Ap1513, Functional description, Pwm control 2a step-down converter – Diodes AP1513 User Manual

AP1513

PWM CONTROL 2A STEP-DOWN CONVERTER

AP1513 Rev. 4

7 of 9

JULY 2009

DS31053

www.diodes.com

©

Diodes Incorporated

Functional Description

PWM Control

The AP1513 is a DC/DC converter that employs pulse width
modulation (PWM) scheme. Its pulse width varies in the range of
0% to 99%, based on the output current loading. The output
ripple voltage caused by the PWM high frequency switching can
easily be reduced through an output filter. Therefore, this
converter provides a low ripple output supply over a broad range
of input voltage & output current loading

Under Voltage Lockout
The under voltage lockout circuit of the AP1513 assures that the
high-side MOSFET driver remains in the off state whenever the
supply voltage drops below 3.3V. Normal operation resumes
once V

CC

rises above 3.5V.

Current Limit Protection
The current limit threshold is set by external resistor R

OCSET

connected from V

CC

supply to OCSET pin. The internal sink

current I

OCSET

(90μA typical) across this resistor sets the voltage

at OCSET pin. When the PWM voltage is less than the voltage at
OCSET, an over-current condition is triggered.

The current limit threshold is given by the following equation:

R

I

R

I

OCSET

OCSET

DS(ON)

PEAK

Ч

=

Ч

2

)

I

(

Δ

+

> I

I

OUT(MAX)

PEAK

where,

IN

OUT

OUT

IN

V

V

L

fs

V

V

I

Ч

Ч

−

=

Δ

I

PEAK

is the output peak current; R

DS (ON)

is the MOSFET ON

resistance; f

S

is the PWM frequency (300KHz typical). Also, the

inductor value will affect the ripple current ΔI.

The above equation is recommended for input voltage range of
5V to 18V. For input voltage lower than 5V or ambient
temperature over 100°C, higher R

OCSET

is recommended.

Inductor Selection

For most designs, the operation range with inductors is from
22µH to 33µH. The inductor value can be derived from the
following equation:

IN

OUT

OUT

IN

V

V

fs

V

V

L

×

Δ

×

−

=

I

Where

ΔI

L

is inductor Ripple Current. Large value inductors lower

ripple current and small value inductors result in high ripple
current. Choose inductor ripple current approximately 15% of the
maximum load current 2A, ∆I

L

=0.30A. The DC current rating of

the inductor should be at least equal to the maximum load current
plus half the ripple current to prevent core saturation (2A+0.15A).

Input Capacitor Selection

This capacitor should be located close to the IC using short leads
and the voltage rating should be approximately 1.5 times the
maximum input voltage. The RMS current rating requirement for
the input capacitor of a buck regulator is approximately 1⁄2 the
DC load current. A low ESR input capacitor sized for maximum
RMS current must be used. A 470µF low ESR capacitor for most
applications is sufficient.

Output Capacitor Selection

The output capacitor is required to filter the output voltage and
provides regulator loop stability. The important capacitor
parameters are the 100KHz Equivalent Series Resistance (ESR),
the RMS ripples current rating, voltage rating and capacitance
value. For the output capacitor, the ESR value is the most
important parameter. The output ripple can be calculated from
the following formula.

ESR

ΔI

V

L

RIPPLE

×

=

The bulk capacitor’s ESR will determine the output ripple voltage
and the initial voltage drop after a high slew-rate transient.

An aluminum electrolytic capacitor's ESR value is related to the
capacitance and its voltage rating. In most case, higher voltage
electrolytic capacitors have lower ESR values. Most of the time,
capacitors with much higher voltage ratings may be needed to
provide the low ESR values required for low output ripple voltage.

PCB Layout Guide

If you need low T

C

& T

J

or large P

D

(Power Dissipation), The dual

SW pins(5& 6) and Vss pins(7& 8)on the SOP-8L package are
internally connected to die pad, The evaluation board should be
allowed for maximum copper area at output (SW) pins.

1.

Connect FB circuits as closely as possible and keep away
from inductor flux for pure V

FB

.

2.

Connect input capacitor to Vcc and Vss pin as closely as
possible to get good power filter effect.

3. Connect

R

OCSET

to Vcc and OCSET pin as closely as

possible.

4.

Connect ground side of the input capacitor & Schottky &
output capacitor as closely as possible and use ground
plane for best performance.