DP83848C-POE-EK National Semiconductor, DP83848C-POE-EK Datasheet - Page 9

DP83848C-POE-EK

Manufacturer Part Number

DP83848C-POE-EK

Description

BOARD EVALUATION DP83848C

Manufacturer

National Semiconductor

Series

PowerWise®r

Datasheets

1.DP83848CVVXNOPB.pdf (84 pages)

2.DP83848C-MAU-EK.pdf (18 pages)

Specifications of DP83848C-POE-EK

Main Purpose

Special Purpose DC/DC, Power Over Ethernet

Outputs And Type

1, Isolated

Power - Output

24W

Voltage - Output

3.3V

Current - Output

7.3A

Voltage - Input

39 ~ 57V

Regulator Topology

Flyback

Frequency - Switching

250kHz

Board Type

Fully Populated

Utilized Ic / Part

LM5072

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

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If the AUX power option is not used in a new design, delete

CE3, DE1, the eight resistors RE1A through RE1D and RE2A

through RE2D, RE13, RE29, and P1 to lower the BOM cost.

AUX Input “OR-ing” Diode Selection

This diode does not need to be a high speed type since there

is no switching action during operation, however, it should be

a low reverse leakage current device. RE29, a 24.9 kΩ resis-

tor is employed on the evaluation board, providing a sinking

path for the leakage current of DE1. It is meant to sink all of

the leakage current of DE1 and prevent a false logic state at

the RAUX pin. Please see the LM5072 datasheet for more

details about the selection of DE1 and RE29.

Flyback Converter Topology

The dc-dc converter stage of the evaluation board features

the flyback topology, which employs the minimum number of

power components to implement an isolated power supply at

the lowest possible cost. Generally, the flyback topology is

best suited for applications of power levels lower than 50W.

When the power level is higher, the forward, push-pull and

bridge topologies will be appropriate candidates.

A unique characteristic of the flyback topology is its power

transformer. Unlike an ordinary power transformer that simul-

taneously transfers the power from the primary to the sec-

ondary, the flyback transformer first stores the energy inside

the transformer while the main switch is turned on, and then

releases the stored energy to the load during the rest of the

cycle. When the stored energy is not completely released be-

fore the main switch is turned on again, it is said that the

flyback converter operates in continuous conduction mode

(CCM). Otherwise, it is in discontinuous conduction mode

(DCM).

Major advantages of CCM over DCM include (i) lower ripple

current and ripple voltage, resulting in smaller input and out-

put filter capacitors; and (ii) lower RMS current, thus reducing

the conduction losses. To keep the flyback converter in CCM

at light load, the transformer’s primary inductance should be

designed as large as is practical.

Major drawbacks of CCM, as compared to DCM, are (i) the

presence of the right-half-plane zero, which may limit the

achievable bandwidth of the feedback loop, and (ii) the need

for slope compensation to stabilize the feedback loop at duty

cycles greater than 50%.

The flyback topology can have multiple secondary windings

for several isolated outputs. One or more of these secondary

channels are normally utilized internally by the converter itself

to provide the necessary bias voltages for the controller. The

transformer uses an EFD20 type core with a primary induc-

tance of 45 µH. The converter runs in CCM at full load over

the entire input voltage range, but it will operate in DCM under

light loads. The LM5072’s built-in slope compensation helps

stabilize the feedback loop when the duty cycle exceeds 50%

in 24V AUX power operation.

A additional transformer winding is used to provide the bias

voltage (VCC) to the LM5072 IC. Although the LM5072 con-

troller includes an internal startup regulator which can support

the bias requirement indefinitely, the transformer winding pro-

duces an output about 2V higher than the startup regulator

output, thus shutting off the startup regulator and reducing the

power dissipation inside the IC. Given the low current limit

value (15 mA nominal) of the high voltage startup regulator,

the VCC line is not meant to source external loads greater

than 3 mA in total. The external load of the VCC line is the

“PoE Power” LED indicating the PoE operation mode.

Factors Limiting the Minimum

Operating Input Voltage

The LM5072 supports operation with as low as 9V AUX power

source. However, limited by the flyback power transformer

design, the minimum AUX voltage of the evaluation board is

22V (voltage drops caused by RE1A and alike and DE1 re-

duce the VIN pin potential to about 20V).

The installed EFD20 type power transformer FA2267-AL is a

low cost, area efficient solution to operate with a wide auxiliary

input voltage range from 24V to 57V. However, it does not

support 24W power operation with the lower input voltage.

Under these conditions the excessive magnetic flux may sat-

urate the transformer core. It is possible to operate with a

lower voltage AUX source, if the output power level is re-

duced. If full power is required under low AUX input voltage,

the power transformer will need to be redesigned. Contact

National Semiconductor for assistance.

PoE Performance Characteristics

PoE INPUT POWER UP SEQUENCE

The PoE power up sequence is as follows. Note that the RTN

pin (IC pin 8) is isolated from the +3.3V RTN output pin of the

evaluation board:

Figure 5 shows key waveforms during a normal PoE power

up sequence. Please note that the PSE used in the test goes

through detection mode, but opts out of classification mode

and directly enters full power application mode.

The circuit first enters detection mode.

Depending on the PSE in use, the circuit may or may not

go through classification mode.

The PSE enters full power application mode. Before the

PoE input voltage reaches the UVLO threshold, the hot

swap MOSFET is in the OFF state. Thus, all nodes in the

non-isolated section of the power supply remain at high

potential. The voltage across the hot swap MOSFET,

namely the voltage across the RTN and VEE pins, will be

approximately equal to the PoE input voltage seen

across the VIN and VEE pins.

When the UVLO is released during the PoE input power

up, the drain of the internal hot swap MOSFET is pulled

down to VEE (IC pin 7) gradually as the input current

charges up the input capacitors.

The VCC regulator powers up during the inrush

sequence. During VCC regulator startup, it draws current

on the order of 20mA, but this will likely not be noticed by

the user. Once the RTN pin of the IC drops below 1.5V

(referenced to VEE), and the gate of the hot swap

MOSFET rises, power good is asserted by pulling the

nPGOOD pin low.

Once power good has been asserted, the SS (Soft-Start)

pin is released. The SS pin will rise at a rate equal to the

SS current source, typically 10 µA, divided by the SS pin

capacitance, CE26.

After the soft start is complete, the switching regulator

achieves output regulation, and the converter enters

steady state operation. The auxiliary winding will raise

the VCC voltage to about 10.5V, thus shutting down the

internal regulator and increasing efficiency.

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DP83848C-POE-EK National Semiconductor, DP83848C-POE-EK Datasheet - Page 9

DP83848C-POE-EK

Specifications of DP83848C-POE-EK

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