MAX8688ALETG+ Maxim Integrated Products, MAX8688ALETG+ Datasheet - Page 15

MAX8688ALETG+

Manufacturer Part Number

MAX8688ALETG+

Description

IC PWR SUPPLY CTRLR/MONTR 24TQFN

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX8688BHETG.pdf (38 pages)

Specifications of MAX8688ALETG+

Applications

Power Supply Controller/Monitor

Voltage - Supply

3 V ~ 3.6 V

Current - Supply

6.7mA

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

24-TQFN Exposed Pad

Supply Voltage (max)

3.6 V

Supply Voltage (min)

3 V

Operating Temperature Range

- 40 C to + 85 C

Mounting Style

SMD/SMT

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Voltage - Input

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

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It is intended that the MAX8688 be placed in close prox-

imity to the POL. An on-chip temperature sensor on the

MAX8688 senses the temperature of the die, which is

related to the exposed pad temperature of the MAX8688

by the junction-to-case thermal resistance. The exposed

pad of the MAX8688 can be connected to the heat dis-

sipating ground plane of the POL, and the POL board

may be characterized to obtain the relationship between

the POL temperature and temperature as measured by

the MAX8688. This information may be used to set

overtemperature fault settings in the MAX8688.

The MAX8688 is capable of communicating with an

EEPROM attached to the A1/SCLE and A2/SDAE. The

MAX8688 communicates to the EEPROM with an

address byte of “1010 0000” for writing and “1010 0001”

for reading. For the data values of 2 bytes, the most sig-

Figure 7. DCR Sensing

______________________________________________________________________________________

External EEPROM Interface

Digital Power-Supply Controller/Monitor

Temperature Sensing

ISN+

BIAS

ISN-

V0+

V0-

RS+

RS-

nificant byte is stored in the lower offset, whereas the

least significant byte is stored in the higher offset.

Upon reset, the MAX8688 tests for the presence of a

configuration EEPROM. It searches for the SIGNATURE

bytes in the attached EEPROM. If the SIGNATURE

bytes are present, it concludes that it has a valid con-

figuration EEPROM and starts reading configuration

information from the attached EEPROM. If slave

address information is present, this overrides the slave

address information previously set by the address

A3:A1 pins.

Table 1 shows the contents and offsets of the configu-

ration information expected by the MAX8688. This infor-

mation is for reference only. It is recommended to use a

properly configured, working MAX8688 and to save its

state to the EEPROM and limit modifications to as few

fields as possible (such as the slave address).

Some ‘reserved’ fields may contain data other than 0

when the state is saved to the EEPROM. These locations

are ignored on restoration from the EEPROM or are fre-

quently recomputed. Some reserved fields need to be set

to greater than 0 to guarantee proper operation timing.

Temperature, voltage, and current values are stored in

internal representation, which is not identical to the for-

mat used by the corresponding PMBus command(s).

For details on EEPROM internal representation, see the

notes following Table 1.

For example, to store to the EEPROM, VOUT_COMMAND

= 3.0V, m = 19995, b = 0, R = -1. First calculate the

PMBus command value, which is 5998. If the voltage

range is 2V, no conversion is required. Hence write 17h

to offset 14 and 6Eh to offset 15. If the voltage range is

5.5V, the stored EEPROM value = 5998/2.75 = 2181. So

at offset 14, write 08h and offset 15, write 85h.

Note that the conversion is automatically handled by

the MAX8688 as it restores and stores configuration

information into the EEPROM.

with PMBus Interface

MAX8688ALETG+ Maxim Integrated Products, MAX8688ALETG+ Datasheet - Page 15

MAX8688ALETG+

Specifications of MAX8688ALETG+

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