MAX8664BEEP+ Maxim Integrated Products, MAX8664BEEP+ Datasheet - Page 21

MAX8664BEEP+

Manufacturer Part Number

MAX8664BEEP+

Description

IC CNTRLR DUAL OUT 20-QSOP

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX8664BEEP.pdf (26 pages)

Specifications of MAX8664BEEP+

Applications

Power Supplies

Current - Supply

1.4mA

Voltage - Supply

4.5 V ~ 28 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

20-QSOP

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Current page: 21 of 26
Download datasheet (362Kb)

The output voltage ripple as a consequence of the

ESR, ESL, and output capacitance is:

where I

These equations are suitable for initial capacitor selec-

tion, but final values should be chosen based on a pro-

totype or evaluation circuit. As a general rule, a smaller

ripple current results in less output-voltage ripple. Since

the inductor ripple current is a factor of the inductor

value and input voltage, the output-voltage ripple

decreases with larger inductance, and increases with

higher input voltages. Ceramic, tantalum, or aluminum

polymer electrolytic capacitors are recommended. The

aluminum electrolytic capacitor is the least expensive;

however, it has higher ESR and ESL. To compensate for

this, use a ceramic capacitor in parallel to reduce the

switching ripple and noise. For reliable and safe opera-

tion, ensure that the capacitor’s voltage and ripple-cur-

rent ratings exceed the calculated values.

The response to a load transient depends on the

selected output capacitors. After a load transient, the

Figure 7. Feedback Network

RIPPLE

P-P

= V

is the peak-to-peak inductor current:

RIPPLE(ESR)

RIPPLE ESL

P P

RIPPLE C

RIPPLE ESR

−

Controller with Fast Transient Response

______________________________________________________________________________________

(

LX_

FB_

( )

(

−

)

+ V

)

OUT

L ESL

RIPPLE(C)

P P

−

P P

Low-Cost, Dual-Output, Step-Down

OUT

−

ESR

OUT

ESL

+ V

RIPPLE(ESL)

DCR

output voltage instantly changes by ESR x ΔI

Before the controller can respond, the output voltage

deviates further depending on the inductor and output

capacitor values. After a short period of time (see the

Typical Operating Characteristics ), the controller

responds by regulating the output voltage back to its

nominal state. The controller response time depends on

its closed-loop bandwidth. With a higher bandwidth,

the response time is faster, thus preventing the output

voltage from further deviation from its regulating value.

Figure 7 shows the feedback network used on the

MAX8664. With this configuration, a portion of the feed-

back signal is sensed on the switched side of the

inductor (LX), and the output voltage droops slightly as

the load current is increased due to the DC resistance

of the inductor (DCR). This allows the load regulation to

be set to match the voltage droop during a load tran-

sient (voltage positioning), reducing the peak-to-peak

output voltage deviation during a load transient, and

reducing the output capacitance requirements.

To set the magnitude of the voltage positioning, select

a value for R2 in the 8kΩ to 24kΩ range, then calculate

the value of R1 as follows:

where I

Δ V

output voltage at full load.

Setting the Output Voltages and Voltage

OUT(MAX)

is the maximum allowable droop in the

ESR

OUT

is the maximum output current and

⎛

⎜

⎝

OUT MAX

LOAD

(

OUT MAX

(

)

OUT

DCR

)

−

Positioning

⎞

⎟

⎠

LOAD

MAX8664BEEP+ Maxim Integrated Products, MAX8664BEEP+ Datasheet - Page 21

MAX8664BEEP+

Specifications of MAX8664BEEP+

Related parts for MAX8664BEEP+