MAX8731A Maxim Integrated Products, MAX8731A Datasheet - Page 29

MAX8731A

Manufacturer Part Number

MAX8731A

Description

SMBus Level 2 Battery Charger

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX8731A.pdf (32 pages)

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The input capacitor must meet the ripple current

requirement (I

Nontantalum chemistries (ceramic, aluminum, or

OS-CON) are preferred due to their resilience to power-

up surge currents:

The input capacitors should be sized so that the temper-

ature rise due to ripple current in continuous conduction

does not exceed approximately +10°C. The maximum

ripple current occurs at 50% duty factor or V

interest does not achieve the maximum value, size the

input capacitors according to the worst-case conditions.

The output capacitor absorbs the inductor ripple current

and must tolerate the surge current delivered from the

battery when it is initially plugged into the charger. As

such, both capacitance and ESR are important parame-

ters in specifying the output capacitor as a filter and to

ensure stability of the DC-DC converter (see the

Compensation section). Beyond the stability require-

ments, it is often sufficient to make sure that the output

capacitor’s ESR is much lower than the battery’s ESR.

Either tantalum or ceramic capacitors can be used on the

output. Ceramic devices are preferable because of their

good voltage ratings and resilience to surge currents.

Smart-battery systems have evolved since the concep-

tion of the smart-battery system (SBS) specifications.

Originally, such systems consisted of a smart battery

and smart-battery charger that were compatible with the

SBS specifications and communicated directly with one

another using SMBus protocols. Modern systems still

employ the original commands and protocols, but often

use a keyboard controller or similar digital intelligence to

mediate the communication between the battery and the

charger

able freedom in the implementation of charging algo-

rithms at the expense of standardization. Algorithms can

vary from the simple detection of the battery with a fixed

set of instructions for charging the battery to highly com-

plex programs that can accommodate multiple battery

BATT

, which equates to 0.5 x I

RMS

(Figure

CHG

RMS

Applications Information

13). This arrangement permits consider-

⎛

⎜

⎝

) imposed by the switching currents.

______________________________________________________________________________________

Output-Capacitor Selection

BATT

Input-Capacitor Selection

Background Information

(

Smart-Battery System

DCIN

SMBus Level 2 Battery Charger

CHG

−

. If the application of

BATT

)

⎞

⎟

⎠

DCIN

= 2 x

configurations and chemistries. Microcontroller pro-

grams can perform frequent tests on the battery’s state

of charge and dynamically change the voltage and cur-

rent applied to enhance safety. Multiple batteries can

also be utilized with a selector that is programmable over

the SMBus.

The input-current limit should be set based on the cur-

rent capability of the AC adapter and the tolerance of

the input-current limit. The upper limit of the input cur-

rent threshold should never exceed the adapter’s mini-

mum available output current. For example, if the

adapter’s output current rating is 5A ±10%, the input

current limit should be selected so that its upper limit is

less than 5A × 0.9 = 4.5A. Since the input current-limit

accuracy of the MAX8731A is ±3%, the typical value of

the input-current limit should be set at 4.5A / 1.03 ≈

4.36A. The lower limit for input current must also be

considered. For chargers at the low end of the spec,

the input-current limit for this example could be 4.36A ×

0.95, or approximately 4.14A.

Bypass DCIN with a 1µF ceramic to ground

D1 protects the MAX8731A when the DC power source

input is reversed. Bypass V

and REF as shown in

Figure

with Remote Sense

13. Typical Smart-Battery System

SMART-BATTERY

POWER-SOURCE

CONVERTER

(ADAPTER)

MAX8731A

CHARGER/

SELECTOR

AC-TO-DC

CONTROL

SIGNALS

BATTERY

SMBus

FOR

Setting Input-Current Limit

Figure

(KEYBOARD CONTROLLER)

SYSTEM HOST

Layout and Bypassing

BATT+

BATT-

, DCIN, LDO, VCC, DAC,

SUPPLIES

BATTERY

CONTROL

SYSTEM

SIGNALS

BATTERY

POWER

SMART

SMBus

FOR

(Figure

1).

MAX8731A Maxim Integrated Products, MAX8731A Datasheet - Page 29

MAX8731A

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