MAX7325ATG+ - Maxim - Datasheet.Live

General Description

The MAX7325 2-wire serial-interfaced peripheral features

16 I/O ports. Ports are divided into eight push-pull out-

puts and eight I/Os with selectable internal pullups and

transition detection. Eight ports are push-pull outputs

and eight I/Os may be used as a logic input or an open-

drain output. Ports are overvoltage protected to +6V.

All I/O ports configured as inputs are continuously mon-

itored for state changes (transition detection). State

changes are indicated by the INT output. The interrupt

is latched, allowing detection of transient changes.

When the MAX7325 is subsequently accessed through

the serial interface, any pending interrupt is cleared.

The open-drain outputs are rated to sink 20mA, and are

capable of driving LEDs. The RST input clears the serial

interface, terminating any I2C communication to or from

the MAX7325.

The MAX7325 uses two address inputs with four-level

logic to allow 16 I2C slave addresses. The slave

address also determines the power-up logic state for

the I/O ports, and enables or disables internal 40kΩ

pullups in groups of four ports.

The MAX7325 is one device in a family of pin-compatible

port expanders with a choice of input ports, open-drain

I/O ports, and push-pull output ports (see Table 1).

The MAX7325 is available in 24-pin QSOP and TQFN

packages and is specified over the -40°C to +125°C

automotive temperature range.

Applications

Cell Phones Notebooks

SAN/NAS Satellite Radio

Servers Automotive

Features

♦400kHz I2C Serial Interface

♦+1.71V to +5.5V Operation

♦8 Push-Pull Outputs

♦8 Open-Drain I/O Ports, Rated to 20mA Sink

Current

♦I/O Ports are Overvoltage Protected to +6V

♦Selectable I/O Port Power-Up Default Logic States

♦Transient Changes are Latched, Allowing

Detection Between Read Operations

♦INT Output Alerts Change on Inputs

♦AD0 and AD2 Inputs Select from 16 Slave

Addresses

♦Low 0.6µA (typ) Standby Current

♦-40°C to +125°C Temperature Range

MAX7325

I2C Port Expander with 8 Push-Pull

and 8 Open-Drain I/Os

________________________________________________________________ Maxim Integrated Products 1

19-3807; Rev 0; 9/06

For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at

1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com.

EVALUATION KIT

AVAILABLE

Ordering Information

PART TEMP RANGE PIN-PACKAGE PKG

CODE

MAX7325AEG+ -40°C to +125°C 24 QSOP E24-1

MAX7325ATG+ -40°C to +125°C 24 TQFN-EP*

(4mm x 4mm) T2444-3

Typical Application Circuit and Functional Diagram appear

at end of data sheet.

Selector Guide

PART INPUTS INTERRUPT

MASK

OPEN-

DRAIN

OUTPUTS

PUSH-PULL

OUTPUTS

MAX7324 8 Yes — 8

MAX7325 Up to 8 — Up to 8 8

MAX7326 4 Yes — 12

MAX7327 Up to 4 — Up to 4 12

+Denotes lead-free package.

*EP = Exposed paddle.

TQFN (4mm x 4mm)

TOP VIEW

MAX7325

12 3456

18 17 16 15 14 13

SCL

V+

SDA

INT

AD2

AD0

O15

O13

O12

O11

RST

O10

GND

O14

EXPOSED PADDLE

Pin Configurations

Pin Configurations continued at end of data sheet.

MAX7325

I2C Port Expander with 8 Push-Pull

and 8 Open-Drain I/Os

2 _______________________________________________________________________________________

ABSOLUTE MAXIMUM RATINGS

Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional

operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to

absolute maximum rating conditions for extended periods may affect device reliability.

(All voltages referenced to GND.)

Supply Voltage V+....................................................-0.3V to +6V

SCL, SDA, AD0, AD2, RST, INT, P0–P7 ...................-0.3V to +6V

O8–O15 ........................................................-0.3V to (V+ + 0.3V)

O8–O15 Output Current ...................................................±25mA

P0–P7 Sink Current ......................................................................25mA

SDA Sink Current ........................................................................ 10mA

INT Sink Current..................................................................10mA

Total V+ Current..................................................................50mA

Total GND Current ...........................................................100mA

Continuous Power Dissipation (TA= +70°C)

24-Pin QSOP (derate 9.5mW/°C over +70°C)...........761.9mW

24-Pin TQFN (derate 20.8mW/°C over+70°C) ........1666.7mW

Operating Temperature Range .........................-40°C to +125°C

Junction Temperature......................................................+150°C

Storage Temperature Range .............................-65°C to +150°C

Lead Temperature (soldering, 10s) .................................+300°C

DC ELECTRICAL CHARACTERISTICS

(V+ = +1.71V to +5.5V, TA= -40°C to +125°C, unless otherwise noted. Typical values are at V+ = +3.3V, TA= +25°C.) (Note 1)

PARAMETER

SYMBOL

CONDITIONS

MIN

TYP

MAX

UNITS

Operating Supply Voltage V+ TA = -40°C to +125°C

1.71 5.50

Power-On-Reset Voltage VPOR V+ falling 1.6 V

Standby Current

(Interface Idle) ISTB SCL and SDA and other

digital inputs at V+

TA = -40°C to

+125°C 0.6 1.9 µA

Supply Current

(Interface Running) I+ fSCL = 400kHz; other

digital inputs at V+

TA = -40°C to

+125°C 23 55 µA

V+ < 1.8V

0.8 x V+

Input High-Voltage

SDA, SCL, AD0, AD2, RST, P0–P7

VIH V+ ≥ 1.8V

0.7 x V+

V+ < 1.8V

0.2 x V+

Input Low-Voltage

SDA, SCL, AD0, AD2, RST, P0–P7

VIL V+ ≥ 1.8V

0.3 x V+

Input Leakage Current

SDA, SCL, AD0, AD2, RST, P0–P7

IIH, IIL SDA, SCL, AD0, AD2, RST, P0–P7 at V+ or

GND, internal pullup disabled

-0.2

+0.2 µA

Input Capacitance

SDA, SCL, AD0, AD2, RST, P0–P7

10 pF

V+ = +1.71V, ISINK = 5mA (QSOP) 90 180

V+ = +1.71V, ISINK = 5mA (TQFN) 90 230

V+ = +2.5V, ISINK = 10mA (QSOP)

110

210

V+ = +2.5V, ISINK = 10mA (TQFN)

110

260

V+ = +3.3V, ISINK = 15mA (QSOP)

130

230

V+ = +3.3V, ISINK = 15mA (TQFN)

130

280

V+ = +5V, ISINK = 20mA (QSOP)

140

250

Output Low Voltage

O8–O15, P0–P7 VOL

V+ = +5V, ISINK = 20mA (TQFN)

140

300

V+ = +1.71V, ISOURCE = 2mA

V + - 250 V + - 30

V+ = +2.5V, ISOURCE = 5mA

V + - 360 V + - 70

V+ = +3.3V, ISOURCE = 5mA

V + - 260 V + - 100

Output High Voltage

O8–O15 VOH

V+ = +5V, ISOURCE = 10mA

V + - 360 V + - 120

Output Low-Voltage SDA

VOLSDA

ISINK = 6mA 250 mV

Output Low-Voltage INT

VOLINT

ISINK = 5mA

130

250 mV

Port Input Pullup Resistor RPU 25 40 55 kΩ

MAX7325

I2C Port Expander with 8 Push-Pull

and 8 Open-Drain I/Os

_______________________________________________________________________________________ 3

PORT AND INTERRUPT INT TIMING CHARACTERISTICS

(V+ = +1.71V to +5.5V, TA= -40°C to +125°C, unless otherwise noted. Typical values are at V+ = +3.3V, TA= +25°C.) (Note 1)

PARAMETER

SYMBOL

CONDITIONS

MIN TYP MAX

UNITS

Port Output Data Valid tPPV CL ≤ 100pF 4 µs

Port Input Setup Time tPSU CL ≤ 100pF 0 µs

Port Input Hold Time tPH CL ≤ 100pF 4 µs

INT Input Data Valid Time tIV CL ≤ 100pF 4 µs

INT Reset Delay Time from STOP

tIP CL ≤ 100pF 4 µs

INT Reset Delay Time from

Acknowledge tIR CL ≤ 100pF 4 µs

TIMING CHARACTERISTICS

(V+ = +1.71V to +5.5V, TA= -40°C to +125°C, unless otherwise noted. Typical values are at V+ = +3.3V, TA= +25°C.) (Note 1)

PARAMETER

SYMBOL

CONDITIONS MIN

TYP MAX

UNITS

Serial-Clock Frequency fSCL 400 kHz

Bus Free Time Between a STOP

and a START Condition tBUF 1.3 µs

Hold Time (Repeated) START

Condition

tHD

STA

0.6 µs

Repeated START Condition

Setup Time

tSU

STA

0.6 µs

STOP Condition Setup Time

tSU

STO

0.6 µs

Data Hold Time

tHD

DAT

(Note 2) 0.9 µs

Data Setup Time

tSU

DAT

100 ns

SCL Clock Low Period tLOW 1.3 µs

SCL Clock High Period tHIGH 0.7 µs

Rise Time of Both SDA and SCL

Signals, Receiving tR(Notes 3, 4) 20 +

0.1Cb

300 ns

Fall Time of Both SDA and SCL

Signals, Receiving tF(Notes 3, 4) 20 +

0.1Cb

300 ns

Fall Time of SDA Transmitting tF,TX (Notes 3, 4) 20 +

0.1Cb

250 ns

Pulse Width of Spike Suppressed

tSP (Note 5)

Capacitive Load for Each Bus

Line Cb(Note 3) 400 pF

RST Pulse Width tW500 ns

RST Rising to START Condition

Setup Time tRST 1µs

Note 1: All parameters are tested at TA= +25°C. Specifications over temperature are guaranteed by design.

Note 2: A master device must provide a hold time of at least 300ns for the SDA signal (referred to VIL of the SCL signal) in order to

bridge the undefined region of SCL’s falling edge.

Note 3: Guaranteed by design.

Note 4: Cb= total capacitance of one bus line in pF. ISINK ≤6mA. tRand tFmeasured between 0.3 x V+ and 0.7 x V+.

Note 5: Input filters on the SDA and SCL inputs suppress noise spikes less than 50ns.

MAX7325

I2C Port Expander with 8 Push-Pull

and 8 Open-Drain I/Os

4 _______________________________________________________________________________________

Typical Operating Characteristics

(TA = +25°C, unless otherwise noted.)

STANDBY CURRENT

vs. TEMPERATURE

TEMPERATURE (°C)

STANDBY CURRENT (µA)

MAX7325 toc01

-40 -25 -10 5 20 35 50 65 80 95 110 125

0.2

0.4

0.6

0.8

1.0

1.2

1.4

1.6

1.8

2.0

V+ = +3.3V

V+ = +5.0V

V+ = +2.5V

V+ = +1.71V

fSCL = 0kHz

SUPPLY CURRENT

vs. TEMPERATURE

TEMPERATURE (°C)

SUPPLY CURRENT (µA)

MAX7325 toc02

-40-25-105 203550658095110125

V+ = +3.3V

V+ = +5.0V

V+ = +2.5V

V+ = +1.71V

fSCL = 400kHz

OUTPUT VOLTAGE LOW

vs. TEMPERATURE

TEMPERATURE (°C)

OUTPUT VOLTAGE LOW (V)

MAX7325 toc03

-40 -25 -10 5 20 35 50 65 80 95 110 125

0.05

0.10

0.15

0.20

0.25

V+ = +3.3V

ISINK = 15mA

V+ = +5.0V

ISINK = 20mA

V+ = +2.5V

ISINK = 10mA

V+ = +1.71V

ISINK = 5mA

OUTPUT VOLTAGE HIGH

vs. TEMPERATURE

TEMPERATURE (°C)

OUTPUT VOLTAGE HIGH (V)

MAX7325 toc04

-40 -25 -10 5 20 35 50 65 80 95 110 125

V+ = +3.3V

ISOURCE = 5mA

V+ = +5.0V

ISOURCE = 10mA

V+ = +2.5V ISOURCE = 5mA

V+ = +1.71V ISOURCE = 2mA

Pin Description

QSOP

TQFN NAME FUNCTION

122 INT Interrupt Output, Active Low. INT is an open-drain output.

223 RST Reset Input, Active Low. Drive RST low to clear the 2-wire interface.

3, 21

24, 18

AD2, AD0 Address Inputs. Select device slave address with AD0 and AD2. Connect AD0 and AD2

to either GND, V+, SCL, or SDA to give four logic combinations (see Tables 2 and 3).

4–11 1–8 P0–P7 Open-Drain I/O Ports

12 9 GND Ground

13–20 10–17 O8–O15 Output Ports. O8–O15 are push-pull outputs rated at 20mA.

22 19 SCL I2C-Compatible Serial-Clock Input

23 20 SDA I2C-Compatible Serial-Data I/O

24 21 V+ Positive Supply Voltage. Bypass V+ to GND with a ceramic capacitor of at least 0.047µF.

— EP EP Exposed Paddle. Connect exposed pad to GND.

Detailed Description

MAX7319–MAX7329 Family Comparison

The MAX7324–MAX7327 family consists of four pin-

compatible, 16-port expanders that integrate the func-

tions of the MAX7320 and one of either MAX7319,

MAX7321, MAX7322, or MAX7323.

Functional Overview

The MAX7325 is a general-purpose port expander oper-

ating from a +1.71V to +5.5V supply with eight push-pull

outputs and eight open-drain I/O ports. Each open-drain

output is rated to sink 20mA, and the entire device is

rated to sink 100mA into all ports combined. The outputs

drive loads connected to supplies up to +5.5V.

The MAX7325 is set to two of 32 I2C slave addresses

(see Tables 2 and 3) using the address select inputs

AD0 and AD2, and is accessed over an I2C serial inter-

face up to 400kHz. The eight outputs and eight I/Os

have different slave addresses. The eight push-pull out-

puts have the 101xxxx addresses and the eight inputs

have addresses with 110xxxx. The RST input clears the

serial interface in case of a bus lockup, terminating any

serial transaction to or from the MAX7325.

Configure any port as a logic input by setting the port

output logic-high (logic-high for an open-drain output is

high impedance). When the MAX7325 is read through

the serial interface, the actual logic levels at the ports

are read back.

MAX7325

I2C Port Expander with 8 Push-Pull

and 8 Open-Drain I/Os

_______________________________________________________________________________________ 5

PART

I2C

SLAVE

ADDRESS

INPUTS

INPUT

INTERRUPT

MASK

OPEN-

DRAIN

OUTPUTS

PUSH-

PULL

OUTPUTS

CONFIGURATION

16-PORT EXPANDERS

MAX7324

8 Yes — 8

8 input and 8 push-pull output versions:

8 input ports with programmable latching transition

detection interrupt and selectable pullups.

8 push-pull outputs with selectable default logic

levels.

Offers maximum versatility for automatic input

monitoring. An interrupt mask selects which inputs

cause an interrupt on transitions, and transition flags

identify which inputs have changed (even if only

for a transient) since the ports were last read.

MAX7325

101xxxx

and

110xxxx

Up to 8

— Up to 8 8

8 I/O and 8 push-pull output versions:

8 open-drain I/O ports with latching transition

detection interrupt and selectable pullups.

8 push-pull outputs with selectable default logic

levels.

Open-drain outputs can level shift the logic-high

state to a higher or lower voltage than V+ using

external pullup resistors, but pullups draw current

when output is low. Any open-drain port can be used

as an input by setting the open-drain output to logic-

high. Transition flags identify which open-drain port

inputs have changed (even if only for a transient)

since the ports were last read.

Table 1. MAX7319–MAX7329 Family Comparison

MAX7325

I2C Port Expander with 8 Push-Pull

and 8 Open-Drain I/Os

6 _______________________________________________________________________________________

PART

I2C

SLAVE

ADDRESS

INPUTS

INPUT

INTERRUPT

MASK

OPEN-

DRAIN

OUTPUTS

PUSH-

PULL

OUTPUTS

CONFIGURATION

MAX7326

4 Yes — 12

4 input-only, 12 push-pull output versions:

4 input ports with programmable latching transition

detection interrupt and selectable pullups.

12 push-pull outputs with selectable default logic

levels.

Offers maximum versatility for automatic input

monitoring. An interrupt mask selects which inputs

cause an interrupt on transitions, and transition flags

identify which inputs have changed (even if only

for a transient) since the ports were last read.

MAX7327

101xxxx

and

110xxxx

Up to 4

— Up to 4 12

4 I/O, 12 push-pull output versions:

4 open-drain I/O ports with latching transition

detection interrupt and selectable pullups.

12 push-pull outputs with selectable default logic

levels.

Open-drain outputs can level shift the logic-high

state to a higher or lower voltage than V+ using

external pullup resistors, but pullups draw current

when output is low. Any open-drain port can be used

as an input by setting the open-drain output to logic-

high. Transition flags identify which open-drain port

inputs have changed (even if only for a transient)

since the ports were last read.

8-PORT EXPANDERS

MAX7319

110xxxx

8 Yes — —

Input-only versions:

8 input ports with programmable latching transition

detection interrupt and selectable pullups.

MAX7320

101xxxx

—— — 8

Output-only versions:

8 push-pull outputs with selectable power-up default

levels.

MAX7321

110xxxx Up to 8

— Up to 8 —

I/O versions:

8 open-drain I/O ports with latching transition

detection interrupt and selectable pullups.

MAX7322

110xxxx

4 Yes — 4

4 input-only, 4 output-only versions:

4 input ports with programmable latching transition

detection interrupt and selectable pullups.

4 push-pull outputs with selectable power-up default

levels.

Table 1. MAX7319–MAX7329 Family Comparison (continued)

MAX7325

I2C Port Expander with 8 Push-Pull

and 8 Open-Drain I/Os

_______________________________________________________________________________________ 7

The open-drain ports offer latching transition detection

when used as inputs. All input ports are continuously

monitored for changes. An input change sets one of 8

flag bits that identify changed input(s). All flags are

cleared upon a subsequent read or write transaction to

the MAX7325.

A latching interrupt output, INT, is programmed to flag

logic changes on ports used as inputs. Data changes

on any input port forces INT to a logic-low. Changing

the I/O port level through the serial interface does not

cause an interrupt. The interrupt output INT is deassert-

ed when the MAX7325 is next accessed through the

serial interface.

Internal pullup resistors to V+ are selected by the

address select inputs, AD0 and AD2. Pullups are

enabled on the input ports in groups of four (see Table 2).

Use the slave address selection to ensure that I/O ports

used as inputs are logic-high on power-up. I/O ports

with internal pullups enabled default to a logic-high out-

put state. I/O ports with internal pullups disabled

default to a logic-low output state.

Output port power-up logic levels are selected by the

address select inputs, AD0 and AD2. Ports default to

logic-high or logic-low on power-up in groups of four

(see Tables 2 and 3).

Initial Power-Up

On power-up, the transition detection logic is reset, and

INT is deasserted. The transition flags are cleared to indi-

cate no data changes. The power-up default states of the

16 I/O ports are set according to the I2C slave address

selection inputs, AD0 and AD2 (Tables 2 and 3). For I/O

ports used as inputs, ensure that the default states are

logic-high so that the I/O ports power up in the high-

impedance state. All I/O ports configured with pullups

enabled also have a logic-high power-up state.

Power-On Reset

The MAX7325 contains an integral power-on-reset

(POR) circuit that ensures all registers are reset to a

known state on power-up. When V+ rises above VPOR

(1.6V max), the POR circuit releases the registers and

2-wire interface for normal operation. When V+ drops to

less than VPOR, the MAX7325 resets all register con-

tents to the POR defaults (Tables 2 and 3).

RST

Input

The active-low RST input voids any I2C transaction

involving the MAX7325, forcing the MAX7325 into the

I2C STOP condition. A reset does not affect the inter-

rupt output (INT).

Standby Mode

When the serial interface is idle, the MAX7325 automatical-

ly enters standby mode, drawing minimal supply current.

Slave Address, Power-Up Default Logic

Levels, and Input Pullup Selection

Address inputs AD0 and AD2 determine the MAX7325

slave address, set the power-up I/O state for the ports,

and select which inputs have pullup resistors. Internal

pullups and power-up default states are set in groups

of four (see Table 2).

The MAX7325 slave address is determined on each I2C

transmission, regardless of whether the transmission is

actually addressing the MAX7325. The MAX7325 distin-

guishes whether address inputs AD0 and AD2 are con-

nected to SDA or SCL instead of fixed logic levels V+

or GND during this transmission. The MAX7325 slave

address can be configured dynamically in the applica-

tion without cycling the device supply.

On initial power-up, the MAX7325 cannot decode the

address inputs AD0 and AD2 fully until the first I2C

transmission. AD0 and AD2 initially appear to be

PART

I2C

SLAVE

ADDRESS

INPUTS

INPUT

INTERRUPT

MASK

OPEN-

DRAIN

OUTPUTS

PUSH-

PULL

OUTPUTS

CONFIGURATION

MAX7323

110xxxx Up to 4

— Up to 4 4

4 I/O, 4 output-only versions:

4 open-drain I/O ports with latching transition

detection interrupt and selectable pullups.

4 push-pull outputs with selectable power-up default

levels.

MAX7328

MAX7329

0100xxx

0111xxx Up to 8

— Up to 8 — 8 open-drain I/O ports with nonlatching transition

detection interrupt and pullups on all ports.

Table 1. MAX7319–MAX7329 Family Comparison (continued)

MAX7325

I2C Port Expander with 8 Push-Pull

and 8 Open-Drain I/Os

8 _______________________________________________________________________________________

connected to V+ or GND. This is important because the

address selection is used to determine the power-up

logic state and whether pullups are enabled. At power-

up, the I2C SDA and SCL bus interface lines are high

impedance at the inputs of every device (master or

slave) connected to the bus, including the MAX7325.

This is guaranteed as part of the I2C specification.

Therefore, when address inputs AD0 and AD2 are con-

nected to SDA or SCL during power-up, they appear to

be connected to V+.

The power-up logic uses AD0 to select the power-up

state and whether pullups are enabled for ports P0–P3,

and AD2 for ports P4–P7. The rule is that a logic-high,

SDA, or SCL connection selects the pullups and sets

the default logic state to high. A logic-low deselects the

pullups and sets the default logic state to low (Table 2).

The port configuration is correct on power-up for a

standard I2C configuration, where SDA or SCL are

pulled up to V+ by the external I2C pullup resistors.

There are circumstances where the assumption that

SDA = SCL = V+ on power-up is not true—for example,

in applications in which there is legitimate bus activity

during power-up. If SDA and SCL are terminated with

pullup resistors to a different supply voltage than the

MAX7325’s supply voltage, and if that pullup supply

rises later than the MAX7325’s supply, then SDA or

SCL may appear at power-up to be connected to GND.

In such applications, use the four address combina-

tions that are selected by connecting address inputs

AD0 and AD2 to V+ or GND (shown in bold in Tables 2

and 3). These selections are guaranteed to be correct

at power-up, independent of SDA and SCL behavior. If

one of the other 12 address combinations is used, an

unexpected combination of pullups might be asserted

until the first I2C transmission (to any device, not neces-

sarily the MAX7325) is put on the bus, and an unex-

pected combination of ports can initialize as logic-low

outputs instead of inputs or logic-high outputs.

CONNECTION

DEVICE ADDRESS PORT POWER-UP DEFAULT

40kΩ INPUT PULLUPS ENABLED

AD2

AD0 A6A5A4A3A2A1A0P7P6P5P4P3P2P1P0P7P6P5P4P3P2P1

SCL

GND110000011110000YYYY———

—

SCL

V+

110000111111111YYYYYYY

SCL

SCL110001011111111YYYYYYY

SCL

SDA110001111111111YYYYYYY

SDA

GND110010011110000YYYY———

—

SDA

V+

110010111111111YYYYYYY

SDA

SCL110011011111111YYYYYYY

SDA

SDA110011111111111YYYYYYY

GND

GND110100000000000———————

—

GND

V+

110100100001111———— YYY

GND

SCL110101000001111———— Y Y Y

GND

SDA110101100001111———— Y Y Y

V+

GND110110011110000YYYY———

—

V+ V+

110110111111111YYYYYYY

V+

SCL110111011111111YYYYYYY

V+

SDA110111111111111YYYYYYY

Table 2. MAX7325 Address Map for Ports P0–P7

MAX7325

I2C Port Expander with 8 Push-Pull

and 8 Open-Drain I/Os

_______________________________________________________________________________________ 9

C O NN EC TIO N

DEVICE ADDRESS OUTPUTS POWER-UP DEFAULT

AD2

AD0 A6 A5 A4 A3 A2 A1 A0 O15 O14 O13 O12 O11 O10 O9

SCL

GND

101000011110000

SCL

V+

101000111111111

SCL

101001011111111

SCL

SDA

101001111111111

SDA

GND

101010011110000

SDA

V+

101010111111111

SDA

SCL

101011011111111

SDA

101011111111111

GND

101100000000000

GND

V+

101100100001111

GND

SCL

101101000001111

GND

SDA

101101100001111

V+

GND

101110011110000

V+

101110111111111

V+

SCL

101111011111111

V+

SDA

101111111111111

Table 3. MAX7325 Address Map for Outputs O8–O15

Port Inputs

I/O port inputs switch at the CMOS-logic levels as

determined by the expander’s supply voltage, and are

overvoltage tolerant to +6V, independent of the

expander’s supply voltage.

I/O Port Input Transition Detection

All I/O ports configured as inputs are monitored for

changes since the expander was last accessed through

the serial interface. The state of the ports is stored in an

internal “snapshot” register for transition monitoring. The

snapshot is continuously compared with the actual input

conditions, and if a change is detected for any port input,

INT is asserted to signal a state change. The input ports

are sampled (internally latched into the snapshot register)

and the old transition flags cleared during the I2C acknowl-

edge of every MAX7325 read and write access. The previ-

ous port transition flags are read through the serial

interface as the second byte of a 2-byte read sequence.

MAX7325

I2C Port Expander with 8 Push-Pull

and 8 Open-Drain I/Os

10 ______________________________________________________________________________________

Serial Interface

Serial Addressing

The MAX7325 operates as a slave that sends and

receives data through an I2C interface. The interface

uses a serial-data line (SDA) and a serial-clock line (SCL)

to achieve bidirectional communication between mas-

ter(s) and slave(s). The master initiates all data transfers

to and from the MAX7325 and generates the SCL clock

that synchronizes the data transfer (Figure 1).

SDA operates as both an input and an open-drain out-

put. A pullup resistor, typically 4.7kΩ, is required on

SDA. SCL operates only as an input. A pullup resistor,

typically 4.7kΩ, is required on SCL if there are multiple

masters on the 2-wire interface, or if the master in a sin-

gle-master system has an open-drain SCL output.

Each transmission consists of a START condition sent

by a master, followed by the MAX7325’s 7-bit slave

addresses plus R/Wbits, 1 or more data bytes, and

finally a STOP condition (Figure 2).

START and STOP Conditions

Both SCL and SDA remain high when the interface is

not busy. A master signals the beginning of a transmis-

sion with a START (S) condition by transitioning SDA

from high to low while SCL is high. When the master

has finished communicating with the slave, the master

issues a STOP (P) condition by transitioning SDA from

low to high while SCL is high. The bus is then free for

another transmission (Figure 2).

Bit Transfer

One data bit is transferred during each clock pulse.

The data on SDA must remain stable while SCL is high

(Figure 3).

SCL

SDA

tRtF

tBUF

START

CONDITION

STOP

CONDITION

REPEATED START CONDITION

START CONDITION

tSU,STO

tHD,STA

tSU,STA

tHD,DAT

tSU,DAT

tLOW

tHIGH

tHD,STA

Figure 1. 2-Wire Serial Interface Timing Details

SDA

SCL

START

CONDITION

STOP

CONDITION

Figure 2. START and STOP Conditions

SDA

SCL

DATA LINE STABLE;

DATA VALID

CHANGE OF DATA

ALLOWED

Figure 3. Bit Transfer

Acknowledge

The acknowledge bit is a clocked 9th bit the recipient

uses to acknowledge receipt of each byte of data

(Figure 4). Each byte transferred effectively requires 9

bits. The master generates the 9th clock pulse, and the

recipient pulls down SDA during the acknowledge

clock pulse, such that the SDA line is stable low during

the high period of the clock pulse. When the master is

transmitting to the MAX7325, the device generates the

acknowledge bit because the MAX7325 is the recipi-

ent. When the MAX7325 is transmitting to the master,

the master generates the acknowledge bit because the

master is the recipient.

Slave Address

Each MAX7325 has two different 7-bit slave addresses

(Tables 2 and 3). The addresses are different to communi-

cate to either the eight push-pull outputs or the eight I/Os.

The 8th bit of the slave address following the 7-bit slave

address is the R/Wbit. It is low for a write command, and

high for a read command (Figure 5). The first (A6), sec-

ond (A5), and third (A4) bits of the MAX7325 slave

address are always 1, 1, and 0 (P0–P7) or 1, 0, and 1

(O8 to O15). Connect AD0 and AD2 to GND, V+, SDA,

or SCL to select the slave address bits A3, A2, A1, and

A0. The MAX7325 has 16 possible pairs of slave

addresses (Tables 2 and 3), allowing up to 16

MAX7325 devices on an I2C bus.

Accessing the MAX7325

The MAX7325 is accessed though an I2C interface. The

MAX7325 has two different 7-bit slave addresses for

either the eight open-drain I/O ports (P0–P7) or the

eight push-pull ports (O8–O15). See Tables 2 and 3.

Asingle-byte read from the I/O ports (P0–P7) of the

MAX7325 returns the status of the eight I/O ports and

clears both the internal transition flags and the INT out-

put when the master acknowledges the slave address

byte. A single-byte read from the eight push-pull ports

(O8–O15) returns the status of the eight output ports,

read back as inputs.

A 2-byte read from the I/O ports (P0–P7) of the

MAX7325 returns the status of the eight I/O ports (as for

a single-byte read), followed by the transition flags.

Again, the internal transition flags and the INT output

are cleared when the master acknowledges the slave

address byte, yet the previous transition flag data is

sent as the second byte. A 2-byte read from the push-

pull ports of the MAX7325 repeatedly returns the status

of the eight output ports, read back as inputs.

Amultibyte read (more than 2 bytes before the I2C

STOP bit) from the I/O ports (P0–P7) of the MAX7325

repeatedly returns the port data, followed by the transi-

tion flags. As the port data is resampled for each trans-

mission, and the transition flags are reset each time, a

multibyte read continuously returns the current data

and identifies any changing input ports.

MAX7325

I2C Port Expander with 8 Push-Pull

and 8 Open-Drain I/Os

______________________________________________________________________________________ 11

SCL

SDA BY

TRANSMITTER

CLOCK PULSE

FOR ACKNOWLEDGEMENT

START

CONDITION

SDA BY

RECEIVER

12 89

Figure 4. Acknowledge

SDA

SCL

MSB LSB

ACKA4 A1A3 A0A2 R/W

Figure 5. Slave Address

MAX7325

I2C Port Expander with 8 Push-Pull

and 8 Open-Drain I/Os

12 ______________________________________________________________________________________

If a port input data change occurs during the read

sequence, then INT is reasserted during the I2C STOP

bit. The MAX7325 does not generate another interrupt

during a single-byte or multibyte read.

Input port data is sampled during the preceding I2C

acknowledge bit (the acknowledge bit for the I2C slave

address in the case of a single-byte or two-byte read).

A multibyte read from the push-pull ports of the

MAX7325 repeatedly returns the status of the eight out-

put ports, read back as inputs.

A single-byte write to either port groups of the

MAX7325 sets the logic state of all eight ports.

A multibyte write to either port group of the MAX7325

repeatedly sets the logic state of all eight ports.

Reading the MAX7325

A read from the open-drain I/O ports of the MAX7325

starts with the master transmitting the port group’s

slave address with the R/Wbit set to high. The

MAX7325 acknowledges the slave address, and sam-

ples the ports during the acknowledge bit. INT

deasserts during the slave address acknowledge.

Typically, the master reads 1 or 2 bytes from the

MAX7325, each byte being acknowledged by the mas-

ter upon reception with the exception of the last byte.

When the master reads one byte from the open-drain

ports of the MAX7325 and subsequently issues a STOP

condition (Figure 6), the MAX7325 transmits the current

port data, clears the change flags, and resets the tran-

sition detection. INT deasserts during the slave

SCL

MAX7325 SLAVE ADDRESS

S1 1 0 A P

PORT

tIV

P0 ACKNOWLEDGE

FROM MASTER

ACKNOWLEDGE

FROM MAX7325 P1

P2P3P4P5

D0D1D2D3D4D5D6D7

PORT I/O

INT OUTPUT

R/W PORT SNAPSHOT

tPH

tIR

PORT SNAPSHOT

S = START CONDITION SHADED = SLAVE TRANSMISSION

P = STOP CONDITION N = NOT ACKNOWLEDGE

tPSU tIP

INT REMAINS HIGH UNTIL STOP CONDITION

Figure 6. Reading Open-Drain Ports of the MAX7325 (1 Data Byte)

MAX7325

I2C Port Expander with 8 Push-Pull

and 8 Open-Drain I/Os

______________________________________________________________________________________ 13

SCL

MAX7325 SLAVE ADDRESSS110 A

PORTS

INT OUTPUT

R/W PORT SNAPSHOT

tIV

tPH

tIR

AD0D1D2D3D4D5D6D7

PORT SNAPSHOT

tPSU tIP

D7 D6 D5 D4 D3 D2 D1 D0 N

PORT SNAPSHOT

INT REMAINS HIGH UNTIL STOP CONDITION

I2I3I4I5

I7 F0

F2F3F4F5

PORT INPUTS INTERRUPT FLAGS

S = START CONDITION SHADED = SLAVE TRANSMISSION

P = STOP CONDITION N = NOT ACKNOWLEDGE

ACKNOWLEDGE

FROM MASTER

ACKNOWLEDGE

FROM MAX7325

Figure 7. Reading Open-Drain Ports of the MAX7325 (2 Data Bytes)

SCL

MAX7325 SLAVE ADDRESS

SA P

ACKNOWLEDGE FROM MAX7325

PORT SNAPSHOT DATA

PORT SNAPSHOT TAKEN

P0P1P2P3

DATA 1

P4P5P6P7

D0D1D2D3D4D5D6D7

PORT SNAPSHOT TAKEN ACKNOWLEDGE

FROM MASTER

R/W

Figure 8. Reading Push-Pull Ports of MAX7325

acknowledge. The new snapshot data is the current

port data transmitted to the master, and therefore, port

changes occuring during the transmission are detect-

ed. INT remains high until the STOP condition.

The master can read 2 bytes from the open-drain ports

of the MAX7325 and subsequently issues a STOP con-

dition (Figure 7). In this case, the MAX7325 transmits

the current port data, followed by the change flags. The

change flags are then cleared, and transition detection

is reset. INT goes high (high impedance if an external

pullup resistor is not fitted) during the slave acknowl-

edge. The new snapshot data is the current port data

transmitted to the master, and therefore, port changes

occuring during the transmission are detected. INT

remains high until the STOP condition.

A read from the push-pull ports of the MAX7325 starts

with the master transmitting the group’s slave address

with the R/Wbit set high. The MAX7325 acknowledges

the slave address, and samples the logic state of the

output ports during the acknowledge bit. The master can

read one or more bytes from the push-pull ports of the

MAX7325 and then issues a STOP condition (Figure 8).

The MAX7325 transmits the current port data, read

back from the actual port outputs (not the port output

latches) during the acknowledge. If a port is forced to a

logic state other than its programmed state, the read-

back reflects this. If driving a capacitive load, the read-

back port level verification algorithms may need to take

the RC rise/fall time into account.

Typically, the master reads one byte from the push-pull

ports of the MAX7325, then issues a STOP condition

(Figure 8). However, the master can read two or more

bytes from the group B ports of the MAX7325, then

issues a STOP condition. In this case, the MAX7325

resamples the port outputs during each acknowledge

and transmits the new data each time.

Writing the MAX7325

A write to either output port groups of the MAX7325

starts with the master transmitting the group’s slave

address with the R/Wbit set low. The MAX7325

acknowledges the slave address and samples the

ports during the acknowledge bit. INT goes high (high

impedance if an external pullup resistor is not fitted)

during the slave acknowledge only when it writes to the

open-drain ports. The master can now transmit one or

more bytes of data. The MAX7325 acknowledges these

subsequent bytes of data and updates the correspond-

ing group’s ports with each new byte until the master

issues a STOP condition (Figure 9).

Applications Information

Port Input and I2C Interface Level

Translation from Higher or

Lower Logic Voltages

The MAX7325’s SDA, SCL, AD0, AD2, RST, INT, O8–O15,

and P0–P7 are overvoltage protected to +6V. This

allows the MAX7325 to operate from a lower supply

voltage, such as +3.3V, while the I2C interface and/or

any of the eight I/O ports are driven as inputs from a

higher logic level, such as +5V.

The MAX7325 can operate from a higher supply volt-

age, such as +3V, while the I2C interface and/or some

of the I/O ports P0–P7 are driven from a lower logic

level, such as +2.5V. For V+ < 1.8V, apply a minimum

voltage of 0.8 x V+ to assert a logic-high on any input.

For a V+ ≥1.8V, apply a voltage of 0.7 x V+ to assert a

logic-high. For example, a MAX7325 operating from a

+5V supply may not recognize a +3.3V nominal logic-

high. One solution for input-level translation is to drive

MAX7325 I/Os from open-drain outputs. Use a pullup

resistor to V+ or a higher supply to ensure a high logic

voltage greater than 0.7 x V+.

Port Output Signal-Level Translation

The open-drain output architecture allows for level trans-

lation to higher or lower voltages than the MAX7325’s

supply. Use an external pullup resistor on any output to

convert the high-impedance logic-high condition to a

positive voltage level. The resistor can be connected to

any voltage up to +6V, and the resistor value chosen to

ensure no more than 20mA is sunk in the logic-low condi-

tion. For interfacing CMOS inputs, a pullup resistor value

of 220kΩis a good starting point. Use a lower resistance

to improve noise immunity, in applications where power

consumption is less critical, or where a faster rise time is

needed for a given capacitive load.

Each of the push-pull output ports has protection

diodes to V+ and GND. When a port output is driven to

a voltage higher than V+ or lower than GND, the appro-

priate protection diode clamps the output to a diode

drop above V+ or below GND. When the MAX7325 is

powered down (V+ = 0V), every output port’s protection

MAX7325

I2C Port Expander with 8 Push-Pull

and 8 Open-Drain I/Os

14 ______________________________________________________________________________________

SCL

SDA

SLAVE ADDRESS

12345678

AAA

DATA 1 DATA 2

DATA TO INTERRUPT MASK DATA TO INTERRUPT MASK

START CONDITION R/W ACKNOWLEDGE

FROM SLAVE

tPV

DATA 2 VALIDDATA 1 VALID

INTERNAL WRITE

TO PORT

DATA OUT

FROM PORT

ACKNOWLEDGE

FROM SLAVE

ACKNOWLEDGE

FROM SLAVE

tPV

Figure 9. Writing to the MAX7325

diodes to V+ and GND continue to appear as a diode

clamp from each output to GND (Figure 10).

Each of the I/O ports P0–P7 has a protection diode to

GND (Figure 11). When a port is driven to a voltage

lower than GND, the protection diode clamps the port

to a diode drop below GND.

Each of the I/O ports P0–P7 also has a 40kΩ(typ)

pullup resistor that can be enabled or disabled. When a

port input is driven to a voltage higher than V+, the

body diode of the pullup enable switch conducts and

the 40kΩpullup resistor is enabled. When the

MAX7325 is powered down (V+ = 0V), each I/O port

appears as a 40kΩresistor in series with a diode con-

nected to 0V. Input ports are protected to +6V under

any of these circumstances (Figure 11).

Driving LED Loads

When driving LEDs from one of the outputs, a resistor

must be fitted in series with the LED to limit the LED

current to no more than 20mA. Connect the LED cath-

ode to the MAX7325 port, and the LED anode to V+

through the series current-limiting resistor, RLED. Set

the port output low to illuminate the LED. Choose the

resistor value according to the following formula:

RLED = (VSUPPLY - VLED - VOL) / ILED

where:

RLED is the resistance of the resistor in series with the

LED (Ω).

VSUPPLY is the supply voltage used to drive the LED

(V).

VLED is the forward voltage of the LED (V).

VOL is the output low voltage of the MAX7325 when

sinking ILED (V).

ILED is the desired operating current of the LED (A).

For example, to operate a 2.2V red LED at 10mA from a

+5V supply:

RLED = (5 - 2.2 - 0.1) / 0.01 = 270Ω

Driving Load Currents Higher than 20mA

The MAX7325 can be used to drive loads, such as relays

that draw more than 20mA, by paralleling outputs. Use at

least one output per 20mA of load current; for example, a

5V 330mW relay draws 66mA, and therefore, requires

four paralleled outputs. Any combination of outputs can

be used as part of a load-sharing design because any

combination of ports can be set or cleared at the same

time by writing to the MAX7325. Do not exceed a total

sink current of 100mA for the device.

The MAX7325 must be protected from the negative-

voltage transient generated when switching off induc-

tive loads (such as relays), by connecting a

reverse-biased diode across the inductive load.

Choose the peak current for the diode to be greater

than the inductive load’s operating current.

Power-Supply Considerations

The MAX7325 operates with a supply voltage of +1.71V

to +5.5V. Bypass the supply to GND with a ceramic

capacitor of at least 0.047µF as close as possible to the

device. For the TQFN version, additionally connect the

exposed pad to GND.

MAX7325

I2C Port Expander with 8 Push-Pull

and 8 Open-Drain I/Os

______________________________________________________________________________________ 15

P0–P7

PULLUP

ENABLE

INPUT

OUTPUT

40kΩ

MAX7325

V+ V+

Figure 11. MAX7325 Open-Drain I/O Port Structure

OUTPUT

V+

GNDGND

V+

O8–O15

MAX7325

Figure 10. MAX7325 Push-Pull Output Port Structure

MAX7325

I2C Port Expander with 8 Push-Pull

and 8 Open-Drain I/Os

16 ______________________________________________________________________________________

TOP VIEW

INT V+

SDA

SCL

AD0

O15

O14

O13

O12

MAX7325

QSOP

RST

AD2

O11

O10

GND

Pin Configurations (continued)

MAX7325

O11

O10

O15

O14

O13

O12

V+

3.3V

µC

SCL SCL

SDA

AD0

SDA

GND

AD2

INT

OUTPUT

RST

INT

RST

INPUT/OUTPUT

Typical Application Circuit

I2C

CONTROL

O11

O10

O12

O13

O14

O15

INT

I/O

PORTS

POWER-

ON RESET

INPUT

FILTER

RST

SDA

SCL

AD2

AD0

MAX7325

Functional Diagram

Chip Information

PROCESS: BiCMOS

MAX7325

I2C Port Expander with 8 Push-Pull

and 8 Open-Drain I/Os

______________________________________________________________________________________ 17

Package Information

(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,

go to www.maxim-ic.com/packages.)

24L QFN THIN.EPS

PACKAGE OUTLINE,

21-0139 2

12, 16, 20, 24, 28L THIN QFN, 4x4x0.8mm

MAX7325

I2C Port Expander with 8 Push-Pull

and 8 Open-Drain I/Os

18 ______________________________________________________________________________________

Package Information (continued)

(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,

go to www.maxim-ic.com/packages.)

PACKAGE OUTLINE,

21-0139

12, 16, 20, 24, 28L THIN QFN, 4x4x0.8mm

MAX7325

I2C Port Expander with 8 Push-Pull

and 8 Open-Drain I/Os

Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are

implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.

Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 ____________________ 19

Heaney

Package Information (continued)

(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,

go to www.maxim-ic.com/packages.)

QSOP.EPS

21-0055

PACKAGE OUTLINE, QSOP .150", .025" LEAD PITCH