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Page 1

EN6347QA 4A PowerSoC

Step-Down DC-DC Switching Converter with Integrated Inductor

DESCRIPTION

The EN6347QA is a Power System on a Chip

(PowerSoC) DC-DC converter that is AEC-Q100

qualified for automotive applications. It integrates

MOSFET switches, small-signal circuits,

compensation, and the inductor in an advanced 4mm

x 7mm x 1.85mm 38-pin QFN package.

The EN6347QA is specifically designed to meet the

precise voltage and fast transient requirements of

present and future high-performance, low-power

processor, DSP, FPGA, memory boards and system

level applications in distributed power architectures.

The device’s advanced circuit techniques, high

switching frequency, and proprietary integrated

inductor technology deliver high-quality, ultra

compact, non-isolated DC-DC conversion.

Intel Enpirion Power Solutions significantly help in

system design and productivity by offering greatly

simplified board design, layout and manufacturing

requirements In addition, a reduction in the number

of vendors required for the complete power solution

helps to enable an overall system cost savings.

All Enpirion products are RoHS compliant and lead-

free manufacturing environment compatible.

FEATURES

• Integrated Inductor, MOSFETs, Controller

• -40°C to +105°C Ambient Temperature Range

• AEC-Q100 Qualified for Automotive Applications

• Up to 4A Continuous Operating Current

• High Efficiency (Up to 95%)

• Frequency Synchronization to External Clock

• Input Voltage Range (2.5V to 6.6V)

• Programmable Light Load Mode

• Optimized Total Solution Size (90mm2)

• Output Enable Pin and Power OK

• Programmable Soft-Start

• Thermal Shutdown, Over-Current, Short Circuit,

and Under-Voltage Protection

• RoHS Compliant, MSL Level 3, 260°C Reflow

APPLICATIONS

• Automotive Applications

• Point of Load Regulation for Low-Power, ASICs

Multi-Core and Communication Processors, DSPs,

FPGAs and Distributed Power Architectures

• Beat Frequency/Noise Sensitive Applications

VOUT

VIN

47F

1210

X7R

22F

1206

X7R

VOUT

PG

AGND

SS

PVIN

AVIN

PGND

CA

PGND

RA

RB

VFB

EN6347QA

LLM/

SYNC

CSS

560

Optional

Figure 1: Simplified Applications Circuit

Figure 2: Highest Efficiency in Smallest Solution Size

0

10

20

30

40

50

60

70

80

90

100

0.01 0.1 1 10

EFFICIENCY (%)

OUTPUT CURRENT (A)

Efficiency vs. Output Current

VOUT = 3.3V LLM

VOUT = 3.3V PWM

CONDITIONS

VIN = 5V

DataSheeT – enpirion® power solutions

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 2

ORDERING INFORMATION

Part Number

Package Markings

TJ Rating

Package Description

EN6347QA

N6347A

-40°C to +125°C

38-pin (4mm x 7mm x 1.85mm) QFN T&R

EVB-EN6347QA

N6347A

QFN Evaluation Board

Packing and Marking Information: https://www.altera.com/support/quality-and-reliability/packing.html

PIN FUNCTIONS

Figure 3: Pin Diagram (Top View)

NOTE A: NC pins are not to be electrically connected to each other or to any external signal, ground or voltage. However,

they must be soldered to the PCB. Failure to follow this guideline may result in part malfunction or damage.

NOTE B: Shaded area highlights exposed metal below the package that is not to be mechanically or electrically connected

to the PCB. Refer to Figure 11 for details.

NOTE C: White ‘dot’ on top left is pin 1 indicator on top of the device package.

NC(SW)

NC

VOUT

1

VOUT

2

3

4

5

6

7

KEEP OUT

8

VOUT

NC(SW)

9

10

11

12

13

14

15

16

17

18

19

BGND

VDDB

BTMP

PG

PVIN

25

24

23

22

21

20

38

37

NC(SW)

AVIN

VFB

AGND

RLLM

SS

ENABLE

POK

LLM / SYNC

36

35

34

33

32

31

30

29

28

27

26

NC(SW)

VOUT

PGND

PVIN

NC(SW)

KEEP OUT

39

PGND

NC(SW)

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 3

PIN DESCRIPTIONS

NAME

TYPE

FUNCTION

1,2, 12,

34-38

NC(SW)

-

NO CONNECT – These pins are internally connected to the common

switching node of the internal MOSFETs. They are not to be electrically

connected to any external signal, ground, or voltage. Failure to follow this

guideline may result in damage to the device.

3,4

NC

-

NO CONNECT – These pins may be internally connected. Do not connect

to each other or to any other electrical signal. Failure to follow this

guideline may result in device damage.

5- 11

VOUT

Power

Regulated converter output. Connect to the load and place output filter

capacitor(s) between these pins and PGND pins. Refer to the Layout

Recommendation section.

13-18

PGND

Ground

Input/Output power ground. Connect to the ground electrode of the input

and output filter capacitors. See VOUT and PVIN pin descriptions for more

details.

19-21

PVIN

Power

Input power supply. Connect to input power supply. Decouple with input

capacitor to PGND pin. Refer to the Layout Recommendation section.

22

PG

Analog

PMOS gate. Connect a 560 Ohm resistor from PVIN to PG. An optional

capacitor (22nF) may be placed from PG to BGND to help filter PG in noisy

environments.

23

BTMP

Analog

Bottom plate ground.

24

VDDB

Power

Internal regulated voltage used for the internal control circuitry. An

optional capacitor (220nF) may be placed from VDDB to BGND to help filter

the VDDB output in noisy environments.

25

BGND

Power

Ground for VDDB. Do not connect BGND to any other ground. See pin 24

description.

26

LLM/SYNC

Analog

Dual function pin providing LLM Enable and External Clock

Synchronization (see Application Section). At static Logic HIGH, device will

allow automatic engagement of light load mode. At static logic LOW, the

device is forced into PWM only. A clocked input to this pin will synchronize

the internal switching frequency to the external signal. If this pin is left

floating, it will pull to a static logic high, enabling LLM.

27

ENABLE

Analog

Input Enable. Applying logic high enables the output and initiates a soft-

start. Applying logic low discharges the output through a soft-shutdown.

28

POK

Digital

Power OK is an open drain transistor used for power system state

indication. POK is logic high when VOUT is within ±10% of VOUT nominal and

has an internal 100kΩ pull-up resistance to AVIN.

29

RLLM

Analog

Programmable LLM engage resistor to AGND allows for adjustment of load

current at which Light-Load Mode engages. Can be left open for PWM only

operation.

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 4

NAME

TYPE

FUNCTION

30

SS

Analog

A soft-start capacitor is connected between this pin and AGND. The value

of the capacitor controls the soft-start interval. Refer to Soft-Start

Operation in the Functional Description section for more details.

31

VFB

Analog

External Feedback Input. The feedback loop is closed through this pin. A

voltage divider at VOUT is used to set the output voltage. The midpoint of

the divider is connected to VFB. A phase lead capacitor from this pin to

VOUT is also required to stabilize the loop.

32

AGND

Power

Ground for internal control circuits. Connect to the power ground plane

with a via right next to the pin.

33

AVIN

Power

Input power supply for the controller. Connect to input voltage at a quiet

point. Refer to the Layout Recommendation section.

39

PGND

Ground

Power ground thermal pad. Not a perimeter pin. Connect thermal pad to

the system GND plane for heat-sinking purposes. Refer to the Layout

Recommendation section.

ABSOLUTE MAXIMUM RATINGS

CAUTION: Absolute Maximum ratings are stress ratings only. Functional operation beyond the recommended

operating conditions is not implied. Stress beyond the absolute maximum ratings may impair device

life. Exposure to absolute maximum rated conditions for extended periods may affect device reliability.

Absolute Maximum Pin Ratings

PARAMETER

SYMBOL

MIN

MAX

UNITS

PVIN, AVIN, VOUT

-0.3

7.0

V

ENABLE, POK

-0.3

VIN+0.3

V

VFB, SS

-0.3

2.5

V

Absolute Maximum Thermal Ratings

PARAMETER

CONDITION

MIN

MAX

UNITS

Maximum Operating Junction

Temperature

+150

°C

Storage Temperature Range

-65

+150

°C

Reflow Peak Body Temperature

(10 Sec) MSL3 JEDEC J-STD-020A

+260

°C

Absolute Maximum ESD Ratings

PARAMETER

CONDITION

MIN

MAX

UNITS

HBM (Human Body Model)

±2000

V

CDM (Charged Device Model)

±500

V

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 5

RECOMMENDED OPERATING CONDITIONS

PARAMETER

SYMBOL

MIN

MAX

UNITS

Input Voltage Range

VIN

2.5

6.6

V

Output Voltage Range

VOUT

0.75

VIN – VDO (1)

V

Output Current Range

IOUT

4

A

Operating Ambient Temperature Range

TA

-40

+105

°C

Operating Junction Temperature

TJ

-40

+125

°C

THERMAL CHARACTERISTICS

PARAMETER

SYMBOL

TYPICAL

UNITS

Thermal Shutdown

TSD

160

°C

Thermal Shutdown Hysteresis

TSDHYS

35

°C

Thermal Resistance: Junction to Ambient (0 LFM) (2)

JA

30

°C/W

Thermal Resistance: Junction to Case (0 LFM)

JC

3

°C/W

(1) VDO (dropout voltage) is defined as (ILOAD x Droput Resistance). Please refer to Electrical Characteristics Table.

(2) Based on 2oz. external copper layers and proper thermal design in line with EIJ/JEDEC JESD51-7 standard for high

thermal conductivity boards.

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 6

ELECTRICAL CHARACTERISTICS

NOTE: VIN = 6.6V, Minimum and Maximum values are over operating ambient temperature range unless

otherwise noted. Typical values are at TA = 25°C.

PARAMETER

SYMBOL

TEST CONDITIONS

MIN

TYP

MAX

UNITS

Operating Input

Voltage

VIN

2.5

6.6

V

Under Voltage Lock-

Out – VIN Rising

VUVLOR

Voltage above which UVLO is

not asserted

2.3

V

Under Voltage Lock-

Out – VIN Falling

VUVLOF

Voltage below which UVLO is

asserted

2.075

V

Shut-Down Supply

Current

IS

ENABLE = 0V

100

A

Operating Quiescent

Current

IQ

LLM/SYNC = High

650

mA

Feedback Pin Voltage

EN6347QA (3)

VFB

VIN = 5V, ILOAD = 0, TA =

25°C

0.7425

0.75

0.7575

V

Feedback Pin Voltage

EN6347QA

VFB

3.0V ≤ VIN ≤ 6.0V

0A ≤ ILOAD ≤ 4A

0.735

0.75

0.765

V

Feedback pin Input

Leakage Current (4)

IFB

VFB pin input leakage current

-5

5

nA

VOUT Rise Time Range (4)

tRISE

Measured from when VIN > VUVLOR

& ENABLE pin voltage crosses its

logic high threshold to when

VOUT reaches its final value. CSS =

15 nF

0.9

1.2

1.5

ms

Soft Start Capacitance

Range

CSS_RANGE

10

47

68

nF

Drop-Out Voltage (4)

VDO

VINMIN - VOUT at full load

240

360

mV

Drop-Out Resistance (4)

RDO

Input to output resistance

60

90

m

Continuous Output

Current

IOUT

PMM mode

LLM mode (5)

0

0.002

4

A

Over Current Trip Level

IOCP

VIN = 5V, VOUT = 1.2V

5

A

Precision Disable

Threshold

VDISABLE

ENABLE pin logic going low

0

0.6

V

Precision Enable

Threshold

VEN

ENABLE pin logic going high

2.5V ≤ VIN ≤ 6.6V

1.8

VIN

V

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 7

PARAMETER

SYMBOL

TEST CONDITIONS

MIN

TYP

MAX

UNITS

ENABLE Lockout Time

TENLOCKOUT

3.2

ms

ENABLE Pin Input

Current (4)

IENABLE

ENABLE pin has ~180k pull

down

40

A

Switching Frequency

(Free Running)

FSW

Free running frequency of

oscillator

3

MHz

External SYNC Clock

Frequency Lock Range

FPLL_LOCK

Range of SYNC clock

frequency

2.5

3.5

MHz

SYNC Input Threshold

– Low (LLM/SYNC PIN)

VSYNC_LO

SYNC Clock Logic Level

0.8

V

SYNC Input Threshold –

High (LLM/SYNC PIN) (6)

VSYNC_HI

SYNC Clock Logic Level

1.8

2.5

V

POK Lower Threshold

POKLT

Output voltage as a fraction of

expected output voltage

90

%

POK Low Voltage

VPOKL

With 4mA current sink into

POK

0.4

V

POK High Voltage

VPOKH

2.5V ≤ VIN ≤ 6.6V

VIN

V

POK Pin Leakage

Current (4)

IPOKH

POK is high

1

µA

LLM Engage Headroom

Minimum VIN-VOUT to ensure

proper LLM operation

800

mV

LLM Logic Low

(LLM/SYNC PIN)

VLLM_LO

LLM Static Logic Level

0.3

V

LLM Logic High

(LLM/SYNC PIN)

VLLM_HI

LLM Static Logic Level

1.5

V

LLM/SYNC Pin Current

LLM/SYNC Pin is <2.5V

<100

nA

(3) The VFB pin is a sensitive node. Do not touch VFB while the device is in regulation.

(4) Parameter not production tested but is guaranteed by design.

(5) LLM operation is normally only guaranteed above the minimum specified output current.

(6) For proper operation of the synchronization circuit, the high-level amplitude of the SYNC signal should not be above

2.5V.

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 8

TYPICAL PERFORMANCE CURVES

0

10

20

30

40

50

60

70

80

90

100

0 0.5 1 1.5 2 2.5 3 3.5 4

EFFICIENCY (%)

OUTPUT CURRENT (A)

PWM Efficiency vs. IOUT (VIN = 3.3V)

VOUT = 2.5V

VOUT = 1.8V

VOUT = 1.5V

VOUT = 1.2V

VOUT = 1.0V

CONDITIONS

VIN = 3.3V

CONDITIONS

VIN = 3.3V

0

10

20

30

40

50

60

70

80

90

100

0 0.5 1 1.5 2 2.5 3 3.5 4

EFFICIENCY (%)

OUTPUT CURRENT (A)

PWM Efficiency vs. IOUT (VIN = 5.0V)

VOUT = 3.3V

VOUT = 2.5V

VOUT = 1.8V

VOUT = 1.5V

VOUT = 1.2V

VOUT = 1.0V

CONDITIONS

VIN = 5V

0

10

20

30

40

50

60

70

80

90

100

0.01 0.1 1 10

EFFICIENCY (%)

OUTPUT CURRENT (A)

LLM Efficiency vs. IOUT (VIN = 3.3V)

VOUT = 2.5V

VOUT = 1.8V

VOUT = 1.5V

VOUT = 1.2V

VOUT = 1.0V

CONDITIONS

VIN = 3.3V

0

10

20

30

40

50

60

70

80

90

100

0.01 0.1 1 10

EFFICIENCY (%)

OUTPUT CURRENT (A)

LLM Efficiency vs. IOUT (VIN = 5.0V)

VOUT = 3.3V

VOUT = 2.5V

VOUT = 1.8V

VOUT = 1.5V

VOUT = 1.2V

VOUT = 1.0V

CONDITIONS

VIN = 5V

0.980

0.985

0.990

0.995

1.000

1.005

1.010

1.015

1.020

0 0.5 1 1.5 2 2.5 3 3.5 4

OUTPUT VOLTAGE (V)

OUTPUT CURRENT (A)

Output Voltage vs. Output Current

VIN = 3.3V

VIN = 5.0V

CONDITIONS

VOUT = 1.0V

1.180

1.185

1.190

1.195

1.200

1.205

1.210

1.215

1.220

0 0.5 1 1.5 2 2.5 3 3.5 4

OUTPUT VOLTAGE (V)

OUTPUT CURRENT (A)

Output Voltage vs. Output Current

VIN = 3.3V

VIN = 5.0V

CONDITIONS

VOUT = 1.2V

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 9

TYPICAL PERFORMANCE CURVES (CONTINUED)

1.480

1.485

1.490

1.495

1.500

1.505

1.510

1.515

1.520

0 0.5 1 1.5 2 2.5 3 3.5 4

OUTPUT VOLTAGE (V)

OUTPUT CURRENT (A)

Output Voltage vs. Output Current

VIN = 3.3V

VIN = 5.0V

CONDITIONS

VOUT = 1.5V

1.780

1.785

1.790

1.795

1.800

1.805

1.810

1.815

1.820

0 0.5 1 1.5 2 2.5 3 3.5 4

OUTPUT VOLTAGE (V)

OUTPUT CURRENT (A)

Output Voltage vs. Output Current

VIN = 3.3V

VIN = 5.0V

CONDITIONS

VOUT = 1.8V

2.480

2.485

2.490

2.495

2.500

2.505

2.510

2.515

2.520

0 0.5 1 1.5 2 2.5 3 3.5 4

OUTPUT VOLTAGE (V)

OUTPUT CURRENT (A)

Output Voltage vs. Output Current

VIN = 3.3V

VIN = 5.0V

CONDITIONS

VOUT = 2.5V

3.280

3.285

3.290

3.295

3.300

3.305

3.310

3.315

3.320

0 0.5 1 1.5 2 2.5 3 3.5 4

OUTPUT VOLTAGE (V)

OUTPUT CURRENT (A)

Output Voltage vs. Output Current

VIN = 5.0V

CONDITIONS

VOUT = 3.3V

1.780

1.785

1.790

1.795

1.800

1.805

1.810

1.815

1.820

2.5 3 3.5 4 4.5 5 5.5 6

OUTPUT VOLTAGE (V)

INPUT VOLTAGE (V)

Output Voltage vs. Input Voltage

CONDITIONS

VOUT_NOM = 1.8V

Load = 0A

1.780

1.785

1.790

1.795

1.800

1.805

1.810

1.815

1.820

2.5 3 3.5 4 4.5 5 5.5 6

OUTPUT VOLTAGE (V)

INPUT VOLTAGE (V)

Output Voltage vs. Input Voltage

CONDITIONS

VOUT_NOM = 1.8V

Load = 1A

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 10

TYPICAL PERFORMANCE CURVES (CONTINUED)

1.780

1.785

1.790

1.795

1.800

1.805

1.810

1.815

1.820

2.5 3 3.5 4 4.5 5 5.5 6

OUTPUT VOLTAGE (V)

INPUT VOLTAGE (V)

Output Voltage vs. Input Voltage

CONDITIONS

VOUT_NOM = 1.8V

Load = 2A

1.780

1.785

1.790

1.795

1.800

1.805

1.810

1.815

1.820

2.5 3 3.5 4 4.5 5 5.5 6

OUTPUT VOLTAGE (V)

INPUT VOLTAGE (V)

Output Voltage vs. Input Voltage

CONDITIONS

Load = A

CONDITIONS

VOUT_NOM = 1.8V

Load = 3A

1.780

1.785

1.790

1.795

1.800

1.805

1.810

1.815

1.820

2.5 3 3.5 4 4.5 5 5.5 6

OUTPUT VOLTAGE (V)

INPUT VOLTAGE (V)

Output Voltage vs. Input Voltage

CONDITIONS

Load = A

CONDITIONS

VOUT_NOM = 1.8V

Load = 4A

1.780

1.790

1.800

1.810

1.820

1.830

-40 -20 0 20 40 60 80 100 120

OUTPUT VOLTAGE (V)

AMBIENT TEMPERATURE (°C)

Output Voltage vs. Temperature

LOAD = 4A

LOAD = 3A

LOAD = 2A

LOAD = 1A

LOAD = 0A

CONDITIONS

VIN = 3.3V

VOUT_NOM = 1.8V

1.780

1.790

1.800

1.810

1.820

1.830

-40 -20 0 20 40 60 80 100 120

OUTPUT VOLTAGE (V)

AMBIENT TEMPERATURE (°C)

Output Voltage vs. Temperature

LOAD = 4A

LOAD = 3A

LOAD = 2A

LOAD = 1A

LOAD = 0A

CONDITIONS

VIN = 5.0V

VOUT_NOM = 1.8V

1.780

1.790

1.800

1.810

1.820

1.830

-40 -20 0 20 40 60 80 100 120

OUTPUT VOLTAGE (V)

AMBIENT TEMPERATURE (°C)

Output Voltage vs. Temperature

LOAD = 4A

LOAD = 3A

LOAD = 2A

LOAD = 1A

LOAD = 0A

CONDITIONS

VIN = 6.0V

VOUT_NOM = 1.8V

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 11

TYPICAL PERFORMANCE CHARACTERISTICS

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

55 60 65 70 75 80 85 90 95 100 105

MAXIMUM OUTPUT CURRENT (A)

AMBIENT TEMPERATURE (°C)

Output Current De-rating

VOUT = 1.8V

VOUT = 2.5V

VOUT = 3.3V

CONDITIONS

VIN = 5.0V

TJMAX = 125°C

θJA = 30°C/W

No Air Flow

10.0

20.0

30.0

40.0

50.0

60.0

70.0

80.0

90.0

100.0

30 300

LEVEL (dBµV/m)

FREQUENCY (MHz)

EMI Performance (Horizontal Scan)

CONDITIONS

VIN = 5.0V

VOUT_NOM = 1.5V

LOAD = 0.5Ω

CISPR 22 Class B 3m

10.0

20.0

30.0

40.0

50.0

60.0

70.0

80.0

90.0

100.0

30 300

LEVEL (dBµV/m)

FREQUENCY (MHz)

EMI Performance (Vertical Scan)

CONDITIONS

VIN = 5.0V

VOUT_NOM = 1.5V

LOAD = 0.5Ω

CISPR 22 Class B 3m

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 12

TYPICAL PERFORMANCE CHARACTERISTICS (CONTINUED)

VOUT

(AC Coupled)

Output Ripple at 20MHz Bandwidth

CONDITIONS

VIN = 3.3V

VOUT = 1V

IOUT = 4A

CIN = 22µF (1206)

COUT = 47 µF (1210) + 10µF (1206)

VOUT

(AC Coupled)

Output Ripple at 500MHz Bandwidth

CONDITIONS

VIN = 3.3V

VOUT = 1V

IOUT = 4A

CIN = 22µF (1206)

COUT = 47 µF (1210) + 10µF (1206)

VOUT

(AC Coupled)

Output Ripple at 20MHz Bandwidth

CONDITIONS

VIN = 5V

VOUT = 1V

IOUT = 4A

CIN = 22µF (1206)

COUT = 47 µF (1210) + 10µF (1206)

VOUT

(AC Coupled)

Output Ripple at 500MHz Bandwidth

CONDITIONS

VIN = 5.0V

VOUT = 1V

IOUT = 4A

CIN = 22µF (1206)

COUT = 47 µF (1210) + 10µF (1206)

VOUT

(AC Coupled)

LLM Output Ripple at 100mA

CONDITIONS

VIN = 5V

VOUT = 1V

IOUT = 100mA

CIN = 22µF (1206)

COUT = 2 x 47 µF (1210)

VOUT

(AC Coupled)

LLM Output Ripple at 100mA

CONDITIONS

VIN = 5V

VOUT = 3V

IOUT = 100mA

CIN = 22µF (1206)

COUT = 2 x 47 µF (1210)

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 13

TYPICAL PERFORMANCE CHARACTERISTICS (CONTINUED)

ENABLE

Enable Power Up/Down

CONDITIONS

VIN = 5.5V, VOUT = 3.3V

NO LOAD, Css = 47nF

CIN = 22µF (1206)

COUT = 47 µF (1210)

VOUT

POK

LOAD

ENABLE

Enable Power Up/Down

CONDITIONS

VIN = 5.0V, VOUT = 3.3V, LOAD=0.825Ω, Css = 47nF

CIN = 22µF (1206), COUT = 47 µF (1210)

VOUT

POK

LOAD

VOUT

(AC Coupled)

LLM Load Transient from 0.01 to 4A

CONDITIONS

LLM = ENABLED

VIN = 5V

VOUT = 1V

CIN = 22µF (1206)

COUT = 2 x 47µF (1210)

LOAD

VOUT

(AC Coupled)

LLM Load Transient from 0.01 to 4A

CONDITIONS

LLM = ENABLED

VIN = 5V

VOUT = 3V

CIN = 22µF (1206)

COUT = 2 x 47µF (1210)

LOAD

VOUT

(AC Coupled)

PWM Load Transient from 0 to 4A

CONDITIONS

LLM = DISABLED

VIN = 5V

VOUT = 1V

CIN = 22µF (1206)

COUT = 47µF (1210) + 10µF (1206)

LOAD

VOUT

(AC Coupled)

PWM Load Transient from 0 to 4A

CONDITIONS

LLM = DISABLED

VIN = 5V

VOUT = 3V

CIN = 22µF (1206)

COUT = 47µF (1210) + 10µF (1206)

LOAD

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

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FUNCTIONAL BLOCK DIAGRAM

Soft Start

Power

Good

Logic

Regulated

Voltage

Reference

Compensation

Network

Thermal Limit

UVLO

Current Limit

Mode

Logic

P-Drive

N-Drive

PLL/Sawtooth

Generator

LLM/SYNC

ENABLE

SS

AGND

POK

AVIN

VFB

PGND

VOUT

NC(SW)

PVINRLLM

Error

Amp

PWM

Comp

(+)

(-)

(+)

PG

BGND

BTMP

VDDB

Figure 4: Functional Block Diagram

FUNCTIONAL DESCRIPTION

Synchronous DC-DC Step-Down PowerSoC

The EN6347QA is a synchronous, programmable power supply with integrated power MOSFET switches and

integrated inductor. The nominal input voltage range is 2.5V to 6.6V. The output voltage is programmed using

an external resistor divider network. The control loop is voltage-mode with a type III compensation network.

Much of the compensation circuitry is internal to the device. However, a phase lead capacitor is required along

with the output voltage feedback resistor divider to complete the type III compensation network. The device

uses a low-noise PWM topology and also integrates a unique light-load mode (LLM) to improve efficiency at

light output load currents. LLM can be disabled with a logic pin. Up to 4A of continuous output current can be

drawn from this converter. The 3MHz switching frequency allows the use of small size input / output

capacitors, and enables wide loop bandwidth within a small foot print.

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Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

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Protection Features:

The power supply has the following protection features:

• Over-current protection (to protect the IC from excessive load current)

• Thermal shutdown with hysteresis.

• Under-voltage lockout circuit to keep the converter output off while the input voltage is less than 2.3V.

Additional Features:

• The switching frequency can be phase-locked to an external clock to eliminate or move beat frequency

tones out of band.

• Soft-start circuit allowing controlled startup when the converter is initially powered up. The soft start time

is programmable with an appropriate choice of soft start capacitor.

• Power good circuit indicating the output voltage is greater than 90% of programmed value as long as

feedback loop is closed.

• To maintain high efficiency at low output current, the device incorporates automatic light load mode

operation.

Precision Enable Operation

The ENABLE pin provides a means to enable normal operation or to shut down the device. When the ENABLE

pin is asserted (high) the device will undergo a normal soft-start. A logic low on this pin will power the device

down in a controlled manner. From the moment ENABLE goes low, there is a fixed lock out time before the

output will respond to the ENABLE pin re-asserted (high). This lock out is activated for even very short logic

low pulses on the ENABLE pin. The ENABLE signal must be pulled high at a slew rate faster than 1V/5µs in

order to meet startup time specifications; otherwise, the device may experience a delay of 4.2ms (lock-out

time) before startup occurs. See the Electrical Characteristics Table for technical specifications for the ENABLE

pin.

LLM/SYNC Pin

This is a dual function pin providing LLM Enable and External Clock Synchronization. At static Logic HIGH,

device will allow automatic engagement of light load mode. At static logic LOW, the device is forced into PWM

only. A clocked input to this pin will synchronize the internal switching frequency – LLM mode is not available

if this input is clocked. If this pin is left floating, it will pull to a static logic high, enabling LLM.

Frequency Synchronization

The switching frequency of the DC-DC converter can be phase-locked to an external clock source to move

unwanted beat frequencies out of band. To avail this feature, the clock source should be connected to the

LLM/SYNC pin. An activity detector recognizes the presence of an external clock signal and automatically

phase-locks the internal oscillator to this external clock. Phase-lock will occur as long as the clock frequency

is in the range specified in the Electrical Characteristics Table. For proper operation of the synchronization

circuit, the high-level amplitude of the SYNC signal should not be above 2.5V. Please note LLM is not available

when synchronizing to an external frequency.

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Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

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Spread Spectrum Mode

The external clock frequency may be swept between the limits specified in the Electrical Characteristics Table

at repetition rates of up to 10kHz in order to reduce EMI frequency components.

Soft-Start Operation

During Soft-start, the output voltage is ramped up gradually upon start-up. The output rise time is controlled

by the choice of soft-start capacitor, which is placed between the SS pin (30) and the AGND pin (32).

Rise Time: TR  (CSS* 80k) ± 25%

During start-up of the converter, the reference voltage to the error amplifier is linearly increased to its final

level by an internal current source of approximately 10μA. Typical soft-start rise time is ~3.8ms with SS

capacitor value of 47nF. The rise time is measured from when VIN > VUVLOR and ENABLE pin voltage crosses its

logic high threshold to when VOUT reaches its programmed value. Please note LLM function is disabled during

the soft-start ramp-up time.

POK Operation

The POK signal is an open drain signal (requires a pull up resistor to VIN or similar voltage) from the converter

indicating the output voltage is within the specified range. The POK signal will be logic high (VIN) when the

output voltage is above 90% of programmed VOUT. If the output voltage goes below this threshold, the POK

signal will be logic low.

Light Load Mode (LLM) Operation

The EN6347QA uses a proprietary light load mode to provide high efficiency at low output currents. When

the LLM/SYNC pin is high, the device is in automatic LLM “Detection” mode. When the LLM/SYNC pin is low,

the device is forced into PWM mode. In automatic LLM “Detection” mode (LLM connected to AVIN with 50kΩ),

when a light load condition is detected, the device will:

(1) Step VOUT up by approximately 1.0% above the nominal operating output voltage setting, VNOM and as low

as -0.5% below VNOM, and then

(2) Shut down unnecessary circuitry, and then

(3) Monitor VOUT.

When VOUT falls below VNOM, the device will repeat (1), (2), and (3). The voltage step up, or pre-positioning,

improves transient droop when a load transient causes a transition from LLM mode to PWM mode. If a load

transient occurs, causing VOUT to fall below the threshold VMIN, the device will exit LLM operation and begin

normal PWM operation. Figure 5 demonstrates VOUT behavior during transition into and out of LLM operation.

Many multi-mode DC-DC converters suffer from a condition that occurs when the load current increases only

slowly so that there is no load transient driving VOUT below the VMIN threshold. In this condition, the device

would never exit LLM operation. This could adversely affect efficiency and cause unwanted ripple. To prevent

this from occurring, the EN6347QA periodically exits LLM mode into PWM mode and measures the load

current. If the load current is above the LLM threshold current, the device will remain in PWM mode. If the

load current is below the LLM threshold, the device will re-enter LLM operation. There may be a small

overshoot or undershoot in VOUT when the device exits and re-enters LLM.

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Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

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Figure 5. VOUT behavior in LLM operation

The load current at which the device will enter LLM mode is a function of input and output voltage, inductance

variation and the RLLM pin resistor. The lower the RLLM resistor value, the lower the current when the device

transitions from LLM into PWM mode. A 60kΩ resistor from RLLM to ground is recommended for most

applications. For PWM only operation, the RLLM pin can be left open.

Figure 6. Typical LLM to PWM Current vs. RLLM

To ensure normal LLM operation, LLM mode should be enabled and disabled with specific sequencing. For

applications with explicit LLM pin control, enable LLM after VIN ramp up is complete. For applications with only

ENABLE controlled, tie LLM to ENABLE. Enable the device after VIN ramps up into regulation and disable the

device before VIN ramps. For designs with ENABLE and LLM tied to VIN, make sure the device soft-start time is

longer than the VIN ramp-up time. LLM will start operating after the soft-start time is completed.

NOTE: For proper LLM operation the EN6347QA requires a minimum difference between VIN and VOUT, and a

minimum LLM load requirement as specified in the Electrical Characteristics Table.

OUT

MAX

NOM

MIN

0.000

0.200

0.400

0.600

0.800

1.000

1.200

1.400

1.600

1.800

2.000

010 20 30 40 50 60 70 80 90 100

LLM TO PWM CURRENT (A)

RLLM RESISTOR (k)

LLM to PWM Current vs. RLLM

VIN = 5V, VOUT = 3.3V

VIN = 3.3V, VOUT = 2.5V

VIN = 5V, VOUT = 1V

VIN = 3.3V, VOUT = 1V

CONDITIONS

TA= 25C

Typical Values

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 18

Over-Current Protection (OCP)

The current limit function is achieved by sensing the current flowing through the Power PFET. When the

sensed current exceeds the over current trip point, both power FETs are turned off for the remainder of the

switching cycle. If the over-current condition is removed, the over-current protection circuit will enable normal

PWM operation. If the over-current condition persists, the soft start capacitor will gradually discharge causing

the output voltage to fall. When the OCP fault is removed, the output voltage will ramp back up to the desired

voltage. This circuit is designed to provide high noise immunity.

Thermal Protection

Thermal shutdown circuit will disable device operation when the Junction temperature exceeds approximately

150°C. After a thermal shutdown event, when the junction temperature drops by approximately 20°C, the

converter will re-start with a normal soft-start.

Input Under-Voltage Lock-Out (UVLO)

Internal circuits ensure that the converter will not start switching until the input voltage is above the specified

minimum voltage. Hysteresis and input de-glitch circuits ensure high noise immunity and prevent false UVLO

triggers.

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

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APPLICATION INFORMATION

Output Voltage Setting

The EN6347QA uses a Type III voltage mode control compensation network. As noted earlier, a piece of the

compensation network is the phase lead capacitor CA in Figure 7. This network is optimized for use with about

50-100μF of output capacitance and will provide wide loop bandwidth and excellent transient performance

for most applications. Voltage mode operation provides high noise immunity at light load.

In some applications, modifications to the compensation may be required. For more information, contact

Power Applications support.

VOUT

PGND

VFB

RACA

COUT

VFB = 0.75V

EN6347QA

RB

RA

VFB

VOUT

x

-

=

AGND

(47µF to 1000µF)

(10pF to 47pF)

200k

Figure 7. VOUT Resistor Divider & Compensation Capacitor

The EN6347QA output voltage is programmed using a simple resistor divider network. Since VFB is a sensitive

node, do not touch the VFB node while the device is in operation as doing so may introduce parasitic

capacitance into the control loop that causes the device to behave abnormally and damage may occur. Figure

7 shows the resistor divider configuration.

An additional compensation capacitor CA is also required in parallel with the upper resistor.

Input Capacitor Selection

The EN6347QA requires at least a 22µF 1206 case size X7R ceramic input capacitor. Additional input

capacitors may be used in parallel to reduce input voltage spikes caused by parasitic line inductance. For

applications where the input of the EN6347QA is far from the input power source, be sure to use sufficient

bulk capacitors to mitigate the extra line inductance. Low-cost, low-ESR ceramic capacitors should be used as

input capacitors for this converter. The dielectric must be X7R rated. Y5V or equivalent dielectric formulations

must not be used as these lose too much capacitance with frequency, temperature and bias voltage. In some

applications, lower value capacitors are needed in parallel with the larger, capacitors in order to provide high

frequency decoupling.

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

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Table 1: Recommended Input Capacitors

Description

MFG

P/N

22µF, 10V, X7R, 1206

Murata

GRM31CR71A226ME15

Taiyo Yuden

LMK316AB7226KL-TR

AVX

1206ZC226KAT2A

Output Capacitor Selection

The EN6347QA requires at least one 47µF 1210 case size X7R or two 22µF 1206 case size X7R ceramic output

capacitor. Additional output capacitors may be used in parallel near the load (>4mΩ away) to improve transient

response as well as lower output ripple. In some cases modifications to the compensation or output filter

capacitance may be required to optimize device performance such as transient response, ripple, or hold-up

time. The EN6347QA provides the capability to modify the control loop response to allow for customization

for such applications. Note that in Type III Voltage Mode Control, the double pole of the output filter is

around 1/2π√LO∙ Cout, where Cout is the equivalent capacitance of all the output capacitors including the

minimum required output capacitors that Altera recommended and the extra bulk capacitors customers added

based on their design requirement. While the compensation network was designed based on the capacitors

that Altera recommended, increasing the output capacitance will shift the double pole to the direction of lower

frequency, which will lower the loop bandwidth and phase margin. In most cases, this will not cause the

instability due to adequate phase margin already in the design. In order to maintain a higher bandwidth as well

as adequate phase margin, a slight modification of the external compensation is necessary. This can be easily

implemented by increasing the leading capacitor value, CA. In addition the ESR of the output capacitors also

helps since the ESR and output capacitance forms a zero which also helps to boost the phase

Table 2: CA for Output Capacitors Ranges

Total COUT Range

Recommended CA

Minimum ESR

2x22µF

10pF

0

100µF to 250µF

27pF

0

250µF to 450µF

33pF

0

450µF to 1000µF

47pF

>4mΩ

Low ESR ceramic capacitors are required with X7R rated dielectric formulation. Y5V or equivalent dielectric

formulations must not be used as these lose too much capacitance with frequency, temperature and bias

voltage. Output ripple voltage is determined by the aggregate output capacitor impedance. Output

impedance, denoted as Z, is comprised of effective series resistance, ESR, and effective series inductance, ESL:

Z = ESR + ESL

Placing output capacitors in parallel reduces the impedance and will hence result in lower PWM ripple voltage.

In addition, higher output capacitance will improve overall regulation and ripple in light-load mode.

nTotal ZZZZ 1

...

111

21



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Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 21

Table 3: Recommended Output Capacitors

Description

MFG

P/N

47µF, 6.3V,

X7R, 1210

Murata

GRM32ER70J476ME20

Taiyo Yuden

LMK325B7476KM-TR

22µF, 10V,

X7R, 1206

Murata

GRM31CR71A226ME15

Taiyo Yuden

LMK316AB7226KL-TR

AVX

1206ZC226KAT2A

10µF, 10V,

X7R, 0805

Murata

GRM21BR71A106KE51

Taiyo Yuden

LMK212AB7106MG-T

AVX

0805ZC106KAT2A

Table 4: Typical PWM Ripple Voltages

Output Capacitor

Configuration

Typical Output Ripple (mVp-p) (as

measured on EN6347QA Evaluation Board)*

1 x 47 µF

25

47 µF + 10 µF

14

* Note: 20 MHz BW limit

For best LLM performance, we recommend using just 2x47µF capacitors mentioned in the above table, and no

10µF capacitor.

The VOUT sense point should be just after the last output filter capacitor right next to the device. Additional

bulk output capacitance beyond the above recommendations can be used on the output node of the

EN6347QA as long as the bulk capacitors are far enough from the VOUT sense point such that they don’t

interfere with the control loop operation.

Power-Up Sequencing

During power-up, ENABLE should not be asserted before PVIN, and PVIN should not be asserted before AVIN.

Tying all three pins together meets these requirements.

Pre-Bias Start-up

The EN6347QA supports startup into a pre-biased output of up to 1.5V. The output of the EN6347QA can be

pre-biased with a voltage up to 1.5V when it is first enabled

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Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 22

THERMAL CONSIDERATIONS

Thermal considerations are important power supply design facts that cannot be avoided in the real world.

Whenever there are power losses in a system, the heat that is generated by the power dissipation needs to be

accounted for. The Enpirion PowerSoC helps alleviate some of those concerns.

The Enpirion EN6347QA DC-DC converter is packaged in a 4x7x1.85mm 38-pin QFN package. The QFN

package is constructed with copper lead frames that have exposed thermal pads. The exposed thermal pad

on the package should be soldered directly on to a copper ground pad on the printed circuit board (PCB) to

act as a heat sink. The recommended maximum junction temperature for continuous operation is 125°C.

Continuous operation above 125°C may reduce long-term reliability. The device has a thermal overload

protection circuit designed to turn off the device at an approximate junction temperature value of 160°C.

The following example and calculations illustrate the thermal performance of the EN6347QA.

Example:

VIN = 5V

VOUT = 3.3V

IOUT = 4A

First calculate the output power.

POUT = 3.3V x 4A = 13.2W

Next, determine the input power based on the efficiency (η) shown in Figure 8.

Figure 8: Efficiency vs. Output Current

0

10

20

30

40

50

60

70

80

90

100

0 0.5 1 1.5 2 2.5 3 3.5 4

EFFICIENCY (%)

OUTPUT CURRENT (A)

PWM Efficiency vs. IOUT (VIN = 5.0V)

VOUT = 3.3V

CONDITIONS

VIN = 5V

~92%

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Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

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For VIN = 5V, VOUT = 3.3V at 4A, η ≈ 92%

η = POUT / PIN = 92% = 0.92

PIN = POUT / η

PIN ≈ 13.2W / 0.92 ≈ 14.35W

The power dissipation (PD) is the power loss in the system and can be calculated by subtracting the output

power from the input power.

PD = PIN – POUT

≈ 14.35W – 13.2W ≈ 1.148W

With the power dissipation known, the temperature rise in the device may be estimated based on the theta JA

value (θJA). The θJA parameter estimates how much the temperature will rise in the device for every watt of

power dissipation. The EN6347QA has a θJA value of 30 °C /W without airflow.

Determine the change in temperature (ΔT) based on PD and θJA.

ΔT = PD x θJA

ΔT ≈ 1.148W x 30°C/W = 34.43°C ≈ 35°C

The junction temperature (TJ) of the device is approximately the ambient temperature (TA) plus the change in

temperature. We assume the initial ambient temperature to be 25°C.

TJ = TA + ΔT

TJ ≈ 25°C + 35°C ≈ 60°C

The maximum operating junction temperature (TJMAX) of the device is 125°C, so the device can operate at a

higher ambient temperature. The maximum ambient temperature (TAMAX) allowed can be calculated.

TAMAX = TJMAX – PD x θJA

≈ 125°C – 35°C ≈ 90°C

The maximum ambient temperature (before de-rating) the device can reach is 90°C given the input and output

conditions. Note that the efficiency will be slightly lower at higher temperatures and this calculation is an

estimate.

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 24

APPLICATION CIRCUITS

Figure 9: Engineering Schematic with Engineering Notes

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 25

LAYOUT RECOMMENDATIONS

Figure 10 shows critical components and layer 1 traces of a typical EN6347QA layout with ENABLE tied to VIN

in PWM mode. Alternate ENABLE configurations and other small signal pins need to be connected and routed

according to specific customer application. Please see the Gerber files on the Altera website

www.altera.com/powersoc for exact dimensions and other layers. Please refer to this Figure while reading the

layout recommendations in this section.

Figure 10: Top PCB Layer Critical Components and Copper for Minimum Footprint (Top View)

Recommendation 1: Input and output filter capacitors should be placed on the same side of the PCB, and as

close to the EN6347QA package as possible. They should be connected to the device with very short and wide

traces. Do not use thermal reliefs or spokes when connecting the capacitor pads to the respective nodes. The

+V and GND traces between the capacitors and the EN6347QA should be as close to each other as possible

so that the gap between the two nodes is minimized, even under the capacitors.

Recommendation 2: Three PGND pins are dedicated to the input circuit, and three to the output circuit. The

slit in Figure 10 separating the input and output GND circuits helps minimize noise coupling between the

converter input and output switching loops.

Recommendation 3: The system ground plane should be the first layer immediately below the surface layer.

This ground plane should be continuous and un-interrupted below the converter and the input/output

capacitors. Please see the Gerber files on the Altera website www.altera.com/powersoc.

Recommendation 4: The large thermal pad underneath the component must be connected to the system

ground plane through as many vias as possible. The drill diameter of the vias should be 0.33mm, and the vias

must have at least 1 oz. copper plating on the inside wall, making the finished hole size around 0.20-0.26mm.

Do not use thermal reliefs or spokes to connect the vias to the ground plane. This connection provides the

path for heat dissipation from the converter.

Recommendation 5: Multiple small vias (the same size as the thermal vias discussed in recommendation 4

should be used to connect ground terminal of the input capacitor and output capacitors to the system ground

plane. It is preferred to put these vias under the capacitors along the edge of the GND copper closest to the

+V copper. Please see Figure 10. These vias connect the input/output filter capacitors to the GND plane, and

help reduce parasitic inductances in the input and output current loops. If the vias cannot be placed under CIN

and COUT, then put them just outside the capacitors along the GND slit separating the two components. Do not

use thermal reliefs or spokes to connect these vias to the ground plane.

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

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Recommendation 6: AVIN is the power supply for the internal small-signal control circuits. It should be

connected to the input voltage at a quiet point. In Figure 10 this connection is made at the input capacitor

close to the VIN connection.

Recommendation 7: The layer 1 metal under the device must not be more than shown in Figure 10. See the

section regarding exposed metal on bottom of package. As with any switch-mode DC-DC converter, try not to

run sensitive signal or control lines underneath the converter package on other layers.

Recommendation 8: The VOUT sense point should be just after the last output filter capacitor. Keep the sense

trace as short as possible in order to avoid noise coupling into the control loop.

Recommendation 9: Keep RA, CA, and RB close to the VFB pin (see Figures 7). The VFB pin is a high-impedance,

sensitive node. Keep the trace to this pin as short as possible. Whenever possible, connect RB directly to the

AGND pin instead of going through the GND plane.

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Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 27

DESIGN CONSIDERATIONS FOR LEAD-FRAME BASED MODULES

Exposed Metal on Bottom of Package

Lead-frames offer many advantages in thermal performance, in reduced electrical lead resistance, and in

overall foot print. However, they do require some special considerations.

In the assembly process lead frame construction requires that, for mechanical support, some of the lead-frame

cantilevers be exposed at the point where wire-bond or internal passives are attached. This results in several

small pads being exposed on the bottom of the package, as shown in Figure 11.

Only the thermal pad and the perimeter pads are to be mechanically or electrically connected to the PC board.

The PCB top layer under the EN6347QA should be clear of any metal (copper pours, traces, or vias) except for

the thermal pad. The “shaded-out” area in Figure 10 represents the area that should be clear of any metal on

the top layer of the PCB. Any layer 1 metal under the shaded-out area runs the risk of undesirable shorted

connections even if it is covered by soldermask.

The solder stencil aperture should be smaller than the PCB ground pad. This will prevent excess solder from

causing bridging between adjacent pins or other exposed metal under the package.

Figure 11: Lead-Frame exposed metal (Bottom View)

Shaded area highlights exposed metal that is not to be mechanically or electrically connected to the PCB.

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 28

Figure 12: EN6347QA PCB Footprint (Top View)

The solder stencil aperture for the thermal pad is shown in blue and is based on Enpirion power product manufacturing

specifications.

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

Page 29

PACKAGE DIMENSIONS

Figure 13: EN6347QA Package Dimensions

Packing and Marking Information: https://www.altera.com/support/quality-and-reliability/packing.html

10318 September 4, 2018 Rev I

Datasheet | Intel® Enpirion® Power Solutions: EN6347QA

WHERE TO GET MORE INFORMATION

For more information about Intel® and Enpirion® PowerSoCs, visit:

www.altera.com/enpirion

Corporation or its subsidiaries in the U.S. and/or other countries. Other marks and brands may be claimed as the property of others. Intel reserves the right to make changes to any products and

services at any time without notice. Intel assumes no responsibility or liability arising out of the application or use of any information, product, or service described herein except as expressly agreed to

in writing by Intel. Intel customers are advised to obtain the latest version of device specifications before relying on any published information and before placing orders for products or services.

* Other marks and brands may be claimed as the property of others.

Page 30

REVISION HISTORY

Rev

Date

Change(s)

I

August 2018

Changed datasheet into Intel format.

10318 September 4, 2018 Rev I