NCP1650 ON, NCP1650 Datasheet - Page 19

NCP1650

Manufacturer Part Number

NCP1650

Description

Power Factor Controller

Manufacturer

Datasheet

1.NCP1650.pdf (32 pages)

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converter to stabilize the units operation when the duty cycle

is greater than 50%.

several variables, including the boost inductor value, and the

desires of the designer. The value should be based on the

falling di/dt of the inductor current. For a boost inductor with

a variable input voltage, this will vary over the AC input

cycle, and with changes in the input line. A di/dt chart is

included in the design spreadsheet that is available for the

NCP1650.

provides a voltage equal to the ramp on the oscillator C

A resistor from this pin to ground, programs a current that

is transformed via a current mirror to the non−inverting

input of the PWM comparator.

the PWM comparator is the current shunt voltage at pin 11

multiplied by 15, which is the gain of the current amplifier

output that feeds the PWM.

The ramp signal injected can be calculated by the following

formula:

Where:

Oscillator

the switching frequency, as well as sets the gain for the

multipliers. Both the frequency and the peak−to−peak

amplitude are important parameters.

capacitor on the C

200 mA and is trimmed to maintain an accurate, repeatable

frequency. Discharge is accomplished by grounding the C

Rcomp

The amount of compensation required is dependent on

This pin is a buffered output of the oscillator, which

The ramp voltage due to the inductor di/dt at the input to

Oscillator

The current mirror is designed with a 1:1.6 current ratio.

The oscillator generates the sawtooth ramp signal that sets

The oscillator uses a current source for charging the

= Ramp compensation resistor (kW)

Figure 36. Ramp Compensation Circuit

= Peak injected ramp signal (v)

V Rcomp +

−

pin. The charge rate is approximately

1.6 Vosc pk 16 k

Ramp Compensation

R RC

1.6

Current

Sense

16 k

Amp

+ 102

R RC

Comparator

AC Ref

Buffer

http://onsemi.com

PWM

−

pin.

NCP1650

pin with a saturated transistor. A hysteretic comparator

monitors that ramp signal and is used to switch between the

current source and discharge transistor. While the cap is

charging, the comparator has a reference voltage of

4.0 volts. When the ramp reaches that voltage, the

comparator switches from the charging circuit to the

discharge circuit, and its reference changes from 4.0

to X0.5 volts (overshoot and delays will allow the valley

voltage to reach 0 volts).

capacitor is:

Where C

this could affect the accuracy of the frequency as well as that

of the multipliers which use the ramp signal. Any use of this

signal should incorporate a high impedance buffer.

voltages, the NCP1650 is not designed to be synchronized

to the frequency of another oscillator.

Average Current Compensation

maximum current that can occur before the controller limits

the current. This allows for higher levels of current under

low line conditions than at high line.

rectified sinewave. The amplifier is a unity gain amplifier,

with a voltage divider on the output that attenuates the signal

by a factor of 0.75. This scaled down fullwave rectified

sinewave is summed with the low frequency current signal

out of the current sense amplifier.

inverting input to the AC error amplifier, which is the output

of the reference multiplier. Since there is a hard limit of

4.5 volts at the inverting input, the sum of the line voltage

plus the current cannot exceed this level.

265 vac, which is a range of 3.1:1. The output of the Average

Current Compensation amplifier will change by this amount

to allow the maximum current to vary inversely to the line

voltage.

Driver

low and medium power applications, or a larger driver for

high power applications.

capable of sourcing and sinking over 1.5 amps, with typical

rise and fall times of 30 ns with a 1.0 nF load. The totem pole

output has been optimized to minimize cross conduction

current during high speed operation.

Driver in its low state whenever the Undervoltage Lockout

is active. This characteristic eliminates the need for an

external gate pulldown resistor.

The relationship between the frequency and timing

It is important not to load the capacitor on this pin, since

Due to the required accuracy of the peak and valley ramp

The Peak Current Compensation circuit adjusts the

The input signal to this amplifier is the input fullwave

The sum of these signals must equal the signal at the

A typical universal input design operates from 85 to

The output driver can be used to directly drive a FET, for

It is a complementary MOS, totem pole design, and is

Additional internal circuitry has been added to keep the

is in pF and f is in kHz.

C T + 47, 000 f

NCP1650 ON, NCP1650 Datasheet - Page 19

NCP1650

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