LINER LT4276 Ltpoe/poe/poe pd forward/flyback controller Datasheet

LT4276
LTPoE++/PoE+/PoE
PD Forward/Flyback Controller
Description
Features
n
n
n
n
n
n
n
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IEEE802.3af/at and LTPoE++™ 90W Powered Device
(PD) with Forward/Flyback Controller
LT4276A Supports All of the Following Standards:
n LTPoE++ 38.7W, 52.7W, 70W and 90W
n IEEE 802.3at 25.5W Compliant
n 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
The LT®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 compliant, 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.
Applications
n
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The LT4276 utilizes an external, low RDS(ON) N-channel
MOSFET for the Hot Swap function, maximizing power
delivery and efficiency, reducing heat dissipation, and
easing the thermal design.
High Power Wireless Data Systems
Outdoor Security Camera Equipment
Commercial and Public Information Displays
High Temperature Applications
L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks and
LTPoE++, and Hot Swap are trademarks of Linear Technology Corporation. All other trademarks
are the property of their respective owners.
Typical Application
AUX
37V-57V
VPORT
LTPoE++ 70W Power Supply in a Forward Mode
+
LT4276 Family
–
+
–
22µF
FMMT723
0.1µF
•
+
100µH
3.3k
VIN HS SW
SRC VCC
VCC FFS
DLY
PG
ISEN+
VCC
20mΩ
ISEN–
LT4276A
SG
RCLASS
RCLASS++
GND FB31 SS ROSC
+
5V
13A
–
10µF
10nF
VPORT HS
GATE
AUX
•
0.1µF
T2P
10k
100pF
MAX DELIVERED
POWER
A
++
l
LTPoE 90W
l
LTPoE++ 70W
LTPoE++ 52.7W
LTPoE++ 38.7W
LT4276
GRADE
B
C
l
l
25.5W
l
l
13W
l
l
l
ITHB
4276 TA01
100k
OPTO
TO MICROPROCESSOR
4276f
For more information www.linear.com/LT4276
1
LT4276
Absolute Maximum Ratings
Pin Configuration
(Notes 1, 2)
SWVCC
VIN
HSSRC
HSGATE
NC
VPORT
TOP VIEW
28 27 26 25 24 23
GND 1
22 DNC
AUX 2
21 VCC
RCLASS++/NC* 3
20 PG
29
GND
RCLASS 4
T2P/NC** 5
19 GND
18 SG
17 ISEN+
VCC 6
VCC 7
16 ISEN–
VCC 8
15 RLDCMP
FB31
ITHB
FFSDLY
SFST
VCC
9 10 11 12 13 14
ROSC
VPORT, HSSRC, VIN Voltages......................–0.3 to 100V
HSGATE Current.................................................. ±20mA
VCC Voltage..................................................... –0.3 to 8V
RCLASS, RCLASS++
Voltages..................................–0.3 to 8V (and ≤ VPORT)
SFST, FFSDLY, ITHB, T2P Voltages.......–0.3 to VCC+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
UFD PACKAGE
28-LEAD (4mm × 5mm) PLASTIC QFN
TJMAX = 150°C, θJC = 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
TAPE AND REEL
PART MARKING* MAX PD POWER PACKAGE DESCRIPTION
TEMPERATURE RANGE
LT4276AIUFD#PBF
LT4276AIUFD#TRPBF
4276A
90W
28-Lead (4mm × 5mm) Plastic QFN
–40°C to 85°C
LT4276AHUFD#PBF
LT4276AHUFD#TRPBF
4276A
90W
28-Lead (4mm × 5mm) Plastic QFN
–40°C to 125°C
LT4276BIUFD#PBF
LT4276BIUFD#TRPBF
4276B
25.5W
28-Lead (4mm × 5mm) Plastic QFN
–40°C to 85°C
LT4276BHUFD#PBF
LT4276BHUFD#TRPBF
4276B
25.5W
28-Lead (4mm × 5mm) Plastic QFN
–40°C to 125°C
LT4276CIUFD#PBF
LT4276CIUFD#TRPBF
4276C
13W
28-Lead (4mm × 5mm) Plastic QFN
–40°C to 85°C
LT4276CHUFD#PBF
LT4276CHUFD#TRPBF
4276C
13W
28-Lead (4mm × 5mm) Plastic QFN
–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.
Consult LTC Marketing for information on nonstandard lead based finish parts.
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/
2
4276f
For more information www.linear.com/LT4276
LT4276
Electrical Characteristics
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TJ = 25°C. VVPORT = VHSSRC = VVIN = 40V, VVCC = VCCREG, ROSC, PG, and SG Open,
RFFSDLY = 5.23kΩ to GND. AUX connected to GND unless otherwise specified. (Note 2)
SYMBOL
PARAMETER
CONDITIONS
MIN
VPORT, HSSRC, VIN Operating Voltage
At VPORT Pin
l
TYP
MAX
UNITS
60
V
VSIG
VPORT Signature Range
At VPORT Pin
l
1.5
10
V
VCLASS
VPORT Classification Range
At VPORT Pin
l
12.5
21
V
VMARK
VPORT Mark Range
At VPORT Pin, After 1st Classification Event
l
5.6
10
V
VPORT AUX Range
At VPORT Pin, VAUX ≥ 6.45V
l
8
60
V
Signature/Class Hysteresis Window
l
1.0
2.6
Reset Threshold
l
VHSON
Hot Swap Turn-On Voltage
l
VHSOFF
Hot Swap Turn-Off Voltage
l
30
Hot Swap On/Off Hysteresis Window
l
3
V
35
5.6
V
37
V
31
V
V
Supply Current
VPORT, HSSRC & VIN Supply Current
VVPORT = VHSSRC = VVIN = 60V
VPORT Supply Current During Classification VVPORT = 17.5V, RCLASS, RCLASS++ Open
0.7
VVPORT = VMARK after 1st Classification Event
l
0.4
Signature Resistance
VSIG (Note 4)
l
23.6
Signature Resistance During Mark Event
RCLASS/RCLASS++ Voltage
VMARK (Note 4)
l
5.2
–10mA ≥ IRCLASS ≥ –36mA
l
1.36
Classification Stability Time
VVPORT Step to 17.5V, RCLS = 35.7Ω
l
VPORT Supply Current During Mark Event
2
mA
1.3
mA
2.2
mA
25.5
kΩ
8.3
11.4
kΩ
1.40
1.43
V
l
l
1.0
Signature and Classification
24.4
2
ms
Digital Interface
VAUXT
AUX Threshold
l
6.05
6.25
6.45
V
IAUXH
AUX Pin Current
VAUX = 6.05V
l
3.3
5.3
7.3
µA
T2P Output High
VVCC - VT2P, –1mA Load
l
T2P Leakage
VT2P = 0V
l
–1
HSGATE Pull Up Current
VHSGATE - VHSSRC = 5V (Note 5)
l
–27
HSGATE Voltage
–10µA Load, with respect to HSSRC
l
10
HSGATE Pull Down Current
VHSGATE - VHSSRC = 5V
l
400
l
7.2
7.6
8.0
V
l
3.11
3.17
3.23
V
0.3
V
1
µA
–18
µA
14
V
Hot Swap Control
IGPU
–22
µA
VCC Supply
VCCREG
VCC Regulation Voltage
Feedback Amplifier
VFB
FB31 Regulation Voltage
FB31 Pin Bias Current
RLDCMP Open
gm
Feedback Amplifier Average TransConductance
Time Average, –2µA < IITHB < 2µA
l
–52
–40
–26
µA/V
ISINK
ITHB Average Sink Current
Time Average, VFB31 = 0V
l
4.4
8.0
13.4
µA
Charging Current
VSFST = 0.5V, 3.0V
l
–49
–42
–36
µA
-0.1
µA
Soft-Start
ISFST
4276f
For more information www.linear.com/LT4276
3
LT4276
Electrical Characteristics
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TJ = 25°C. VVPORT = VHSSRC = VVIN = 40V, VVCC = VCCREG, ROSC, PG, and SG Open,
RFFSDLY = 5.23kΩ to GND. AUX connected to GND unless otherwise specified. (Note 2)
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
Gate Outputs
VCC –0.1
V
PG, SG Output High Level
I = –1mA
l
PG, SG Output Low Level
I = 1mA
l
PG Rise Time, Fall Time
PG = 1000pF
15
ns
SG Rise Time, Fall Time
SG = 400pF
15
ns
1
V
Current Sense/Overcurrent
VFAULT
Overcurrent Fault Threshold
l
125
140
155
mV
ΔVSENSE/
ΔVITHB
Current Sense Comparator Threshold with
Respect to VITHB
VISEN+ - VISEN–
l
–130
–111
–98
mV/V
VITHB(OS)
VITHB Offset
l
3.03
3.17
3.33
V
Timing
fOSC
Default Switching Frequency
ROSC Pin Open
l
200
214
223
kHz
ROSC = 45.3kΩ to GND
l
280
300
320
kHz
fT2P
Switching Frequency
LTPoE++ Signal Frequency
tMIN
Minimum PG On Time
l
175
250
330
ns
DMAX
Maximum PG Duty Cycle
l
63
66
70
%
tPGDELAY
PG Turn-On Delay-Flyback
PG Turn-On Delay-Forward
fSW/256
5.23kΩ from FFSDLY to GND
52.3kΩ from FFSDLY to GND
10.5kΩ from FFSDLY to VCC
52.3kΩ from FFSDLY to VCC
45
171
92
391
ns
ns
ns
ns
tFBDLY
Feedback Amp Enable Delay Time
350
ns
tFB
Feedback Amp Sense Interval
550
ns
tPGSG
PG Falling to SG Rising Delay Time-Flyback
PG Falling to SG Falling Delay TimeForward
Resistor from FFSDLY to GND
10.5kΩ from FFSDLY to VCC
52.3kΩ from FFSDLY to VCC
20
67
301
ns
ns
ns
tSTART
Start Timer (Note 6)
Delay After Power Good
l
80
86
93
ms
tFAULT
Fault Timer (Note 6)
Delay After Overcurrent Fault
l
80
86
93
ms
IMPS
MPS Current
l
10
12
14
mA
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.
4
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. IGPU available in PoE powered operation. That is, available after
V(VPORT) > VHSON and V(AUX) < VAUXT, over the range where V(VPORT)
is between VHSOFF and 60V.
Note 6. Guaranteed by design, not subject to test.
4276f
For more information www.linear.com/LT4276
LT4276
Typical Performance Characteristics
Input Current vs Input Voltage
25k Detection Range
SIGNATURE RESISTANCE (kΩ)
125°C
85°C
25°C
–40°C
0.4
VPORT CURRENT (mA)
26.25
0.3
0.2
0.1
0
2
0
4
6
VPORT VOLTAGE (V)
8
125°C
85°C
25°C
–40°C
25.75
10
300KHz
25.25
24.75
24.25
23.75
10
VCC Current vs Temperature
12
VCC CURRENT (mA)
0.5
Signature Resistance
vs Input Voltage
214KHz
6
4
2
1
2
3
4
5
6
7
VPORT VOLTAGE (V)
8
4276 G01
0
–50
9
15
3.178
3.176
3.168
5
0
–5
125
325
ROSC = 45.3k
300
FREQUENCY (kHz)
ITHB CURRENT (µA)
3.170
100
Switching Frequency
vs Temperature
125°C
85°C
25°C
–40°C
10
3.172
0
25
50
75
TEMPERATURE (°C)
4276 G03
Feedback Amplifier Output Current
vs VFB31
3.174
–25
4276 G02
VFB31 vs Temperature
VFB31 (V)
8
275
250
225
ROSC OPEN
3.166
200
–10
3.164
–25
0
25
50
75
TEMPERATURE (°C)
100
–15
2.57
125
2.77
2.97 3.17 3.37
FB31 VOLTAGE (V)
3.57
Current Sense Voltage
vs Duty Cycle, ITHB
VITHB = 0.96V (FB31 = 0V)
PG DELAY TIME (ns)
V(ISEN+ - ISEN–) (mV)
VITHB = 1.8V
100
80
VITHB = 2.3V
60
40
VITHB = 2.6V
20
0
0
10
20
30
40
50
DUTY CYCLE (%)
60
70
4276 G07
100
400
300
350
250
200
150
100
0
–50
TPGDELAY, RFFSDLY = 52.3k
300
RFFSSDLY = 52.3k
TPGSG, RFFSDLY = 52.3k
250
200
150
TPGDELAY, RFFSDLY = 10.5k
100
RFFSSDLY = 5.23k
50
–25
0
25
50
75
TEMPERATURE (°C)
100
125
4276 G08
125
PG Delay Time vs Temperature in
Forward Mode
350
50
VITHB = 2.9V
0
25
50
75
TEMPERATURE (°C)
4276 G06
PG Delay Time vs Temperature in
Flyback Mode
160
120
–25
4276 G05
4276 G04
140
175
–50
3.77
DELAY TIME (ns)
3.162
–50
0
–50
TPGSG, RFFSDLY = 10.5k
–25
0
25
50
75
TEMPERATURE (°C)
100
125
4276 G09
4276f
For more information www.linear.com/LT4276
5
LT4276
Pin Functions
GND(Pins 1, 19, Exposed Pad Pin 29): Device Ground.
Exposed Pad must be electrically and thermally connected
to PCB GND and Pin 19.
RCLASS++ (Pin 3, LT4276A Only): LTPoE++ Class Select
Input. Connect a resistor between RCLASS++ to GND per
Table 1.
AUX (Pin 2): Auxiliary Sense. Assert AUX via a resistive
divider from the auxiliary power input to set the voltage
at which the auxiliary supply takes over. Asserting AUX
pulls down HSGATE, disconnects the signature resistor
and disables classification. The AUX pin sinks IAUXH when
below its threshold voltage of VAUXT to provide hysteresis.
Connect to GND if not used.
RCLASS (Pin 4): Class Select Input. Connect a resistor
between RCLASS to GND per Table 1.
T2P (Pin 5, LT4276A and LT4276B only): PSE Type
Indicator. Low impedance to VCC indicates 2-event classification. Alternating low/high impedance indicates
LTPoE++ classification (LT4276A only, see Applications
Information). High impedance indicates 1-event classification. This pin is not connected on the LT4276C. See the
Applications Information Section for pin behavior when
using the AUX pin.
DNC (Pin 22): Do Not Connect. Leave pin open.
ROSC (Pin 10): Programmable Frequency Adjustment.
Resistor to GND programs operating frequency. Leave
open for default frequency of 214kHz.
SFST (Pin 11): Soft-Start. Capacitor to GND sets softstart timing.
FFSDLY (Pin 12): Forward/Flyback Select and Primary
Gate Delay Adjustment. Resistor to GND adjusts gate drive
delay for a flyback topology. Resistor to VCC adjusts gate
drive delay for a forward topology.
ITHB (Pin 13): Current Threshold Control. The voltage on
this pin corresponds to the peak current of the external
6
FET. Note that the voltage gain from ITHB to the input of
the current sense comparator (VSENSE) is negative.
FB31 (Pin 14): Feedback Input. In flyback mode, connect
external resistive divider from the third winding feedback.
Reference voltage is 3.17V. Connect to GND in forward
mode.
RLDCMP (Pin 15): Load Compensation Adjustment. Optional resistor to GND controls output voltage set point as
a function of peak switching current. Leave RLDCMP open
if load compensation is not needed.
ISEN– (Pin 16): Current Sense, Negative Input. Route as
a dedicated trace to the current sense resistor.
ISEN+ (Pin 17): Current Sense, Positive Input. Route as
a dedicated trace to the current sense resistor.
SG (Pin 18): Secondary (Synchronous) Gate Drive, Output.
PG (Pin 20): Primary Gate Drive, Output.
VCC (Pins 6, 7, 8, 9, 21): Switching Regulator Controller
Supply Voltage. Connect a local 1µF ceramic capacitor
from VCC pin 21 to GND pin 19 as close as possible to
LT4276 as shown in Table 2.
SWVCC(Pin 23): Switch Driver for VCC’s Buck Regulator.
This pin drives the base of a PNP in a buck regulator to
generate VCC.
VIN (Pin 24): Buck Regulator Supply Voltage. Usually
separated from HSSRC by a pi filter.
HSSRC (Pin 25): External Hot Swap MOSFET Source.
Connect to source of the external MOSFET.
HSGATE (Pin 26): External Hot Swap MOSFET Gate Control, Output. Capacitance to GND determines inrush time.
NC (Pin 27): No Connection. Not internally connected.
VPORT (Pin 28): PD Interface Supply Voltage and External
Hot Swap MOSFET Drain Connection.
4276f
For more information www.linear.com/LT4276
LT4276
Block Diagram
VPORT
VIN
SWVCC
START-UP
REGULATOR
INTERNAL
BUCK
CONTROLLER
CP
HSGATE
VCC
11V
VCC
PD INTERFACE
CONTROLLER
HSSRC
VPORT
–
+
–
+
RCLASS
T2P
1.4V
1.4V
TSD
GND
VPORT
RCLASS++
PG
SG
+
–
AUX
VAUXT
IAUXH
FB31
VFB
+
–
ITHB
VCC
FEEDBACK AMP
gm = –40µA/V
SFST
SWITCHING
REGULATOR
CONTROLLER
LOAD
COMP
FFSDLY
OSC
+
–
VFAULT
+
–
–
+
AV = 10
AV =
SLOPE
COMP
∆VSENSE
∆VITHB
VSENSE
AV = 1
ISEN+
–
+
CURRENT
SENSE
COMPARATOR
–
+
CURRENT
FAULT
COMPARATOR
ROSC
VITHB(OS)
4276 BD
ISEN–
RLDCMP
4276f
For more information www.linear.com/LT4276
7
LT4276
Applications Information
OVERVIEW
VSENSE
Power over Ethernet (PoE) continues to gain popularity
as products take advantage of DC power and high speed
data available from a single RJ45 connector. The LT4276A
allows higher power while maintaining backwards compatibility with existing PSE systems. The LT4276 combines
a PoE PD controller and a switching regulator controller
capable of either flyback or forward isolated power supply operation.
∆VSENSE
∆VITHB
VITHB(OS)
VITHB
4276 F01
SIGNIFICANT DIFFERENCES FROM PREVIOUS
PRODUCTS
The LT4276 has several significant differences from previous Linear Technology products. These differences are
briefly summarized below. See Applications Information
for more detail.
ITHB Is Inverted from the Usual ITH pin
The ITHB pin voltage has an inverse relationship to the current sense comparator threshold, VSENSE. Furthermore, the
ITHB pin offset voltage, VITHB(OS), is 3.17V. See Figure 1.
Duty-Cycle Based Soft-Start
The LT4276 uses a duty cycle ramp soft-start that injects
charge into ITHB. This allows startup without appreciable
overshoot and with inexpensive external components.
The Feedback Pin (FB31) is 3.17V rather than 1.25V
The error amp feedback voltage (VFB) is 3.17V.
Figure 1. VSENSE vs. VITHB
Flyback/Forward Mode Is Pin Selectable
The LT4276 operates in flyback mode if FFSDLY is pulled
down by a resistor to GND. It operates in forward mode
if FFSDLY is pulled up by a resistor to VCC. The value of
this resistor determines the tPGDELAY and tPGSG.
T2P Pin Polarity Is Reversed
The T2P pin pulls up to VCC when active rather than pulling down to GND.
VCC Is Powered by Internally Driven Buck Regulator
The LT4276 includes a buck regulator controller that must
be used to generate the VCC supply voltage.
PoE MODES OF OPERATION
The LT4276 has several modes of operation, depending
on the input voltage sequence applied to the VPORT pin.
Table 1. Classification Codes, Power Levels and Resistor Selection
PD POWER
NOMINAL CLASS
CLASS
AVAILABLE
PD TYPE
CURRENT
0
13W
Type 1
0.7mA
1
3.84W
Type 1
10.5mA
2
6.49W
Type 1
18.5mA
3
13W
Type 1
28mA
4
25.5W
Type 2
40mA
4*
38.7W
LTPoE++
40mA
4*
52.7W
LTPoE++
40mA
4*
70W
LTPoE++
40mA
4*
90W
LTPoE++
40mA
*An LTPoE++ PD classifies as class 4 by an IEEE 802.3 compliant PSE.
8
A
√
√
√
√
√
√
√
√
√
LT4276 GRADE CAPABILITY
B
√
√
√
√
√
C
√
√
√
√
RESISTOR (1%)
RCLS
RCLS++
Open
Open
150Ω
Open
80.6Ω
Open
52.3Ω
Open
35.7Ω
Open
Open
35.7Ω
150Ω
47.5Ω
80.6Ω
64.9Ω
52.3Ω
118Ω
4276f
For more information www.linear.com/LT4276
LT4276
Applications Information
Detection
POWER ON
During detection, the PSE looks for a 25kΩ signature
resistor which identifies the device as a PD. The LT4276
signature resistor is smaller than 25k to compensate for
the additional series resistance introduced by the IEEE
required bridge.
VHSON
VHSOFF
VPORT
CLASS
VCLASSMIN
VSIGMAX
Classification
The detection/classification process varies depending on
whether the PSE is Type 1, Type 2, or LTPoE++. A Type 1
PSE, after a successful detection, may apply a classification probe voltage of 15.5V to 20.5V and measure current.
VRESET
VSIGMIN
POWER ON
VHSON
VHSOFF
VPORT
1ST CLASS 2ND CLASS
LTPoE++ Classification
VCLASSMIN
VSIGMAX
The LT4276A allows higher power allocation while maintaining backwards compatibility with existing PSE systems
by extending the classification signaling of IEEE 802.3.
Linear Technology PSE controllers capable of LTPoE++
are listed in the Related Parts section. IEEE PSEs classify
an LTPoE++ PD as a Type 2 PD.
1ST MARK
2ND MARK
VSIGMIN
4276 F03
Figure 3. Type 2 Detect/Class Signaling Waveform
POWER ON
VHSON
VHSOFF
VPORT
1ST CLASS 2ND CLASS 3RD CLASS
VCLASSMIN
VSIGMAX
VRESET
VSIGMIN
During the mark state, the LT4276 presents <11kΩ to the
port as required by the IEEE specification.
DETECT
VRESET
Classification Resistors (RCLS and RCLS++)
Signature Corrupt During Mark
4276 F02
Figure 2. Type 1 Detect/Class Signaling Waveform
In 2-event classification, a Type 2 PSE probes for power
classification twice as shown in Figure 3. The LT4276A or
LT4276B recognizes this and pulls the T2P pin up to VCC to
signal the load that Type 2 power is available. Otherwise it
does not pull up on the T2P pin, indicating that only Type
1 power is available. If an LT4276A senses an LTPoE++
PSE it alternates between pulling T2P up and floating T2P
at a rate of fT2P to indicate the LTPoE++ power is available.
The RCLS and RCLS++ resistors set the classification current corresponding to the PD power classification. Select
the value of RCLS from Table 1 and connect the resistor
between the RCLASS pin and GND. For LTPoE++, use
the LT4276A and select the value of RCLS++ from Table
1 in addition to RCLS.The resistor tolerance must be 1%
or better to avoid degrading the overall accuracy of the
classification circuit.
DETECT
DETECT
1ST MARK
2ND MARK 3RD MARK
4276 F04
Figure 4. LTPoE++ Detect/Class Signaling Waveform
4276f
For more information www.linear.com/LT4276
9
LT4276
Applications Information
Inrush and Powered On
EXTERNAL VCC SUPPLY
Once the PSE detects and optionally classifies the PD, the
PSE then powers on the PD. When the port voltage rises
above the VHSON threshold, it begins to source IGPU out
of the HSGATE pin. This current flows into an external
capacitor (CGATE in Figure 5) that causes a voltage to
ramp up the gate of the external MOSFET. The external
MOSFET acts as a source follower and ramps the voltage
up on the output bulk capacitor (CPORT in Figure 5), thereby
determining the inrush current (IINRUSH in Figure 5). To
meet IEEE requirements, design IINRUSH to be ~100mA.
The external VCC supply must be configured as a buck
regulator shown in Figure 6. To optimize the buck regulator,
use the external component values in Table 2 corresponding to the VIN operating range. This buck regulator runs
in discontinuous mode with the inductor peak current
considerably higher than average load current on VCC.
Thus, the saturation current rating of the inductor must
exceed the values shown in Table 2. Place the capacitor, C,
as close as possible to VCC pin 21 and GND pin 19. For
optimal performance, place the external components as
close as possible to the LT4276.
The LT4276 internal charge pump provides an N-channel
MOSFET solution, eliminating a larger and more costly
P-channel FET. The low RDS(ON) MOSFET also maximizes
power delivery and efficiency, reduces power and heat
dissipation, and eases thermal design.
VIN
VIN
Re
LT4276
IINRUSH
+
VPORT
3.3k
IGPU
L(µH)
VCC
GND
CPORT
VPORT
CPORT
CGATE
VCC
C(µF)
CGATE
4276 F06
Figure 6. VCC Buck Regulator
HSGATE
IINRUSH =IGPU •
FMMT723
PBSS9110T
SWVCC
HSSRC
Table 2 . Buck Regulator Component Selection
LT4276
VIN
9V-57V
PoE
GND
C
22µF
10µF
L
22µH
100µH
ISAT
≥700mA
≥300mA
Re
10Ω
20Ω
4276 F05
AUXILIARY SUPPLY OVERRIDE
Figure 5. Programming IINRUSH
DELAY START
After the HSGATE charges up to approximately 7V above
HSSRC, fully enhancing the external Hot Swap MOSFET,
the switching regulator controller operates after a delay
of tSTART. During this delay, the LT4276 draws IMPS from
VPORT to ensure that the PSE does not DC disconnect
the PD due to Maintain Power Signature requirements.
If the AUX pin is held above VAUXT, the LT4276 enters
auxiliary power supply override mode. In this mode the
signature resistor is disconnected, classification is disabled, and HSGATE is pulled down. The T2P pin pulls up
to VCC on the LT4276B (or the LT4276A when no RCLS++
resistor is present). The T2P pin alternates between pulling
up and floating at fT2P on the LT4276A when the RCLS++
resistor is present.
The AUX pin allows for setting the auxiliary supply turn on
(VAUXON) and turn off (VAUXOFF) voltage thresholds. The
auxiliary supply hysteresis voltage (VAUXHYS) is set by
sinking current (IAUXH) only when the AUX pin voltage is
10
4276f
For more information www.linear.com/LT4276
LT4276
Applications Information
less than VAUXT. Use the following equations to set VAUXON
and VAUXOFF via R1 and R2 in Figure 7. A capacitor up to
1000pF may be placed between the AUX pin and GND to
improve noise immunity.
PG
VAUXON must be lower than VHSOFF.
SG
R1=
R2 =
R1≥
VAUXON − VAUXOFF VAUXHYS
=
IAUXH
IAUXH
VAUX(MAX) − VAUXT
1.4mA
tPGDELAY
tPGSG
+
R1
 VAUXOFF 
− 1
 V

AUXT
tPGon
4276 F07
VAUX
Figure 8: PG and SG Relationship in Flyback Mode
LT4276
R1
•
AUX
R2
–
+
•
GND
4276 F08a
Figure 7. AUX Threshold and Hysteresis Calculation
PG
LT4276
ISEN+
SWITCHING REGULATOR CONTROLLER OPERATION
The switching regulator controller portion of the LT4276
is a current mode controller capable of implementing
either a flyback or a forward power supply. When used
in flyback mode, no opto-isolator is required for feedback
because the output voltage is sensed via the transformer’s
third winding.
ISEN–
GND
FFSDLY SG
RFFSDLY
•
•
4276 F08
Figure 9: Example PG and SG Connections in Flyback Mode
Flyback Mode
Forward Mode
The LT4276 is programmed into flyback mode by placing
a resistor RFFSDLY from the FFSDLY pin to GND. This resistor must be in the range of 5.23kΩ to 52.3kΩ. If using a
potentiometer to adjust RFFSDLY, ensure the adjustment
of the potentiometer does not exceed 52.3kΩ.The value
of RFFSDLY determines tPGDELAY according to the following
equations:
tPGDELAY ≈ 2.69ns / kΩ •RFFSDLY + 30ns
The LT4276 is programmed into forward mode by placing
a resistor RFFSDLY from the FFSDLY pin to VCC. The RFFSDLY
resistor must be in the range of 10.5kΩ to 52.3kΩ. If using
a potentiometer to adjust RFFSDLY ensure the adjustment
of the potentiometer does not exceed 52.3kΩ.
tPGSG ≈ 20ns
The PG and SG relationships in flyback mode are shown
in Figure 8.
The SG pin must be connected to the secondary side
MOSFET through a gate drive transformer as shown in
Figure 9. Add a Schottky diode from PG to GND as shown
in Figure 9 to prevent PG from going negative.
The value of RFFSDLY determines tPGDELAY and tPGSG according to the following equations:
tPGDELAY ≈ 7.16ns/kΩ • RFFSDLY + 17ns
tPGSG ≈ 5.60ns/kΩ • RFFSDLY + 7.9ns
The PG and SG relationships in forward mode are shown
in Figure 10.
4276f
For more information www.linear.com/LT4276
11
LT4276
Applications Information
RFB1
PG
VFB
RFB2
THIRD
LT4276
FEEDBACK
FB31
+
–
ITHB
VIN
•
SECONDARY
PRIMARY
•
SG
tPGDELAY
PG
tPGSG
4276 F09
+
–
Figure 10: PG and SG relationship in Forward Mode
AV = 10
+
–
VOUT
•
ISEN+
ISEN–
RSENSE
RLDCMP
4276 F11
RLDCMP
VCC
•
•
RFFSDLY
VCC
FFSDLY
LT4276
Figure 12: Feedback and Load Compensation Connection
PG
ISEN+
FB31
VOLTAGE
ISEN–
GND
VFB
GND
SG
PG
4276 F10
Figure 11: Example PG and SG Connections in Forward Mode
SG
4276 F09
tFBDLY tFB
In forward mode, the SG pin has the correct polarity to
drive the active clamp P-channel MOSFET through a simple
level shifter as shown in Figure 11. Add a Schottky diode
from the PG to GND as shown in Figure 11 to prevent PG
from going negative.
FEEDBACK AMPLIFIER
In the flyback mode, the feedback amplifier senses the
output voltage through the transformer’s third winding as
shown in Figure 12.The amplifier is enabled only during the
fixed interval, tFB, as shown in Figure 13. This eliminates
the opto-isolator in isolated designs, thus greatly improving
the dynamic response and stability over lifetime. Since tFB
is a fixed interval, the time-averaged transconductance,
gm, varies as a function of the user-selected switching
frequency.
12
Figure 13: Feedback Amplifier Timing Diagram
FEEDBACK AMPLIFIER OUTPUT, ITHB
As shown in the Block Diagram, VSENSE is the input of
the Current Sense Comparator. VSENSE is derived from
the output of a linear amplifier whose input is the voltage
on the ITHB pin, VITHB.
This linear amplifier inverts its input, VITHB, with a gain,
ΔVSENSE/ΔVITHB, and with an offset voltage of VITHB(OS)
to yield its output, VSENSE. This relationship is shown
graphically in Figure 1. Note the slope ΔVSENSE/ΔVITHB
is a negative number and is provided in the electrical
characteristics table.
⎛ ΔV
⎞
VITHB = VITHB(OS) + VSENSE • ⎜ SENSE ⎟
⎝ ΔVITHB ⎠
–1
4276f
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LT4276
Applications Information
The block diagram shows VSENSE is compared against
the voltage across the current sense resistor, V(ISEN+)V(ISEN–) modified by the internal slope compensation
voltage discussed subsequently.
VOUT differs from the desired VOUT due to offset injected
by load compensation. The change to RFB2 to correct this
is predicted by:
ΔRFB2 =
LOAD COMPENSATION
As can be seen in Figure 13, the voltage on the FB31 pin
droops slightly during the flyback period. This is mostly
caused by resistances of components of the secondary
side such as: the secondary winding, RDS(ON) of the synchronous MOSFET, ESR of the output capacitor, etc. These
resistances cause a feedback error that is proportional to
the current in the secondary loop at the time of feedback
sample window. To compensate for this error, the LT4276
places a voltage proportional to the peak current in the
primary winding on the RLDCMP pin.
Determining Feedback and Load Compensation
Resistors
Because the resistances of components on the secondary
side are generally not well known, an empirical method
must be used to determine the feedback and load compensation resistor values.
ΔVOUT NTHIRD RFB22
VFB NSECONDARY RFB1
Where:∆VOUT is the desired change to VOUT
∆RFB2 is the required change to RFB2
NTHIRD/NSECONDARY is the transformer third winding to secondary winding
OPTO-ISOLATOR FEEDBACK
For forward mode operation, the flyback voltage cannot
be sensed across the transformer. Thus, opto-isolator
feedback must be used. When using opto-isolator feedback, connect the FB31 pin to GND and leave the RLDCMP
pin open. In this condition, the feedback amplifier sinks
an average current of ISINK into the ITHB pin. An example
for feedback connections is shown in Figure 14. Note that
since ISINK is time-avereged over the switching period,
the sink current varies as a function of the user-selected
switching frequency.
INITIALLY SET RFB2 = 2kΩ
VOUT
VCC
V
NTHIRD
RFB1 ≈RFB2 OUT
–R
VFB NSECONDARY FB2
Connect the resistor RLDCMP between the RLDCMP pin and
GND. The RLDCMP resistor must be at least 10kΩ. Adjust
RLDCMP for minimum change of VOUT over the full input
and output load range. A potentiometer in series with
10kΩ may be initially used for RLDCMP and adjusted. The
potentiometer+10kΩ may then be removed, measured, and
replaced with the equivalent fixed resistor. The resulting
LT4276
ITHB
GND
RX
CX
FB31
4276 F13
Figure 14: Opto-isolator Feedback
Connections in the Forward Mode
4276f
For more information www.linear.com/LT4276
13
LT4276
Applications Information
SOFT-START
In PoE applications, a proper soft-start design is required
to prevent the PD from drawing more current than the
PSE can provide.
In forward mode, each of the back page applications schematics provides a chart with tSFST vs. CSFST. Select the
application and choose a value of CSFST that corresponds
to the desired soft-start time.
The soft-start time, tSFST, is approximately the time in
which the power supply output voltage, VOUT, is charging
its output capacitance, COUT. This results in an inrush
current at the port of the PD, Iport_inrush. Care must be
taken in selecting tSFST to prevent the PD from drawing
more current than the PSE can provide.
CURRENT SENSE COMPARATOR
In the absence of an output load current, the Iport_inrush,
is approximated by the following equation:
Like most switching regulator controllers, the current
sense comparator begins sensing the current tMIN after
PG turns on. Then, the comparator turns PG off after the
voltage across ISEN+ and ISEN– exceeds the current
sense comparator threshold, VSENSE. Note that the voltage
across ISEN+ and ISEN– is modified by LT4276’s internal
slope compensation.
Iport_inrush ≈ (COUT • VOUT2)/(η • tSFST • VIN)
where η is the power supply efficiency,
VIN is the input voltage of the PD
Iport_inrush plus the port current due to the load current
must be below the current the PSE can provide. Note that
the PSE current capability depends on the PSE operating
standard.
The LT4276 contains a soft-start function that controls
tSFST by connecting an external capacitor, CSFST, between
the SFST pin and GND. The SFST pin is pulled up with ISFST
when the LT4276 begins switching. The voltage ramp on
the SFST pin is proportional to the duty cycle ramp for PG.
For flyback mode, the soft-start time is:
t SFST =
600µA ⎛ CSFST ⎞
–t )
(t + t
nF ⎜⎝ ISFST ⎟⎠ PGon PGDELAY MIN
where tPGon is the time when PG is high as shown in
Figure 8 once the power supply is in steady-state.
14
The LT4276 uses a differential current sense comparator
to reduce the effects of stray resistance and inductance
on the measurement of the primary current. ISEN+ and
ISEN– must be Kelvin connected to the sense resistor pads.
SLOPE COMPENSATION
The LT4276 incorporates current slope compensation.
Slope compensation is required to ensure current loop
stability when the duty cycle is greater than or near 50%.
The slope compensation of the LT4276 does not reduce
the maximum peak current at higher duty cycles.
CONTROL LOOP COMPENSATION
In flyback mode, loop frequency compensation is performed by connecting a resistor/capacitor network from
the output of the feedback amplifier (ITHB pin) to GND as
shown in Figure 12. In forward mode, loop compensation
is performed by varying RX and CX in Figure 14.
4276f
For more information www.linear.com/LT4276
LT4276
Applications Information
ADJUSTABLE SWITCHING FREQUENCY
The LT4276 has a default switching frequency, fOSC, of 214
kHz when the ROSC pin is left open. If a higher switching
frequency, fSW, is desired (up to 300 kHz), a resistor no
smaller than 45.3kΩ may be added between the ROSC pin
to GND. The resistor can be calculated below:
ROSC =
3900kΩ •kHz
(kΩ )
( fSW – fOSC )
The LT4276 includes an over-temperature protection
feature which is intended to protect the device during
momentary overload conditions. If the junction temperature
exceeds the over-temperature threshold, the LT4276 pulls
down HSGATE pin, disables classification, and disables
the switching regulator operation.
MAXIMUM DUTY CYCLE
The maximum duty cycle of the PG pin is modified by the
chosen tPGDELAY and fSW. It is calculated below:
SHORT CIRCUIT RESPONSE
If the power supply output voltage is shorted, overloaded,
or if the soft-start capacitor is too small, an overcurrent
fault event occurs when the voltage across the sense pins
exceeds VFAULT (after the blanking period of tMIN). This
begins the internal fault timer tFAULT. For the duration
of tFAULT, the LT4276 turns off PG and SG and pulls the
SFST pin to GND. After tFAULT expires, the LT4276 initiates soft-start.
The fault and soft-start sequence repeats as long as the
short circuit or overload conditions persist. This condition
is recognized by the PG waveform shown in Figure 15
re­peating at an interval of tFAULT.
tFAULT
4276 F14
Figure 15: PG Waveform with Output Shorted
OVERTEMPERATURE PROTECTION
The IEEE 802.3 specification requires a PD to withstand
any applied voltage from 0V to 57V indefinitely. During
classification, however, the power dissipation in the LT4276
may be as high as 1.5W. The LT4276 can easily tolerate
this power for the maximum IEEE classification timing but
overheats if this condition persists abnormally.
MAX POWER SUPPLY DUTY CYCLE
= DMAX – tPGDELAY • fSW
For an appropriate margin during transient operation, the
forward or flyback power supply should be designed so
that its maximum steady-state duty cycle should be about
10% lower than the LT4276 Maximum Power Supply Duty
Cycle calculated above.
EXTERNAL INTERFACE AND COMPONENT SELECTION
PoE Input Diode Bridge
PDs are required to polarity-correct its input voltage.
When diode bridges are used, the diode forward voltage
drops affect the voltage at the VPORT pin. The LT4276
is designed to tolerate these voltage drops. The voltage
parameters shown in the Electrical Characteristics are
specified at the LT4276 package pins.
For high efficiency applications, the LT4276 supports
an LT4321-based PoE ideal diode bridge that reduces
the forward voltage drop from 0.7V to nearly 20mV per
diode in normal operation, while maintaining IEEE 802.3
compliance.
4276f
For more information www.linear.com/LT4276
15
LT4276
Applications Information
Auxiliary Input Diode Bridge
Transient Voltage Suppressor
Some PDs are required to receive AC or DC power from an
auxiliary power source. A diode bridge is typically required
to handle the voltage rectification and polarity correction.
The LT4276 specifies an absolute maximum voltage of
100V and is designed to tolerate brief overvoltage events
due to Ethernet cable surges.
In high efficiency applications, the voltage drop across the
rectifier cannot be tolerated. The LT4276 can be configured
with an LT4320-based ideal diode bridge to recover the
diode voltage drop and ease thermal design.
To protect the LT4276, install a unidirectional transient
voltage suppressor (TVS) such as an SMAJ58A between
the VPORT and GND pins. This TVS must be placed as close
as possible to the VPORT and GND pins of the LT4276.
For PD applications that require an auxiliary power input,
install a TVS between VIN and GND as close as possible
to the LT4276.
Input Capacitor
A 0.1µF capacitor is needed from VPORT to GND to meet
the input impedance requirement in IEEE 802.3 and to
properly bypass the LT4276. This capacitor must be placed
as close as possible to the VPORT and GND pins.
16
For extremely high cable discharge and surge protection
contact Linear Technology Applications.
4276f
For more information www.linear.com/LT4276
LT4276
Typical Applications
13W (TYPE 1) PoE Power Supply in Flyback Mode with 5V, 2.3A Output
L2
10µH
Q1
VPORT
L1: COILCRAFT, DO1813P-181HC
L2: COILCRAFT, DO1608C-103
L4: COILCRAFT, DO1608C-104
C2: 22µF, 6.3V, MURATA GRM31CR70J226KE19
C5: 47µF, 6.3V, PANASONIC 6SVP47M
C7: 2.2µF, 100V, MURATA GRM32ER72A225KA35
T1: WÜRTH, 750313109
Q1: PSMN075-100MSE
+
10µF
100V
•
L1
180nH
C7
2.2µF
3.3k
10nF
100V
L4
100µH
•
47pF
630V
270Ω
1/4W
20Ω
FMMT723
6.04k
VCC FB31
PG
VIN SWVCC
•
–VOUT
PSMN4R2-30MLD
1nF
11Ω
1/4W
BAT54WS
VPORT
ISEN+
60mΩ
1/4W
MMBT3906
ISEN–
0.1µF
100V
PTVS58VP1UTP
52.3Ω
SFST
ROSC
5.23k
ITHB
1µF
•
•
4.7nF
330pF
1µF
2.2nF
100Ω
107k
0.1µF
MMBT3904
15Ω
SG
GND RCLASS FFSDLY
10k
BAT46WS
20k
GND
PE-68386NL
Efficiency vs Load Current
2.2nF
2KV
4276 TA02
Output Regulation vs Load Current
92
5.20
90
5.15
88
5.10
86
5.05
VOUT (V)
EFFICIENCY (%)
VOUT
5V AT 2.3A
FDN86246
LT4276C
84
82
80
78
C5
47µF
6.3V
T1
HSGATE
8.2Ω
C2
22µF
2k
10µF
BAV19WS 10V
HSSRC
2.2nF
2kV
5.00
4.95
4.90
VPORT = 37V
VPORT = 48V
VPORT = 57V
76
0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4
LOAD CURRENT (A)
4.85
VPORT = 37V
VPORT = 48V
VPORT = 57V
4.80
0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4
LOAD CURRENT (A)
4276 TA02a
4276 TA02b
4276f
For more information www.linear.com/LT4276
17
SPARE
PAIRS
8
5
7
4
6
2
3
DATA
PAIRS 1
T2
BG45 TG45
IN78
IN45
IN36
IN12
TG12 BG12
Q5
Q3
Q7
Q9
Q6
Q8
LT4321
Q4
Q2
For more information www.linear.com/LT4276
47nF
100V
VPORT = 42.5V
VPORT = 50V
VPORT = 57V
4276 TA03a
0.1µF
ITHB
VPORT = 42.5V
VPORT = 50V
VPORT = 57V
4276 TA03b
1µF
•
•
•
5.1Ω
1/4W
1nF
T1
OPTO
2.2nF
PE-68386NL 2KV
100Ω
BAT54WS
•
•
2.2nF
2kV
40mΩ
1/4W
160Ω||160Ω
1/4W
100pF
100V
BSZ520N15NS3G
3.3nF
2k
5.90k
20k
T2P
SG
ISEN–
ISEN+
VCC FB31
PG
220pF
107k
ROSC
10µF
10V
VOUT vs Load Current
7.50k
SFST
LT4276B
BAV19WS
L4
100µH
4.80
0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0
LOAD CURRENT (A)
4.85
4.90
4.95
5.00
5.05
5.10
5.15
5.20
20Ω
FMMT723
FFSDLY
35.7Ω
GND RCLASS
VPORT
VIN SWVCC
C7
2.2µF
HSSRC
HSGATE
47nF
100V
10µF
100V
PTVS58VP1UTP
8.2Ω
10nF
100V
Efficiency vs Load Current
24V
3.3k
+
78
0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0
LOAD CURRENT (A)
80
82
84
86
88
90
92
94
EN
OUTN
TG78 BG78
EN
OUTP
BG36 TG36
Q1
L2
10µH
VOUT (V)
18
EFFICIENCY (%)
L1: COILCRAFT, DO1813P-181HC
L2: COILCRAFT, DO1608C-103
L4: COILCRAFT, DO1608C-104
C2, C3: 22µF, 6.3V, MURATA GRM31CR70J226KE19
C5: 47µF, 6.3V, PANASONIC 6SVP47M
C7: 2.2µF, 100V, MURATA GRM32ER72A225KA35
T1: WÜRTH, 750313082 OR PCA EPC3409G
Q1-Q9: PSMN075-100MSE
25.5W (Type 2) PoE+ Power Supply in Flyback Mode with 5V, 4.7A Output
10k
BAT46WS
15Ω
MMBT3904
4276 TA03
1µF
–VOUT
VOUT
5V AT 4.7A
TO MICROPROCESSOR
MMBT3906
2.2nF
C5
47µF
PSMN2R4-30MLD
C2, C3
22µF||22µF
L1
180nH
LT4276
Typical Applications
4276f
GND
VPORT
PTVS58VP1UTP
8.2Ω
10nF
100V
3.3k
Q1
EFFICIENCY (%)
+
For more information www.linear.com/LT4276
76
78
80
82
84
86
88
90
92
94
0.47µF
107k
64.9Ω
80.6Ω
1
SG
ISEN–
ISEN+
VCC FFSDLY
PG
13k
ROSC ITHB
LT4276A
10µF
10V
BAV19WS
VCC
GND FB31 RCLASS RCLASS++ SFST
T2P
20Ω
FMMT723
L4
100µH
VIN SWVCC
C7
2.2µF
(×2)
2
3
4
4276 TA04a
5 6 7 8 9 10 11 12 13
LOAD CURRENT (A)
VPORT = 41V
VPORT = 50V
VPORT = 57V
Efficiency vs Load Current
0.1µF
100V
VPORT
HSGATE
HSSRC
22µF
100V
20m
1/4W
OPTO
2.2nF
2kV
4
1.2
0.10
4.80
4.85
4.90
4.95
5.00
4276 TA04b
5 6 7 8 9 10 11 12 13
LOAD CURRENT (A)
3.3
38
12
tSFST (ms)
CSFST (µF)
4276 TA04
3.8
3
10.0k
10nF
TO MICROPROCESSOR
ZR431
10.0k
L1
2.2µH
C5
100µF
(×2)
+
+VOUT
+5V AT
C8
13A
100µF
6HVA100M
L1: COILCRAFT, XAL-1010-222ME
L2: WÜRTH, 744314490
L4: COILCRAFT, DO1608C-104
C5, 100µF, 6.3V, SUNCON 6HVA100M
C7: 2.2µF, 100V, MURATA GRM32ER72A225KA35L
C8: 100µF, 6.3V, SUNCON 6HVA100M
T1: WÜRTH, 750313095
Q1: PSMN040-100MSE
18V
CMHZ5248B
1.0
2
240Ω
4.7n
33nF
+VOUT
0.1µF
18V
CMHZ5248B
BSC054N04NS
5.05
VPORT = 41V
VPORT = 50V
VPORT = 57V
10k
330Ω
1k
0.1µF
8.2V
CMHZ4694
MMBT3904
10Ω
5Ω
CMMSH1-40L
0.33
1
10Ω
CMMSH1-40L BSC054N04NS
CMMSH1-40L
5.10
5.15
5.20
750Ω
10nF
250V
•
M0C207M
VCC
100Ω
1206
100nF
250V
T1
VOUT vs Load Current
100pF
10k
FDMC2523P
CMMSH1-40L
100k
0.1µF
BAT54WS
BSC190N12NS3
•
70W LTPoE++ Power Supply in Forward Mode with 5V, 13A Output
VOUT (V)
L2
4.9µH
LT4276
Typical Applications
4276f
19
SPARE
PAIRS
8
5
7
4
6
2
3
DATA
PAIRS 1
T2
BG45 TG45
IN78
IN45
IN36
IN12
TG12 BG12
Q5
Q4
For more information www.linear.com/LT4276
VCC
47nF
100V
47nF
100V
PTVS58VP1UTP
8.2Ω
10nF
100V
3.3k
LT4276A
4276 TA05a
76
0.7 1.4 2.1 2.8 3.5 4.2 4.9 5.6 6.3 7.0
LOAD CURRENT (A)
78
100pF*
100pF
CMMSH1-40L
100k
10k
FDMC2523P
15mΩ
1/4W
750Ω
33nF
250V
VPORT = 41V
VPORT = 50V
VPORT = 57V
OPTO
2.2nF
2kV
M0C207M
VCC
100Ω
1206
0.22µF
250V
VOUT vs Load Current
1µF
107k
0.1µF
BAT54WS
•
CMMSH1-60
•
T1
4276 TA05b
10Ω
10k
820Ω
10.0k
38.3k
+VOUT
0.1µF
CMMSH1-100
330pF
BSC123N08S3
7.5V
CMHZ5236B
5.1k
100pF
1.5
4.9
15
0.33
1.0
48
tSFST (ms)
0.10
4276 TA05
CSFST (µF)
3.3
FMMT624
+VOUT
CMMSH1-100
L1: COILCRAFT, XAL-1010-822ME
L2: WÜRTH, 744314650
L4: COILCRAFT, DO1608C-104
C5, 100µF, 6.3V, TDK C3225X5R0J107M
C7: 2.2µF, 100V, MURATA GRM32ER72A225KA35L
C8: 100µF, 16V, SUNCON 16HVA100M
T1: PCA EPC3577G-LF
T1: WÜRTH, 749022016
Q1: PSMN040-100MSE
Q2-Q9: PSMN075-100MSE
FMMT624
+VOUT
100pF
7.5V
CMHZ5236B
5.1k
TO MICROPROCESSOR
ZR431
100pF
6.8nF
20k
13k
7.5Ω
820pF
0.1µF
13V
CMHZ4700
MMBT3904
11.5
0.7 1.4 2.1 2.8 3.5 4.2 4.9 5.6 6.3 7.0
LOAD CURRENT (A)
11.6
11.7
11.9
12.0
12.1
12.2
12.3
12.4
12.5
64.9Ω
11.8
76.8Ω
ITHB
SG
ISEN–
ISEN+
BSC190N12NS3
29.4k
VCC
VCC FFSDLY
PG
SFST ROSC
10µF
BAV19WS 10V
L4
100µH
80
VPORT = 41V
VPORT = 50V
VPORT = 57V
20Ω
FMMT723
VIN SWVCC
C7
2.2µF
(×2)
GND FB31 RCLASS RCLASS++
T2P
VPORT
HSGATE
HSSRC
22µF
100V
L2
6.5µH
82
84
86
88
90
92
94
EN
OUTN
TG78 BG78
EN
OUTP
BG36 TG36
+
Efficiency vs Load Current
Q9
Q8
96
Q7
Q6
LT4321
Q3
Q2
Q1
VOUT (V)
20
EFFICIENCY (%)
90W LTPoE++ Power Supply in Forward Mode with 12V, 7A Output
BSC123N08S3
22µF
16V
(×2)
L1
8.2µH
+VOUT
+12V AT
7A
100µF
16V
16HVA100M
LT4276
Typical Applications
4276f
SPARE
PAIRS
8
5
7
4
6
2
3
T2
BG45 TG45
IN78
IN45
IN36
IN12
TG12 BG12
Q5
Q3
Q7
Q9
Q6
Q8
LT4321
Q4
Q2
For more information www.linear.com/LT4276
47nF
100V
PTVS58VP1UTP
8.2Ω
10nF
100V
LT4276A
BAV19WS
FMMT723
20Ω
51k
220pF
107k
4276 TA06a
4276 TA06b
4.85
VPORT = 50V
VPORT = 57V
4.80
0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0 6.5 7.0
LOAD CURRENT (A)
20k
3.3nF
80
VPORT = 50V
VPORT = 57V
78
0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0 6.5 7.0
LOAD CURRENT (A)
Output Regulation
vs Load Current
0.1µF
7.50k
4.90
4.95
5.00
5.05
5.10
5.15
5.20
35.7Ω
ITHB
T2P
SG
ISEN–
ISEN+
•
•
5.1Ω
1/4W
1nF
T1
•
OPTO
2.2nF
PE-68386NL 2KV
100Ω
•
•
2.2nF
2kV
40mΩ
1/4W
1µF
BSZ900N20
NS3G
100pF
100V
80Ω
1/4W
BAT54WS
2.00kΩ
10µF
10V
VCC FB31
PG
5.90k
L4
100µH
GND RCLASS++ FFSDLY SFST RLDCMP ROSC
VPORT
VIN SWVCC
C7
2.2µF
HSSRC
HSGATE
47µF
100V
10µF
100V
L1: COILCRAFT, DO1813P-181HC
L2: COILCRAFT, DO1608C-103
L4: COILCRAFT, DO1608C-104
C2, C3: 47µF, 6.3V, GRM31CR60J476ME19L
C5: 47µF, 6.3V, PANASONIC 6SVP47M
C7: 2.2µF, 100V, MURATA GRM32ER72A225KA35L
T1: WÜRTH, 750314783 OR PCA EPC3586G
Q1-Q9: PSMN075-100MSE
82
84
86
88
90
92
94
24V
3.3k
+
Efficiency vs Load Current
EN
OUTN
TG78 BG78
EN
OUTP
BG36 TG36
Q1
L2
10µH
VOUT (V)
DATA
PAIRS 1
EFFICIENCY (%)
38.7W LTPoE++ Power Supply in Flyback Mode with 5V, 7A Output
10k
BAT46WS
15Ω
MMBT3904
4276 TA06
1µF
–VOUT
VOUT
5V AT 7A
TO MICROPROCESSOR
MMBT3906
2.2nF
C5
47µF
PSMN2R4-30MLD
C2, C3
47µF||47µF
L1
180nH
LT4276
Typical Applications
4276f
21
SPARE
PAIRS
8
5
7
4
6
2
3
DATA
PAIRS 1
T2
BG45 TG45
IN78
IN45
IN36
IN12
TG12 BG12
MMSD4148 x3
VAUX
9V TO 57VDC
OR 24VAC
Q5
Q3
Q7
Q9
Q6
Q8
LT4321
Q4
Q2
For more information www.linear.com/LT4276
8.2Ω
+
68nF 0.1µF
100V
3.3k
Q1
PTVS58VP1UTP
47nF
100V
OUTN
1µF
VAUX = 9V
VAUX = 24V
VAUX = 42.5V
VAUX = 57V
47nF
100V
4276 TA08a
931k
158k
10µF
100V
L2
8.2µH
L3
2.2µH
63V
+ 680µF
Efficiency vs Load Current
24V
LT4320
OUTP
70
0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0
LOAD CURRENT (A)
72
74
76
78
80
82
84
86
88
90
92
94
EN
OUTN
TG78 BG78
EN
OUTP
BG36 TG36
BG1
BG2
IN2
IN1
TG1
TG2
VIN SWVCC
LT4276B
22µF
10V
BAV19WS
L4
FMMT723 22µH
10Ω
35.7Ω
220pF
107k
VAUX = 9V
VAUX = 24V
VAUX = 42.5V
VAUX = 57V
43k
1µF
•
15mΩ
1/4W
•
4276 TA08b
OPTO
2.2nF
PE-68386NL 2KV
100Ω
BAT54WS
T1
•
220pF
•
•
2.2nF
2kV
82Ω||82Ω
1/4W
100pF
100V
62Ω
1/4W
FDMC86160
4.7nF
2.00k
4.75k
11.5
0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0
LOAD CURRENT (A)
11.6
11.7
11.8
11.9
12.0
12.1
12.2
12.3
12.4
12.5
51k
ITHB
T2P
SG
ISEN–
ISEN+
VCC FB31
PG
Output Regulation
vs Load Current
0.1µF
9.31k
GND RCLASS FFSDLY SFST RLDCMP ROSC
VPORT
AUX
HSSRC
HSGATE
C7, C8
3.3µF
L1: COILCRAFT, DO1813P-561ML
L2: WÜRTH, 7443330820
L3: MURATA, LQM31PN2R2M00L
L4: COILCRAFT, DO1608C-104
C2, C3: 10µF, 16V, MURATA GRM31CR61C106KA88
C5: 33µF, 20V, KEMET, T494V336M020AS
C7, C8: 3.3µF, 100V, TDK C3225X7S2A335M
T1: PCA EPC3601G
Q1: PSMN075-100MSE
Q1-Q9:PSMN075-100MSE
10k
BAT46WS
15Ω
CMLT3820G
4276 TA08
1µF
–VOUT
VOUT
12V AT 1.9A
TO MICROPROCESSOR
CMLT7820G
2.2nF
C5
33µF
BSZ900NF20NS3
C2, C3
10µF||10µF
L1
560nH
25.5W (Type 2) PoE+ and 9V-57V Auxiliary Input Power Supply in Flyback Mode with 12V, 1.9A Output
EFFICIENCY (%)
22
VOUT (V)
BSZ110N06NS3 x4
LT4276
Typical Applications
4276f
SPARE
PAIRS
8
5
7
4
6
2
3
T2
BG45 TG45
IN78
IN45
IN36
IN12
TG12 BG12
Q5
Q3
Q7
Q9
Q6
Q8
LT4321
Q4
Q2
For more information www.linear.com/LT4276
47nF
100V
VPORT = 42.5V
VPORT = 50V
VPORT = 57V
4276 TA09a
107k
470pF
ITHB
8.25k
4.7nF
4276 TA09b
1µF
•
•
•
5.1Ω
1/4W
1nF
T1
OPTO
2.2nF
PE-68386NL 2KV
100Ω
BAT54WS
•
•
2.2nF
2kV
40mΩ
1/4W
100pF
100V
100Ω
1/4W
BSZ900N20NS3
VPORT = 42.5V
VPORT = 50V
VPORT = 57V
2k
6.49k
3.1
0.7 1.4 2.1 2.8 3.5 4.2 4.9 5.6 6.3 7.0
LOAD CURRENT (A)
3.2
3.3
3.4
3.5
0.1µF
ROSC
T2P
SG
ISEN–
ISEN+
VCC FB31
PG
Output Regulation
vs Load Current
6.81k
SFST
LT4276B
3.6
L4
100µH
10µF
BAV19WS 10V
FMMT723
20Ω
FFSDLY
35.7Ω
GND RCLASS
VPORT
VIN SWVCC
C7
2.2µF
HSSRC
HSGATE
47nF
100V
10µF
100V
PTVS58VP1UTP
8.2Ω
10nF
100V
Efficiency vs Load Current
24V
3.3k
+
72
0.7 1.4 2.1 2.8 3.5 4.2 4.9 5.6 6.3 7.0
LOAD CURRENT (A)
74
76
78
80
82
84
86
88
90
92
EN
OUTN
TG78 BG78
EN
OUTP
BG36 TG36
Q1
L2
10µH
L1: COILCRAFT, DO1813P-181HC
L2: COILCRAFT, DO1608C-103
L4: COILCRAFT, DO1608C-104
C2, C3: 22µF, 6.3V, MURATA GRM31CR70J226KE19
C5: 68µF, 4V, 4SVPA68MAA
C7: 2.2µF, 100V, MURATA GRM32ER72A225KA35
T1: WÜRTH, 750310743 OR PCA EPC3408G
Q1-Q9: PSMN075-100MSE
VOUT (V)
DATA
PAIRS 1
EFFICIENCY (%)
25.5W (Type 2) PoE+ Power Supply in Flyback Mode with 3.3V, 6.8A Output
10k
BAT46WS
15Ω
MMBT3904
4276 TA09
1µF
–VOUT
VOUT
3.3V AT 6.8A
TO MICROPROCESSOR
MMBT3906
2.2nF
47Ω
C5
68µF
PSMN2R4-30MLD
B0540WS
C2, C3
22µF||22µF
L1
180nH
LT4276
Typical Applications
4276f
23
SPARE
PAIRS
8
5
7
4
6
2
3
DATA
PAIRS 1
T2
BG45 TG45
IN78
IN45
IN36
IN12
TG12 BG12
Q5
Q3
Q7
Q9
Q6
Q8
LT4321
Q4
Q2
For more information www.linear.com/LT4276
47nF
100V
PTVS58VP1UTP
8.2Ω
10nF
100V
4276 TA10a
74
0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0
LOAD CURRENT (A)
3.3nF
160k
VPORT = 42.5V
VPORT = 50V
VPORT = 57V
VOUT vs Load Current
10pF
107k
4276 TA10b
•
40mΩ
1/4W
1µF
•
150pF
T1
•
OPTO
C5
22µF
10k
4276 TA10
0.1µF
–VOUT
VOUT
24V AT 1A
TO MICROPROCESSOR
BAT46WS
15Ω
MMBT3904
BSZ12DN20NS3
C2, C3
4.7µF
50V
MMBT3906
2.2nF
120Ω||120Ω
1/4W
•
•
2.2nF
2kV
2.2nF
PE-68386NL 2KV
100Ω
BAT54WS
23.0
0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0
LOAD CURRENT (A)
23.2
23.4
76
23.6
23.8
24.0
24.2
24.4
24.6
24.8
25.0
0.47µF
24k
ITHB
T2P
SG
ISEN–
ISEN+
100Ω
1/4W
47pF
100V
BSZ520N15NS3G
2.00kΩ
10µF
10V
VCC FB31
PG
6.49k
L4
100µH
SFST RLDCMP ROSC
LT4276B
BAV19WS
5.23k
78
VPORT = 42.5V
VPORT = 50V
VPORT = 57V
20Ω
FMMT723
FFSDLY
35.7Ω
GND RCLASS
VPORT
VIN SWVCC
C7
2.2µF
HSSRC
HSGATE
47nF
100V
10µF
100V
Efficiency vs Load Current
24V
3.3k
+
80
82
84
86
88
90
92
94
EN
OUTN
TG78 BG78
EN
OUTP
BG36 TG36
Q1
L2
10µH
L2: COILCRAFT, DO1608C-103
L4: COILCRAFT, DO1608C-104
C2: 4.7µF, 50V, MURATA GRM31CR71H475M012
C5: 22µF, 35V, PANASONIC EEH-ZA1V220R
C7: 2.2µF, 100V, MURATA GRM32ER72A225KA35
T1: WÜRTH, 750314782 OR PCA EPC3603G
Q1-Q9: PSMN075-100MSE
VOUT (V)
24
EFFICIENCY (%)
25.5W (Type 2) PoE+ Power Supply in Flyback Mode with 24V, 1A Output
LT4276
Typical Applications
4276f
LT4276
Package Description
Please refer to http://www.linear.com/designtools/packaging/ for the most recent package drawings.
UFD Package
28-Lead Plastic QFN (4mm × 5mm)
(Reference LTC DWG # 05-08-1712 Rev B)
0.70 ±0.05
4.50 ±0.05
3.10 ±0.05
2.50 REF
2.65 ±0.05
3.65 ±0.05
PACKAGE OUTLINE
0.25 ±0.05
0.50 BSC
3.50 REF
4.10 ±0.05
5.50 ±0.05
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED
4.00 ±0.10
(2 SIDES)
0.75 ±0.05
R = 0.05
TYP
PIN 1 NOTCH
R = 0.20 OR 0.35
× 45° CHAMFER
2.50 REF
R = 0.115
TYP
27
28
0.40 ±0.10
PIN 1
TOP MARK
(NOTE 6)
1
2
5.00 ±0.10
(2 SIDES)
3.50 REF
3.65 ±0.10
2.65 ±0.10
(UFD28) QFN 0506 REV B
0.25 ±0.05
0.200 REF
0.50 BSC
0.00 – 0.05
BOTTOM VIEW—EXPOSED PAD
NOTE:
1. DRAWING PROPOSED TO BE MADE A JEDEC PACKAGE OUTLINE MO-220 VARIATION (WXXX-X).
2. DRAWING NOT TO SCALE
3. ALL DIMENSIONS ARE IN MILLIMETERS
4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE
MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.15mm ON ANY SIDE
5. EXPOSED PAD SHALL BE SOLDER PLATED
6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION
ON THE TOP AND BOTTOM OF PACKAGE
4276f
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection
of its circuits
as described
herein will not infringe on existing patent rights.
For more
information
www.linear.com/LT4276
25
LT4276
Typical Application
25.5W (Type 2) PoE+ Power Supply in Flyback Mode with 12V, 1.9A
+
DATA
PAIRS
Q2
1
T2
2
3
Q4
SPARE
PAIRS
Q5
HSSRC
HSGATE
BG36 TG36
OUTP
IN36
IN45
5
7
8
Q8
Q9
T1
FDMC86160
470pF
13Ω
1/4W
MMBT3906
35.7Ω
SFST
ROSC
5.23k
15Ω
1µF
ITHB
107k
MMBT3904
2.2nF
100Ω
SG
47nF
100V
1µF
40mΩ
1/4W
T2P
FFSDLY
VOUT
12V AT 1.9A
–VOUT
ISEN–
VPORT
PTVS58VP1UTP
C5
22µF
BSZ520N15NS3G
LT4276B
GND RCLASS
Q7
•
47pF
630V
150V
1/4W
BAT54WS
8.2Ω
Q6
VCC FB31
PG
C2
10µF
ISEN+
EN
OUTN
TG78 BG78
BG45 TG45
2.00kΩ
VIN SWVCC
10nF
100V
47nF
100V
24V
LT4321
IN78
6.49k
3.3k
EN
4
20Ω
10µF
BAV19WS 10V
IN12
6
•
L4
FMMT723 100µH
Q3
TG12 BG12
•
L1
180nH
C7
2.2µF
10µF
100V
2.2nF
2kV
C5: 22µF, 16V, PANASONIC 16SVP22M
C7: 2.2µF, 100V, MURATA GRM32ER72A225KA35
T1: WÜRTH, 750310742 OR PCA EPC3410G
Q1-Q9: PSMN075-100MSE
L1: COILCRAFT, DO1813P-181HC
L2: COILCRAFT, DO1608C-103
L4: COILCRAFT, DO1608C-104
C2: 10µF, 16V, MURATA GRM31CR61C106KA88
L2
10µH
Q1
•
•
10k
BAT46WS
3.3nF
0.1µF
220pF
26.1k
10k
2.2nF VOUT
2KV
47k
TO MICROPROCESSOR
MOC207M
4276 TA11
Efficiency vs Load Current
Output Regulation vs Load Current
92
12.5
90
12.4
88
12.3
EFFICIENCY (%)
EFFICIENCY (%)
86
84
82
80
78
76
VPORT = 42.5V
VPORT = 50V
VPORT = 57V
74
72
70
0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0
LOAD CURRENT (A)
4276 TA11a
12.2
12.1
12.0
11.9
11.8
11.7
11.6
VPORT = 42.5V
VPORT = 50V
VPORT = 57V
11.5
0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0
LOAD CURRENT (A)
4276 TA11b
Related Parts
PART NUMBER
DESCRIPTION
COMMENTS
LTC4267/
LTC4267-1/
LTC4267-3
LTC4269-1
IEEE 802.3af PD Interface With Integrated Internal 100V, 400mA Switch, Programmable Class, 200/300kHz Constant Frequency
Switching Regulator
PWM
IEEE 802.3af PD Interface With Integrated
Flyback Switching Regulator
LTC4269-2
IEEE 802.3af PD Interface With Integrated
Forward Switching Regulator
LT4275A/B/C
LTPoE++/PoE+/PoE PD Controller
LTC4278
IEEE 802.3af PD Interface With Integrated
Flyback Switching Regulator
LTC4290/LTC4271 8-Port PoE/PoE+/LTPoE++ PSE Controller
LT4320/LT4320-1 Ideal Diode Bridge Controller
LT4321
PoE Ideal Diode Bridge Controller
2-Event Classification, Programmable Class, Synchronous No-Opto Flyback Controller,
50kHz to 250kHz, Aux Support
2-Event Classification, Programmable Class, Synchronous Forward Controller, 100kHz to
500kHz, Aux Support
External Switch, LTPoE++ Support
2-Event Classification, Programmable Class, Synchronous No-Opto Flyback Controller,
50kHz to 250kHz, 12V Aux Support
Transformer Isolation, Supports IEEE 802.3af, IEEE 802.3at and LTPoE++ PDs
9V-72V ,DC to 600Hz Input. Controls 4-NMOSFETs, Voltage Rectification without Diode Drops
Controls 8-NMOSFETs for IEEE-required PD Voltage Rectification without Diode Drops
26 Linear Technology Corporation
1630 McCarthy Blvd., Milpitas, CA 95035-7417
For more information www.linear.com/LT4276
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com/LT4276
4276f
LT 0615 • PRINTED IN USA
 LINEAR TECHNOLOGY CORPORATION 2015
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