AP6503 Datasheet, PDF(9/13 Page) Diodes Incorporated – 340kHz 23V 3A SYNCHRONOUS DC/DC BUCK CONVERTER

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AP6503 Datasheet, PDF (9/13 Pages) Diodes Incorporated – 340kHz 23V 3A SYNCHRONOUS DC/DC BUCK CONVERTER

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AP6503

340kHz 23V 3A SYNCHRONOUS DC/DC BUCK CONVERTER

Applications Information (cont.)

Compensation Components (cont.)

2. Choose the compensation capacitor (C3) to achieve the

desired phase margin set the compensation zero, fZ1, to

below one forth of the crossover frequency to provide

sufficient phase margin. Determine the C3 value by the

following equation:

C3 >

Ï Ã R3 Ã fc

Where R3 is the compensation resistor value.

VOUT

(V)

Cin/C1

(ÂµF)

Cout/C2

(ÂµF)

Rc/R3

(kâ¦)

Cc/C3

(nF)

(ÂµH)

1.2

3.24

6.8

3.3

1.8

6.8

3.3

2.5

6.8

3.3

6.8

Table 2âRecommended

Component Selection

Inductor

Calculating the inductor value is a critical factor in

designing a buck converter. For most designs, the

following equation can be used to calculate the inductor

value;

L = VOUT â (VIN â VOUT )

VIN â ÎIL â fSW

Where ÎIL is the inductor ripple current.

And fSW is the buck converter switching frequency.

Choose the inductor ripple current to be 30% of the

maximum load current. The maximum inductor peak

current is calculated from:

IL(MAX)

ILOAD

ÎIL

Peak current determines the required saturation current

rating, which influences the size of the inductor. Saturating

the inductor decreases the converter efficiency while

increasing the temperatures of the inductor and the

internal MOSFETs. Hence choosing an inductor with

appropriate saturation current rating is important.

A 1ÂµH to 10ÂµH inductor with a DC current rating of at least

25% percent higher than the maximum load current is

recommended for most applications.

For highest efficiency, the inductorâs DC resistance should

be less than 200mâ¦. Use a larger inductance for

improved efficiency under light load conditions.

Input Capacitor

The input capacitor reduces the surge current drawn from

the input supply and the switching noise from the device.

The input capacitor has to sustain the ripple current

produced during the on time on the upper MOSFET. It

must hence have a low ESR to minimize the losses.

The RMS current rating of the input capacitor is a critical

parameter that must be higher than the RMS input current.

As a rule of thumb, select an input capacitor which has an

RMs rating that is greater than half of the maximum load

current.

Due to large dI/dt through the input capacitors, electrolytic

or ceramics should be used. If a tantalum must be used, it

must be surge protected. Otherwise, capacitor failure

could occur. For most applications, a 4.7ÂµF ceramic

capacitor is sufficient.

Output Capacitor

The output capacitor keeps the output voltage ripple small,

ensures feedback loop stability and reduces the overshoot

of the output voltage. The output capacitor is a basic

component for the fast response of the power supply. In

fact, during load transient, for the first few microseconds it

supplies the current to the load. The converter recognizes

the load transient and sets the duty cycle to maximum, but

the current slope is limited by the inductor value.

Maximum capacitance required can be calculated from the

following equation:

ESR of the output capacitor dominates the output voltage

ripple. The amount of ripple can be calculated from the

equation below:

Voutcapacitor = ÎIinductor * ESR

An output capacitor with ample capacitance and low ESR

is the best option. For most applications, a 22ÂµF ceramic

capacitor will be sufficient.

L(Iout

ÎIinductor

(Î V + Vout )2 â Vout2

Where ÎV is the maximum output voltage overshoot.

AP6503

Document number: DS35077 Rev. 1 - 2

9 of 13

www.diodes.com

September 2011

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