NCP1550_06 ONSEMI [ON Semiconductor], NCP1550_06 Datasheet - Page 14

NCP1550_06

Manufacturer Part Number

NCP1550_06

Description

600 kHz PWM/PFM Step−Down DC−DC Controller

Manufacturer

ONSEMI [ON Semiconductor]

Datasheet

1.NCP1550_06.pdf (17 pages)

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Inductor Value Calculation

inductor’s physical size, transient respond and power

conversion requirements. Lower value inductor saves cost,

PC board space and providing faster transient response, but

result in higher ripple current and core losses. Considering an

application with loading current, I

inductor ripple current, I

than 40% of the load current, i.e. 0.5 A x 40% = 0.2 A.

The relationship between the inductor value and inductor

ripple current is given by,

L +

P−channel MOSFET. Figure 39 is a plot for recommended

inductance against nominal input voltage for different output

options.

P−Channel Power MOSFET Selection

the NCP1550. The key selection criteria for the power

MOSFET are the gate threshold, V

operation, we need to select a low gate threshold device that

can work down to the minimum input voltage level. R

determines the conduction losses for each switching cycle,

the lower the ON resistance, the higher the efficiency can be

achieved. A power MOSFET with lower gate charge can give

lower switching losses but the fast transient can cause

unwanted EMI to the system. Compromise in between is

required during the design stage. For 1.0 A and 2.0 A load

current, NTGS3441T1 and NTGS3443T1 are tested to be

appropriate for most applications.

Flywheel Diode Selection

during the off time. The average diode current depends on the

DS(ON)

Selecting the proper inductance is a trade−off between

Where R

An external P−Channel power MOSFET must be used with

The flywheel diode is turned on and carries load current

T ON * (V IN * R DS(ON)

2.2

1.8 V

and its total gate charge, Q

DS(ON)

Figure 39. Inductor Selection Chart

DS(ON)

2.7

1.9 V

= 0.1 W

I L*RIPPLE(P*P)

, INPUT VOLTAGE OF NCP1550 (V)

is the ON resistance of the external

3.2

2.5 V

L−RIPPLE(P−P)

3.7

2.7 V

I OUT * V OUT)

OUT

. For low input voltage

, the “ON” resistance,

is designed to be less

4.2

3.0 V

= 0.5 A and the

APPLICATIONS INFORMATION

3.3 V

4.7

(eq. 1)

http://onsemi.com

DS(ON)

5.2

NCP1550

P−Channel switch duty cycle. At high input voltages, the

diode conducts most of the time. In case of V

While the output terminals are shorted, the diode will subject

to its highest stress. Under this condition, the diode must be

able to safely handle the peak current circulating in the loop.

So, it is important to select a flywheel diode that can meet the

diode peak current and average power dissipation

requirements. Under normal conditions, the average current

conducted by the flywheel diode is given by:

diode voltage drop.

efficiency. Schottky diodes are a good choice for low forward

drop and fast switching times.

Input and Output Capacitor Selection (C

P−Channel MOSFET is a square wave of duty cycle (V

input capacitor that can support the maximum RMS input

current must be selected. The maximum RMS input current,

where I

worst−case condition is used for design.

governed by the required effective series resistance (ESR) of

the capacitor. Typically, once the ESR requirement is met, the

capacitance will be adequate for filtering. The output voltage

ripple, V

effective series resistance of the output capacitor.

ripple contributed by two parts. For most of the case, the

major contributor is the capacitor ESR. Ordinary

aluminum−electrolytic capacitors have high ESR and should

be avoided. Higher quality Low ESR aluminum−electrolytic

capacitors are acceptable and relatively inexpensive. For even

better performance, Low ESR tantalum capacitors should be

used. Surface−mount tantalum capacitors are better and

provide neat and compact solution for space sensitive

applications.

RMS(MAX)

I RMS(MAX) [ I OUT

OUT

Where I

A fast switching diode must also be used to optimize

In continuous mode operation, the source current of the

Above estimation has a maximum value at V

Selection of the output capacitor, C

Where F

From equation (4), it can be noted that the output voltage

)/V

, the diode conducts only a small fraction of the cycle.

RMS(MAX)

. To prevent large input voltage transients, a low ESR

RIPPLE

V RIPPLE [ I L * RIPPLE(P*P)

OSC

can be estimated by the equation in below:

is the average diode current and V

I D + V IN * V OUT

is the switching frequency and ESR is the

is approximated by:

= I

OUT

V IN ) V F

/2. As a general practice, this simple

(ESR )

V OUT (V IN * V OUT )

4 F OSC C OUT

V IN

I OUT

OUT

and C

is the forward

is primarily

approaches

)

= 2V

(eq. 2)

(eq. 3)

OUT

(eq. 4)

OUT

)

NCP1550_06 ONSEMI [ON Semiconductor], NCP1550_06 Datasheet - Page 14

NCP1550_06

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