MAX8731AETI+T Maxim Integrated Products, MAX8731AETI+T Datasheet - Page 24

MAX8731AETI+T

Manufacturer Part Number

MAX8731AETI+T

Description

IC SMBUS LVL2 BATT CHRGR 28TQFN

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX8731AETI.pdf (32 pages)

Specifications of MAX8731AETI+T

Function

Charge Management

Battery Type

Multi-Chemistry

Voltage - Supply

8 V ~ 26 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

28-WFQFN Exposed Pad

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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SMBus Level 2 Battery Charger

with Remote Sense

The charge-voltage and charge-current regulation

loops are independent and compensated separately at

the CCV, CCI, and CCS.

The simplified schematic in

describe the operation of the MAX8731A when the volt-

age loop (CCV) is in control. The required compensa-

tion network is a pole-zero pair formed with C

formed by the output capacitor and the load. R

the equivalent series resistance (ESR) of the charger

output capacitor (C

output load, where R

lent output impedance of the GMV amplifier, R

Figure

Table

CCV Zero

CCV Pole

Output

NAME

Zero

Pole

. The zero is necessary to compensate the pole

______________________________________________________________________________________

7. CCV Loop Diagram

5. CCV Loop Poles and Zeros

CCV

P CV

OGMV

P OUT

Z CV

OUT

= ΔV

GMV

). R

EQUATION

2π

ChargeVoltage( )

2π

CCV Loop Compensation

BATT

OGMV

is the equivalent charger

Figure 7

/ ΔI

FBS_

OUT

Compensation

CHG

is sufficient to

ESR

. The equiva-

OUT

OGMV

Lowest frequency pole created by C

Voltage-loop compensation zero. If this zero is at the same frequency or

lower than the output pole f

approximates a single-pole response near the crossover frequency. Choose

adequate phase margin.

Output pole formed with the effective load resistance R

capacitance C

stability of the system or the crossover frequency.

Output ESR Zero. This zero can keep the loop from crossing unity gain if

capacitor with an ESR zero greater than the crossover frequency.

Z_OUT

ESR

and

, is

to place this zero at least 1 decade below crossover to ensure

is less than the desired crossover frequency; therefore, choose a

greater than 10MΩ. The voltage amplifier transconduc-

tance, GMV = 0.125µA/mV. The DC-DC converter

transconductance is dependent upon the charge-cur-

rent sense resistor RS2:

where A

application circuits, so GM

fer function is given by:

The poles and zeros of the voltage loop-transfer function

are listed from lowest frequency to highest frequency in

Table

Near crossover C

inates the parallel impedance near crossover.

Additionally, R

and dominates the series combination of R

so near crossover:

OUT

OGMV

. R

LTF GM

. Since C

influences the DC gain but does not affect the

CSI

P_OUT

= 20V/V, and RS2 = 10mΩ in the typical

(

OGMV

(

DESCRIPTION

OUT

, then the loop-transfer function

is much higher impedance than C

OUT

is in parallel with R

(

is much lower impedance than

and GMV’s finite output resistance.

CSI

OGMV

GMV R

OUT

ESR

OGMV

)(

= 5A/V. The loop-trans-

)

OGMV

)

and the output

≅

OUT

OGMV

, C

and C

)

dom-

MAX8731AETI+T Maxim Integrated Products, MAX8731AETI+T Datasheet - Page 24

MAX8731AETI+T

Specifications of MAX8731AETI+T

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