NCP5318FTR2G ON Semiconductor, NCP5318FTR2G Datasheet - Page 30

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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10. Current Limit Setting

block diagram) exceeds the voltage on the I

will latch off. For inductive sensing, the I

should be set based on the inductor’s maximum resistance

resistance increase due to current heating and ambient

temperature rise. Also, depending on the current sense

points, the circuit board may add additional resistance. In

general, the temperature coefficient of copper is +0.39% per

°C. If using a current sense resistor (R

voltage should be set based on the maximum value of the

sense resistor.

voltage at the I

constant. A step load change may cause the current signal to

appear larger than the actual inductor current and trip the

current limit at a lower level than desired. The waveforms in

Figure 36 show a simulation of the current sense signal and

the actual inductor current during a positive step in load

current with values of L = 500 nH, R

20 kW, and C

compensation would require V

faster than ideal RC time constant, there is an overshoot of

50% and the overshoot decays with a 200 ms time constant.

With this compensation, the I

more than 50% above the full load current to avoid

triggering current limit during a large output load step.

Figure 36. Inductive sensing waveform during a load

CSx

When the output of the current sense amplifier (COx in the

For the overcurrent protection to avoid false tripping, the

LMAX

x C

step with fast RC time constant (50 ms/div)

). The design must consider the inductor’s

CSx

time constant is set faster than the L

CSx

LIM

= 0.01 mF. In this case, ideal current signal

pin should be set even higher if the

LIM

CSx

pin threshold must be set

to be 31 k. Due to the

SENSE

= 1.6 mW, R

LIM

), the I

pin, the part

pin voltage

/ R

LIM

http://onsemi.com

CSx

time

where:

from the R

1.0 V. This allows the user to determine the resistor divider

above by:

Where R

V ILIM + (I RIPP−P (2

The proper I

This voltage can be programmed by a resistor divider

When the NCP5318 is powered up, the R

Figure 37. Programming the Current Limit

#PH

R2 = R

R1 = R

RIPP−P

TOTAL

(T L * 25))

ILIM

OSC

TOTAL

LIM

pin, as shown in Figure 37.

= maximum converter current (A)

= maximum 25°C sense element

= maximum current sense to I

= peak−to−peak phase ripple current (A)

= number of phases

= inductor temperature at overload (°C)

= maximum I

is determined as in Section 1 above.

resistance (W)

(see tabulated specs)

(see tabulated specs) (V)

pin voltage can be calculated by:

LIM

x V

− R2

g ) OS ILIM

#PH) ) I L )

LIM

/ 1.0 V

offset

R L

(1 ) 0.004

OSC

LIM

pin will be

gain

NCP5318FTR2G ON Semiconductor, NCP5318FTR2G Datasheet - Page 30

NCP5318FTR2G

Specifications of NCP5318FTR2G

Available stocks

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