PAM2400 Datasheet, PDF(11/14 Page) Power Analog Micoelectronics – 3-Pin Synchronous Step-Up DC/DC Converter

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PAM2400 Datasheet, PDF (11/14 Pages) Power Analog Micoelectronics – 3-Pin Synchronous Step-Up DC/DC Converter

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PAM2400

3-Pin Synchronous Step-Up DC/DC Converter

Application Information

Inductor Selection

To select an inductor for PAM2400 applications,

it should be noted that the inductors current

saturation rating should be larger than the

possible peak inductor current to ensure proper

operation, and it should have low DCR (DC

resistance). Using an inductor with the saturation

current lower than the possible peak indicator

current can cause a dramatic drop in the

inductance and severely decay the maximum

output current levels. An inductor is chosen

based on desired ripple current. Larger

inductors result in lower ripple currents, and

smaller ones higher ripple. A 100uH inductor will

be a suitable choice for most PAM2400

applications. The following equation can also

help to get a good approximate value for the

inductor.

L=V *IN D/ (â³IL* f)

D ( Duty Cycle)= 1- V / IN VOUT

ÎIL (Ripple Current) in the Inductor, i.e., 20% to

40% of the maximum inductor current(Ip).

F (Switching Frequency)=100K.

Output and Input Capacitor Selection

Input Capacitor

An input capacitor of minimum 22Î¼F is

recommended to reduce input ripple and

switching noise for normal operating conditions.

A larger capacitor with lower ESR (Equivalent

Series Resistance) may be needed if the

application requires very low input ripple.

Usually ceramic capacitors are a good choice for

applications. Note that the input capacitor should

be located as close as possible to the IC.

Output Capacitor

A minimum 47Î¼F output capacitor is

recommended and may-be a larger one is better.

The total output voltage ripple has two

components, the capacitive ripple caused by the

charging and discharging on the output

capacitor, and the ohmic ripple due to the

capacitor's equivalent series resistance (ESR):

V =V +V RIPPLE

RIPPLE(C)

RIPPLE(ESR)

VRIPPLE(C) â1/ 2* ( L/ ( C(OUT)* ( ( VOUT(MAX)- VIN(MIN)) ) ) )

(

- 2

PEAK

) 2

OUT

And V = I * R RIPPLE(ESR) PEAK

ESR(COUT)

Where Ipeak is the peak inductor current.

Multilayer ceramic capacitors are a good choice

as they have extremely low ESR and are

available in small footprints. Capacitance and

ESR variation vs temperature should be

considered for best performance in applications

with wide operating temperature ranges.

Component Power Dissipation

Operating in discontinuous mode, power loss in

the winding resistance of the inductor is

approximately equal to

PDL=2/3(T / ON L)*RD*((V + OUT VF)/V ) OUT *POUT

The power dissipated in a switch loss is

PDsw=2/3(T / ON L)*R * ON ((V + OUT VD-V )IN /V ) OUT *(POUT)

The power disspated in rectifier diode(Internal

Diode) is

PDd=VD*IOUT

Where POUT=VOUT*IOUT, RD=Inductor DCR,

VD=Diode drop

PC Board Layout considerations

Careful PC board layout is important for

minimizing ground bounce and noise. Keep the

IC's GND pin and the ground leads of input and

output capacitors as close as possible. In

addition, connect L1 and SW with short and wide

connections.

Power Analog Microelectronics,Inc

www.poweranalog.com

12/2007 Rev 1.0

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