NCP1547 데이터 시트보기 (PDF) - ON Semiconductor

부품명

상세내역

일치하는 목록

NCP1547

1.5 A, 340 kHz, Buck Regulator with Synchronization Capability

ON Semiconductor 

NCP1547

102.5

100

97.5

95

92.5

90

−40 −20 0 20 40 60 80 100 120 140

TJ, JUNCTION TEMPERATURE (°C)

Figure 4. Oscillator Frequency Versus Junction

Temperature

An external clock signal can sync the NCP1547 to a higher

frequency. The SYNC pin equivalent input circuit is shown

in Figure 5.

Sync

10k

±33%

VZ = 11V

to 20V

50k

±33%

50k

±33%

GND

Figure 5.

The rising edge of the sync pulse turns on the power

switch to start a new switching cycle, as shown in Figure 6.

There is approximately 0.5 ms delay between the rising edge

of the sync pulse and rising edge of the VSW pin voltage. The

sync threshold is TTL logic compatible, and duty cycle of

the sync pulses can vary from 10% to 90%. The frequency

foldback feature is disabled during the sync mode.

Figure 6. A NCP1547 Buck Regulator is

Synchronized to an External 443 kHz Pulse Signal

Power Switch and Current Limit

The collector of the built−in NPN power switch is

connected to the VIN pin, and the emitter to the VSW pin.

When the switch turns on, the VSW voltage is equal to the

VIN minus switch Saturation Voltage. In the buck regulator,

the VSW voltage swings to one diode drop below ground

when the power switch turns off, and the inductor current is

commutated to the catch diode. Due to the presence of high

pulsed current, the traces connecting the VSW pin, inductor

and diode should be kept as short as possible to minimize the

noise and radiation. For the same reason, the input capacitor

should be placed close to the VIN pin and the anode of the

diode.

The saturation voltage of the power switch is dependent

on the switching current, as shown in Figure 7.

0.7

0.6

0.5

0.4

0.3

0.2

0.1

0

0

0.5

1.0

1.5

SWITCHING CURRENT (A)

Figure 7. The Saturation Voltage of the Power Switch

Increases with the Conducting Current

The NCP1547 contains pulse−by−pulse current limiting

to protect the power switch and external components. When

the peak of the switching current reaches the Current Limit,

the power switch turns off after the Current Limit Delay. The

switch will not turn on until the next switching cycle. The

current limit threshold is independent of switching duty

cycle. The maximum load current, given by the following

formula under continuous conduction mode, is less than the

Current Limit due to the ripple current.

IO(MAX)

+

ILIM

*

VO(VIN * VO)

2(L)(VIN)(fs)

where:

fS = switching frequency,

ILIM = current limit threshold,

VO = output voltage,

VIN = input voltage,

L = inductor value.

When the regulator runs under current limit, the

subharmonic oscillation may cause low frequency

http://onsemi.com

7

Share Link: