LINER LTC4263CDE-1-TRPBF High power single pse controller with internal switch Datasheet

LTC4263-1
High Power
Single PSE Controller
with Internal Switch
FEATURES
DESCRIPTION
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The LTC®4263-1 is a high power, single PSE controller for
use in Power over Ethernet systems. The internal current
limit and short-circuit protection are designed to provide
up to 30W of PSE output power for power hungry PoE
applications such as WAPs, security cameras and RFID
readers.
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30W PSE Output Power
IEEE 802®.3af Compatible
Operation from a Single 56V Supply
Fully Autonomous Operation Without a
Microcontroller
Internal MOSFET with Thermal Protection
Precision Inrush Control with Internal Sense Resistor
Forced Current PD Detection for Noise Immunity
AC and DC Disconnect Sensing
Legacy PD Detection
Robust Short-Circuit Protection
Pin-Selectable Detection Backoff for Midspan PSEs
LED Driver Indicates Port On and Blinks
Status Codes
Available in a Miniature14-Pin 4mm × 3mm DFN
Package
APPLICATIONS
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High Power Endpoint/Midspan PSEs
Single-Port or Multi-Port Power Injectors
Low Port Count PSEs
Environment B PSEs
Standalone PSEs
The LTC4263-1 includes IEEE 802.3af compliant PD detection circuitry along with selectable AC and DC disconnect
sensing, allowing seamless operation in conventional
IEEE 802.3af systems as well as propriety, high power
applications. The LTC4263-1 simplifies PSE implementation, needing only a single supply and a small number of
passive support components. Onboard control algorithms
provide complete PSE functionality without the need of a
microcontroller and built-in foldback and thermal shutdown
provide comprehensive fault protection. An LED pin indicates the state of the port and detection backoff timing is
configurable for either endpoint or midspan operation.
The LTC4263-1 is available in a miniature 14-pin 4mm ×
3mm DFN package.
L, LT, LTC and LTM are registered trademarks of Linear Technology Corporation.
All other trademarks are the property of their respective owners.
TYPICAL APPLICATION
Single-Port Fully Autonomous High Power PSE
1A
+
0.1μF
100V
ISOLATED
56V SUPPLY
LED
0.1μF
LEGACY
MIDSPAN
–
0.1μF
100V
LTC4263-1
VSS
VDD5
VSS
SMAJ58A
TO PORT
MAGNETICS
SD
VDD48
VSS
OUT
VSS
OUT
OSC
ACOUT
42631 TA01
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1
LTC4263-1
ABSOLUTE MAXIMUM RATINGS
PIN CONFIGURATION
(Note 1, Note 2)
Supply Voltages
VSS – VDD48 ........................................... 0.3V to –80V
VDD5........................................VSS – 0.3V to VSS + 6V
Pin Voltages and Currents
LEGACY, MIDSPAN, SD, OSC ..VSS – 0.3V to VSS +6V
LED .......................................VSS – 0.3V to VSS + 80V
OUT, ACOUT ............................................ (See Note 3)
Operating Ambient Temperature Range
LTC4263CDE-1 ............................................ 0°C to 70°C
LTC4263IDE-1 ......................................... –40°C to 85°C
Junction Temperature (Note 4) ............................. 125°C
Storage Temperature Range................... –65°C to 150°C
Lead Temperature (Soldering, 10 sec) .................. 300°C
TOP VIEW
LED
1
14 VDD5
LEGACY
2
MIDSPAN
3
13 VSS
12 SD
15
VSS
4
VSS
5
10 OUT
VSS
6
9 OUT
OSC
7
8 ACOUT
11 VDD48
DE14 PACKAGE
14-LEAD (4mm s 3mm) PLASTIC DFN
TJMAX = 125°C, θJA = 43°C/W, θJC = 4.3°C/W
EXPOSED PAD (PIN 15) IS VSS, MUST BE SOLDERED TO PCB
ORDER INFORMATION
LEAD FREE FINISH
TAPE AND REEL
PART MARKING*
PACKAGE DESCRIPTION
TEMPERATURE RANGE
LTC4263CDE-1#PBF
LTC4263IDE-1#PBF
LTC4263CDE-1#TRPBF
LTC4263IDE-1#TRPBF
42631
42631
14-Lead (4mm × 3mm) Plastic DFN
14-Lead (4mm × 3mm) Plastic DFN
0°C to 70°C
–40°C to 85°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 non-standard 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/
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VDD48 – VSS = 48V and VDD5 not driven externally. All voltages are
relative to VSS unless otherwise noted. (Note 2, Note 5)
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
VSUPPLY
Supply Voltage
VDD48 – VSS
30W Output Power
VUVLO_OFF
UVLO Turn-Off Voltage
VDD48 – VSS Decreasing
VUVLO_HYS
UNITS
l
33
48
56
66
V
V
l
29
31
33
V
UVLO Hysteresis
l
0.1
1
V
VOVLO_OFF
OVLO Turn-Off Voltage
l
66
VOVLO_HYS
OVLO Hysteresis
l
0.2
VDD5
VDD5 Supply Voltage
Driven Externally
l
4.5
VDD5 Internal Supply
Driven Internally
l
4.3
IDD48
VDD48 Supply Current
l
l
IDD5
VDD5 Supply Current
VDD5 – VSS = 5V
Internal VDD5
VDD5 – VSS = 5V
Power Supplies
VDD48 – VSS Increasing
l
70
74
V
2
V
5
5.5
V
4.4
4.5
V
1
2
1
2
4
2
mA
mA
mA
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LTC4263-1
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VDD48 – VSS = 48V and VDD5 not driven externally. All voltages are
relative to VSS unless otherwise noted. (Note 2, Note 5)
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
RON
On-Resistance
I = 350mA, Measured From OUT to VSS
IOUT_LEAK
OUT Pin Leakage
VOUT – VSS = VDD48 – VSS = 57V
l
RPU
OUT Pin Pull-Up Resistance to VDD48
0V ≤ (VDD48 – VOUT) ≤ 5V
l
360
l
UNITS
1.5
1
2.4
3.0
10
Ω
Ω
μA
500
640
kΩ
540
570
600
mA
Power MOSFET
l
Current Control
ICUT
Overload Current Threshold
ILIM
Short-Circuit Current Limit
VOUT – VSS = 5V
VDD48 – VOUT = 30V
l
l
615
615
645
645
675
675
mA
mA
IFB
Foldback Current Limit
VDD48 – VOUT = 0V (Note 6)
VDD48 – VOUT = 10V
l
l
45
165
90
220
180
275
mA
mA
IMIN
DC Disconnect Current Threshold
IFAULT
High Speed Fault Current Limit
IDET
l
5.2
7.5
9.8
mA
(Note 7)
l
750
1000
1200
mA
Detection Current
First Point, VDD48 – VOUT = 10V
Second Point, VDD48 – VOUT = 3.5V
l
l
235
160
255
180
275
200
μA
μA
VDET
Detection Voltage Compliance
VDD48 – VOUT, Open Port
VDD48 – VSS = 57V
l
21
V
RDETMIN
Minimum Valid Signature Resistance
l
15.5
17
18.5
kΩ
RDETMAX
Maximum Valid Signature Resistance
l
27.5
29.7
32
kΩ
ROPEN
Open-Circuit Threshold
l
500
2000
kΩ
325
kΩ
140
μA
Detection
AC Disconnect
ROSC
OSC Pin Input Impedance
2V ≤ (VOSC – VSS) ≤ 3V
l
175
IOSC
OSC Pin Output Current
VOSC – VSS = 2V
l
–140
fOSC
OSC Pin Frequency
VOSC – VSS = 2V
l
103
110
115
Hz
AVACD
Voltage Gain OSC to ACOUT
2V ≤ (VOSC – VSS) ≤ 3V
l
0.95
1.0
1.05
V/V
IACDMAX
AC Disconnect Output Current
VOSC – VSS = 2V, 0V ≤ (VACOUT – VSS) ≤ 4V
l
–1
1
mA
130
190
μA
1.5
IACDMIN
Remain Connected AC Pin Current
VOSC – VSS = 2V
l
VACDEN
AC Disconnect Enable Signal
VOSC – VSS, Port On
l
250
160
V
Digital Interface (Note 8)
VOLED
LED Output Low Voltage
ILED = 10mA
l
VILD
Digital Input Low Voltage
MIDSPAN, SD
LEGACY
l
l
VIHD
Digital Input High Voltage
MIDSPAN, SD
LEGACY
l
l
2.2
2.2
VOZ
Voltage of Legacy Pin if Left Floating
l
1.1
IOLEG
Current In/Out of Legacy Pin
l
l
IFLT
Maximum Allowed Leakage at Legacy
Pin When Floating
0V ≤ (VLEGACY – VSS) ≤ 5V
1.1
2.2
V
0.8
0.4
V
V
V
V
1.25
1.4
V
–60
60
μA
–10
10
μA
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LTC4263-1
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VDD48 – VSS = 48V and VDD5 not driven externally. All voltages are
relative to VSS unless otherwise noted. (Note 2, Note 5)
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
290
310
ms
620
ms
155
ms
Timing Characteristics
tDET
Detection Time
Beginning to End of Detection
l
270
tDETDLY
Detection Delay
PD Insertion to Detection Complete
l
300
tPON
Power Turn-On Delay
End of Valid Detect to Application of Power
l
135
145
tRISE
Turn-On Rise Time
VDD48 – VOUT : 10% to 90%
CPSE = 0.1μF
l
40
170
tOVLD
Overload/Short-Circuit Time Limit
tED
Error Delay
tMPDO
μs
l
52
62
72
ms
ICUT Fault to Next Detect
l
3.8
4.0
4.2
s
Maintain Power Signature (MPS)
Disconnect Delay
PD Removal to Power Removal
l
320
350
380
ms
tMPS
MPS Minimum Pulse Width
PD Minimum Current Pulse Width
Required to Stay Connected (Note 9)
l
20
ms
tDBO
Midspan Mode Detection Backoff
RPORT = 15.5kΩ
l
3.0
3.2
3.4
s
tDISDLY
Power Removal Detection Delay
l
0.8
0.95
1.1
s
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 currents into device pins are positive; all currents out of device
pins are negative. All voltages are referenced to VSS unless otherwise
specified.
Note 3: 80mA of current may be pulled from the OUT or ACOUT pin
without damage whether the LTC4263-1 is powered or not. These pins will
also withstand a positive voltage of VSS + 80V.
Note 4: This IC includes overtemperature protection that is intended
to protect the device during momentary overload conditions. Junction
temperature will exceed 125°C when overtemperature protection is active.
Continuous operation above the specified maximum operating junction
temperature may impair device reliability.
Note 5: The LTC4263-1 operates with a negative supply voltage. To avoid
confusion, voltages in this data sheet are referred to in terms of absolute
magnitude.
Note 6: In order to reduce power dissipated in the switch while charging
the PD, the LTC4263-1 reduces the current limit when VOUT – VSS is large.
Refer to the Typical Performance Characteristics for more information.
Note 7: The LTC4263-1 includes a high-speed current limit circuit
intended to protect against faults. The fault protection is activated
for port current in excess of IFAULT. After the high-speed current limit
activates, the short-circuit current limit (ILIM) engages and restricts
current to IEEE 802.3af levels.
Note 8: The LTC4263-1 digital interface operates with respect to VSS.
All logic levels are measured with respect to VSS.
Note 9: The IEEE 802.3af specification allows a PD to present its
Maintain Power Signature (MPS) on an intermittent basis without being
disconnected. In order to stay powered, the PD must present the MPS for
tMPS within any tMPDO time window.
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LTC4263-1
TYPICAL PERFORMANCE CHARACTERISTICS
Powering a Legacy PD with
470μF Bypass Capacitor
Powering an IEEE 802.3af PD
VDD48
VOUT
10V/DIV
DETECTION DETECTION
PHASE 1
PHASE 2
POWER
ON
VDD48
VOUT
20V/DIV
VDD48
VSS
VOUT
10V/DIV
tED
LOAD
FULLY
CHARGED
570mA CURRENT LIMIT
600mA
IOUT
300mA/DIV
0mA
VSS
100ms/DIV
FOLDBACK
42631 G01
VSS
IPORT
1A/DIV
500ms/DIV
42631 G02
25ms/DIV
Midspan Backoff with Invalid PD
VDD48
Overload Restart Delay
Response to PD Removal with
AC Disconnect Enabled
Overcurrent Response Time
VDD48
tDBO
VDD48
VOUT
20V/DIV
PORT OFF
VOUT
10V/DIV
VSS
VOUT
2V/DIV
PD REMOVAL
600mA
IOUT
300mA/DIV
0mA
RPORT = 15.5k
500ms/DIV
tOVLD
10ms/DIV
tMPDO
42631 G12
VDD48
VDD48
VOUT
20V/DIV
VOUT
20V/DIV
1Ω SHORT
APPLIED
IPORT = CURRENT IN
1Ω RESISTOR APPLIED
TO OUTPUT OF CIRCUIT
ON FRONT PAGE
1μs/DIV
50ms/DIV
42631 G13
Rapid Response to
Momentary 33Ω Short
Rapid Response to 1Ω Short
IPORT 20A
20A/DIV 0A
PORT OFF
VSS
LOAD
APPLIED
42631 G11
VSS
42631 G10
42631 G14
VSS
600mA
IPORT
300mA/DIV
0mA
33Ω SHORT APPLIED
SHORT
CURRENT
REMOVED
LIMIT ACTIVE
FOLDBACK CURRENT LIMIT
100μs/DIV
42631 G15
IPORT = CURRENT IN 33Ω RESISTOR APPLIED
TO OUTPUT OF CIRCUIT ON FRONT PAGE
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LTC4263-1
TYPICAL PERFORMANCE CHARACTERISTICS
675
4
450
375
300
225
150
TA = 25°C
25k LOAD WITH
AC ENABLED
2.0
3
IDD48 (mA)
VLED PIN PULL-DOWN (V)
525
2.5
TA = 25°C
INTERNAL VDD5
600
IOUT (mA)
IDD48 DC Supply Current vs Supply
Voltage with Internal VDD5
LED Pin Pull-Down
vs Load Current
Current Limit and Foldback
2
1
1.5
NO LOAD
1.0
0.5
75
0
0
0
5
10 15 20 25 30 35 40 45 50
VDD48 – VOUT (V)
0
10
20
30
40
ILED LOAD CURRENT (mA)
0
50
42631 G03
25k LOAD WITH
AC ENABLED
1.0
30
40
VDD48 (V)
50
60
42631 G07
IDD5 DC Supply Current
vs Supply Voltage
2
TA = 25°C
20
42631 G04
IDD48 DC Supply Current vs
Supply Voltage with VDD5 = 5V
1.2
10
0
VDD48 = 48V
25k LOAD WITH
AC ENABLED
1
NO LOAD
IDD5 (mA)
IDD48 (mA)
0.8
NO LOAD
0.6
0
–1
0.4
–2
0.2
0
–3
0
10
20
30
40
50
60
4.5
4.0
VDD48 (V)
5.0
VDD5 (V)
5.5
6.0
42631 G08
42631 G09
RON vs Temperature
Legacy Pin Current vs Voltage
40
2.0
LEGACY MODE
20
ILEGACY (μA)
RON (Ω)
1.8
1.6
1.4
FORCE POWER ON MODE
0
–20
1.2
1.0
–40
COMPLIANT DETECTION MODE
–40
–20
40
20
0
60
TEMPERATURE (°C)
80
100
42631 G16
0
1
3
2
VLEGACY (V)
4
5
42631 G17
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LTC4263-1
TEST TIMING
Detect and Turn-On Timing
Current Limit Timing
PD
INSERTED
ILIM
IOUT
VDD48
ICUT
tOVLD
VDD48
VOUT
tDET
VSS
VOUT
42631 TT02
PORT
TURN-ON
tDETDLY
tPON
42631 TT01
DC Disconnect Timing
IOUT
AC Disconnect Timing
IMIN
VOSC
VDD48
VDD48
VOUT
VSS
VOUT
tMPS
tMPDO
VSS
42631 TT03
IACOUT
IACDMIN
PD REMOVED
tMPDO
42631 TT04
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LTC4263-1
PIN FUNCTIONS
LED (Pin 1): Port State LED Drive. This pin is an opendrain output that pulls down when the port is powered.
Under port fault conditions, the LED will flash in patterns
to indicate the nature of the port fault. See the Applications
Information section for a description of these patterns.
When the LTC4263-1 is operated from a single 48V supply, this pin is pulsed low with a 6% duty cycle during
the periods when the LED should be on. This allows use
of a simple inductor, diode, and resistor circuit to avoid
excess heating due to the large voltage drop from VDD48.
See the Applications Information section for details on
this circuit.
LEGACY (Pin 2): Legacy Detect. This pin controls whether
legacy detect is enabled. If held at VDD5, legacy detect is
enabled and testing for a large capacitor is performed to
detect the presence of a legacy PD on the port. See the
Applications Information section for descriptions of legacy
PDs that can be detected. If held at VSS, only IEEE 802.3af
compliant PDs are detected. If left floating, the LTC4263-1
enters force-power-on mode and any PD that generates
between 1V and 10V when biased with 270μA of detection
current will be powered as a legacy device. This mode is
useful if the system uses a differential detection scheme
to detect legacy devices.
MIDSPAN (Pin 3): Midspan Enable. If this pin is connected
to VDD5, Midspan backoff is enabled and a 3.2 second
delay occurs after every failed detect cycle unless the
result is open circuit. If held at VSS, no delay occurs after
failed detect cycles.
VSS (Pins 4, 5, 6, 13): Negative Power Supply. Pins 4, 5,
6 and 13 should be tied together on the PCB. For optimum
power delivery, supply voltage should be maximized. See
Applications Information section for more information.
ACOUT (Pin 8): AC Disconnect Sense. Senses the port
to determine whether a PD is still connected when in AC
disconnect mode. If port capacitance drops below about
0.15μF for longer than TMPDO the port is turned off. If
AC disconnect is used, connect this pin to the port with
a series combination of a 1k resistor and a 0.47μF 100V
X7R capacitor. See the Applications Information section
for more information.
OUT (Pins 9, 10): Port Output. If DC disconnect is used,
these pins are connected to the port. If AC disconnect is
used, these pins are connected to the port through a parallel
combination of a 1A diode and a 500k resistor. Pins 9 and
10 should be tied together on the PCB. See the Applications
Information section for more information.
VDD48 (Pin 11): Power Return for VSS. Must be bypassed
with a 0.1μF capacitor to VSS. For optimum power delivery,
supply voltage should be maximized. See Applications
Information section for more information.
SD (Pin 12): Shutdown. If held low, the LTC4263-1 is
prevented from performing detection or powering the port.
Pulling SD low will turn off the port if it is powered. When
released, a 4-second delay will occur before detection is
attempted. If not used, tie to VDD5.
VDD5 (Pin 14): Logic Power Supply. Apply 5V referenced
to VSS, if such a supply is available, or place a 0.1μF
bypass capacitor to VSS to enable the internal regulator.
When the internal regulator is used, this pin should only
be connected to the bypass capacitor and to any logic pins
of the LTC4263-1 that are being held at VDD5.
Exposed Pad (Pin 15): VSS. Must be connected to VSS
on the PCB. The Exposed Pad acts as a heat sink for the
internal MOSFET.
OSC (Pin 7) Oscillator for AC Disconnect. If AC disconnect is used, connect a 0.1μF X7R capacitor from OSC to
VSS. Tie OSC to VSS to disable AC disconnect and enable
DC disconnect.
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LTC4263-1
BLOCK DIAGRAM
1A
11
14
VDD5
VDD5
RLED
INT5 EXT5
VDD48
12 SD
5V REG
0.1μF
2 LEGACY
3 MIDSPAN
+
1
56V
3
LED
–
TO PORT
MAGNETICS
500k
CONTROL
+
SMAJ58A
5V
–
Hot SwapTM
13
4
5
6
IDET
500k
9
VSS
10
OUT
0.47μF
0.1μF
1k
7
OSC
BOLD LINES INDICATE HIGH CURRENT
Hot Swap IS A TRADEMARK OF LINEAR TECHNOLOGY CORPORATION
8
ACOUT
42631 BD
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LTC4263-1
APPLICATIONS INFORMATION
POE OVERVIEW
A PSE is required to provide 44V to 57V DC between
either the signal pairs or the spare pairs as shown in
Figure 1. The power is applied as a voltage between two
of the pairs, typically by powering the center taps of the
isolation transformers used to couple the differential
data signals to the wire. Since Ethernet data is transformer coupled at both ends and is sent differentially,
a voltage difference between the transmit pairs and the
receive pairs does not affect the data. A 10Base-T/
100Base-TX Ethernet connection only uses two of the four
pairs in the cable. The unused or spare pairs can optionally be powered directly, as shown in Figure 1, without
affecting the data. 1000Base-T uses all four pairs and
power must be connected to the transformer center taps
if compatibility with 1000Base-T is required.
Over the years, twisted-pair Ethernet has become the most
commonly used method for local area networking. The
IEEE 802.3 group, the originator of the Ethernet standard,
has defined an extension to the standard, IEEE 802.3af,
which allows DC power to be delivered simultaneously
over the same cable used for data communication. This
has enabled a whole new class of Ethernet devices, including IP telephones, wireless access points, and PDA
charging stations which do not require additional AC
wiring or external power transformers, a.k.a. “wall warts.”
These small data devices can now be powered directly from
their Ethernet connection. Sophisticated detection and
power monitoring techniques prevent damage to legacy
data-only devices while still supplying power to newer,
Ethernet-powered devices over the twisted-pair cable.
The LTC4263-1 provides a complete high power PSE
solution for powering newer power hungry PDs such as
dual-radio wireless access points, security cameras and
RFID readers. With proper system design, proprietary high
power PoE solutions using the LTC4263-1 can deliver 25W
(min) to a high power 2-pair PD at the end of a 100 meter
CAT5 cable and 50W (min) using a 4-pair solution.
The device that supplies power is called the Power Sourcing Equipment (PSE). A device that draws power from the
wire is called a Powered Device (PD). A PSE is typically an
Ethernet switch, router, hub, or other network switching
equipment that is commonly found in the wiring closets
where cables converge. PDs can take many forms. Digital
IP telephones, wireless network access points, PDA or
notebook computer docking stations, cell phone chargers,
and HVAC thermostats are examples of devices that can
draw power from the network.
PSE
RJ45
4
CAT 5
CABLE
5
PD
RJ45
4
5
1N4002
s4
SPARE PAIR
+
0.1μF
0.1μF
VDD48
1
1
2
2
Tx
SMAJ58A
58V
Rx
DATA PAIR
CIN ≥ 5mF
LTC4263-1
56V
3
VDD5
3
Rx
Tx
6
0.1μF
–
The LTC4263-1 provides a high power PSE solution while
simultaneously being compatible with existing IEEE 802.3af
systems. By maintaining a compliant detection protocol,
the LTC4263-1 insures legacy data-only devices are not
DATA PAIR
6
1N4002
s4
SMAJ58A
58V
VSS
OUT
7
7
6
6
0.1μF
GND
RCLASS
–48VOUT
LTC4264-BASED
OUT
PD/SWITCHER
–48VIN
+
VOUT
–
SPARE PAIR
42631 F01
Figure 1. 2-Pair High Power PoE System Diagram
42631fa
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LTC4263-1
accidentally powered. Disconnect with either AC or DC
methods using the LTC4263-1 is fully compliant and
insures safe power removal after PD disconnect. Command and control for the LTC4263-1 is handled internally
without the need of a microcontroller, thereby simplifying
system design.
LTC4263-1 OPERATION
The IEEE 802.3af specification defines a specific pair-topair signature resistance used to identify a device that
can accept power via its Ethernet connection. When the
port voltage is below 10V, an IEEE 802.3af compliant
PD will have an input resistance of approximately 25kΩ.
Figure 2 illustrates the relationship between the PD signature resistance and the required resistance ranges the
PSE must accept and reject. According to the IEEE 802.3af
specification, the PSE must accept PDs with signatures
between 19kΩ and 26.5kΩ and may or may not accept
resistances in the two ranges of 15kΩ to 19kΩ and 26.5kΩ
to 33kΩ. The black box in Figure 2 represents the typical
150Ω pair-to-pair termination used in Ethernet devices
like a computer’s network interface card (NIC) that cannot
accept power.
10k
20k
30k
23.75k 26.25k
PD
PSE
255
25k | SLOPE
180
VALID PD
Signature Detection
RESISTANCE 0Ω
CURRENT (μA)
APPLICATIONS INFORMATION
150Ω (NIC)
REJECT
ACCEPT
15k
19k
0V-2V
OFFSET
FIRST
DETECTION
POINT
SECOND
DETECTION
POINT
VOLTAGE
42631 F03
Figure 3. PD 2-Point Detection
The LTC4263-1 uses a force-current detection method in
order to reduce noise sensitivity and provide a more robust
detection algorithm. The first test point is taken by forcing
a test current into the port, waiting a short time to allow
the line to settle and measuring the resulting voltage. This
result is stored and the second current is applied to the
port, allowed to settle and the voltage measured.
The LTC4263-1 will not power the port if the PD has more
than 5μF in parallel with its signature resistor unless legacy
mode is enabled.
The LTC4263-1 autonomously tests for a valid PD connected to the port. It repeatedly queries the port every
580ms, or every 3.2s if midspan backoff mode is active
(see below). If detection is successful, it then powers up
the port.
REJECT
26.5k
33k
42631 F02
Figure 2. IEEE 802.3af Signature Resistance Ranges
The LTC4263-1 checks for the signature resistance by
forcing two test currents on the port in sequence and
measuring the resulting voltages. It then subtracts the two
V-I points to determine the resistive slope while removing voltage offset caused by any series diodes or current
offset caused by leakage at the port (see Figure 3). The
LTC4263-1 will typically accept any PD resistance between
17kΩ and 29.7kΩ as a valid PD. Values outside this range
(excluding open and short-circuits) are reported to the
user by a code flashed via the LED pin.
Midspan Backoff
IEEE 802.3af requires the midspan PSE to wait two seconds
after a failed detection before attempting to detect again
unless the port resistance is greater than 500kΩ. This
requirement is to prevent the condition of an endpoint PSE
and a midspan PSE, connected to the same PD at the same
time, from each corrupting the PD signature and preventing power-on. After the first corrupted detection cycle, the
midspan PSE waits while the endpoint PSE completes
detection and turns the port on. If the midspan mode of
the LTC4263-1 is enabled by connecting the MIDSPAN
pin to VDD5, a 3.2 second delay occurs after every failed
detect cycle unless the result is an open circuit.
42631fa
11
LTC4263-1
APPLICATIONS INFORMATION
Power Control
The primary function of the LTC4263-1 is to control the
delivery of power to the PSE port. In order to provide
a robust solution, a variety of current limit and current
monitoring functions are needed, as shown in Figure 4. All
control circuitry is integrated and the LTC4263-1 requires
no external MOSFET, sense resistor, or microcontroller.
The LTC4263-1 includes an internal MOSFET for driving
the PSE port. The LTC4263-1 drives the gate of the internal
MOSFET while monitoring the current and the output voltage at the OUT pin. This circuitry couples the 56V input
supply to the port in a controlled manner that satisfies
the PD’s power needs while minimizing disturbances on
the 56V backplane.
PORT CURRENT
750mA
CURRENT LIMIT
PORT OFF IN tOVLD
600mA
450mA
NORMAL
OPERATION
300mA
DC DISCONNECT CUT
(IMIN)
(ICUT)
LIMIT
(ILIM)
If at any time the port is shorted or an excessive load
is applied, the LTC4263-1 limits port current to avoid a
hazardous condition. The current is limited to ILIM for port
voltages above 30V and is reduced for lower port voltages
(see the Foldback section). Inrush and short-circuit current limit are allowed to be active for 62ms (typ) before
the port is shut off.
Port Fault
If the port is suddenly shorted, the internal MOSFET power
dissipation can rise to very high levels until the short-circuit
current limit circuit can respond. A separate high-speed
current limit circuit detects severe fault conditions (IOUT >
1000mA (typ)) and quickly turns off the internal MOSFET if
such an event occurs. The circuit then limits current to ILIM
while the tOVLD timer increments. During a short-circuit,
ILIM will be reduced by the foldback circuitry.
tOVLD Timing
150mA
0mA
rise until the PD reaches its input turn-on threshold. At this
point, the PD begins to draw current to charge its bypass
capacitance, slowing the rate of port voltage increase.
DC DISCONNECT
PORT OFF IN tMPDO
42631 F07
Figure 4. Current Thresholds and Current Limits
Port Overload
Based on the IEEE 802.3af standard, the LTC4263-1 detects
port overload conditions by monitoring port current. This
ensures the port stays within the designed continuous
power budget while allowing for brief power surges. If
the port current exceeds 570mA (typ) for greater than
62ms (typ), power is removed and the LTC4263-1 waits
4 seconds (typ) before returning to detection mode.
Port Inrush and Short-Circuit
When 56V power is applied to the port, the LTC4263-1 is
designed to power-up the PD in a controlled manner without causing transients on the input supply. To accomplish
this, the LTC4263-1 implements inrush current limit. At
turn-on, current limit will allow the port voltage to quickly
For overload, inrush, and short-circuit conditions, the
LTC4263-1 includes a 62ms (typ) tOVLD timer to limit the
duration of these events. The timer is incremented whenever current greater than ICUT flows through the port. If
the current is still above ICUT when the tOVLD timer expires,
the LTC4263-1 will turn off power to the port and flash the
LED. In this situation, the LTC4263-1 waits four seconds
and then restarts detection. If the overload condition is
removed before the t OVLD timer expires, the port stays
powered and the timer is reset.
Foldback
Foldback is designed to limit power dissipation in the
LTC4263-1 during power-up and momentary short-circuit conditions. At low port output voltages, the voltage
across the internal MOSFET is high, and power dissipation will be large if significant current is flowing. Foldback
monitors the port output voltage and reduces the ILIM
current limit level for port voltages of less than 28V, as
shown in Figure 5.
42631fa
12
LTC4263-1
APPLICATIONS INFORMATION
If the undercurrent condition goes away before tMPDO
(350ms (typ)), the timer is reset to zero. The DC disconnect circuit includes a glitch filter to prevent noise from
falsely resetting the timer. The current must be present for
a period of at least 20ms to guarantee reset of the timer.
To enable DC disconnect, tie the OSC pin to VSS .
750
ILIM (mA)
600
450
300
AC Disconnect
150
0
5
0
10 15 20 25 30 35 40 45 50
VDD48 – VOUT (V)
42631 F07
Figure 5. Current Limit Foldback
Thermal Protection
The LTC4263-1 includes thermal overload protection in
order to provide full device functionality in a miniature
package while maintaining safe operating temperatures.
Several factors create the possibility for very large power
dissipation within the LTC4263-1. At port turn-on, while
ILIM is active, the instantaneous power dissipated by the
LTC4263-1 can be as high as 18W. This can cause 40ºC or
more of die heating in a single turn-on sequence. Similarly,
excessive heating can occur if an attached PD repeatedly
pushes the LTC4263-1 into ILIM by drawing too much
current. Excessive heating can also occur if the VDD5 pin
is shorted or overloaded.
AC disconnect is an alternate method of sensing the presence or absence of a PD by monitoring the port impedance.
The LTC4263-1 forces an AC signal from an internal sine
wave generator on to the port. The ACOUT pin current is
then sampled once per cycle and compared to IACDMIN.
Like DC disconnect, the AC disconnect sensing circuitry
controls the tMPDO disconnect timer. When the connection
impedance rises due to the removal of the PD, AC peak
current falls below IACDMIN and the disconnect timer increments. If the impedance remains high (AC peak current
remains below IACDMIN), the disconnect timer counts to
tMPDO and the port is turned off. If the impedance falls,
causing AC peak current to rise above IACDMIN for two
consecutive samples before the maximum count of the
disconnect timer, the timer resets and the port remains
powered.
DC Disconnect
The AC disconnect circuitry senses the port via the ACOUT
pin. Connect a 0.47μF 100V X7R capacitor (CDET) and a 1k
resistor (RDET) from the DETECT pin to the port output as
shown in Figure 6. This provides an AC path for sensing
the port impedance. The 1k resistor, RDET, limits current
flowing through this path during port power-on and poweroff. An AC blocking diode (DAC) is inserted between the
OUT pin and the port to prevent the AC signal from being
shorted by the LTC4263-1’s power control MOSFET. The
500k resistor across DAC allows the port voltage to decay
after disconnect occurs.
The DC disconnect circuit monitors port current whenever
power is on to detect continued presence of the PD. IEEE
802.3af mandates a minimum current of 10mA that the
PD must draw for periods of at least 75ms with optional
dropouts of no more than 250ms. The tMPDO disconnect
timer increments whenever port current is below 7.5mA
(typ). If the timer expires, the port is turned off and the
LTC4263-1 waits 1.5 seconds before restarting detection.
Sizing of capacitors is critical to ensure proper function
of AC disconnect. CPSE (Figure 6) controls the connection
impedance on the PSE side. Its capacitance must be kept
low enough for AC disconnect to be able to sense the PD.
On the other hand, CDET has to be large enough to pass
the signal at 110Hz. The recommended values are 0.1μF
for CPSE and 0.47μF for CDET. The sizes of CPSE, CDET,
and RDET are chosen to create an economical, physically
The LTC4263-1 protects itself from thermal damage by
monitoring die temperature. If the die temperature exceeds
the overtemperature trip point, the LTC4263-1 removes
port power and shuts down all functions including the
internal 5V regulator. Once the die cools, the LTC4263-1
waits four seconds, then restarts detection.
42631fa
13
LTC4263-1
APPLICATIONS INFORMATION
1A
+
0.1μF
100V
ISOLATED
56V SUPPLY
CPSE
0.1μF
X7R, 100V
LTC4263-1
NC
0.1μF
LED
LEGACY
MIDSPAN
–
0.1μF
X7R
VDD5
SMAJ58A
VSS
500k
SD
VSS
VDD48
VSS
OUT
VSS
OUT
CMLSH05-4
42631 F06
DAC
RDET
1k
OSC
CDET
0.47μF
X7R, 100V
ACOUT
Figure 6. LTC4263-1 Using AC Disconnect
compact and functionally robust system. Moreover, the
complete Power over Ethernet AC disconnect system (PSE,
transformers, cabling, PD, etc.) is complex; deviating from
the recommended values of CDET, RDET and CPSE is strongly
discouraged. Contact the Linear Technology Applications
department for additional support.
Internal 110Hz AC Oscillator
The LTC4263-1 includes onboard circuitry to generate
a 110Hz (typ), 2VP-P sine wave on its OSC pin when a
0.1μF capacitor is connected between the OSC pin and
VSS. This sine wave is synchronized to the controller
inside the LTC4263-1 and should not be externally driven.
Tying the OSC pin to VSS shuts down the oscillator and
enables DC disconnect.
Power-On Reset and Reset/Backoff Timing
Upon startup, the LTC4263-1 waits four seconds before
starting its first detection cycle. Depending on the results
of this detection it will either power the port, repeat detection, or wait 3.2 seconds before attempting detection again
if in midspan mode.
The LTC4263-1 may be reset by pulling the SD pin low.
The port is turned off immediately and the LTC4263-1 sits
idle. After SD is released there will be a 4-second delay
before the next detection cycle begins.
VDD5 Logic-Level Supply
The VDD5 supply for the LTC4263-1 can either be supplied
externally or generated internally from the VDD48 supply.
If supplied externally, a voltage between 4.5V and 5.5V
should be applied to the VDD5 pin to cause the internal
regulator to shut down. If VDD5 is to be generated internally, the voltage will be 4.4V (typ) and a 0.1μF capacitor
should be connected between VDD5 and VSS. Do not
connect the internally generated VDD5 to anything other
than a bypass capacitor and the logic control pins of the
same LTC4263-1.
LED Flash Codes
The LTC4263-1 includes a multi-function LED driver to
inform the user of the port status. The LED is turned on
when the port is connected to a PD and power is applied. If
the port is not connected or is connected to a non-powered
device with a 150Ω or shorted termination, the port will
not be powered and the LED will be off. For other port
conditions, the LTC4263-1 blinks a code to communicate
the status to the user as shown in Table 1. One flash indicates low signature resistance, two flashes indicates high
resistance and five flashes indicates an overload fault.
When active, the LED flash codes are repeated every 1.2
seconds. The duration of each LED flash is 75ms. Multiple
LED flashes occur at a 300ms interval.
The LTC4263-1 includes a feature for efficiently driving
the LED from a 56V power supply without the wasted
power caused by having to drop over 52V in a current limit
resistor. When operating the VDD5 supply internally, the
LTC4263-1 drives the LED pin with a 6% duty cycle PWM
signal. This allows use of the simple LED drive circuit in
Figure 7 to minimize power dissipation. The modulation
frequency of the LED drive is 28kHz, making the on period
42631fa
14
LTC4263-1
APPLICATIONS INFORMATION
Table 1. Port Status and LED Flash Codes
PORT STATUS
LED FLASH CODE
FLASH PATTERN
Non-Powered Device
0Ω < RPORT < 200Ω
Off
LED Off
Port Open
RPORT > 1MΩ
Off
LED Off
Port On
25kΩ
On
LED On
Low Signature Resistance
300Ω < RPORT < 15kΩ
1 Flash
High Signature Resistance
33kΩ < RPORT < 500kΩ
2 Flashes
Port Overload Fault
5 Flashes
EXTERNAL COMPONENT SELECTION
VDD48
This section discusses the other elements needed to make
a system including the LTC4263-1 function correctly. It is
recommended to adhere closely to the example application
circuits provided. For further assistance contact the Linear
Technology Applications department.
D1
10mH, 21mA
COILCRAFT
DS1608C-106
D2
BAS19
RLED
1k
PoE System Power Delivery
LED
VDD48
LTC4263-1
VDD5
0.1μF
VSS
4263 F07
Figure 7. LED Drive Circuit with Single 48V Supply
2.2μs. During the 2.2μs that the LED pin is pulled low, current ramps up in the inductor, limited by RLED. Diode D2
completes the circuit by allowing current to circulate while
the LED pin is open circuit. Since current is only drawn
from the power supply 6% of the time, power dissipation
is substantially reduced.
When VDD5 is powered from an external supply, the PWM
signal is disabled and the LED pin will pull down continuously when on. In this mode, the LED can be powered from
the 5V supply with a simple series resistor.
The LTC4263-1 can output over 30W(typ) and is designed
to deliver 25W(min) to the PD over a 100 meter CAT5
cable for high power applications such as wireless access
points, security cameras and RFID readers. There are
several parameters external to the LTC4263-1 that limit
the power available to the PD. Figure 8 provides a simple
model used to calculate this power delivery.
The primary element affecting the delivery of power to the
PD is the supply feeding the LTC4263-1. By maximizing
this voltage, the highest and most efficient power delivery
can be obtained. However, in order to adhere to common
safety requirements, the supply is normally limited to
60V and the IEEE 802.3af committee has chosen 57V as
a nominal maximum. In this example, a 56±1V power
supply output sets the lower limit to 55V. The LTC4263-1
overload current limit monitors port current and removes
42631fa
15
LTC4263-1
APPLICATIONS INFORMATION
POUT(MIN)
= 28.8W (MIN, DC DISCONNECT)
= 28.5W (MIN, AC DISCONNECT)
POWER (MIN)
= 55V (MIN) • 540mA (MIN)
= 29.7W (MIN)
LTC4263-1
POWER
SUPPLY
VSUPPLY
55V TO 57V
ICUT(MIN) = 540mA
RON(MAX) = 3Ω
CABLE LOSS (MAX)
= (540mA)2 • 12.5Ω
= 3.6W
AC
DISCONNECT
DIODE
(OPTIONAL)
PD
100M CAT5 CABLE
12.5Ω (MAX)
PLOSS_AC DIODE(MAX)
= 0.5V • 540mA
= 0.3W (MAX)
PLOSS_4263-1(MAX)
= (540mA)2 • 3Ω
= 0.9W (MAX)
42631 F08
POUT(MIN)
= 25.2W (MIN, DC DISCONNECT)
= 24.9W (MIN, AC DISCONNECT)
Figure 8. Example of Power Delivery Calculation Using the LTC4263-1
power if the port exceeds 540mA(min). This sets the
maximum system operating current and along with the
working voltage, limits the power available to the PD. The
power at the PSE output is reduced by the resistance of
the LTC4263-1 internal power MOSFET and the voltage
drop of the AC blocking diode if used for AC disconnect
as shown in Figure 8. The cabling can be responsible for
the largest loss. In our example based on a worst-case
100 meter CAT5 cable and connectors, the power loss can
be as much as 3.6W. Obviously for shorter cable runs the
loss is less and lower resistance cables such as CAT6 will
have correspondingly lower losses.
The total power available at the PD can be calculated taking
in to account these losses using the formula:
(
PPD = (VSUPPLY • ICUT ) – ICUT 2 • RON
(
)
– (VDAC • ICUT ) – ICUT 2 • RCABLE
)
For many PoE systems, the only parameter affecting power
delivery that is under the control of the PSE designer is the
power supply. Optimum power delivery can be obtained
by maximizing this power supply voltage. 4-pair systems
can be treated as two independent 2-pair systems and
therefore the power will be twice that of the 2-pair.
2-Pair vs 4-Pair
One of the basic architectural decisions associated with
a high power PoE system is whether to deliver power
using four conductors (2-pair) or all eight conductors
(4-pair). Each method provides advantages and the
system vendor needs to decide which method best suits
their application.
2-pair power is used today in IEEE 802.3af systems (see
Figure 1). One pair of conductors is used to deliver the
current and a second pair is used for the return while two
conductor pairs are not powered. This architecture offers
the simplest implementation method but suffers from
higher cable loss than an equivalent 4-pair system.
4-pair power delivers current to the PD via two conductor
pairs in parallel (Figure 9). This lowers the cable resistance but raises the issue of current balance between
each conductor pair. Differences in resistance of the
transformer, cable and connectors along with differences
in diode bridge forward voltage in the PD can cause an
imbalance in the currents flowing through each pair. The
4-pair system in Figure 9 solves this problem by using
two independent DC/DC converters in the PD. Using a
2-pair architecture with the LTC4263-1 allows delivery of
25W to the PD while using a 4-pair architecture allows
delivery of 50W. Contact Linear Technology applications
support for detailed information on implementing 2-pair
and 4-pair PoE systems.
Common Mode Chokes
Both non-powered and powered Ethernet connections
achieve best performance for data transfer and EMI when a
common mode choke is used on each port. For cost reduction reasons, some designs share a common mode choke
between two adjacent ports. This is not recommended.
42631fa
16
LTC4263-1
APPLICATIONS INFORMATION
PSE
PD
+
0.1μF
0.1μF
VDD48
56V
1
1
2
2
Rx
Tx
DATA PAIR
0.1μF
SMAJ58A
GND
RCLASS PWRGD
LTC4263-1
3
VDD5
3
6
DATA PAIR
VIN
6
VOUT
SMAJ58A
58V
–
VSS
OUT
0.1μF
VDD48
4
4
Tx
Rx
5
56V
DATA PAIR
5
– –
DC/DC
CONVERTER
VOUT
7
Rx
Tx
8
0.1μF
+
5μF
MIN
GND
RCLASS PWRGD
VIN
7
+ +
LTC4264
LTC4263-1
VDD5
–
SMAJ58A
0.1μF
0.1μF
–
VOUT
8s B2100
+
DC/DC
CONVERTER
LTC4264
Tx
Rx
0.1μF
5μF
MIN
DATA PAIR
8
SMAJ58A
58V
VSS
OUT
42631 F
Figure 9. 4-Pair High Power PoE Gigabit Ethernet System Diagram
Sharing a common mode choke between two ports couples
start-up, disconnect and fault transients from one port
to the other. The end result can range from intermittent
behavior to excessive voltages that may damage circuitry
in both the PSE and PD connected to the port.
Transient Suppressor Diode
Power over Ethernet is a challenging Hot Swap application
because it must survive unintentional abuse by repeated
plugging in and out of devices at the port. Ethernet cables
could potentially be cut or shorted together. Consequently,
the PSE must be designed to handle these events without
damage.
The most severe of these events is a sudden short on a
powered port. What the PSE sees depends on how much
CAT-5 cable is between it and the short. If the short occurs on the far end of a long cable, the cable inductance
will prevent the current in the cable from increasing too
quickly and the LTC4263-1 built-in short-circuit protection
will control the current and turn off the port. However, the
high current along with the cable inductance causes a
large flyback voltage to appear across the port when the
MOSFET is turned off. In the case of a short occurring
with a minimum length cable, the instantaneous current
can be extremely high due to the lower inductance. The
LTC4263-1 has a high speed fault current limit circuit that
shuts down the port in 20μs (typ). In this case, there is
lower inductance but higher current so the event is still
severe. A transient suppressor is required to clamp the
port voltage and prevent damage to the LTC4263-1. An
SMAJ58A or equivalent device works well to maintain
port voltages within a safe range. A bidirectional transient
suppressor should not be used.
Good layout practices place the transient voltage suppressor close to the LTC4263-1, before the common
mode choke (if used) and data magnetics to enhance the
protective function.
42631fa
17
LTC4263-1
APPLICATIONS INFORMATION
If the port voltage reverses polarity and goes positive,
the OUT pin can be overstressed because this voltage is
stacked on top of the 56V supply. In this case, the transient
suppresser is used to clamp the voltage to a small positive
value to protect the LTC4263-1 and the PSE capacitor. For
this reason, it is critical that only a unidirectional TVS
be used.
Component leakages across the port can have an adverse
affect on AC disconnect and even affect DC disconnect if
the leakage becomes severe. The SMAJ58A is rated at less
than 5μA leakage at 58V and works well in this application. There is a potential for stress induced leakage, so
sufficient margins should be used when selecting transient
suppressors for these applications.
Capacitors
Sizing of both the CDET and CPSE capacitors is critical for
proper operation of the LTC4263-1 AC disconnect sensing.
See the AC Disconnect section for more information. Note
that many ceramic capacitors have dramatic DC voltage
and temperature coefficients. Use 100V or higher rated
X7R capacitors for CDET and CPSE , as these have reduced
voltage dependence while also being relatively small and
inexpensive. Bypass the 48V supply with a 0.1μF, 100V
capacitor located close to the LTC4263-1. The VDD5 supply
also requires a 0.1μF bypass capacitor.
Fuse
While the LTC4263-1 does not require a fuse for proper
operation, some safety requirements state that the output
current must be limited to less than 2A in less than 60
seconds if any one component fails or is shorted. Since
the LTC4263-1 is the primary current limiter, its failure
could result in excess current to the port. To meet these
safety requirements, a fuse can be placed in the positive
leg of the port. The fuse must be large enough that it will
pass at least 675mA when derated for high temperature
but small enough that it will fuse at less than 2A at cold
temperature. This requirement can usually be satisfied
with a 1A fuse or PTC. Placing the fuse between the RJ-45
connector and the LTC4263-1 and its associated circuitry
provides additional protection for this circuitry. Consult
a safety requirements expert for the application specific
requirements.
Isolation
The IEEE 802.3af standard requires Ethernet ports to be
electrically isolated from all other conductors that are
user accessible. This includes the metal chassis, other
connectors, and the AC power line. Environment A isolation is the most common and applies to wiring within a
single building serviced by a single AC power system.
For this type of application, the PSE isolation requirement
can be met with the use of a single, isolated 56V supply
powering several LTC4263-1 ports. Environment B, the
stricter isolation requirement, is for networks that cross
an AC power distribution boundary. In this case, electrical
isolation must be maintained between each port in the
PSE. The LTC4263-1 can be used to build a multi-port
Environment B PSE by powering each LTC4263-1 from
a separate, isolated 56V supply. In all PSE applications,
there should be no user accessible connections to the
LTC4263-1 other than the RJ-45 port.
42631fa
18
LTC4263-1
PACKAGE DESCRIPTION
DE Package
14-Lead Plastic DFN (4mm × 3mm)
(Reference LTC DWG # 05-08-1708 Rev B)
0.70 ±0.05
3.30 ±0.05
3.60 ±0.05
2.20 ±0.05
1.70 ± 0.05
PACKAGE
OUTLINE
0.25 ± 0.05
0.50 BSC
3.00 REF
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED
R = 0.115
TYP
4.00 ±0.10
(2 SIDES)
R = 0.05
TYP
3.00 ±0.10
(2 SIDES)
0.40 ± 0.10
8
14
3.30 ±0.10
1.70 ± 0.10
PIN 1 NOTCH
R = 0.20 OR
0.35 s 45°
CHAMFER
PIN 1
TOP MARK
(SEE NOTE 6)
(DE14) DFN 0806 REV B
7
0.200 REF
1
0.25 ± 0.05
0.50 BSC
0.75 ±0.05
3.00 REF
0.00 – 0.05
BOTTOM VIEW—EXPOSED PAD
NOTE:
1. DRAWING PROPOSED TO BE MADE VARIATION OF VERSION (WGED-3) IN JEDEC
PACKAGE OUTLINE MO-229
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
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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.
19
LTC4263-1
TYPICAL APPLICATION
Complete High Power Single Port Endpoint PSE
L2
6
+
ISOLATED
56V
–
L1: COILCRAFT DS1608C-106
L2: COILCRAFT ETH1-230LD
•
•
9
•
•
1
2
10
11
PHY
L1
10mH
R2
1k
•
5
D1
BAS19
LTC4263-1
11
14
VDD48
VDD5
1
12
LED
SD
7
2
OSC
LEGACY
3
MIDSPAN
13
VSS
4
8
VSS
ACOUT
5
10
VSS
OUT
6
9
VSS
OUT
C1
0.1μF
LED1
LN1351C-TR
GRN
C3
0.1μF
100V
•
C5
0.1μF
X7R
C7
0.47μF
R6 100V, X7R
1k
D5
CMLSHO5-4
4
3
OUT TO
CABLE
12
2
1
•
•
•
•
13
•
•
3
6
14
F1
1A
D2
SMAJ58A
C4
0.1μF
100V, X7R
4
5
C8
0.01μF
200V
R5
510k
2kV
1000pF
C9
0.01μF
200V
R7
75Ω
R8
75Ω
7
8
R9
75Ω
R10
75Ω
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LTC1737
High Power Isolated Flyback Controller
Sense Output Voltage Directly from Primary-Side Winding
LTC3803
Current Mode Flyback DC/DC Controller in ThinSOTTM
200kHz Constant-Frequency, Adjustable Slope Compensation,
Optimized for High Input Voltage Applications
LTC4257
IEEE 802.3af PD Interface Controller
100V 400mA Internal Switch, Programmable Classification
LTC4257-1
IEEE 802.3af PD Interface Controller
100V 400mA Dual Current Limit
LTC4258
Quad IEEE 802.3af Power Over Ethernet Controller
DC Disconnect Only
LTC4259A-1
Quad IEEE 802.3af Power Over Ethernet Controller
With AC Disconnect
LTC4263
Single IEEE 802.3af Compliant PSE Controller
IEEE 802.3af Power Levels
LTC4264
High Power PD Interface Controller
100V 750mA Internal Switch, Programmable Classification
LTC4267
IEEE 802.3af PD Interface with Switcher
Integrated Current Mode Switching Regulator
ThinSOT is a trademark of Linear Technology Corporation.
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20
Linear Technology Corporation
LT 1007 REV A • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900
●
FAX: (408) 434-0507 ● www.linear.com
© LINEAR TECHNOLOGY CORPORATION 2007
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