NCP1653ADR2G ON Semiconductor, NCP1653ADR2G Datasheet - Page 12

NCP1653ADR2G

Manufacturer Part Number

NCP1653ADR2G

Description

IC PFC CONTROLLER CCM 8SOIC

Manufacturer

ON Semiconductor

Datasheet

1.NCP1653PG.pdf (19 pages)

Specifications of NCP1653ADR2G

Mode

Continuous Conduction (CCM)

Frequency - Switching

67kHz

Voltage - Supply

8.75 V ~ 18 V

Operating Temperature

-40°C ~ 125°C

Mounting Type

Surface Mount

Package / Case

8-SOIC (0.154", 3.90mm Width)

Switching Frequency

67 KHz

Maximum Operating Temperature

+ 125 C

Mounting Style

SMD/SMT

Minimum Operating Temperature

- 40 C

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Current - Startup

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

Other names

NCP1653ADR2G
NCP1653ADR2GOSTR

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As a result, the on time t

makes the loss of the inductor and power MOSFET smaller.

Hence, it allows cheaper cost in the inductor and power

MOSFET or allows the circuit components to operate at a

lower stress condition in most of the time.

Output Feedback

feedback current I

device. Since the FB pin voltage V

(Pin 1) and the output voltage referring to Figure 2.

voltage V

regulation,

overvoltage protection (OVP).

Output Voltage Regulation

function in Figure 32. The output of the voltage regulation

block, low−pass filter on V

And the input is feedback current I

is the output of I

There are three linear regions including: (1) I

discussed separately as follows:

Region (1): I

× I

regulation block output V

becomes (eq.15).

with a particular value of RMS input voltage V

power P

ref

control

control(max)

V out + h

out

ref

control

The output voltage V

where R

Then, the feedback current I

Feedback current I

When I

The output voltage V

ref

, (2) 96% × I

, it is usually neglected.

), the NCP1653 operates in follower boost mode. The

is processed in a function with a reference current

= 200 mA typical) as shown in regulation block

/ R

becomes its maximum value (i.e., I

out

control(max)

P out

V ac

out

2 R S R vac I control(max) V ref V ac

. However, this output level is not constant and

= I

block is in Figure 30 is control current I

is less than 96% of I

is the feedback resistor across the FB pin

undervoltage

Figure 32. Regulation Block

and will be used in the output voltage

ref

I FB +

< 96% × I

ref

/2 = 100 mA) which is a constant. (eq.13)

and it can be described as in Figure 32.

R M R CS P out

flowing into the FB pin (Pin 1) of the

control

V out * V FB1

96%

out

which represents the output voltage

< I

ref

is reduced. Reduction of on time

R FB

of the PFC circuit is sensed as a

is regulated at a particular level

ref

reg

ref

control

, and (3) I

protection

is at its maximum value.

ref

FB1

[

pin and the I

represents the output

. It means that I

(i.e., V

is much smaller than

V out

R FB

> I

out

(UVP),

ref

< 96% R

. They are

and output

< 96% ×

control

(eq.14)

(eq.15)

http://onsemi.com

control

and

depending on different values of V

boost operating area is illustrated in Figure 33.

Region (2): 96% × I

× I

output voltage mode which is similar to the follower boost

mode characteristic but with narrow output voltage range.

The regulation block output V

function of I

× I

of V

that output voltage increases when power decreases. It is

similar to the follower boost characteristic in (eq.15). On

the other hand in (eq.17), output voltage V

× I

maximum value of V

can also be concluded that output voltage increases when

RMS input voltage increases. It is similar to another

follower boost characteristic in (eq.15). This characteristic

is illustrated in Figure 34.

Region (3): I

NCP1653 provides no output or zero duty ratio. The

regulation block output V

becomes zero. The multiplier voltage V

96% I

V out +

When I

Resolving (eq.16) and (eq.13),

According to (eq.17), output voltage V

When I

ref

in the range from 96% of I

out

< V

I control +

when power is low (P

ref

when RMS input voltage V

Figure 34. Constant Output Voltage Region

V out

in this operating region. Hence, it can be concluded

V out

V in

out

2 R S R vac V ref

Figure 33. Follower Boost Region

< R

is between 96% and 100% of I

R M R CS

control

is greater than I

> I

I control(max)

ac(min)

× I

ref

in (eq.16).

P out(min)

ref

P out(min)

0.04

ref

out

I control(max)

< I

), the NCP1653 operates in constant

in this operating region. Hence, it

V ac

0.04

out

reg

< I

ac(max)

ref

ac(max)

≈ 0). It is the maximum value

1. P

2. V

1. P

2. V

ref

1 *

becomes 0 V. I

reg

(i.e., V

ref

P out

P out(max)

out

P out(max)

out

decreases linearly with

to I

decreases, V

)

R FB I ref

increases, V

decreases, V

and P

increases, V

is very high. It is the

V out

R FB I ref

out

ref

V ac

. It gives a linear

> R

out

ref

out

. The follower

(i.e., 96% R

becomes R

out

control

× I

decreases

in (eq.8)

decreases

ref

(eq.16)

(eq.17)

), the

also

NCP1653ADR2G ON Semiconductor, NCP1653ADR2G Datasheet - Page 12

NCP1653ADR2G

Specifications of NCP1653ADR2G

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