MAX1639ESE Maxim Integrated Products, MAX1639ESE Datasheet - Page 11

MAX1639ESE

Manufacturer Part Number

MAX1639ESE

Description

DC/DC Switching Controllers

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX1639ESE.pdf (13 pages)

Specifications of MAX1639ESE

Number Of Outputs

Output Voltage

1.1 V to 4.5 V

Input Voltage

4.5 V to 5.5 V

Mounting Style

SMD/SMT

Package / Case

SOIC-16

Maximum Operating Temperature

+ 85 C

Minimum Operating Temperature

- 40 C

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

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where f is the switching frequency, between 300kHz

and 1MHz; I

LIR is the ratio of AC to DC inductor current (typically

0.3). The exact inductor value is not critical and can be

adjusted to make trade-offs among size, transient

response, cost, and efficiency. Although lower inductor

values minimize size and cost, they also reduce efficien-

cy due to higher peak currents. In general, higher

inductor values increase efficiency, but at some point

resistive losses due to extra turns of wire exceed the

benefit gained from lower AC current levels. Load-

transient response can be adversely affected by

high inductor values, especially at low (V

differentials.

The peak inductor current at full load is 1.15 x I

the previous equation is used; otherwise, the peak cur-

rent can be calculated using the following equation:

The inductor’s DC resistance is a key parameter for effi-

cient performance, and should be less than the current-

sense resistor value.

Calculate the current-sense resistor value according to

the worst-case minimum current-limit threshold voltage

(from the Electrical Characteristics) and the peak

inductor current required to service the maximum load.

Use I

the Inductor.

The high inductance of standard wire-wound resistors

can degrade performance. Low-inductance resistors,

such as surface-mount power metal-strip resistors, are

preferred. The current-sense resistor’s power rating

should be higher than the following:

PEAK

from the equation in the section Specifying

OUT

IN MAX

OUT

Synchronous Rectification for CPU Power

(

Calculating the Current-Sense

OUT MAX

OUT

is the maximum DC load current; and

______________________________________________________________________________________

SENSE

)

(

x f

High-Speed Step-Down Controller with

IN MAX

OUT

OSC

)

(

OSC

x R

(

)

x I

IN MAX

PEAK

SENSE

x L x V

−

(

OUT

Resistor Value

OUT

)

x LIR

−

IN MAX

)

(

OUT

)

- V

)

OUT

)

In high-current applications, connect several resistors

in parallel as necessary to obtain the desired resis-

tance and power rating.

Output filter capacitor values are generally determined

by effective series resistance (ESR) and voltage-rating

requirements, rather than by the actual capacitance

value required for loop stability. Due to the high switch-

ing currents and demanding regulation requirements in

a typical MAX1639 application, use only specialized

low-ESR

regulator applications, such as AVX TPS, Kemet T510,

Sprague 595D, Sanyo OS-CON, or Sanyo GX series. Do

not use standard aluminum-electrolytic capacitors,

which can cause high output ripple and instability due

to high ESR. The output voltage ripple is usually domi-

nated by the filter capacitor’s ESR, and can be approxi-

mated as I

capacitor must meet both minimum capacitance and

maximum ESR values as given in the following equa-

tions:

The feedback loop needs proper compensation to pre-

vent excessive output ripple and poor efficiency

caused by instability. Compensation cancels unwanted

poles and zeros in the DC-DC converter’s transfer func-

tion that are due to the power-switching and filter ele-

ments with corresponding zeros and poles in the

feedback network. These compensation zeros and

poles are set by the compensation components CC1,

CC2, and RC1. The objective of compensation is to

ensure stability by ensuring that the DC-DC converter’s

phase shift is less than 180° by a safe margin, at the

frequency where the loop gain falls below unity.

Compensate the fast-voltage feedback loop by con-

necting a resistor and a capacitor in series from the

CC1 pin to AGND. The pole from CC1 can be set to

cancel the zero from the filter-capacitor ESR. Thus the

capacitor at CC1 should be as follows:

Selecting the Output Filter Capacitor

ESR

OUT

Compensating the Feedback Loop

capacitors

RIPPLE

x R

SENSE

OUT

REF

ESR

Canceling the Sampling Pole

intended

and Output Filter ESR Zero

x R

. To ensure stability, the







SENSE

IN MIN

OUT

(

for

x f

)

OSC







switching-

MAX1639ESE Maxim Integrated Products, MAX1639ESE Datasheet - Page 11

MAX1639ESE

Specifications of MAX1639ESE

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