V battery pack was connected to the input, what would the output voltage be with a 250mA load?

Answer:

If the input voltage is above dropout voltage then the part will regulate for the entire output current range up

to 500mA.

Product Characterization Report

for the

SPX5205 Family of Products

SPX3819, SPX5205 Products

Prepared By: Velvet Doung, Salvador Wu & Greg West

Date: October 6, 2006

SPX5205

Product Family

Characterization Report

Page 2 of 21

11/17/2006

Table of Contents

Section Page

Introduction 3

Characterization Procedure 3

Data Summary for Key Parameters 4

Conclusions 6

Data Histograms Appendix A

SPX5205

Product Family

Characterization Report

Page 3 of 21

11/17/2006

Introduction: This product family characterization was done as part of the

qualification of Sipex’s fabrication site transfer from Sipex’s Hillview Fab in

Milpitas, CA, to a contract foundry, Silan, in Hangzhou, China. This

characterization report summarizes data for key SPX5205 product family

characteristics and contains distributions for all parameters. A complete listing of

the product numbers covered by the characterization report is included in the

“Conclusion” section of this report. A distribution for a given parameter shows

different temperature data which are at -40ºC, 25ºC, and 85ºC.

Wafer Fab: Silan

Fab Location: Hangzhou, China

Process: Silan – bp4

MS: 1631

Characterization Procedure:

Silan Lot number(s): CA10068

Hillview Lot number(s): A133102

Temperatures: Ambient (25C), 85C, -40C

Tester: TMT

Test Program: SPX5205_S_33_01_FT

SPX5205

Product Family

Characterization Report

Page 4 of 21

11/17/2006

Data Summary:

Key Parameter Across Temperature Data Summary

Parameter Units Hillview

Fab

Distribution

Mean

Hillview

Fab

Distribution

Variance

Hillview

Fab

Cpk

Silan Fab

Distribution

Mean

Silan Fab

Distribution

Variance

Silan Fab

Cpk

-40C

Vout@1mA V

3.3063 0.0145 0.1453

3.3101 0.0145 0.2313

Vout@150mA V 3.3059 0.0143 0.1377

3.3096 0.0146 0.2201

Load Reg % 0.0163 0.0239 2.5591

0.0155 0.0124 >4.0000

Vout@16V V

3.3033 0.0146 0.0755

3.3066 0.0160 0.1374

Vout@Ven16V V 3.3031 0.0146 0.0698

3.3084 0.0159 0.1756

Line Reg %/V 0.0095 0.0022 >4.0000

0.0106 0.0092 3.2365

Vdrop@100uA mV 4.4206 0.4011 >4.0000

4.8494 0.1847 >4.0000

Vdrop@150mA mV 165.9586 5.1199 >4.0000

171.5026 3.1504 >4.0000

Ien_Hi uA

2.5512 0.7638 >4.0000

6.6740 0.6094 >4.0000

Ien_Lo uA

0.0766 0.0507 >4.0000

0.0418 0.0348 >4.0000

Iq uA

0.1293 0.1387 2.0921

0.1244 0.1015 2.8759

Ignd@100uA uA

65.9978 5.4764 3.5913

61.9901 12.8836 1.6302

Ignd@150mA mA 0.1791 0.0095 >4.0000

0.1367 0.0136 >4.0000

Ilim mA

245.0682 0.7598 >4.0000

244.7949 1.0248 >4.0000

25C

Vout@1mA V 3.3116 0.0127 0.3030

3.3155 0.0052 0.9831

Vout@150mA V 3.3101 0.0127 0.2635

3.3140 0.0051 0.9141

Load Reg % 0.0454 0.0133 3.8768

0.0434 0.0161 3.2412

Vout@16V V

3.3063 0.0127 0.1658

3.3113 0.0053 0.7049

Vout@Ven16V V 3.3063 0.0127 0.1654

3.3113 0.0054 0.7008

Line Reg %/V 0.0154 0.0012 >4.0000

0.0125 0.0029 >4.0000

Vdrop@100uA mV 5.8073 0.4263 >4.0000

6.2024 0.1236 >4.0000

Vdrop@150uA mV 198.4826 1.4465 >4.0000

202.5361 1.1720 >4.0000

Ien_Hi uA

2.0744 0.5860 >4.0000

5.6495 0.7200 >4.0000

Ien_Lo uA

0.0889 0.0381 >4.0000

0.0491 0.0227 >4.0000

Iq uA

0.0712 0.0202 >4.0000

0.0848 0.0140 >4.0000

Ignd@100uA uA

67.5626 3.5699 >4.0000

68.1415 3.3238 >4.0000

Ignd@150uA mA

0.1561 0.0103 >4.0000

0.1256 0.0077 >4.0000

Ilim mA

246.5068 0.5756 >4.0000

247.4643 0.5002 >4.0000

SPX5205

Product Family

Characterization Report

Page 5 of 21

11/17/2006

85C

Vout@1mA V 3.2970 0.0109 -0.0910

3.2998 0.0058 -0.0113

Vout@150mA V 3.2945 0.0109 -0.1690

3.2950 0.0058 -0.2835

Load Reg % 0.0768 0.0226 1.8173

0.1440 0.0261 0.7146

Vout@16V V

3.3219 0.0150 0.4887

3.3184 0.0062 0.9950

Vout@Ven16V V 3.3189 0.0143 0.4418

3.3188 0.0097 0.6478

Line Reg %/V 0.0366 0.0160 1.3243

0.0310 0.0172 1.3345

Vdrop@100uA mV 7.3246 0.4241 >4.0000

8.0661 0.1438 >4.0000

Vdrop@150uA mV 234.8495 2.2662 >4.0000

239.0377 1.8582 >4.0000

Ien_Hi uA

1.7742 0.4554 >4.0000

4.6596 0.3992 >4.0000

Ien_Lo uA

0.1911 0.0379 >4.0000

0.1981 0.0446 >4.0000

Iq uA

2.2378 0.6659 -0.6196

1.5455 0.3054 -0.5954

Ignd@100uA uA

65.8955 3.1628 >4.0000

64.1807 3.4968 >4.0000

Ignd@150uA mA

0.1215 0.0122 >4.0000

0.0960 0.0086 >4.0000

Ilim mA

236.4959 0.8179 >4.0000

236.7823 0.6988 >4.0000

SPX5205

Product Family

Characterization Report

Page 6 of 21

11/17/2006

Conclusion:

Characterization data over temperature and Vcc range show datasheet

parameters meet the spec. Cpk’s for most parameters are comparable between

Hillview and Silan although many show a strong temperature dependence that

tends to produce lower Cpk’s in this analysis.

The performance of SPX5205 parts fabricated at Silan are comparable to the

current SPX5205 parts built from the Hillview fab.

This characterization report applies to the following SPX5205 family of product

part numbers:

SPX3819A1-3-3 SPX3819R2-1-5 SPX3819S-L-3-3 SPX3819U-L-3-0

SPX3819A1-L-3-3 SPX3819R2-1-8 SPX3819S-L-5-0 SPX3819U-L-3-1

SPX3819M3-1-8 SPX3819R2-2-5 SPX3819T-1-8 SPX3819U-L-3-3

SPX3819M3-3-0 SPX3819R2-3-0 SPX3819T-3-0 SPX3819U-L-5-0

SPX3819M3-3-1 SPX3819R2-3-1 SPX3819T-3-1 SPX5205M5

SPX3819M3-3-3 SPX3819R2-3-3 SPX3819T-3-3 SPX5205M5-1-2

SPX3819M3-L-1-8 SPX3819R2-5-0 SPX3819T5-1-8 SPX5205M5-1-5

SPX3819M3-L-3-0 SPX3819R2-L SPX3819T5-3-0 SPX5205M5-1-8

SPX3819M3-L-3-1 SPX3819R2-L-1-2 SPX3819T5-3-1 SPX5205M5-2-0

SPX3819M3-L-3-3 SPX3819R2-L-1-5 SPX3819T5-3-3 SPX5205M5-2-5

SPX3819M5 SPX3819R2-L-1-8 SPX3819T5-L-1-8 SPX5205M5-2-8

SPX3819M5-1-2 SPX3819R2-L-2-5 SPX3819T5-L-3-0 SPX5205M5-3-0

SPX3819M5-1-5 SPX3819R2-L-3-0 SPX3819T5-L-3-1 SPX5205M5-3-3

SPX3819M5-1-8 SPX3819R2-L-3-1 SPX3819T5-L-3-3 SPX5205M5-5-0

SPX3819M5-2-5 SPX3819R2-L-3-3 SPX3819T-L-1-8 SPX5205M5-L

SPX3819M5-3-0 SPX3819R2-L-5-0 SPX3819T-L-3-0 SPX5205M5-L-1-2

SPX3819M5-3-1 SPX3819S SPX3819T-L-3-1 SPX5205M5-L-1-5

SPX3819M5-3-3 SPX3819S-1-8 SPX3819T-L-3-3 SPX5205M5-L-1-8

SPX3819M5-5-0 SPX3819S-2-5 SPX3819U SPX5205M5-L-2-0

SPX3819M5-L SPX3819S-3-0 SPX3819U-1-8 SPX5205M5-L-2-5

SPX3819M5-L-1-2 SPX3819S-3-1 SPX3819U-2-5 SPX5205M5-L-2-8

SPX3819M5-L-1-5 SPX3819S-3-3 SPX3819U-3-0 SPX5205M5-L-3-0

SPX3819M5-L-1-8 SPX3819S-5-0 SPX3819U-3-1 SPX5205M5-L-3-3

SPX3819M5-L-2-5 SPX3819S-L SPX3819U-3-3 SPX5205M5-L-5-0

SPX3819M5-L-3-0 SPX3819S-L-1-2 SPX3819U-5-0

SPX3819M5-L-3-1 SPX3819S-L-1-5 SPX3819U5-3-3

SPX3819M5-L-3-3 SPX3819S-L-1-8 SPX3819U5-L-3-3

SPX3819M5-L-5-0 SPX3819S-L-2-5 SPX3819U-L

SPX3819R2 SPX3819S-L-3-0 SPX3819U-L-1-8

SPX3819R2-1-2 SPX3819S-L-3-1 SPX3819U-L-2-5

SPX5205

Product Family

Characterization Report

Page 7 of 21

11/17/2006

Appendix A

Characterization Data Histograms

SPX5205

Product Family

Characterization Report

Page 8 of 21

11/17/2006

HV SPX5205 - Vref @1m a

0

2

4

6

8

10

12

14

16

18

20

3

3.04

3.08

3.12

3.16

3.2

3.24

3.28

3.32

3.36

3.4

3.44

3.48

3.52

3.56

3.6

Vre f (v)

Frequency

cold

room

hot

Sil a n SPX5205 - Vref @1ma

0

5

10

15

20

25

30

3

3.04

3.08

3.12

3.16

3.2

3.24

3.28

3.32

3.36

3.4

3.44

3.48

3.52

3.56

3.6

Vre f (v)

Frequency

cold

room

hot

SPX5205

Product Family

Characterization Report

Page 9 of 21

11/17/2006

HV SP X52 05 - Vref@150ma

0

2

4

6

8

10

12

14

16

18

3

3.04

3.08

3.12

3.16

3.2

3.24

3.28

3.32

3.36

3.4

3.44

3.48

3.52

3.56

3.6

Vref (v)

Frequency

cold

room

hot

Silan SPX5205 - Vr ef @150ma

0

5

10

15

20

25

30

3

3.04

3.08

3.12

3.16

3.2

3.24

3.28

3.32

3.36

3.4

3.44

3.48

3.52

3.56

3.6

Vre f (v)

Frequency

cold

room

hot

SPX5205

Product Family

Characterization Report

Page 10 of 21

11/17/2006

HV SPX5202 - Load Reg

0

2

4

6

8

10

12

14

0

0.02

0.04

0.06

0.08

0.1

0.12

0.14

0.16

0.18

0.2

0.22

0.24

0.26

0.28

0.3

Loa dRe g (%)

Frequency

cold

room

hot

Si lan SPX520 2 - Load Reg

0

2

4

6

8

10

12

14

16

0

0.02

0.04

0.06

0.08

0.1

0.12

0.14

0.16

0.18

0.2

0.22

0.24

0.26

0.28

0.3

Loa dRe g (%)

Frequency

cold

room

hot

SPX5205

Product Family

Characterization Report

Page 11 of 21

11/17/2006

HV SPX5205 - Vout @ Vi n= 16v

0

2

4

6

8

10

12

14

16

3

3.04

3.08

3.12

3.16

3.2

3.24

3.28

3.32

3.36

3.4

3.44

3.48

3.52

3.56

3.6

Vout (v)

Frequency

cold

room

hot

Sil an SPX5205 - Vout@ Vin= 16v

0

5

10

15

20

25

30

3

3.04

3.08

3.12

3.16

3.2

3.24

3.28

3.32

3.36

3.4

3.44

3.48

3.52

3.56

3.6

Vout (v)

Frequency

cold

room

hot

SPX5205

Product Family

Characterization Report

Page 12 of 21

11/17/2006

HV SPX5205 - Vout @ Ven=16v

0

2

4

6

8

10

12

14

16

3

3.04

3.08

3.12

3.16

3.2

3.24

3.28

3.32

3.36

3.4

3.44

3.48

3.52

3.56

3.6

Vout (v)

Freqeuncy

cold

room

hot

Sil an SPX5205 - Vout @ Ven=16v

0

5

10

15

20

25

30

3

3.04

3.08

3.12

3.16

3.2

3.24

3.28

3.32

3.36

3.4

3.44

3.48

3.52

3.56

3.6

Vout (v)

Freqeuncy

cold

room

hot

SPX5205

Product Family

Characterization Report

Page 13 of 21

11/17/2006

HV SPX5205 - Li neReg

0

5

10

15

20

25

0

0.01

0.02

0.03

0.04

0.05

0.06

0.07

0.08

0.09

0.1

0.11

0.12

0.13

0.14

0.15

Line Reg (%/ v)

Frequency

cold

room

hot

Si l an SPX5205 - Li neReg

0

2

4

6

8

10

12

14

16

18

20

0

0.01

0.02

0.03

0.04

0.05

0.06

0.07

0.08

0.09

0.1

0.11

0.12

0.13

0.14

0.15

Line Reg (%/ v)

Frequency

cold

room

hot

SPX5205

Product Family

Characterization Report

Page 14 of 21

11/17/2006

HV SPX52 05 - Vdropou t @1 00 ua

0

5

10

15

20

25

30

35

0

2

4

6

8

10

12

14

16

18

20

22

24

26

28

30

Vdropout (v)

Freqeuncy

cold

room

hot

Si lan SPX5 20 5 - Vdr opout@100 ua

0

5

10

15

20

25

30

35

0

2

4

6

8

10

12

14

16

18

20

22

24

26

28

30

Vdropout (v)

Freqeuncy

cold

room

hot

SPX5205

Product Family

Characterization Report

Page 15 of 21

11/17/2006

HV SPX5205 - Vdrop@150ma

0

5

10

15

20

25

30

35

0

20

40

60

80

100

120

140

160

180

200

220

240

260

280

300

Vdrop (v)

Frequency

cold

room

hot

Silan SPX5205 - Vdrop@150ma

0

5

10

15

20

25

30

35

0

20

40

60

80

100

120

140

160

180

200

220

240

260

280

300

Vdrop (v)

Frequency

cold

room

hot

SPX5205

Product Family

Characterization Report

Page 16 of 21

11/17/2006

HV SPX5205 - I en_Hi

0

2

4

6

8

10

12

14

16

18

0

2

4

6

8

10

12

14

16

18

20

22

24

26

28

30

Ie n (ua)

Freqeuncy

cold

room

hot

Si lan SPX5 205 - Ien_Hi

0

2

4

6

8

10

12

14

16

18

20

0

2

4

6

8

10

12

14

16

18

20

22

24

26

28

30

Ie n (ua)

Freqeuncy

cold

room

hot

SPX5205

Product Family

Characterization Report

Page 17 of 21

11/17/2006

HV SPX5205 - Ien_Lo

0

2

4

6

8

10

12

14

16

0

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

1

1.1

1.2

1.3

1.4

1.5

Ie n (ua)

Freqeuncy

cold

room

hot

Si l a n SPX5205 - Ien_Lo

0

2

4

6

8

10

12

14

16

18

20

0

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

1

1.1

1.2

1.3

1.4

1.5

Ie n (ua)

Freqeuncy

cold

room

hot

SPX5205

Product Family

Characterization Report

Page 18 of 21

11/17/2006

HV SPX5205 - Q ui escent_I

0

5

10

15

20

25

30

35

0

0.4

0.8

1.2

1.6

2

2.4

2.8

3.2

3.6

4

4.4

4.8

5.2

5.6

6

Iq (ua)

Freqeuncy

cold

room

hot

Sil an SPX5205 - Q ui escent_I

0

5

10

15

20

25

30

35

0

0.4

0.8

1.2

1.6

2

2.4

2.8

3.2

3.6

4

4.4

4.8

5.2

5.6

6

Iq (ua)

Freqeuncy

cold

room

hot

SPX5205

Product Family

Characterization Report

Page 19 of 21

11/17/2006

HV SPX5205 - I gnd@100ua

0

2

4

6

8

10

12

14

16

18

0

10

20

30

40

50

60

70

80

90

100

110

120

130

140

150

Ignd (ua)

Frequency

cold

room

hot

Silan SPX5205 - I gnd@100ua

0

2

4

6

8

10

12

14

16

18

20

0

10

20

30

40

50

60

70

80

90

100

110

120

130

140

150

Ignd (ua)

Frequency

cold

room

hot

SPX5205

Product Family

Characterization Report

Page 20 of 21

11/17/2006

HV SPX5205 - Ignd@150m a

0

5

10

15

20

25

30

35

0

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

1

1.1

1.2

1.3

1.4

1.5

Ignd (ma)

Frequency

cold

room

hot

Si lan SPX5 205 - I gnd@150ma

0

5

10

15

20

25

30

35

0

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

1

1.1

1.2

1.3

1.4

1.5

Ignd (ma)

Frequency

cold

room

hot

SPX5205

Product Family

Characterization Report

Page 21 of 21

11/17/2006

HV SPX5205 - Curr ent Li m i t

0

5

10

15

20

25

30

35

0

40

80

120

160

200

240

280

320

360

400

440

480

520

560

600

Curre nt Lim i t

Frequency

cold

room

hot

Silan SPX5205 - Curr ent Limi t

0

5

10

15

20

25

30

35

0

40

80

120

160

200

240

280

320

360

400

440

480

520

560

600

Curre nt Lim i t

Frequency

cold

room

hot

SPX29150 Reliability Report Page 1 of 4

Reliability and Qualification Report

Silan BP4 Process Reliability Qualification

using the SPX29150

Prepared By: Salvador Wu & Greg West Reviewed By: Fred Claussen

QA Engineering VP Quality & Reliability

Date: September 15, 2006 Date: September 15, 2006

SPX29150 Reliability Report Page 2 of 4

Table Of Contents

Title Page 1

Table Of Contents 2

Device Description 2

Pin Out 2

Manufacturing Information 2

Package Information 2

Reliability Test Summary 3

Life Test Data 3

FIT Data Calculations 4

MTBF Data Calculations 4

ESD Testing 4

Early Life Failure Rate Testing 5

5L TO-263 Pb Free Package Qualification Addendum 4

Device Description:

The SPX29150/51/52/53 are 1.5A, highly accurate voltage regulators with a low dropout

voltage of 390mV (typical) @ 1.5A. These regulators are specifically designed for low

voltage applications that require a low dropout voltage and a fast transient response. They

are fully fault protected against over-current, reverse battery, and positive and negative

voltage transients. On-chip trimming adjusts the reference voltage to 1% initial accuracy.

Other features in the 5 pin versions include Enable and Error Flag.

The SPX29150/51/52/53 is offered in 3-pin and 5-pin TO-220 & TO-263 packages. For a

3A version, refer to the SPX29300 data sheet.

Manufacturing Information:

Product: SPX29150

Description: 1.5A PNP LDO

Mask Set: MS1562

Lot Number(s): SPXBP4012EC,

A135428.3 (15), A136411.2 (16)

Process: sil-bp4

Wafer Fab: Silan

Package Information:

Package Type: TO 263-5L

Package Code:: JEDEC

PIN OUT SPX29150

SPX29150 Reliability Report Page 3 of 4

Reliability Qualification Test Summary:

Stress Level

Device Lot Numbe

r

Burn-In Temp Sample Size No. Fail

168Hrs SPX29150 SPXBP401

2EC

125 °C 77 0

168Hrs SPX29150 A135428.3

(15)

125 °C 77 0

168Hrs SPX29150 A136411.2

(16)

125 °C 77 0

1000Hrs SPX29150 SPXBP401

2EC

125 °C 77 0

1000Hrs SPX29150 A135428.3

(15)

125 °C 77 0

1000Hrs SPX29150 A136411.2

(16)

125 °C 77 0

Life Test

Life testing is conducted to determine if there are any fundamental reliability related

failure mechanism(s) present in the device.

These failure mechanisms can be divided roughly into four groups:

1. Process or die related failures such as oxide defects, metallization defects, and

diffusion defects.

2. Assembly related failures such as chip mount defects, wire bond defects, molding

defects, and trim/form/singulation defects.

3. Design related defects.

4. Miscellaneous, undetermined, or application induced failures.

125C Operating Life Test Results

As part of the Sipex design qualification program, the Product/Reliability Engineering

group subjected 231 parts to 168 hours and 1000 hours of 125° C life stress testing.

168 Hour Timepoint

The 231 parts were subjected to the life test profile and completed the stress with no

failures.

1000 Hour Timepoint

231 parts were reintroduced to life stress testing, completing the 1000 hour HTOL time

point without any failures or significant shifts in process parameters

FIT Rate Calculations

FIT rate (failures in time) is the predicted number of failures per billion device hours.

This predicted value is based upon,

SPX29150 Reliability Report Page 4 of 4

• The Life Test conditions summarized in the HTOL table (time/temperature, device

quantity, failure quantity).

• The Activation Energy (Ea) for potential failure modes. The weighted Activation

Energy(Ea) of observed failure mechanisms for Sipex products has been determined

to be 0.8eV.

Based on the above criteria SPX29150 product FIT rates for 25°, 55°, and 70°C of

operation at 60% and 90% confidence levels have been calculated and listed below.

FIT Failure Rates: SPX29150 BP4 Silan Process

Confidence Level +25°C +55°C +70°C

60% 1.6 26.4 89.0

90% 3.9 64.2 216.0

1 FIT = 1 Failure per Billion Device-Hours

MTBF Calculation: SPX29150 BP4 Silan Process

Confidence Level +25°C +55°C +70°C

60% 6.15E+08 3.78E+07 1.12E+07

90% 2.53E+08 1.56E+07 4.63E+06

ESD Testing

Human Body Model ESD – 32 units were subjected to Human Body Model ESD testing

at +/- 2KV. All units passed.

Early Life Failure Rate Testing

Early Life Test – 600 units were subject to Early Life test for 48 Hours. All units passed

Additional Reliability Tests

77 of the units were placed on Unbiased HAST testing, 77 of the units were placed on Thermal

Shock testing, and 77 on -65C/+150C Temperature Cycle testing. All units passed testing as summarized

in the following table.

Test Condition Time Sample Size

# of

rejects

TEMP. Cycles -65C/+150C 500 Cycles 77 0

HAST Unbiased 130C/85%RH 96hrs 77 0

Thermal Shock -65C/+150C 500 Cycles 77 0