MAX5941BCSE-T Maxim Integrated, MAX5941BCSE-T Datasheet - Page 14

MAX5941BCSE-T

Manufacturer Part Number

MAX5941BCSE-T

Description

Power Switch ICs - POE / LAN

Manufacturer

Maxim Integrated

Datasheet

1.MAX5941AESE-T.pdf (24 pages)

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During classification mode, if the PSE applies the maxi-

mum DC voltage, the maximum voltage drop from GND

to V

of 42mA flows through the MAX5941A/MAX5941B, then

the maximum DC power dissipation will be close to

546mW, which is slightly higher than the maximum DC

power dissipation of the IC at maximum operating tem-

perature. However, according to the IEEE 802.3af stan-

dard, the duration of the classification mode is limited to

75ms (max). The MAX5941A/MAX5941B handles the

maximum classification power dissipation for the maxi-

mum duration time without sustaining any internal dam-

age. If the PSE violates the IEEE 802.3af standard by

exceeding the 75ms maximum classification duration, it

may cause internal damage to the IC.

The MAX5941A/MAX5941B offer current-mode control

operation with added features such as leading-edge

blanking with dual internal path that only blanks the

sensed current signal applied to the input of the PWM

comparator. The current-limit comparator monitors the

CS pin at all times and provides cycle-by-cycle current

limit without being blanked. The leading-edge blanking

of the CS signal prevents the PWM comparator from

prematurely terminating the on cycle. The CS signal

contains a leading-edge spike that is the result of the

MOSFET gate charge current, capacitive and diode

reverse recovery current of the power circuit. Since this

leading-edge spike is normally lower than the current

limit comparator threshold, current limiting is not

blanked and cycle-by-cycle current limiting is provided

under all conditions.

Use the MAX5941A in discontinuous flyback applica-

tions where wide line voltage and load current variation

is expected. Use the MAX5941B for single transistor

forward converters where the maximum duty cycle must

be limited to less than 50%.

Under certain conditions, it may be advantageous to

use a forward converter with greater than 50% duty

cycle. For those cases, use the MAX5941A. The large

duty cycle results in much lower operating primary RMS

currents through the MOSFET switch and in most cases

a smaller output filter inductor. The major disadvantage

to this is that the MOSFET voltage rating must be higher

and that slope compensation must be provided to sta-

bilize the inner current loop. The MAX5941A provides

internal slope compensation.

IEEE 802.3af-Compliant Power-Over-Ethernet

Interface/PWM Controller for Power Devices

RCL

______________________________________________________________________________________

will be 13V. If the maximum classification current

Thermal Dissipation

Current-Mode Control

PWM Controller

Isolated voltage feedback is achieved by using an opto-

coupler and a shunt regulator as shown in Figure 5. The

output voltage set-point accuracy is a function of the

accuracy of the shunt regulator and feedback resistor-

divider tolerance.

The internal regulators of the MAX5941A/MAX5941B

enable initial startup without a lossy startup resistor and

regulate the voltage at the output of a tertiary (bias) wind-

ing to provide power for the IC. At startup, V+ is regulat-

ed down to V

regulator then regulates from the output of the tertiary

winding to V

ing to have only a small filter capacitor at its output thus

eliminating the additional cost of a filter inductor.

When designing the tertiary winding, calculate the num-

ber of turns so the minimum reflected voltage is always

higher than 12.7V. The maximum reflected voltage must

be less than 36V.

To reduce power dissipation, the high-voltage regulator

is disabled when the V

greatly reduces power dissipation and improves effi-

ciency. If V

threshold (V

abled, and soft-start is reinitiated. In undervoltage lock-

out the MOSFET driver output (NDRV) is held low.

If the input voltage range is between 13V and 36V, V+

and V

that the maximum power dissipation is not exceeded.

This eliminates the need for a tertiary winding.

The soft-start feature of the MAX5941A/MAX5941B

allows the load voltage to ramp up in a controlled man-

ner, thus eliminating output voltage overshoot.

While the controller is in undervoltage lockout, the

capacitor connected to the SS_SHDN pin is dis-

charged. Upon coming out of undervoltage lockout, an

internal current source starts charging the capacitor to

initiate the soft-start cycle. Use the following equation to

calculate total soft-start time:

where C

Operation begins when V

When soft-start has completed, V

PWM Controller Undervoltage Lockout,

may be connected to the line voltage provided

is the soft-start capacitor as shown in Figure 5.

. This architecture allows the tertiary wind-

= 6.6V), the low-voltage regulator is dis-

startup

falls below the undervoltage lockout

to provide bias for the device. The V

Soft-Start, and Shutdown

0 45

Optocoupled Feedback

SS_SHDN

voltage reaches 12.7V. This

Internal Regulators

SS_SHDN

ramps above 0.6V.

is regulated

MAX5941BCSE-T Maxim Integrated, MAX5941BCSE-T Datasheet - Page 14

MAX5941BCSE-T

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