SPX1117M3-L/TR - MaxLinear, Inc.

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September 2018

Rev. 2.1.1

1/11 Rev. 2.1.1

GENERAL DESCRIPTION

The SPX1117 is a low power positive-voltage

regulator designed to satisfy moderate power

requirements with a cost effective, small

footprint solution.

This device is an excellent choice for use in

battery-powered applications and portable

computers. The SPX1117 features very low

quiescent current and a low dropout voltage of

1.1V at a full load. As output current

decreases, quiescent current flows into the

load, increasing efficiency. SPX1117 is

available in adjustable or fixed 1.5V, 1.8V,

2.5V, 3.3V and 5V output voltages.

The SPX1117 is offered in a 3-pin SOT-223

surface mount packages.

An output capacitor of 10µF provides

unconditional stability while a smaller 2.2µF

capacitor is sufficient for most applications.

APPLICATIONS

• Desktop PC Servers

• Graphic/Video Cards

• Industrial Equipments

• Power Supplies

FEATURES

• Guaranteed 800mA Output Current

• Guaranteed 1A Peak Current

• Three Terminal Adjustable or Fixed

1.5V, 1.8V, 2.5V, 3.3V an d 5V

• Low Quiescent Current

• Low Dropout Voltage of 1.1V at 800mA

• 0.1% Line and 0.2% Load Regulation

• Stable with 2.2µF Ceramic Capacitor

• Overcurrent and Thermal Protection

• Lead Free, RoHS Compliant SOT223

Package

FUNCTIONAL DIAGRAM

Fig. 1: SPX1117 Application Diagram

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2/11 Rev. 2. 1.1

ABSOLUTE MAXIMUM RATINGS

These are stress ratings only and functional operation of

the device at these ratings or any other above those

indicated in the operation sections of the specifications

below is not implied. Exposure to absolute maximum

rating conditions for extended periods of time may affect

reliability.

Power Dissipation ................................ Inter na lly Limite d

Lead Tempera tur e (Soldering , 5 sec) ..................... 260°C

Stor age Temperature .............................. -65°C to 150°C

Operating Junc tion Temperature Range ... -40°C to +125°C

Input Supply Voltage .............................................. 20V

Input to Output Vol tag e ........................................ 18.8V

ESD Rating (HBM - Human Body Model) .................... 2kV

ELECTRICAL SPECIFICATIONS

Spec ifications wi th standard type ar e for an Operating Ambient Temp eratur e o f TA = 25°C only ; limits apply ing over the full

Operating Junction Temperature range are denoted by a “•”. Minimum and Maximum limits are guaranteed through test,

design, or stati s tic al c or relation. Typ ic al values re pr ese nt the most likely parame tric nor m at TJ = 25°C, and are provided for

referenc e purposes only. Unless otherwise indicated, CIN = COUT =10µF, TA= 25°C.

Parameter Min. Typ. Max. Units Conditions

1.5V Version

Output Voltag e

1.485

1.500

1.515

V

I

OUT

=5mA, V

IN

=3.0V, T

J

=25°C

1.470

1.530

•

5mA≤ IOUT ≤800mA, 2.9V≤ VIN ≤10V

1.8V Version

Output Voltag e

1.782

1.800

1.818

V

I

OUT

=5mA, V

IN

=3.3V, T

J

=25°C

1.764

1.836

•

5mA≤ I

OUT

≤800mA, 3.2V≤ V

IN

≤10V

2.5V Version

Output Voltag e

2.475

2.500

2.525

V

IOUT=5mA, VIN=4.0V, TJ=25°C

2.450

2.550

•

5mA≤ IOUT ≤800mA, 3.9V≤ VIN ≤10V

3.3V Version

Output Voltag e

3.267

3.300

3.333

V

I

OUT

=5mA, V

IN

=4.8V, T

J

=25°C

3.234

3.366

•

5.0V Version

Output Voltag e

4.950

5.000

5.050

V

I

OUT

=5mA, V

IN

=6.5V, T

J

=25°C

4.900

5.100

•

5mA≤ I

OUT

≤800mA, 6.4V≤ V

IN

≤12V

All Voltage Options

Reference Voltage

1.238

1.250

1.262

V

IOUT=5mA, (VIN – VOUT)=2V, TJ=25°C

1.225

1.270

•

5mA≤IOUT≤800mA, 1.4V≤(VIN–VOUT)≤10V

Output Voltag e Temp er ature

Stability

0.3 %

Line Regulatio n (note 1) 3 7 mV

V

INMIN

≤ V

IN

≤12V, V

OUT

= Fixed/Adj.,

IOUT=5mA

Load Regulation (note 1)

6

12

mV

•

5mA≤ I

OUT

≤800mA, V

OUT

= Fixed/Adj.

Dropout Volta g e (note 2)

1.00 1.20 V

•

I

OUT

=100mA

1.05

1.25

•

I

OUT

=500mA

1.10

1.30

•

IOUT=800mA

Quiescent Current

5

10

mA

•

4.25V≤ VIN ≤6.5V

Adjust Pin Current

50 120 µA

•

Current Limit

1.0

1.5

2.0

A

(V

IN

– V

OUT

)=5V

Thermal Regulation

0.01

0.1

%/W

25°C, 30m s pulse

Ripp le Reje c tion 60 75 dB

f

RIPPLE

=120Hz , (V

IN

– V

OUT

)=2V,

V

RIPPLE

=1V

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3/11 Rev. 2. 1.1

Parameter Min. Typ. Max. Units Conditions

Long Term Stab ility

0.03

%

125°C, 1000Hrs

RMS Output Noise

0.003

%

% of V

OUT

, 10Hz≤f≤10kHz

Note 1:

For fixed voltage option VINMIN=VOUT+1.5V

For adjusta b le voltage option VIN-VOUT=1.4V

Note 2: Dropout voltage is the input voltage minus output voltage that produces a 1% decrease in output voltage with

respec t to the nomina l o utp ut vo lta g e at VIN=VOUT+1.5V

PIN ASSIGNMENT

Fig. 2: SPX1117 Pin Ass ignment (Top View, TAB co nnecte d to VOUT)

ORDERING INFORMATION(1)

Part Number Operating

Temperature Range Lead-Free Package Packing Me thod Output Volta ge

SPX1117M3-L/TR

-40°C≤TJ≤+125°C Yes(2) SOT223-3 Tape & Reel

Adjustable

SPX1117M3-L-1-5/TR 1.5V

SPX1117M3-L-1-8/TR 1.8V

SPX1117M3-L-2-5/TR 2.5V

SPX1117M3-L-3-3/TR 3.3V

SPX1117M3-L-5-0/TR 5.0V

NOTE:

1. Refer to www.exar.com/SPX1117 for mos t u p-to-date Ordering Information.

2. Visit www.exar.com for additional inform ation on Environmental Ra ting .

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4/11 Rev. 2. 1.1

TYPICA L P ERFORMANCE CHARACTERISTICS

All data taken at TA = 25°C, unless otherwise specified - Schematic and BOM from Application Information section of this

datasheet.

Fig. 3: Load Regulation

SPX1117M3-L-3-3, VIN=4.8V

Fig. 4: Line Regulation

SPX1117M3-L-3-3, IOUT=10mA

Fig. 5: Dropout Voltage vs Output Current

SPX1117M3-L-3-3, VIN=4.8V, COUT=2.2µF

Fig. 6: Current Limit

IOUT p uls ed fro m 10mA to Current limit

SPX1117M3-L-3-3, VIN=4.8V, CIN=COUT=2.2µF

Fig. 7: Curre nt Limit

Output Voltage Deviation

SPX1117M3-L-3-3, IOUT=10mA to 1A Step

Fig. 8: VOUT vs Temperature

VIN=2.5V, IOUT=10mA

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5/11 Rev. 2. 1.1

Fig. 9: VIN=3.0V, IOUT=10mA

Fig. 10: VIN= 3.3V, IOUT=10mA

Fig. 11: VIN= 4.0V , IOUT=10mA

Fig. 12: VIN=4.85V, IOUT=10mA

Fig. 13: Line Regulation vs Temperature

VOUT=1.8V (Adj), VIN=3.3V

Fig. 14: Output Voltage vs Temperature

Different IOUT, VOUT=1.8V (Adj), VIN=3.3V

Fig. 15: Line Regulation over Temperature

ILOAD=800m A , VOUT=1.8V(adj)

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6/11 Rev. 2. 1.1

APPLICATION INFORMATION

OUTPUT CAPACITOR

To ensure the stability of the SPX1117, an

output capacitor of at least 2.2µF (tantalum or

ceramic) or 10µF (aluminum) is required. The

value may change based on the application

requirements of the output load or

temperature rang e. The value of ESR can vary

based on the type of capacitor used in the

applications to guarantee stability. The

recommended value for ESR is 0.5Ω or less. A

larger value of output capacitance (up to

100µF) can improve the load transient

response.

Fig. 16: Load Step Response 0mA to 800mA

VIN=3.3V, VOUT=1.8V, CIN=10 µF, COUT=2.2µF, Ceramic

Signal 1=V OUT, Signal 4=ILOAD

Fig. 17: Load Step Response 0mA to 800mA

VIN=3.3V, VOUT=1.8V, CIN=10 µF, COUT=2.2µF, OSCON

Signal 1=V OUT, Signal 4=ILOAD

Fig. 18

SOLDERING METHODS

The SPX1117 SOT-223 package is designed to

be compatible with infrared reflow or vapor-

phase reflow soldering techniques. During

soldering, the non-active or mildly active

fluxes may be used. The SPX1117 die is

attached to the heatsink lead which exits

opposite the input, output, and ground pins.

Hand soldering and wave soldering should be

avoided since these methods can cause

damage to the device with excessive thermal

gradients on the package. The SOT-223

recommended soldering method are as

follows: vapor phase reflow and infrared

reflow with the component preheated to within

65°C of the soldering temperature range.

THERMAL CHARACTERISTICS

The thermal resistance of SPX1117 (SOT-223

package) is 15°C/W from junction to tab and

31°C/W from tab to ambient for a total of 46

°C/W from junction to ambient (Table 1). The

SPX1117 features the internal thermal limiting

to protect the device during overload

conditions. Special care needs to be taken

during continuous load conditions such that

the maximum junction temperature does not

exceed 125 °C. Thermal protection is activate d

at >155°C and deactivated at <140 °C.

Taking the FR-4 printed circuit board and 1/16

thick with 1 ounce copper foil as an

experiment (fig.19), the PCB material is

effective at transmitting heat with the tab

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7/11 Rev. 2. 1.1

attached to the pad area and a ground plane

layer on the backside of the substrate. Refer

to table 1 for the results of the experiment.

The thermal interaction from other

components in the application can affect the

thermal resistance of the SPX1117. The actual

thermal resistance can be determined with

experimentation.

SPX1117 power dissipation is calculated as

follows:



= (

 − 

 ) × 

Maximum Junction Temperature



=

()+

×ℎ  (  . )

Maximum junction temperature must not

exceed 125°C.

Fig. 19: Substrate Layout for SOT-223

RIPPLE REJECTION

Ripple rejection can be improved by adding a

capacitor between the ADJ pin and ground as

shown in Figure 23. When ADJ pin bypassing

is used, the value of the output capacitor

required increases to its maximum. If the ADJ

pin is not bypassed, the value of the output

capacitor can be lowered to 10μF for an

electrolytic aluminum capacitor or 2.2μF for a

ceramic or solid tantalum capacitor (Fig 22).

However the value of the ADJ-bypass

capacitor should be chosen wi th respect to the

following equation:

=1

6.28 ××1

Where

C: value of capacitor in Farads

FR: ripple frequency in Hz

R1: value of resistor R1 in ohms

If an ADJ-bypass capacitor is used, the

amplitude of the output ripple will be

independent of the output voltage. If an ADJ-

bypass capacitor is not used, the output ripple

will be proportional to the ratio of the output

voltage to the re ference voltage:

=







Where M=multiplier for the ripple seen when

the ADJ pin is optimally bypassed.

VREF=1.25V

Ripple rejection for the adjustable version is

shown in Figure 20.

Fig. 20: Ripple Rejection

VIN=3.3V, VOUT=1.8V(adj), ILOAD=200mA

OUTPUT VOLTAGE

The output of the adjustable regulator can be

set to any voltage between 1.25V and 15V.

The val ue of VOUT can be quickly approximated

using the f ormula



 = 1.25 ×1+2

1

A small correction to this formula is required

depending on the values of resistors R1 and

R2, since the adjustable pin current (approx

50μA) flows through R2. When IADJ is taken

into account, the formula becomes



 =

×1+2

1

+

 ×2

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8/11 Rev. 2. 1.1

Whe re VREF=1.25V

PRE-BIAS OUTPUT VOLTAGE START-UP

The SPX1117 is not intended for operations

requiring start-up into a pre-biased load.

Proper discharge of the output voltage is

recommended prior of turning on the device

through the application of the input voltage.

LAYOUT CONSIDERATIONS

Parasitic line resistance can degrade local

regulation. In order to avoid this, connect R1

directly to VOUT as illustrated in figure 25. For

the same reason R2 should be connected to

the negative side of the load.

Fig. 21: Current Cource

Fig. 22:Typical Adjustable Regulator

Fig. 23: Improving Ripple Rejection

Fig. 24: 5V Regulator with Shutdown

Fig. 25: Recommended Connections for Best Results

PC Board

mm2

Topside

Copper

mm2

Backside

Copper

mm2

Thermal

Resistance

Jct to amb.

°C/W

2500

46

2500

1250

2500

47

2500

950

2500

49

2500

0

51

2500

1800

0

53

1600

600

1600

55

2500

1250

0

58

2500

915

0

59

1600

600

0

67

900

240

900

72

900

240

0

85

Table 1

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9/11 Rev. 2. 1.1

MECHANICAL DIMENSIONS

3-PIN SOT-223

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10/11 Rev. 2. 1.1

RECOMM ENDED LAND PATTERN AND STENCIL

3-PIN SOT-223

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11/11 Rev. 2. 1.1

REVISION HISTORY

Revision Date Description

2.0.0

06/23/2010

Reformat of Datasheet

2.1.0

08/24/2011

Addition of the Pre-Bias Output Voltage Start-up section

2.1.1 09/05/2018

Update to MaxLine ar logo. Update format and Ordering Information. Removed obsolete

TO-263-3.

Corporate Headquarters:

5966 La Place Court

Suite 100

Carlsbad, CA 92008

Tel.:+1 (760) 692-0711

Fax: +1 (760) 444-8598

www.maxlinear.com

High Performance Analog:

1060 Rincon Circle

San Jose, CA 95131

Tel.: +1 (669) 265-6100

Fax: +1 (669) 265-6101

www.exar.com

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