DS2778G+T&R Maxim Integrated Products, DS2778G+T&R Datasheet - Page 22

DS2778G+T&R

Manufacturer Part Number

DS2778G+T&R

Description

IC FUEL GAUGE LI+ 2CELL 14-TDFN

Manufacturer

Maxim Integrated Products

Datasheet

1.DS2775G.pdf (46 pages)

Specifications of DS2778G+T&R

Function

Fuel, Gas Gauge/Monitor

Battery Type

Lithium-Ion (Li-Ion), Lithium-Polymer (Li-Pol)

Voltage - Supply

4 V ~ 9.2 V

Operating Temperature

-20°C ~ 70°C

Mounting Type

Surface Mount

Package / Case

14-TDFN

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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2-Cell, Stand-Alone, Li+ Fuel-Gauge IC with

Protector and Optional SHA-1 Authentication

IMIN stores the charge-current threshold used to detect

a fully charged state. It is stored as a 1-byte value with

units of 50µV (IMIN x R

12.75mV. Assuming R

grammed from 0 to 637.5mA in 2.5mA steps. IMIN

should be set marginally greater than the charge cur-

rent at the end of the charge cycle to ensure reliable

charge termination detection. IMIN is located in the

parameter EEPROM block.

VAE stores the voltage threshold used to detect the

active-empty point. The value is stored in 1 byte with

units of 19.5mV and can range from 0 to 4.978V. VAE is

stored as an average of the cell’s voltages. VAE is locat-

ed in the parameter EEPROM block. See the Modeling

Cell Characteristics section for more information.

IAE stores the discharge-current threshold used to

detect the active-empty point. The unsigned value rep-

resents the magnitude of the discharge current and is

stored in 1 byte with units of 200µV and can range from

0 to 51.2mV. Assuming R

grammed from 0 to 2550mA in 10mA steps. IAE is locat-

ed in the parameter EEPROM block. See the Modeling

Cell Characteristics section for more information.

AC stores the rated cell capacity, which is used to esti-

mate the decrease in battery capacity that occurs dur-

ing normal use. The value is stored in 2 bytes in the

same units as the ACR (6.25µVh). When set to the man-

ufacturer’s rated cell capacity, the aging estimation rate

is approximately 2.4% per 100 cycles of equivalent full

capacity discharges. Partial discharge cycles are

added to form equivalent full capacity discharges. The

default aging estimation results in 88% capacity after

500 equivalent cycles. The aging estimation rate can

be adjusted by setting the AC to a value other than the

cell manufacturer’s rating. Setting AC to a lower value

accelerates the aging estimation rate. Setting AC to a

higher value retards the aging estimation rate. The AC

is located in the parameter EEPROM block.

AS adjusts the cell capacity estimation results down-

ward to compensate for aging. The AS is a 1-byte value

that has a range of 49.2% to 100%. The LSb is weight-

ed at 0.78% (precisely 2

mal or 80h) represents an unaged battery. A value of

95% is recommended as the starting AS value at the

______________________________________________________________________________________

Minimum Charge Current (IMIN)

Active-Empty Voltage (VAE)

Active-Empty Current (IAE)

SNS

-7

SNS

). A value of 100% (128 deci-

= 20mΩ, IMIN can be pro-

) and can range from 0 to

Aging Capacity (AC)

= 20mΩ, IAE can be pro-

Age Scalar (AS)

time of pack manufacture to allow the learning of a larg-

er capacity on batteries that have an initial capacity

greater than the rated cell capacity programmed in the

cell characteristic table. The AS is modified by aging

estimation introduced under aging capacity and by the

learn function.

Batteries are typically considered worn out when the full

capacity reaches 80% of the rated capacity; therefore,

the AS value is not required to range to 0%. It is

clamped to 50% (64 decimal or 40h). If a value of 50%

is read from the AS, the host should prompt the user to

initiate a learning cycle.

The host system has read and write access to the AS;

however, caution should be exercised when writing it to

ensure that the cumulative aging estimate is not over-

written with an incorrect value. The AS is automatically

saved to EEPROM. The EEPROM value is recalled on

power-up.

As previously discussed, the AS register value is

adjusted occasionally based on cumulative discharge.

As the ACR register decrements during each discharge

cycle, an internal counter is incremented until equal to

32 times the AC. The AS is then decremented by one,

resulting in a decrease of the scaled full battery capaci-

ty by 0.78% (approximately 2.4% per 100 cycles). The

internal counter is reset in the event of a learn cycle.

See the Aging Capacity (AC) section for recommenda-

tions on customizing the age estimation rate.

Because Li+ cells exhibit charge efficiencies near unity,

the charge delivered to a Li+ cell from a known empty

point to a known full point is a dependable measure of

the cell’s capacity. A continuous charge from empty to

full results in a learn cycle. First, the active-empty point

must be detected. The learn flag (LEARNF) is set at this

point. Then, once charging starts, the charge must con-

tinue uninterrupted until the battery is charged to full.

Upon detecting full, the LEARNF is cleared, the charge-

to-full (CHGTF) flag is set, and the AS is adjusted

according to the learned capacity of the cell.

Full capacity estimation based on the learn function is

more accurate than the cycle-count-based estimation

introduced under aging capacity. The learn function

reflects the current performance of the cell. Cycle-

count-based estimation is an approximation derived

from the manufacturer’s recommendation for a typical

cell. Therefore, the internal counter used for cycle-

Capacity Estimation Operation

Cycle-Count-Based Aging Estimation

Learn Function

DS2778G+T&R Maxim Integrated Products, DS2778G+T&R Datasheet - Page 22

DS2778G+T&R

Specifications of DS2778G+T&R

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