LTC4257IS8-1 Linear Technology, LTC4257IS8-1 Datasheet - Page 12

LTC4257IS8-1

Manufacturer Part Number

LTC4257IS8-1

Description

IC CONTROLLER POE INTERFAC 8SOIC

Manufacturer

Linear Technology

Type

Power over Ethernet Switch (PoE)r

Datasheet

1.LTC4257CS8-1.pdf (20 pages)

Specifications of LTC4257IS8-1

Applications

IP Phones, Power over LAN, Network Routers and Switches

Internal Switch(s)

Yes

Current Limit

350mA

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

8-SOIC (0.154", 3.90mm Width)

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

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Company

Part Number

Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

LTC4257IS8-1

Manufacturer:

Quantity:

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Company:

Meier Automation Equipment Co., Limited

Part Number:

LTC4257IS8-1#PBF

Manufacturer:

LINEAR/凌特

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Company:

Bonase Electronics (HK) Co., Limited

Part Number:

LTC4257IS8-1#TRPBF

Manufacturer:

LINEAR

Quantity:

7 556

Current page: 12 of 20
Download datasheet (266Kb)

APPLICATIO S I FOR ATIO

LTC4257-1

If a sudden increase in voltage appears on the input line,

this voltage step will be transferred through capacitor C1

and appear across the power MOSFET. The response of

the LTC4257-1 will depend on the magnitude of the

voltage step, the rise time of the step, the value of capacitor

C1 and the DC load. For fast rising inputs, the LTC4257-1

will attempt to quickly charge capacitor C1 using an

internal secondary current limit circuit. In this scenario,

the PSE current limit should provide the overall limit for

the circuit. For slower rising inputs, the 375mA current

limit in the LTC4257-1 will set the charge rate of capacitor

C1. In either case, the PWRGD signal may go inactive

briefly while the capacitor is charged up to the new line

voltage. In the design of a PD, it is necessary to determine

if a step in the input voltage will cause the PWRGD signal

to go inactive and how to respond to this event. In some

designs, the charge on C1 is sufficient to power the PD

through this event. In this case, it may be desirable to filter

the PWRGD signal so that intermittent power bad condi-

tions are ignored. Figure 10 demonstrates methods to

insert a lowpass filter on the power good interface.

For PD designs that use a large load capacitor and also

consume a lot of power, it is important to delay activation

of the PD circuitry with the PWRGD signal. If the PD cir-

cuitry is not disabled during the current-limited turn-on se-

quence, the PD circuitry will rob current intended for charg-

ing up the load capacitor and create a slow rising input,

possibly causing the LTC4257-1 to go into thermal shut-

down.

The PWRGD pin connects to an internal open-drain, 100V

transistor capable of sinking 1mA. Low impedance indi-

cates power is good. PWRGD is high impedance during

signature and classification probing and in the event of a

thermal overload.

During turn-off, PWRGD is deactivated when the input

voltage drops below 30V. In addition, PWRGD may go

active briefly at turn-on for fast rising input waveforms.

PWRGD is referenced to the V

be near the V

typically be referenced to V

ensure that the difference in potential of the PWRGD signal

does not cause any detrimental effects. Use of diode clamp

D6, as shown in Figure 10, will alleviate any problems.

potential. The PD DC/DC converter will

OUT

and care must be taken to

pin and when active will

Thermal Protection

The LTC4257-1 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 tremendous

power dissipation within the LTC4257-1. At turn on,

before the load capacitor has charged up, the instanta-

neous power dissipated by the LTC4257-1 can be 10W. As

the load capacitor charges up, the power dissipation in the

LTC4257-1 will decrease until it reaches a steady-state

value dependent on the DC load current. The size of the

load capacitor determines how fast the power dissipation

in the LTC4257-1 will subside. At room temperature, the

LTC4257-1 can handle load capacitors as large as 800µF

without going into thermal shutdown. With a large load

capacitor like this, the LTC4257-1 die temperature will

increase by about 50°C during a single turn-on sequence.

If for some reason power were removed from the part and

then quickly reapplied so that the LTC4257-1 has to

charge up the load capacitor again, the temperature

rise would be excessive if safety precautions were not

implemented.

The LTC4257-1 protects itself from thermal damage by

monitoring the die temperature. If the die temperature

exceeds the overtemperature trip point, the current is

reduced to zero and very little power is dissipated in the

part until it cools below the overtemperature set point.

Once the LTC4257-1 has charged up the load capacitor

and the PD is powered and running, there will be some

residual heating due to the DC load current of the PD

flowing through the internal MOSFET. In some applica-

tions, the LTC4257-1 power dissipation may be signifi-

cant and if dissipated in the S8 package, excessive pack-

age heating could occur. This problem can be solved with

the use of the DD package which has superior thermal

performance. The DD package includes an exposed pad

which should be soldered to an isolated heatsink on the

printed circuit board.

During classification, excessive heating of the LTC4257-1

can occur if the PSE violates the 75ms probing time limit.

To protect the LTC4257-1, thermal protection circuitry will

disable classification current if the die temperature exceeds

42571fb

LTC4257IS8-1 Linear Technology, LTC4257IS8-1 Datasheet - Page 12

LTC4257IS8-1

Specifications of LTC4257IS8-1

Available stocks

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