NCP1091DRG Datasheet NCP1091DRG, NCP1091DG, NCP1090DG | P7-P9

NCP1090, NCP1091, NCP1092

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Description of Operation

Powered Device Interface

The integrated PD interface supports the IEEE 802.3af

defined operating modes: detection signature, current

source classification, undervoltage lockout, inrush and

operating current limits. The following sections give an

overview of these previous processes.

Detection

During the detection phase, the incremental equivalent

resistance seen by the PSE through the cable must be in the

IEEE 802.3af standard specification range (23.70 kW to

26.30 kW) for a PSE voltage from 2.7 V to 10.1 V. In order

to compensate for the non−linear effect of the diode bridge

and satisfy the specification at low PSE voltage, the

NCP1090/91/92 present a suitable impedance in parallel

with the 24.9 kW Rdet external resistor. For some types of

diodes (especially Schottky diodes), it may be necessary to

adjust this external resistor.

The Rdet resistor has to be inserted between VPORTP and

DET pins. During the detection phase, the DET pin is pulled

to ground and goes in high impedance mode (open−drain)

once the device exit this mode, reducing thus the current

consumption on the cable.

Classification

Once the PSE device has detected the PD device, the

classification process begins. In classification, the PD

regulates a constant current source that is set by the external

resistor RCLASS value on the CLASS pin. Figure 4 shows

the schematic overview of the classification block. The

current source is defined as:

Iclass +

9.8 V

Rclass

Figure 4. Classification Block Diagram

CLASS

VPORTP

1.2 V

Class_enable

VPORTP

VPORTN

9.8 V

Power Mode

When the classification hand−shake is completed, the

PSE and PD devices move into the operating mode.

Under Voltage Lock Out (UVLO)

The NCP1090/91/92 incorporate a fixed under voltage

lock out (ULVO) circuit which monitors the input voltage

and determines when to turn on the pass switch and charge

the dc−dc converter input capacitor before the power up of

the application.

The NCP1091 offers a fixed or adjustable Vuvlo_on

threshold depending if the UVLO pin is used or not. In

Figure 5, the UVLO pin is strapped to ground and the

Vuvlo_on threshold is defined by the internal level.

Figure 5. Default Internal UVLO Configuration

(NCP1091 only)

UVLO

VPORTP

VPORTN1,2

VPORT

To define the UVLO threshold externally, the ULVO pin

must be connected to the center of an external resistor

divider between VPORTP and VPORTN as shown in

Figure 6.

In order to guarantee the detection signature, the

equivalent input resistor made of the Ruvlo1, Ruvlo2 and

Rdet should be equal to 24.9 kW.

UVLO

VPORTN1,2

VPORT

Ruvlo2

Ruvlo1

VPORTP

NCP1091

DET

Rdet

Figure 6. Default Internal UVLO Configuration

(NCP1091 only)

For a Vuvlo_on desired turn−on voltage threshold,

Ruvlo1 and Ruvlo2 can be calculated using the following

equations:

Ruvlo +

24.9 k @ Rdet

Rdet * 24.9 k

Ruvlo1 ) Ruvlo2 + Ruvlo

with

Ruvlo2 +

1.2

Vuvlo_on

@ Ruvlo

and

With:

Vuvlo_on: Desired Turn−On voltage threshold

NCP1090, NCP1091, NCP1092

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Example for a Targeted Uvlo_on of 35 V:

Let’s start with a Rdet of 30.1 kΩ. This gives a Ruvlo of

144 kΩ made with a Ruvlo2 of 4.99 kΩ and a Ruvlo1 of

140 kΩ (closest values from E96 series). Note that there is

a pull down current of 2.5 mA typ on the UVLO. Assuming

the previous example, this pull down current will create a

(non critical) systematic offset of 350 mV on the Uvlon_on

level of 35 V.

The external UVLO hysteresis on the NCP1091 is about

15 percent typical.

Inrush and Operational Current Limitations

Both inrush and operational current limit are defined by

an external Rinrush resistor connected between INRUSH

and VPORTN. The low inrush current limit allows smooth

charge of large dc−dc converter input capacitor by limiting

the power dissipation over the internal pass switch. In power

mode, the operational current limit protects the pass switch

and the PD application against excessive transient current

and failure on the dc−dc converter output.

Once the input supply reached the Vulvo_on level, the

charge of Cpd capacitor starts with a current limitation set to

to the INRUSH level. When this capacitor is fully charged,

the current limit switches without any spikes from the inrush

current to the operational current level and the power good

indicator on PGOOD pin is turned on. The capacitor is

considered to be fully charged once the following conditions

are satisfied:

1. The drain−source voltage of the Pass Switch has

decreased below the Vds_pgood_on level (typical

1V)

2. The gate−source voltage of the Pass Switch is

sufficiently high (above 2 V typical) which means

the current in the pass switch has decreased below

the current limit.

This mechanism is depicted in the following Figure 7.

Operational current limit

VPORTNx

Pass Switch

Inrush current limit

RTN

VDDA1

1 V / 10 V 2 V

Delay

detector

PGOOD

Pgood_on

VDDA1

RTN

Pgood_on

Sense Resistor

Vds_pgood comparator

Vgs_pgood comparator

Figure 7. Inrush and Operational Current Limitation Selection Mechanism

100 mS

The operational current limit and the power good

indicator stays active as long as RTN voltage stays below the

vds_pgood_off threshold (10 V typical) and the input supply

stay above the Vulvo_off level. Therefore, fast and large

voltage step lower than 10 V are tolerated on the input

without interruption of the converter controller. Higher

input transient will not affect the behavior if RTN does not

exceed 10 V for more than 100 mS. Such input voltage steps

may be introduced by a PSE which is switched to a higher

power supply. In case RTN is still above 10 V after this delay,

the power good is turned off and the pass switch current limit

falls back to the inrush level.

PGOOD Indicator

The NCP1090/91/92 integrate a Power Good indicator

circuitry indicating the end of the dc−dc converter input

capacitor charge, and the enabling of the operational current

limit. This indicator is implemented on the PGOOD pin

which goes in open drain state when active and which is

pulled to ground during turn off.

A possible usage of this PGOOD pin is illustrated in

Figure 8. During the inrush phase, the converter controller

is forced in standby mode due to the PGOOD pin forcing low

the under voltage lock out pin of the controller. Once the Cpd

capacitor is fully charged, PGOOD goes in open drain state,

allowing the start up sequence of the converter controller.

NCP1090, NCP1091, NCP1092

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NCP1090

Rclass

Rinrush

RTN

VPORTN

CLASS

INRUSH

VPORTP

DET

Cpd

PGOOD

DC−DC Converter

Controller

VSS

VDD

OVLO

UVLO

GATE

Rdet

Figure 8. Power GOOD Implementation

NCP103x

Auxiliary Supply

To support application connected to non−PoE enabled

networks and minimize the bill of materials, the NCP1093

supports drawing power from an external supply and allows

simplified designs with PoE or auxiliary supply priorities.

In most of the cases, the auxiliary supply is connected

between VPORTP and RTN with a serial diode between

VPORTP and VAUX, as shown in Figure 9.

NCP1092

Data

Pairs

Cline

Spare

Pairs

Rclass

Rinrush

RJ−45

DB1

DB2

Z_line

RTN

VPORTN

CLASS

INRUSH

AUX

VPORTP

DET

To DC−DC

Converter

Cpd

PGOOD

Rdet

VAUX (+)

VAUX (−)

Figure 9. Auxiliary Supply Dominant PD Interface

The NCP1092 offers an AUX input pin which turns off the

pass switch when pulled high. This feature is useful for PD

applications where the auxiliary supply has to be dominant

over the PoE supply. When the auxiliary supply is inserted

on a POE powered application, the pass switch

disconnection will move the current path from the PSE to the

rear auxiliary supply. Since the current delivered by the PSE

will goes below the DC MPS level (specified in IEEE

802.3 af/at standard), the PSE will disconnect the PoE−PD

and the application will remain supplied by the auxiliary

supply. The transition will happens without any power

conversion interruption since the PGOOD indicator stays

active (high impedance state).

Next Figure 10 depicts an other PD application where the

POE supply is dominant over the VAUX supply. A diode D1

has been added in order to not corrupt the PD detection

signature when the dc−dc converter is supplied by VAUX.

P1-P3 P4-P6 P7-P9 P10-P12

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