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LT4276

LTPoE++/PoE+/PoE

PD Forward/Flyback Controller

FeaTures

DescripTion

The

4276

is a pin-for-pin compatible family of IEEE

802.3 and LTPoE++ Powered Device (PD) controllers. It

includes an isolated switching regulator controller capable

of synchronous operation in both forward and flyback

topologies with auxiliary power support.

The LT4276A employs the LTPoE++ classification scheme,

receiving 38.7W, 52.7W, 70W or 90W of power at the PD

RJ45 connector, and is backwards compatible with IEEE

802.3. The LT4276B is a fully 802.3at compliant, 25.5W

Type 2 (PoE+) PD. The LT4276C is a fully 802.3af compli-

ant, 13W Type 1 (PoE) PD.

The LT4276 supports both forward and flyback power

supply topologies, configurable for a wide range of PoE

applications. The flyback topology supports No-Opto

feedback. Auxiliary input voltage can be accurately sensed

with just a resistor divider connected to the AUX pin.

The LT4276 utilizes an external, low R

DS(ON)

N-channel

MOSFET for the Hot Swap function, maximizing power

delivery and efficiency, reducing heat dissipation, and

easing the thermal design.

LT, LTC, LTM, LTPoE++, Linear Technology and the Linear logo are registered trademarks of

Linear Technology Corporation. All other trademarks are the property of their respective owners.

IEEE802.3af/at and LTPoE++

™

90W Powered Device

(PD) with Forward/Flyback Controller

LT4276A Supports All of the Following Standards:

LTPoE++ 38.7W, 52.7W, 70W and 90W

IEEE 802.3at 25.5W Compliant

IEEE 802.3af up to 13W Compliant

LT4276B is IEEE 802.3at/af Compliant

LT4276C is IEEE 802.3af Compliant

Superior Surge Protection (100V Absolute Maximum)

Wide Junction Temperature Range (–40°C to 125°C)

Auxiliary Power Support as Low as 9V

No Opto-Isolator Required for Flyback Operation

External Hot Swap

™

N-Channel MOSFET for Lowest

Power Dissipation and Highest System Efficiency

>94% End-to-End Efficiency with LT4321 Ideal Bridge

Available in a 28-Lead 4mm

5mm QFN Package

applicaTions

High Power Wireless Data Systems

Outdoor Security Camera Equipment

Commercial and Public Information Displays

High Temperature Applications

Typical applicaTion

AUX

37V-57V

–

FMMT723

0.1µF

3.3k

10nF

VPORT HS

GATE

AUX

HS SW

SRC VCC

100µH

BAV19WS

≤50ns)

10µF

FFS PG

DLY

ISEN+

20m

ISEN–

T2P

ITHB

4276 TA01

LTPoE++ 70W Power Supply in a Forward Mode

•

13A

–

LT4276 Family

PORT

22µF

MAX DELIVERED

POWER

LTPoE++ 90W

LTPoE++ 70W

LTPoE++ 52.7W

LTPoE++ 38.7W

25.5W

13W

LT4276

GRADE

LT4276A

CLASS

CLASS++

GND FB31 SS ROSC

0.1µF

10k

100pF

OPTO

100k

TO MICROPROCESSOR

4276fa

For more information

www.linear.com/LT4276

LT4276

absoluTe MaxiMuM raTings

(Notes 1, 2)

pin conFiguraTion

TOP VIEW

HSGATE

SWVCC

22 DNC

21 V

20 PG

GND

19 GND

18 SG

17 ISEN+

16 ISEN–

15 RLDCMP

9 10 11 12 13 14

SFST

ITHB

ROSC

FFSDLY

FB31

HSSRC

VPORT

VPORT, HSSRC, V

Voltages .....................–0.3 to 100V

HSGATE Current.................................................. ±20mA

Voltage .................................................... –0.3 to 8V

RCLASS, RCLASS++

Voltages .................................–0.3 to 8V (and ≤ VPORT)

SFST, FFSDLY, ITHB, T2P Voltages ......–0.3 to V

+0.3V

ISEN+, ISEN – Voltages ...........................................±0.3V

FB31 Voltage ..................................................+12V/–30V

RCLASS/RCLASS++ Current .............................. –50mA

AUX Current ........................................................ ±1.4mA

ROSC Current ..................................................... ±100µA

RLDCMP Current ................................................±500µA

T2P Current.........................................................–2.5mA

Operating Junction Temperature Range (Note 3)

LT4276AI/LT4276BI/LT4276CI..............–40°C to 85°C

LT4276AH/LT4276BH/LT4276CH ....... –40°C to 125°C

Storage Temperature Range .................. –65°C to 150°C

28 27 26 25 24 23

GND 1

AUX 2

RCLASS++/NC* 3

RCLASS 4

T2P/NC** 5

UFD PACKAGE

28-LEAD (4mm

5mm) PLASTIC QFN

JMAX

= 150°C,

= 3.4°C/W

EXPOSED PAD (PIN 29) IS GND, MUST BE SOLDERED TO PCB

*RCLASS++ is not connected in the LT4276B and LT4276C

**T2P is not connected in the LT4276C

orDer inForMaTion

LEAD FREE FINISH

LT4276AIUFD#PBF

LT4276AHUFD#PBF

LT4276BIUFD#PBF

LT4276BHUFD#PBF

LT4276CIUFD#PBF

LT4276CHUFD#PBF

TAPE AND REEL

LT4276AIUFD#TRPBF

LT4276AHUFD#TRPBF

LT4276BIUFD#TRPBF

LT4276BHUFD#TRPBF

LT4276CIUFD#TRPBF

LT4276CHUFD#TRPBF

PART MARKING* MAX PD POWER PACKAGE DESCRIPTION

4276A

4276B

4276C

90W

25.5W

13W

28-Lead (4mm

5mm) Plastic QFN

28-Lead (4mm

5mm) Plastic QFN

28-Lead (4mm

5mm) Plastic QFN

28-Lead (4mm

5mm) Plastic QFN

28-Lead (4mm

5mm) Plastic QFN

28-Lead (4mm

5mm) Plastic QFN

TEMPERATURE RANGE

–40°C to 85°C

–40°C to 125°C

–40°C to 85°C

–40°C to 125°C

–40°C to 85°C

–40°C to 125°C

Consult LTC Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container.

For more information on lead free part marking, go to:

http://www.linear.com/leadfree/

For more information on tape and reel specifications, go to:

http://www.linear.com/tapeandreel/.

Some packages are available in 500 unit reels through

designated sales channels with #TRMPBF suffix.

4276fa

For more information

www.linear.com/LT4276

LT4276

The

denotes the specifications which apply over the full operating

temperature range, otherwise specifications are at T

= 25°C. V

VPORT

= V

HSSRC

= V

VIN

= 40V, V

VCC

= VCCREG, ROSC, PG, and SG Open,

FFSDLY

= 5.23kΩ to GND. AUX connected to GND unless otherwise specified. (Note 2)

SYMBOL

SIG

CLASS

MARK

PARAMETER

VPORT, HSSRC, V

Operating Voltage

VPORT Signature Range

VPORT Classification Range

VPORT Mark Range

VPORT AUX Range

Signature/Class Hysteresis Window

Reset Threshold

HSON

HSOFF

Hot Swap Turn-On Voltage

Hot Swap Turn-Off Voltage

Hot Swap On/Off Hysteresis Window

Supply Current

VPORT, HSSRC & V

Supply Current

VPORT Supply Current During Mark Event

Signature and Classification

Signature Resistance

Signature Resistance During Mark Event

RCLASS/RCLASS++ Voltage

Classification Stability Time

Digital Interface

AUXT

AUXH

AUX Threshold

AUX Pin Current

T2P Output High

T2P Leakage

Hot Swap Control

GPU

HSGATE Pull Up Current

HSGATE Voltage

HSGATE Pull Down Current

Supply

VCCREG

SINK

Soft-Start

SFST

Charging Current

SFST

= 0.5V, 3.0V

elecTrical characTerisTics

CONDITIONS

At VPORT Pin

At VPORT Pin, After 1st Classification Event

At VPORT Pin, V

AUX

≥ 6.45V

MIN

1.5

12.5

5.6

1.0

2.6

TYP

MAX

5.6

UNITS

VPORT

= V

HSSRC

= V

VIN

= 60V

VPORT

= V

MARK

after 1st Classification Event

SIG

(Note 4)

MARK

(Note 4)

–10mA ≥ I

RCLASS

≥ –36mA

VPORT

Step to 17.5V, R

CLS

= 35.7Ω

PORT

= 17.5V, V

= V

HSSRC

= 18.5V

AUX

= 6.05V, V

PORT

= 17.5V, V

= 9V, V

= 0V

VCC

- V

T2P

, –1mA Load

T2P

= 0V

HSGATE

- V

HSSRC

= 5V (Note 5)

–10µA Load, with respect to HSSRC

HSGATE

- V

HSSRC

= 5V

0.7

0.4

23.6

5.2

1.36

24.4

8.3

1.40

1.0

1.3

2.2

25.5

11.4

1.43

6.05

3.3

–1

–27

400

7.2

3.11

–52

4.4

–49

7.6

3.17

-0.1

–40

8.0

–42

8.0

3.23

–26

13.4

–36

–22

6.25

5.3

6.45

7.3

0.3

–18

kΩ

µA

µA/V

µA

VPORT Supply Current During Classification V

VPORT

= 17.5V, RCLASS, RCLASS++ Open

Regulation Voltage

FB31 Regulation Voltage

FB31 Pin Bias Current

Feedback Amplifier Average Trans-

Conductance

ITHB Average Sink Current

RLDCMP Open

Time Average, –2µA < I

ITHB

< 2µA

Time Average, V

FB31

= 0V

Feedback Amplifier

4276fa

For more information

www.linear.com/LT4276

LT4276

The

denotes the specifications which apply over the full operating

temperature range, otherwise specifications are at T

= 25°C. V

VPORT

= V

HSSRC

= V

VIN

= 40V, V

VCC

= VCCREG, ROSC, PG, and SG Open,

FFSDLY

= 5.23kΩ to GND. AUX connected to GND unless otherwise specified. (Note 2)

SYMBOL

PARAMETER

PG, SG Output High Level

PG, SG Output Low Level

PG Rise Time, Fall Time

SG Rise Time, Fall Time

Current Sense/Overcurrent

FAULT

ΔV

SENSE

ΔV

ITHB

ITHB(OS)

Timing

OSC

T2P

MIN

MAX

PGDELAY

Default Switching Frequency

Switching Frequency

LTPoE++ Signal Frequency

Minimum PG On Time

Maximum PG Duty Cycle

PG Turn-On Delay-Flyback

PG Turn-On Delay-Forward

FBDLY

PGSG

START

FAULT

MPS

Feedback Amp Enable Delay Time

Feedback Amp Sense Interval

PG Falling to SG Rising Delay Time-Flyback

PG Falling to SG Falling Delay Time-

Forward

Start Timer (Note 6)

Fault Timer (Note 6)

MPS Current

Resistor from FFSDLY to GND

10.5kΩ from FFSDLY to V

52.3kΩ from FFSDLY to V

Delay After Power Good

Delay After Overcurrent Fault

elecTrical characTerisTics

Gate Outputs

CONDITIONS

I = –1mA

I = 1mA

PG = 1000pF

SG = 400pF

ISEN

+ - V

ISEN

–

MIN

–0.1

TYP

MAX

UNITS

125

–130

3.03

200

280

175

140

–111

3.17

214

300

/256

250

171

391

350

550

301

155

–98

3.33

223

320

330

mV/V

kHz

Overcurrent Fault Threshold

Current Sense Comparator Threshold with

Respect to V

ITHB

Offset

ROSC Pin Open

OSC

= 45.3kΩ to GND

5.23kΩ from FFSDLY to GND

52.3kΩ from FFSDLY to GND

10.5kΩ from FFSDLY to V

52.3kΩ from FFSDLY to V

Note 1:

Stresses beyond those listed under Absolute Maximum Ratings

may cause permanent damage to the device. Exposure to any Absolute

Maximum Rating condition for extended periods may affect device

reliability and lifetime.

Note 2.

All voltages with respect to GND unless otherwise noted. Positive

currents are into pins; negative currents are out of pins unless otherwise

noted.

Note 3.

This IC includes overtemperature protection that is intended

to protect the device during momentary overload conditions. Junction

temperature can exceed 150°C when overtemperature protection is active.

Continuous operation above the specified maximum operating junction

temperature may impair device reliability.

Note 4.

Signature resistance specifications do not include resistance

added by the external diode bridge which can add as much as 1.1kΩ to the

port resistance.

Note 5.

GPU

available in PoE powered operation. That is, available after

V(VPORT) > V

HSON

and V(AUX) < V

AUXT

, over the range where V(VPORT)

is between V

HSOFF

and 60V.

Note 6.

Guaranteed by design, not subject to test.

4276fa

For more information

www.linear.com/LT4276

LT4276

Typical perForMance characTerisTics

Input Current vs Input Voltage

25k Detection Range

0.5

125°C

85°C

25°C

–40°C

26.25

Signature Resistance

vs Input Voltage

125°C

85°C

25°C

–40°C

CURRENT (mA)

Current vs Temperature

SIGNATURE RESISTANCE (k )

0.4

VPORT CURRENT (mA)

25.75

300KHz

214KHz

–50

0.3

25.25

0.2

24.75

0.1

24.25

VPORT VOLTAGE (V)

4276 G01

23.75

VPORT VOLTAGE (V)

–25

TEMPERATURE (°C)

100

125

4276 G02

4276 G03

FB31

vs Temperature

3.178

3.176

ITHB CURRENT (µA)

3.174

FB31

(V)

3.172

3.170

3.168

3.166

3.164

3.162

–50

–25

TEMPERATURE (°C)

100

125

–10

–5

Feedback Amplifier Output Current

vs V

FB31

125°C

85°C

25°C

–40°C

FREQUENCY (kHz)

325

300

275

250

225

200

Switching Frequency

vs Temperature

OSC

= 45.3k

ROSC OPEN

–15

2.57

2.77

2.97 3.17 3.37

FB31 VOLTAGE (V)

3.57

3.77

4276 G05

175

–50

–25

TEMPERATURE (°C)

100

125

4276 G04

4276 G06

Current Sense Voltage

vs Duty Cycle, I

THB

160

140

(ISEN+ - ISEN–)

(mV)

120

100

ITHB

= 2.3V

ITHB

= 2.6V

ITHB

= 2.9V

DUTY CYCLE (%)

ITHB

= 0.96V (FB31 = 0V)

200

PG DELAY TIME (ns)

ITHB

= 1.8V

250

PG Delay Time vs Temperature in

Flyback Mode

400

350

FFSDLY

= 52.3k

DELAY TIME (ns)

150

300

250

200

150

100

–50

–25

TEMPERATURE (°C)

100

125

PG Delay Time vs Temperature in

Forward Mode

PGDELAY

, R

FFSDLY

= 52.3k

PGSG

, R

FFSDLY

= 52.3k

100

FFSDLY

= 5.23k

PGDELAY

, R

FFSDLY

= 10.5k

PGSG

, R

FFSDLY

= 10.5k

–25

TEMPERATURE (°C)

100

125

–50

4276 G07

4276 G08

4276 G09

4276fa

For more information

www.linear.com/LT4276

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