MAX1758EAI+ Maxim Integrated Products, MAX1758EAI+ Datasheet - Page 15

MAX1758EAI+

Manufacturer Part Number

MAX1758EAI+

Description

IC BATT CHRG 4-LI+ 28V SW 28SSOP

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX1758EAI.pdf (17 pages)

Specifications of MAX1758EAI+

Function

Charge Management

Battery Type

Lithium-Ion (Li-Ion)

Voltage - Supply

6 V ~ 28 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

28-SSOP

Output Voltage

5.4 V

Operating Supply Voltage

6 V to 28 V

Supply Current

5 mA

Maximum Operating Temperature

+ 85 C

Minimum Operating Temperature

- 40 C

Charge Safety Timers

Yes

Mounting Style

SMD/SMT

Temperature Monitoring

Yes

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Current page: 15 of 17
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cell voltage limit battery regulation voltage is deter-

mined, the VADJ voltage is calculated by the equation:

CELL is the programming input for selecting cell count

N. Table 2 shows how CELL is connected to charge 1,

2, 3, or 4 cells.

A resistor-divider from REF to GND sets the voltage at

ISETOUT (V

rent during the current-regulation (fast-charge) mode.

The full-scale charging current is 1.5A.

The charging current (I

Connect ISETOUT to REF to get the full-scale current

limit.

A resistor-divider from REF to GND sets the voltage at

ISETIN (V

allowed at any time during charging. The source cur-

rent I

between CSSP and CSSN. The full-scale source current

is I

The input current limit (I

Connect ISETIN to REF to get the full-scale input cur-

rent limit. Short CSSP and CSSN if the input source cur-

rent limit is not used.

In choosing the current-sense resistor, note that the drop

across this resistor adds to the power loss and thus

reduces efficiency. However, too low a resistor value

may degrade input current-limit accuracy.

The inductor value may be changed for more or less

ripple current. The higher the inductance, the lower the

ripple current will be; however, as the physical size is

kept the same, typically, higher inductance will result in

higher series resistance and lower saturation current. A

good tradeoff is to choose the inductor so that the rip-

ple current is approximately 30% to 50% of the DC

average charging current. The ratio of ripple current to

FSS

Li+ Battery Charger with Internal 28V Switch

= 0.1V / R1 (Figure 1).

ISETIN

VADJ

is set by the current-sense resistor R

Setting the Charging Current Limit

ISETOUT

= (9.5 V

). This sets the maximum source current

CHG

Setting the Input Current limit

______________________________________________________________________________________

). This determines the charging cur-

CHG

BATTR

1 5

FSS

) is therefore:

) is, therefore:













/ N) - (9.0 x V

ISETIN

Inductor Selection

ISETOUT

REF













REF

)

SOURCE

Stand-Alone, Switch-Mode

DC charging current (LIR) can be used to calculate the

optimal inductor value:

where f

The peak inductor current is given by:

The input capacitor shunts the switching current from

the charger input and prevents that current from circu-

lating through the source, typically an AC wall cube.

Thus, the input capacitor must be able to handle the

input RMS current. Typically, at high charging currents,

the converter will operate in continuous conduction (the

inductor current does not go to 0). In this case, the

RMS current of the input capacitor may be approximat-

ed by the equation:

where:

The maximum RMS input current occurs at 50% duty

cycle; thus, the worst-case input ripple current is 0.5 x

PWM controller will never work at 50% duty cycle, then

the worst-case capacitor current will occur where the

duty cycle is nearest 50%.

The input capacitor impedance is critical to preventing

AC currents from flowing back into the wall cube. This

requirement varies depending on the wall cube imped-

ance and the requirements of any conducted or radiat-

ed EMI specifications that must be met. Aluminum

electrolytic capacitors are generally the cheapest, but

usually are a poor choice for portable devices due to

their large size and poor equivalent series resistance

(ESR). Tantalum capacitors are better in most cases, as

are high-value ceramic capacitors. For equivalent size

and voltage rating, tantalum capacitors will have higher

capacitance, but also higher ESR than ceramic capaci-

tors. This makes consideration of RMS current and power

CHG

D is the PWM converter duty ratio (typically V

CIN

CHG

DCIN

. If the input-to-output voltage ratio is such that the

is the input capacitor RMS current.

is the battery charging current.

OSC

is the switching frequency (300kHz).

PEAK

DCIN MAX

CIN

BATT

(

≅

(

ISETOUT

)

DCIN MAX

CHG

x f

OSC

(

Capacitor Selection







)

x I

−

CHG

LIR

BATT







x LIR

)

BATT

MAX1758EAI+ Maxim Integrated Products, MAX1758EAI+ Datasheet - Page 15

MAX1758EAI+

Specifications of MAX1758EAI+

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