NCP5318FTR2G ON Semiconductor, NCP5318FTR2G Datasheet - Page 19

NCP5318FTR2G

Manufacturer Part Number

NCP5318FTR2G

Description

IC CTLR CPU 2/3/4 PHASE 32-LQFP

Manufacturer

ON Semiconductor

Datasheet

1.NCP5318FTR2G.pdf (32 pages)

Specifications of NCP5318FTR2G

Applications

Controller, CPU

Voltage - Input

9.5 ~ 13.2 V

Number Of Outputs

Operating Temperature

0°C ~ 70°C

Mounting Type

Surface Mount

Package / Case

32-LQFP

Switching Frequency

1 MHz

Mounting Style

SMD/SMT

Primary Input Voltage

18V

No. Of Pins

Operating Temperature Range

0Â°C To +70Â°C

Termination Type

SMD

Supply Voltage Min

12V

Packaging Type

Tape And Reel

Peak Reflow Compatible (260 C)

Yes

Frequency

1MHz

Rohs Compliant

Yes

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Voltage - Output

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

Other names

NCP5318FTR2G
NCP5318FTR2GOSTR

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

BOSTOCK HK LIMITED

Part Number:

NCP5318FTR2G

Manufacturer:

ON Semiconductor

Quantity:

10 000

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Transient Response and Adaptive Voltage Positioning

filter is frequently sized larger than ripple currents require in

order to reduce voltage excursions during load transients. In

addition, adaptive voltage positioning can reduce

peak−peak output voltage deviations due to load transients

and allow use of a smaller output filter. Adaptive voltage

positioning sets output voltage higher than nominal at light

loads, and output voltage is allowed limited sag when the

load current is applied. Upon removal of the load, output

voltage returns no higher than the original level, allowing

one output transient peak to be canceled over a load

application and release cycle.

series with the output can provide fast, accurate adaptive

positioning. However, at high currents, the loss in a dropping

resistor becomes excessive. For example, a 50 A converter

with a 1.0 mW resistor would provide a 50 mV change in

output voltage between no load and full load and would

dissipate 2.5 W. Lossless Adaptive Voltage Positioning

(AVP) is an alternative to using a droop resistor. Figure 20

shows how AVP works. The waveform labeled “normal”

shows a converter without AVP.

On the left, the output voltage sags when the output current

is stepped up and later overshoots when current is stepped

back down. With fast (ideal) AVP, the peak−to−peak

excursions are cut in half. In the slow AVP waveform, the

output voltage is not repositioned quickly enough after

current is stepped up and the upper limit is exceeded. The

controller can be configured to adjust the output voltage

based on the output current of the converter as shown in the

application diagram in Figure 1. The no−load positioning is

set internally to VID − 19 mV, reducing the potential error

due to resistor and bias current mismatches. In order to

realize the AVP function, a resistor divider network is

connected between V

conditions, the V

pin. As the output current increases, the V

increases proportionally. This drives the V

causing V

resistor divider network. The response during the first few

For applications with fast transient currents, the output

For low current applications, a simple dropping resistor in

Figure 20. Adaptive Voltage Positioning

OUT

Normal

Slow

Fast

Limits

to “droop” according to a loadline set by the

Adaptive Positioning

DRP

pin is at the same voltage as the V

, V

DRP

and V

OUT

. During no−load

DRP

voltage higher,

pin voltage

http://onsemi.com

microseconds of a load transient is controlled primarily by

power stage output impedance, and by the ESR and ESL of

the output filter. The transition between fast and slow

positioning is controlled by the total ramp size and the error

amp compensation. If the ramp size is too large or the error

amp too slow, there will be a long transition to the final

voltage after a transient. This will be most apparent with low

capacitance output filters.

Overvoltage Protection

control topology is provided by operation of the

synchronous rectifiers. The control loop responds to an

overvoltage condition within 40 ns, causing the GATEx

output to shut off. The (external) MOSFET driver should

react normally to turn off the top MOSFET and turn on the

bottom MOSFET. This acts quickly to discharge the output

voltage and prevent damage to the load. The regulator will

remain in this state until the fault latch is reset by cycling

power at the V

200 mV above the VID voltage, the converter will latch off.

soon as the V

part. The OVP circuit is then always active, regardless of

operating status.

Power Good

PWRLS is greater then one half of the no load set point

voltage, and the voltage on the Vffb pin is less then the no

load set point voltage + 100 mV. The internal Power Good

comparator and logic circuitry is shown in Figure 21.

V ID ) 100 mV

Overvoltage Protection (OVP) in the Enhanced V

The OVP circuit begins monitoring the output voltage as

Power Good (PWRGD) is asserted when the voltage at the

PWRLS

Vffb

Figure 21. Adjusting the PWRGD Threshold

Figure 22. Adjusting the PWRGD Threshold

V ID

−

OUT

voltage exceeds the UVLO threshold of the

pin. If the voltage at the V

PWRLS

0 ms

2ms

FFB

Delay

pin exceeds

PWRGD

NCP5318FTR2G ON Semiconductor, NCP5318FTR2G Datasheet - Page 19

NCP5318FTR2G

Specifications of NCP5318FTR2G

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