MAX1864TEEE+ Maxim Integrated Products, MAX1864TEEE+ Datasheet - Page 17

MAX1864TEEE+

Manufacturer Part Number

MAX1864TEEE+

Description

IC PWR SUPPLY CONTROLLER 16QSOP

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX1864TEEE.pdf (25 pages)

Specifications of MAX1864TEEE+

Applications

Power Supply Controller

Voltage - Input

4.5 ~ 28 V

Current - Supply

1mA

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

16-QSOP

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Voltage - Supply

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

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The key selection parameters for the output capacitor

are the actual capacitance value, the equivalent series

resistance (ESR), and voltage-rating requirements,

which affect the overall stability, output ripple voltage,

and transient response.

The output ripple has two components: variations in the

charge stored in the output capacitor, and the voltage

drop across the capacitor’s ESR caused by the current

into and out of the capacitor:

The output voltage ripple as a consequence of the ESR

and output capacitance is:

where I

Inductor Value section). These equations are suitable

for initial capacitor selection, but final values should be

set by testing a prototype or evaluation circuit. As a

general rule, a smaller ripple current results in less out-

put ripple. Since the inductor ripple current is a factor

of the inductor value and input voltage, the output volt-

age ripple decreases with larger inductance but

increases with lower input voltages.

Figure 5. Reducing the Switching EMI

P-P

MAX1864

MAX1865

TO VL

RIPPLE

xDSL/Cable Modem Triple/Quintuple Output

is the peak-to-peak inductor current (see

P P

RIPPLE ESR

RIPPLE C

−

______________________________________________________________________________________

GND

BST

⎛

⎜

⎝

(

( )

RIPPLE ESR

)

(OPTIONAL)

(

OUT

BST

P P

OUT SW

GATE

−

P P

)

⎞

⎟

⎠

−

ESR

⎛

⎜

⎝

OUT

RIPPLE C

Output Capacitor

⎞

⎟

⎠

( )

With low-cost aluminum electrolytic capacitors, the

ESR-induced ripple can be larger than that caused by

the current into and out of the capacitor. Consequently,

high-quality low-ESR aluminum-electrolytic, tantalum,

polymer, or ceramic filter capacitors are required to

minimize output ripple. Best results at reasonable cost

are typically achieved with an aluminum-electrolytic

capacitor in the 470µF range, in parallel with a 0.1µF

ceramic capacitor.

Since the MAX1864/MAX1865 use a current-mode con-

trol scheme, the output capacitor forms a pole that

affects circuit stability (see Compensation Design).

Furthermore, the output capacitor’s ESR also forms a

zero.

The MAX1864/MAX1865s’ response to a load transient

depends on the selected output capacitor. After a load

transient, the output instantly changes by ESR

ΔI

will sag further, depending on the inductor and output

capacitor values.

After a short period of time (see Typical Operating

Characteristics), the controller responds by regulating

the output voltage back to its nominal state. For appli-

cations that have strict transient requirements, low-ESR

high-capacitance electrolytic capacitors are recom-

mended to minimize the transient voltage swing.

Do not exceed the capacitor’s voltage or ripple-current

ratings.

The MAX1864/MAX1865 controllers use an internal

transconductance error amplifier whose output com-

pensates the control loop. Connect a series resistor

and capacitor between COMP and GND to form a pole-

zero pair. The external inductor, high-side MOSFET,

output capacitor, compensation resistor, and compen-

sation capacitor determine the loop stability. The induc-

tor and output capacitor are chosen based on

performance, size, and cost. Additionally, the compen-

sation resistor and capacitor are selected to optimize

control-loop stability. The component values shown in

the standard application circuits (Figures 1 and 6) yield

stable operation over a broad range of input-to-output

voltages.

The controller uses a current-mode control scheme that

regulates the output voltage by forcing the required

current through the external inductor, so the

MAX1864/MAX1865 use the voltage across the high-

side MOSFET’s R

Using the current-sense amplifier’s output signal and

the amplified feedback voltage, the control loop deter-

mines the peak inductor current by:

LOAD

. Before the controller can respond, the output

DS(ON)

Power Supplies

to sense the inductor current.

Compensation Design

MAX1864TEEE+ Maxim Integrated Products, MAX1864TEEE+ Datasheet - Page 17

MAX1864TEEE+

Specifications of MAX1864TEEE+

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