MAX7349ATG+T - Maxim Integrated Products, Inc.

General Description

The MAX7347/MAX7348/MAX7349 I2C interfaced periph-

erals provide microprocessors with management of up to

64 key switches. Key inputs are monitored statically, not

dynamically scanned, to ensure low-EMI operation. The

MAX7347 can monitor up to 24 switches, the MAX7348

can monitor up to 40 switches, and the MAX7349 can

monitor up to 64 switches. The switches can be metallic

or resistive (carbon) up to 1kΩ.

The key controller debounces and maintains a FIFO of

key-press events (including autorepeat, if enabled). An

interrupt (INT) output can be configured to alert key

presses either as they occur, or at maximum rate.

The MAX7348/MAX7349 feature a tone generator to

generate automatic key-click sounds or alarm tones

under processor control.

The sounder frequencies cover the 5th musical octave

(523.25Hz to 987.77Hz), plus seven other musical

notes up to 2637Hz. The output can also be pro-

grammed to be high or low for the sound duration to

operate an electronic sounder, relay, or lamp.

The MAX7347 is offered in 16-pin QSOP and TQFN

packages. The MAX7348 is offered in a 20-pin QSOP

package. The MAX7349 is available in 24-pin QSOP and

TQFN packages. The MAX7347/MAX7348/MAX7349

operate over the -40°C to +125°C temperature range.

Applications

Medical Instruments

Instrumentation Panels

Security and Access

Industrial Controls

Features

♦400kbps, 5.5V-Tolerant 2-Wire Serial Interface

♦2.4V to 3.6V Operation

♦Monitor Up to 64 Keys (MAX7349),

40 Keys (MAX7348), or 24 Keys (MAX7347)

♦FIFO Queues Up to 8 Debounced Key Events

♦Key Debounce Time User Configurable from 9ms

to 40ms

♦Key Autorepeat Rate and Delay User Configurable

♦Low-EMI Design Uses Static Matrix Monitoring

♦Hardware Interrupt on Each Debounced Event or

FIFO Level, or at End of Definable Time Period

♦Up to Six Open-Drain Logic Outputs Available

Capable of Driving LEDs

♦Sounder Output Generates Automatic Key Clicks

♦14 Programmable Musical Sounder Frequencies

♦Continuous or Programmable Sounder Duration

♦Easy Automatic Single-Tone and Dual-Tone Alarm

Sound Generation

♦Four I2C Address Choices

♦Selectable 2-Wire Serial Bus Timeout

♦Under 10µA Shutdown Current

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

________________________________________________________________

Maxim Integrated Products

Ordering Information

19-3556; Rev 5; 5/07

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

PART TEMP RANGE PIN-

PACKAGE

PKG

CODE

MAX7347AEE+ -40°C to +125°C 16 QSOP E16-4

MAX7347ATE+ -40°C to +125°C 16 TQFN-EP* T1644-4

MAX7348AEP+ -40°C to +125°C 20 QSOP E20-1

MAX7349AEG+ -40°C to +125°C 24 QSOP E24-1

MAX7349ATG+ -40°C to +125°C 24 TQFN-EP* T2444-4

Denotes lead-free package.

EP = Exposed paddle.

MAX7349

V+ COL_

SOUNDER

GND

SCL

SDA

AD0

ALERT

ROW_

PIEZO

TRANSDUCER

SWITCH

ARRAY, UP

TO 64

SWITCHES

INPUT

2.4V TO 3.6V

INT

Typical Application Circuit

Pin Configurations appear at end of data sheet.

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

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.)

V+ ............................................................................-0.3V to +4V

COL2/PORT2–COL7/PORT7 ....................................-0.3V to +4V

SDA, SCL, AD0, ALERT, INT ....................................-0.3V to +6V

All Other Pins................................................-0.3V to (V+ + 0.3V)

DC Current on COL2/PORT2–COL7/PORT7 ......................25mA

DC Current on SOUNDER ................................................±25mA

GND Current .......................................................................80mA

Continuous Power Dissipation (TA= +70°C)

16-Pin QSOP (derate 8.3mW/°C above +70°C)...........666mW

16-Pin TQFN (derate 16.9mW/°C above +70°C).......1349.1mW

20-Pin QSOP (derate 9.1mW/°C above +70°C)...........727mW

24-Pin QSOP (derate 9.5mW/°C above +70°C)...........761mW

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

Operating Temperature Range (TMIN to TMAX) ...-40°C to +125°C

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

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

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

ELECTRICAL CHARACTERISTICS

(V+ = 2.4V to 3.6V, TA= TMIN to TMAX, unless otherwise noted. Typical values are at V+ = 3.3V, TA= +25°C.) (Notes 1, 2)

PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS

Operating Supply Voltage V+ 2.4 3.6 V

Operating Supply Current I+ All key switches open 75 100 µA

Shutdown Supply Current ISH 6.44 10 µA

SOUNDER Output High Voltage VOHBUZ ISOURCE = 10mA V+ -

0.45 V

SOUNDER Output Low Voltage VOLBUZ ISINK = 10mA 0.15 V

SOUNDER Frequency Accuracy TA = +25°C, V+ = 3.3V 1.2 %

Key-Switch Source Current IKEY 28 40 µA

Key-Switch Source Voltage VKEY 0.35 0.65 V

Key-Switch Resistance RKEY (Note 3) 1 kΩ

Startup Time from Shutdown tSTART 57 200 µs

Output Low Voltage

COL2/PORT2 to COL7/PORT7,

INT Output

VOLPORT ISINK = 10mA 0.15 V

Input voltage ≤ V+ -1 +1

Input Leakage Current Alert Input voltage > V+ -5 +5 µA

Input High Voltage ALERT VIH 2.2 V

Input Low Voltage ALERT VIL 0.8 V

SERIAL-INTERFACE SPECIFICATIONS

Serial Bus Timeout tOUT With bus timeout enabled 20 68 ms

Input High Voltage

SDA, SCL, AD0 VIH 2.2 V

Input Low Voltage

SDA, SCL, AD0 VIL 0.6 V

Input voltage ≤ V+ -1 +1

Input Leakage Current

SDA, SCL, AD0 Input voltage > V+ -5 +5 µA

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

_______________________________________________________________________________________ 3

I2C TIMING CHARACTERISTICS

(V+ = 2.4V to 3.6V, TA= TMIN to TMAX, unless otherwise noted. Typical values are at V+ = 3.3V, TA= +25°C.) (Notes 1, 2)

PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS

Input Capacitance

(SCL, SDA, AD0) CIN (Notes 3, 4) 10 pF

With bus timeout enabled 0.05 400

SCL Serial Clock Frequency fSCL With bus timeout disabled 0 400 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 5) 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 +

0.1Cb300 ns

Fall Time of Both SDA and SCL

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

0.1Cb300 ns

Fall Time of SDA Transmitting tF.TX (Notes 3, 6) 20 +

0.1Cb250 ns

Pulse Width of Spike Suppressed tSP (Notes 3, 7) 50 ns

Capacitive Load for Each Bus

Line Cb(Note 3) 400 pF

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

Note 2: All digital inputs at V+ or GND.

Note 3: Guaranteed by design.

Note 4: Cb= total capacitance of one bus line in pF. tRand tFmeasured between 0.8V and 2.1V.

Note 5: A master device must provide a hold time of at least 300ns for the SDA signal (referred to VIL of the SCL signal) to bridge

the undefined region of SCL’s falling edge.

Note 6: ISINK ≤6mA. Cb= total capacitance of one bus line in pF. tRand tFmeasured between 0.8V and 2.1V.

Note 7: Input filters on the SDA, SCL, and AD0 inputs suppress noise spikes less than 50ns.

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

4 _______________________________________________________________________________________

GPO OUTPUT LOW VOLTAGE

vs. SINK CURRENT

MAX7347 toc01

ISINK (mA)

VOL (mV)

2015105

100

150

200

250

300

025

V+ = 2.4V

TA = +125°C

TA = +25°C

TA = -40°C

GPO OUTPUT LOW VOLTAGE

vs. SINK CURRENT

MAX7347 toc02

ISINK (mA)

VOL (mV)

2015105

100

150

200

250

300

025

V+ = 3V

TA = +125°C

TA = +25°C

TA = -40°C

GPO OUTPUT LOW VOLTAGE

vs. SINK CURRENT

MAX7347 toc03

ISINK (mA)

VOL (V)

2015105

100

150

200

250

300

025

V+ = 3.6V

TA = +125°C

TA = +25°C

TA = -40°C

SUPPLY CURRENT

vs. SUPPLY VOLTAGE

MAX7347 toc04

SUPPLY VOLTAGE (V)

SUPPLY CURRENT (μA)

3.43.22.6 2.8 3.0

2.4 3.6

TA = +125°C

TA = +25°C

TA = -40°C

KEY-SWITCH SOURCE CURRENT

vs. SUPPLY VOLTAGE

MAX7347 toc05

SUPPLY VOLTAGE (V)

KEY-SWITCH SOURCE CURRENT (μA)

3.43.22.6 2.8 3.0

2.4 3.6

TA = +125°C

COL0 = GND

TA = +25°C

TA = -40°C

SOUNDER FREQUENCY

vs. SUPPLY VOLTAGE

MAX7347 toc06

SUPPLY VOLTAGE (V)

SOUNDER FREQUENCY (Hz)

3.32.7 3.0

876

878

880

882

884

886

874

2.4 3.6

SOUNDER FREQUENCY

CONFIGURED FOR 880Hz

TA = +125°C

TA = +25°C

TA = -40°C

SOUNDER OUTPUT

MAX7347 toc07

VSOUNDER

1V/div

200μs/div

OSCILLATOR FREQUENCY

vs. SUPPLY VOLTAGE

MAX7347 toc08

SUPPLY VOLTAGE (V)

OSCILLATOR FREQUENCY (kHz)

3.32.7 3.0

2.4 3.6

OSCILLATOR FREQUENCY

vs. TEMPERATURE

MAX7347 toc09

TEMPERATURE (°C)

OSCILLATOR FREQUENCY (kHz)

11010 60

-40

Typical Operating Characteristics

(V+ = 3.3V, TA= +25°C, unless otherwise noted. Supply range for V+ is 2.4V to 3.6V. Temperature range is -40°C to +125°C.)

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

_______________________________________________________________________________________ 5

Detailed Description

The MAX7347/MAX7348/MAX7349 are microprocessor

peripherals that combine a low-noise key-switch inter-

face with a piezo sounder controller. Up to 64 key

switches can be monitored and debounced with optional

autorepeat, and the key events are presented in an

eight-deep FIFO. Key-switch functionality can be traded

to provide up to one (MAX7347), three (MAX7348), or six

(MAX7349) open-drain logic outputs. (Table 1).

The piezo sounder controller generates a variety of

audio tones. Tones are programmable for frequency

and duration, and may be intermittent, two tone, or con-

tinuous. The piezo sounder controller can be config-

ured to deliver an automatic, customizable sound on

every key press to provide a udible key-click feedback.

Interrupt requests can be configured to be issued on

every key-press event, or can be limited to a maximum

rate to prevent overloading the microprocessor with

Pin Description

MAX7347

(QSOP)

MAX7347

(TQFN) MAX7348 MAX7349

(QSOP)

MAX7349

(TQFN)

NAME FUNCTION

1 15 1 2 23 ROW0 Row Input from Key Matrix. Leave open circuit if unused.

2 16 2 3 24 ROW1 Row Input from Key Matrix. Leave open circuit if unused.

3 1 3 4 1 ROW2 Row Input from Key Matrix. Leave open circuit if unused.

4 2 4 5 2 ROW3 Row Input from Key Matrix. Leave open circuit if unused.

5 3 7 8 5 ROW4 Row Input from Key Matrix. Leave open circuit if unused.

6 4 8 9 6 ROW5 Row Input from Key Matrix. Leave open circuit if unused.

7 5 9 10 7 ROW6 Row Input from Key Matrix. Leave open circuit if unused.

8 6 10 11 8 ROW7 Row Input from Key Matrix. Leave open circuit if unused.

9 7 11 14 11 COL2/PORT2 Column Output to Key Matrix or GPO

10 8 12 15 12 COL1 Column Output to Key Matrix

11 9 13 16 13 COL0 Column Output to Key Matrix

12 10 15 18 15 GND Ground

13 11 17 20 17 SDA I2C-Compatible Serial Data I/O

14 12 18 21 18 SCL I2C-Compatible Serial Clock Input

15 13 19 22 19 INT Active-Low Interrupt Output. Output is open drain.

16 14 20 23 20 V+ Positive Supply Voltage. Bypass V+ to GND with a

0.047µF or higher ceramic capacitor.

— — 5 6 3 COL3/PORT3 Column Output to Key Matrix or GPO

— — 6 7 4 COL4/PORT4 Column Output to Key Matrix or GPO

— — 14 17 14 SOUNDER

S ound er D r i ver Outp ut. Typ i cal l y connect a p i ezo- cer am i c

sound er or other tr ansd ucer fr om thi s outp ut to g r ound .

O utp ut i s p ush- p ul l .

——161916 AD0

Address Input 0. Sets device slave address. Connect to

GND, V+, SDA, or SCL to give four logic combinations.

See Table 3.

— — — 1 22 COL7/PORT7 Column Output to Key Matrix or GPO

— — — 12 9 COL6/PORT6 Column Output to Key Matrix or GPO

— — — 13 10 COL5/PORT5 Column Output to Key Matrix or GPO

— — — 24 21 ALERT Alert Input. Connect to GND or V+ if unused.

—EP— —EP EP

E xp osed P ad d l e. Inter nal l y connected to GN D . C onnect to

a l ar g e g r ound p l ane to m axi m i ze ther m al p er for m ance.

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

6 _______________________________________________________________________________________

too many interrupts. The key-switch status can be

checked at any time by reading the key-switch FIFO. A

1-byte read access returns both the first key-press

event in the FIFO (if there is one) and the FIFO status,

so it is easy to operate the MAX7347/MAX7348/

MAX7349 by polling. If the INT pin is not required, it

can be configured as an open-drain general-purpose

output (GPO) capable of driving an LED.

The MAX7349 monitors up to 64 keys. The MAX7348

monitors up to 40 keys. The MAX7347 monitors up to

24 keys (Table 1).

If the application requires fewer keys to be scanned, up

to six of the key-switch outputs can be configured as

open-drain GPOs capable of driving LEDs. For each

key-switch output used as a GPO, the number of key

switches that can be scanned is reduced by eight.

An alert logic input (MAX7349 only) can be configured

to deliver an automatic, customizable sound and/or an

interrupt on every falling edge of the logic input. The

logic state of the alert input can be read at any time.

Tone Generator

The piezo sounder controller generates a square wave

with the frequency of a musical tone under processor con-

trol. The selection of tones covers the 5th musical octave

(523.25Hz to 987.77Hz), plus seven other notes up to

2637Hz. The sounder output is also programmable to be

either high or low for the entire sound duration to operate

an electronic sounder, relay, or lamp instead of a piezo

transducer. The sound duration is programmable from

15.625ms in seven binary steps up to a maximum of 1s.

The piezo sounder controller interface uses a single 1-

byte access to its own separate slave address.

Commands are double-buffered to allow two commands

(2 bytes) to be stored and executed in succession. The

sounder controller performs the transition between

queued sound commands without click artifacts. The

controller can also autoloop between the two most

recent commands. Autolooping allows a wide range of

intermittent and two-tone sounds to be initiated, and

then run automatically without further intervention.

Key-Scan Controller

Key inputs are scanned statically, not dynamically, to

ensure low-EMI operation. As inputs only toggle in

response to switch changes, the key matrix can be

routed closer to sensitive circuit nodes.

The key controller debounces and maintains a FIFO of

key-press events (including autorepeated key presses,

if autorepeat is enabled). Figure 1 shows keys order.

Serial Interface

Figure 2 shows the 2-wire serial interface timing details.

Serial Addressing

The MAX7347/MAX7348/MAX7349 operate as slaves

that send and receive data through an I2C-compatible

2-wire interface. The interface uses a serial data line

(SDA) and a serial clock line (SCL) to achieve bidirec-

tional communication between master(s) and slave(s).

A master (typically a microcontroller) initiates all data

transfers to and from the MAX7347/MAX7348/MAX7349

and generates the SCL clock that synchronizes the

data transfer.

The MAX7347/MAX7348/MAX7349s’ SDA line operates

as both an input and an open-drain output. A pullup

resistor, typically 4.7kΩ, is required on SDA. The

MAX7347/MAX7348/MAX7349s’ SCL line operates only

as an input. A pullup resistor, typically 4.7kΩ, is required

on SCL if there are multiple masters on the 2-wire inter-

face, or if the master in a single-master system has an

open-drain SCL output.

Each transmission consists of a START condition

(Figure 3) sent by a master, followed by the MAX7347/

MAX7348/MAX7349 7-bit slave address plus R/Wbit, a

a STOP condition.

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, it issues a

PART PACKAGE-

PINS

MAXIMUM

KEY

SWITCHES

INT

OUTPUT

KEY-

SCAN

SLAVE

IDs

SOUNDER

SLAVE IDs

SOUNDER

OUTPUT GPOs ALERT

INPUT

MAX7349 24 64 Yes 4 4 Yes 6 + 1 (INT) Yes

MAX7348 20 40 Yes 4 4 Yes 3 + 1 (INT)—

MAX7347 16 24 Yes 1 fixed — — 1 + 1 (INT)—

Table 1. Product Features Table

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

_______________________________________________________________________________________ 7

STOP (P) condition by transitioning SDA from low to

high while SCL is high. The bus is then free for another

transmission.

Bit Transfer

One data bit is transferred during each clock pulse

(Figure 4). The data on SDA must remain stable while

SCL is high.

Acknowledge

The acknowledge bit is a clocked 9th bit (Figure 5),

which the recipient uses to handshake receipt of each

byte of data. Thus, 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, so the SDA line is stable low

during the high period of the clock pulse. When the

master is transmitting to the MAX7347/MAX7348/

MAX7349, the MAX7347/MAX7348/MAX7349 generate

the acknowledge bit because the MAX7347/MAX7348/

MAX7349 are the recipients. When the MAX7347/

MAX7348/MAX7349 are transmitting to the master, the

master generates the acknowledge bit because the

master is the recipient.

KEY

ROW0

ROW1

ROW2

ROW3

ROW4

ROW5

ROW6

ROW7

COL0

COL1

COL2/PORT2

COL3/PORT3*

COL4/PORT4*

COL5/PORT5**

COL6/PORT6**

COL7/PORT7**

*MAX7348 AND

MAX7349 ONLY.

**MAX7349 ONLY.

Figure 1. Keys Order

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

8 _______________________________________________________________________________________

SDA

SCL

tHD, STA

tLOW

tHIGH

tRtF

tSU, DAT tSU, STA

tSU, STO

tBUF

tHD, STA

tHD, DAT

START

CONDITION

STOP

CONDITION

START

CONDITION

REPEATED

START CONDITION

Figure 2. 2-Wire Serial Interface Timing Details

SDA

SCL

START

CONDITION

STOP

CONDITION

S P

Figure 3. Start and Stop Conditions

SDA

SCL

DATA LINE STABLE;

DATA VALID

CHANGE OF DATA

ALLOWED

Figure 4. Bit Transfer

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

_______________________________________________________________________________________ 9

Slave Addresses

The MAX7347/MAX7348/MAX7349 have two 7-bit long

slave addresses (Figure 6). The bit following a 7-bit

slave address is the R/Wbit, which is low for a write

command and high for a read command.

The first 4 bits (MSBs) of the MAX7347/MAX7348/

MAX7349 slave addresses are always 0111. Slave

address bits A3, A2, and A1 correspond, by the matrix

in Table 3, to the states of the device address input

AD0, and A0 corresponds to the R/Wbit. MAX7347/

MAX7348/MAX7349 use two slave addresses, one for

the main key-scan controller, and one for the sounder

controller. The AD0 input can be connected to any of

four signals: GND, V+, SDA, or SCL, giving four possible

slave address pairs, allowing up to four MAX7348/

MAX7349 devices to share the bus. Only one MAX7347

can share the bus. The MAX7347 AD0 input is internally

connected to GND.

The MAX7347/MAX7348/MAX7349 monitor the bus

continuously, waiting for a START condition followed by

its slave address. When MAX7347/MAX7348/MAX7349

recognize their slave address, they acknowledge and

are then ready for continued communication.

PIN COL0 COL1 COL2/PORT2 COL3/PORT3 COL4/PORT4 COL5/PORT5 COL6/PORT6 COL7/PORT7

ROW0 KEY 0 KEY 8 KEY 16 KEY 24 KEY 32 KEY 40 KEY 48 KEY 56

ROW1 KEY 1 KEY 9 KEY 17 KEY 25 KEY 33 KEY 41 KEY 49 KEY 57

ROW2 KEY 2 KEY 10 KEY 18 KEY 26 KEY 34 KEY 42 KEY 50 KEY 58

ROW3 KEY 3 KEY 11 KEY 19 KEY 27 KEY 35 KEY 43 KEY 51 KEY 59

ROW4 KEY 4 KEY 12 KEY 20 KEY 28 KEY 36 KEY 44 KEY 52 KEY 60

ROW5 KEY 5 KEY 13 KEY 21 KEY 29 KEY 37 KEY 45 KEY 53 KEY 61

ROW6 KEY 6 KEY 14 KEY 22 KEY 30 KEY 38 KEY 46 KEY 54 KEY 62

ROW7 KEY 7 KEY 15 KEY 23 KEY 31 KEY 39 KEY 47 KEY 55 KEY 63

Table 2. Key-Switch Mapping

DEVICE ADDRESS

PIN AD0 A7 A6 A5 A4 A3 A2 A1 A0 R/WFUNCTION

0 Key-scan controller write

01 Key-scan controller read

0 Sounder controller write

GND 011100

11 Sounder controller read

0 Key-scan controller write

01 Key-scan controller read

0 Sounder controller write

V+ 011101

11 Sounder controller read

0 Key-scan controller write

01 Key-scan controller read

0 Sounder controller write

SDA 011110

11 Sounder controller read

0 Key-scan controller write

01 Key-scan controller read

0 Sounder controller write

SCL 011111

11 Sounder controller read

Table 3. 2-Wire Interface Address Map

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

10 ______________________________________________________________________________________

Bus Timeout

The MAX7347/MAX7348/MAX7349 feature a 20ms mini-

mum bus timeout on the 2-wire serial interface, largely to

prevent the MAX7347/MAX7348/MAX7349 from holding

the SDA I/O low during a read transaction if the SCL

hangs for any reason before a serial transaction has

been completed. Bus timeout operates by causing the

MAX7347/MAX7348/MAX7349 to internally terminate a

serial transaction, either read or write, if the time between

adjacent edges on SCL exceeds 20ms. After a bus time-

out, the MAX7347/MAX7348/MAX7349 wait for a valid

START condition before responding to a consecutive

transmission. The bus timeout feature requires the serial

interface to operate above 50Hz bus speed. This feature

can be enabled or disabled under user control by writing

to the configuration register (Table 12).

Message Format for Writing the

Key-Scan Controller

A write to the MAX7347/MAX7348/MAX7349s’ key-scan

controller comprises the transmission of the

MAX7347/MAX7348/MAX7349s’ key-scan slave address

with the R/Wbit set to zero, followed by at least 1 byte of

information. The first byte of information is the command

byte. The command byte determines which register of the

MAX7347/MAX7348/MAX7349 is to be written by the next

byte, if received. If a STOP condition is detected after the

command byte is received, then the MAX7347/MAX7348

/MAX7349 take no further action (Figure 7) beyond stor-

ing the command byte.

Any bytes received after the command byte are data

bytes. The first data byte goes into the internal register

of the MAX7347/MAX7348/MAX7349 selected by the

command byte (Figure 8).

If multiple data bytes are transmitted before a STOP

condition is detected, these bytes are generally stored

in subsequent MAX7347/MAX7348/MAX7349 internal

registers (Table 7) because the command byte address

generally autoincrements (Table 4).

Message Format for Reading the

Key-Scan Controller

The MAX7347/MAX7348/MAX7349 are read using the

MAX7347/MAX7348/MAX7349s’ internally stored com-

mand byte as an address pointer, the same way the

stored command byte is used as an address pointer for

a write. The pointer generally autoincrements after each

data byte is read using the same rules as for a write

(Table 4). Thus, a read is initiated by first configuring

the MAX7347/MAX7348/MAX7349s’ command byte by

performing a write (Figure 7). The master can now read

n consecutive bytes from the MAX7347/MAX7348/

MAX7349, with the first data byte being read from the

When performing read-after-write verification, remem-

ber to reset the command byte’s address because the

stored command byte address is generally autoincre-

mented after the write (Figure 9, Table 4).

SDA

SCL

01 1A3A2A11

MSB LSB

ACKR/W

Figure 6. Slave Address

SCL

SDA

TRANSMITTER

CLOCK PULSE FOR

ACKNOWLEDGE

START

CONDITION

SDA

RECEIVER

1 2 8 9

Figure 5. Acknowledge

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

______________________________________________________________________________________ 11

Message Format for Writing the Sounder

Controller

A write to the MAX7347/MAX7348/MAX7349s’ sounder

controller comprises the transmission of the

MAX7347/MAX7348/MAX7349s’ sounder slave address

with the R/Wbit set to zero, followed by at least 1 com-

mand byte of information. The sounder controller ana-

lyzes each incoming data byte, and depending on the

state of the sounder controller’s 2-deep FIFO and the

contents of the command byte, the command byte is

added to the FIFO or it overwrites the last FIFO data

item (Table 16).

Message Format for Reading the Sounder

Controller

A read from the MAX7347/MAX7348/MAX7349s’ sounder

controller comprises the transmission of the

MAX7347/MAX7348/MAX7349s’ sounder slave address

with the R/Wbit set to 1. The master can now read n con-

secutive bytes from the MAX7347/MAX7348/MAX7349,

each byte being a snapshot of the FIFO status of the

sounder controller (Table 16). If the master wishes to poll

the sounder controller until there is room for another com-

mand to be sent, the master can read bytes continuously

from the sounder controller until the information is satis-

factory and then issue a STOP condition.

Operation with Multiple Masters

If the MAX7347/MAX7348/MAX7349 are operated on a 2-

wire interface with multiple masters, a master reading the

MAX7347/MAX7348/MAX7349 should use a repeated

start between the write that sets the MAX7347/MAX7348/

MAX7349s’ address pointer, and the read(s) that takes

the data from the location(s). This is because it is possi-

ble for master 2 to take over the bus after master 1 has

set up the MAX7347/MAX7348/MAX7349s’ address

pointer but before master 1 has read the data. If master 2

subsequently resets the MAX7347/MAX7348/MAX7349s’

address pointer, then master 1’s read may be from an

unexpected location.

FUNCTION

ADDRESS

CODE (hex)

AUTOINCREMENT

ADDRESS (hex)

Keys FIFO 0x00 0x00

Debounce 0x01 0x02

Autorepeat 0x02 0x03

Interrupt 0x03 0x04

Configuration 0x04 0x05

Port 0x05 0x06

Key Sound 0x06 0x07

Alert Sound 0x07 0x00

Table 4. Key-Scan Command Address

Autoincrement Rules

SAAP0SLAVE ADDRESS COMMAND BYTE

D7 D6 D5 D4 D3 D2 D1 D0

COMMAND BYTE IS STORED ON RECEIPT OF

ACKNOWLEDGE CONDITION

ACKNOWLEDGE FROM MAX7347/MAX7348/MAX7349

R/W

Figure 7. Command Byte Received

SAAAP0SLAVE ADDRESS COMMAND BYTE DATA BYTE

1 BYTE

AUTOINCREMENT

COMMAND BYTE ADDRESS

D7 D6 D5 D4 D3 D2 D1 D0 D1 D0D3 D2D5 D4D7 D6

ACKNOWLEDGE FROM MAX7347/MAX7348/MAX7349 ACKNOWLEDGE FROM MAX7347/MAX7348/MAX7349

ACKNOWLEDGE FROM MAX7347/MAX7348/MAX7349

R/W

Figure 8. Command and Single Data Byte Received

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

12 ______________________________________________________________________________________

FUNCTION POWER-UP CONDITION ADDRESS

CODE (hex) D7 D6 D5 D4 D3 D2 D1 D0

Keys FIFO Empty 0x00 00000000

Debounce Ports 2–7 are enabled; debounce time is 39ms 0x01 11111111

Autorepeat Autorepeat is disabled 0x02 00000000

Interrupt INT is a port, not an interrupt output 0x03 00000000

Configuration

Shutdown mode: key sound is disabled; alert sound is

disabled; alert INT is disabled; timeout enabled; no

sound output

0x04 00000001

Ports Ports 2–7 and INT are logic-high (high impedance) 0x05 1111111X

Key Sound Key-sound default is 31.25ms of 987.77Hz 0x06 01010001

Alert Sound Key-sound default is 250ms of 2093Hz 0x07 10111011

Table 5. Key-Scan Power-Up Configuration

POWER-UP CONDITION D7 D6 D5 D4 D3 D2 D1 D0

Sounder output is a general-purpose output, logic 0; queue is empty 0 0 0 0 0 0 0 0

Table 6. Sounder Power-Up Configuration

SAAAP0SLAVE ADDRESS COMMAND BYTE DATA BYTE

N BYTES

AUTOINCREMENT

COMMAND BYTE ADDRESS

D7 D6 D5 D4 D3 D2 D1 D0 D1 D0D3 D2D5 D4D7 D6

ACKNOWLEDGE FROM MAX7347/MAX7348/MAX7349 ACKNOWLEDGE FROM MAX7347/MAX7348/MAX7349

ACKNOWLEDGE FROM MAX7347/MAX7348/MAX7349

R/W

Figure 9. N Data Bytes Received

= Don’t care.

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

______________________________________________________________________________________ 13

Command Address Autoincrementing

Address autoincrementing allows the MAX7347/

MAX7348/MAX7349 to be configured with fewer trans-

missions by minimizing the number of times the com-

mand address needs to be sent. The command

address stored in the MAX7347/MAX7348/MAX7349

generally increments after each data byte is written or

read (Table 4). Autoincrementing applies only to the

key-scan command addresses and not to the sounder

command addresses.

Registers Description

Initial Power-Up

On power-up, all control registers are reset and the

MAX7347/MAX7348/MAX7349 enter shutdown mode

(Tables 5, 6). Table 7 shows the register address map

for the key-scan section.

COMMAND ADDRESS

FUNCTION D15 D14 D13 D12 D11 D10 D9 D8

ADDRESS

CODE

(hex)

Keys FIFO 000000000x00

Debounce 000000010x01

Autorepeat 000000100x02

Interrupt 000000110x03

Configuration 000001000x04

Ports 000001010x05

Key Sound 000001100x06

Alert Sound 000001110x07

Table 7. Key-Scan Register Address Map

ADDRESS

CODE

(hex) D7 D6 D5 D4 D3 D2 D1 D0

KEYS FIFO REGISTER* 0X00 OVERFLOW

FLAG

KEY SWITCH THAT HAS BEEN

DEBOUNCED

FIFO has not overflowed 0x00 0 X X X X X X X

FIFO overflowed; FIFO contains the first eight

key events 0x00 1 X X X X X X X

This key is the last FIFO item (key-switch data

not zero) 0x00 X 0 X X X X X X

Key 0 was EITHER the last FIFO item OR the

FIFO is empty and no key has been pressed 0x00 0 0 0 0 0 0 0 0

This key is not the last FIFO item 0x00 X 1 X X X X X X

Power-up default setting 0x00 0 0 0 0 0000

Table 8. Keys FIFO Register Format

Reading the key-scan FIFO clears the INT. INT is only reasserted by a key event after the FIFO has been emptied by read(s).

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

14 ______________________________________________________________________________________

Key-Scan Registers

Eight key-scan registers are described in the following

sections.

Keys FIFO Register

The keys FIFO register contains the information pertain-

ing to the status of the keys FIFO, as well as the key-

press events that have been debounced (Table 8). Bits

D0 to D5 denote which of the 64 keys have been

debounced and the keys are numbered as in Table 2

and Figure 1. D6 indicates whether the present

debounced key is the last one in the FIFO, with 1

denoting that there are more keys after the present one,

and 0 denoting that the present debounced key is the

last one stored in the FIFO. D7 is the overflow flag,

which denotes whether the keys FIFO has overflowed.

Reading the key-scan FIFO clears the interrupt INT. INT

is only reasserted after the FIFO has been emptied by

performing enough read operations.

Debounce Register

The debounce register sets the time for each debounce

cycle, as well as setting whether the GPO ports are

enabled or disabled. Bits D0 through D4 set the

debounce time in increments of 1ms starting at 9ms

and ending at 40ms (Table 9). Bits D5 through D7 set

which one of the GPO ports is to be enabled. Note that

not any port can be enabled at a particular time. The

GPO ports can be enabled only in the combinations

shown in Table 9, from all disabled to all enabled.

Autorepeat Register

The autorepeat register sets the autorepeat frequency

(repeat rate) and its delay. The autorepeat function allows

a key to be consecutively asserted when the key itself is

pressed down without being released. The autorepeat

delay specifies the delay between the first press and the

beginning of the autorepeating, provided that the key has

not been released. The autorepeat frequency specifies

how fast the continuously pressed-down key to be assert-

ed once autorepeating has started is. Bits D0 through D3

specify the autorepeat delay in terms of debounce cycles

(hex) REGISTER DATA

D7 D6 D5 D4 D3 D2 D1 D0

DEBOUNCE REGISTER 0x01 PORTS ENABLE DEBOUNCE TIME

Debounce time is 9ms 0x01 X X X 0000 0

Debounce time is 10ms 0x01 X X X 0000 1

Debounce time is 11ms 0x01 X X X 0001 0

Debounce time is 12ms 0x01 X X X 0001 1

All the way through to 0x01 X X X ———— —

Debounce time is 37ms 0x01 X X X 1110 0

Debounce time is 38ms 0x01 X X X 1110 1

Debounce time is 39ms 0x01 X X X 1111 0

Debounce time is 40ms 0x01 X X X 1111 1

GPO ports disabled (full key-scan functionality) 0x01 0 0 0 XXXX X

GPO port 7 enabled 0x01 0 0 1 XXXX X

GPO ports 7 and 6 enabled 0x01 0 1 0 XXXX X

GPO ports 7, 6, and 5 enabled 0x01 0 1 1 XXXX X

GPO ports 7, 6, 5, and 4 enabled 0x01 1 0 0 XXXX X

GPO ports 7, 6, 5, 4, and 3 enabled 0x01 1 0 1 XXXX X

GPO ports 7, 6, 5, 4, 3, and 2 enabled 0x01 1 1 XXXXX X

Power-up default setting 0x01 1 111111 1

Table 9. Debounce Register Format

MAX7347/MAX7348/MAX7349

ranging from 8 debounce cycles to 128 debounce cycles

(Table 10). Bits D4 through D6 specify the autorepeat

rate or frequency ranging from 4 to 32 debounce cycles.

Bit D7 specifies whether the auto-repeat function is

enabled with 0 denoting autorepeat disabled and 1

denoting autorepeat enabled.

Interrupt Register

The interrupt register contains information related to the

settings of the interrupt request function, as well as the

status of the INT output, which can also be configured

as a GPO. Bits D0 through D4 set the key-scan interrupt

frequency. By setting bits D0 through D4 to an appropri-

ate value, the interrupt can be asserted at the end of the

selected number of debounce cycles (Table 11). This

number ranges from 1 to 31 debounce cycles. If bits D0

through D4 are set to 00000, the INT output is config-

ured as a GPO that is controlled by bit D6 in the ports

INT status bits D5, D6, and D7 are still set and cleared in

the normal way at the end of each debounce cycle as if

bits D0 through D4 were set to 00001.

Bits D5 and D6 denote whether an interrupt was set

due to a key-scan event (bit D5) or to an alert event (bit

D6). Bit D7 represents whether an interrupt request has

been asserted with 0 denoting no INT asserted and 1

denoting that INT has been asserted.

The interrupt register is a read-only register and writes

to it are ignored. Reading the interrupt register does

clear an alert event INT, but does not clear a key-scan

event INT. An interrupt request caused by a key-scan

event(s) is cleared when the FIFO is emptied.

Configuration Register

The configuration register reflects the sounder status,

controls the I2C bus timeout feature, enables the alert

input interrupt feature, enables the sounder to respond

to both alert input and key debounce events, and con-

trols the shutdown of the device (Table 12).

Ports Register

The ports register sets the values of ports 2 through 7 and

the INT port when configured as GPOs. The settings in

this register are ignored for ports not configured as

GPOs, and a read from this register returns the values

stored in the register and not the actual port conditions

(Table 13). The ports register also serves to read the alert

input and this is done through bit D0 with a 0 denoting a

low on the alert input and a 1 denoting a high.

Key-Sound Register

The key-sound register specifies the duration and fre-

quency of the sound to be executed by the sounder con-

troller when a key or a set of keys are debounced if the

sounder output has been enabled to be set by a key

debounce event in the configuration register. When this

happens, the information of bits D7 through D1 is passed

on to the sounder register and the appropriate sound is

executed (Tables 14, 16). Least significant bit D0 is

ignored and always set to 1 when transferred to the

sounder register. See Table 16 for the format of setting

the frequency and duration of the sound to be executed.

If a key-sound register command is sent as 000xxxx

(continuous), then the command is stored as 111xxxx

(1000ms) in the sounder register.

Alert Sound Register

The alert sound register specifies the duration and fre-

quency of the sound to be executed by the sounder con-

troller at the falling edge of the alert input if the sounder

output has been enabled to be set by the alert input in

the configuration register. If this is the case, the informa-

tion of bits D7 through D1 is passed on to the sounder

15, 16). Least significant bit D0 is always set to 1 and

this value is ignored when transferred to the sounder

frequency and duration of the sound to be executed.

Note that if an alert sound register command is sent as

000xxxx (continuous), then the command is actually

stored as 111xxxx (1000ms) in the sounder register.

Sounder Register

The sounder register stores the frequencies and duration

of the sounds to be executed by the sounder, as well as

the state of its two-deep FIFO (Table 16). D0 denotes

whether another command is lined in the queue at any

given moment. A 0 in D0 denotes that the queue is empty

while a 1 denotes that there is another command. By writ-

ing 0 to D0, the present command is executed and the

queue is cleared. When sending a command that has a

D0 set to 1, the queue is checked and, if empty, the sent

command is added to it while, if full, the sent command

replaces the queued command.

Bits D0 and D1, when taken in conjunction, set the level

of the sounder output when configured as a GPO and

also control the autoloop function provided that the rest of

the bits (D7 through D2) are set to 0. When the sounder is

configured as a GPO, the levels of the output are set by

D1, a 0 denoting a low and a 1 denoting a high. When D0

is set to 1 and the rest of the bits are set to 0, D1 controls

the autoloop function as defined in Table 16.

Bits D7 through D1 control the frequency and duration of

the sounds to be executed by the sounder. These sounds

include the musical notes of the 5th octave plus some

notes from the 6th and 7th octaves as well. See Table 16.

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

______________________________________________________________________________________ 15

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

16 ______________________________________________________________________________________

ADDRESS

CODE

(hex) D7 D6 D5 D4 D3 D2 D1 D0

AUTOREPEAT REGISTER 0x02 ENABLE AUTOREPEAT

RATE AUTOREPEAT DELAY

Autorepeat is disabled 0x02 0 X X X X X X X

Autorepeat is enabled 0x02 1 AUTOREPEAT

RATE AUTOREPEAT DELAY

Key-switch autorepeat delay is 8 debounce cycles 0x02 1 X X X 0000

Key-switch autorepeat delay is 16 debounce cycles 0x02 1 X X X 0001

Key-switch autorepeat delay is 24 debounce cycles 0x02 1 X X X 0010

Key-switch autorepeat delay is 32 debounce cycles 0x02 1 X X X 0011

Key-switch autorepeat delay is 40 debounce cycles 0x02 1 X X X 0100

Key-switch autorepeat delay is 48 debounce cycles 0x02 1 X X X 0101

Key-switch autorepeat delay is 56 debounce cycles 0x02 1 X X X 0110

Key-switch autorepeat delay is 64 debounce cycles 0x02 1 X X X 0111

Key-switch autorepeat delay is 72 debounce cycles 0x02 1 X X X 1000

Key-switch autorepeat delay is 80 debounce cycles 0x02 1 X X X 1001

Key-switch autorepeat delay is 88 debounce cycles 0x02 1 X X X 1010

Key-switch autorepeat delay is 96 debounce cycles 0x02 1 X X X 1011

Key-switch autorepeat delay is 104 debounce cycles 0x02 1 X X X 1100

Key-switch autorepeat delay is 112 debounce cycles 0x02 1 X X X 1101

Key-switch autorepeat delay is 120 debounce cycles 0x02 1 X X X 1110

Key-switch autorepeat delay is 128 debounce cycles 0x02 1 X X X 1111

Key-switch autorepeat frequency is 4 debounce cycles 0x02 1 0 0 0 XXXX

Key-switch autorepeat frequency is 8 debounce cycles 0x02 1 0 0 1 XXXX

Key-switch autorepeat frequency is 12 debounce cycles 0x02 1 0 1 0 XXXX

Key-switch autorepeat frequency is 16 debounce cycles 0x02 1 0 1 1 XXXX

Key-switch autorepeat frequency is 20 debounce cycles 0x02 1 1 0 0 XXXX

Key-switch autorepeat frequency is 24 debounce cycles 0x02 1 1 0 1 XXXX

Key-switch autorepeat frequency is 28 debounce cycles 0x02 1 1 1 0 XXXX

Key switch autorepeat frequency is 32 debounce cycles 0x02 1 1 1 1 XXXX

Power-up default setting 0x02 0 0000000

Table 10. Autorepeat Register Format

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

______________________________________________________________________________________ 17

CODE (hex) D7 D6 D5 D4 D3 D2 D1 D0

INTERRUPT REGISTER 0x03 INT

STATUS*

ALERT

EVENT*

KEY-

SCAN

EVENT*

KEY-SCAN INTERRUPT

FREQUENCY

Current INT is due to key-scan event(s) 0x03 1 0 1 X X X X X

Current INT is due to alert event 0x03 1 1 0 X X X X X

Current INT is due to both key-scan event(s)

and alert event 0x03 1 1 1 X X X X X

INT has not been asserted 0x03 0 0 0 X X X X X

INT has been asserted 0x03 1 ALERT

EVENT

KEY-

SCAN

EVENT

XXXXX

INT output pin is NOT asserted; INT output

pin is used as a general-purpose output

called INT port under control of bit D6 in

ports register; INT status bits D5, D6, D7 are

still set and cleared in the normal way at the

end of every debounce cycle as if bits D4–D0

were set to 00001

0x03 X X X 0 0 0 0 0

Key-scan INT is asserted at the end of every

debounce cycle, if new key(s) is debounced 0x03 X X X 0 0 0 0 1

Key-scan INT is asserted at the end of every

2 debounce cycles, if new key(s) is

debounced

0x03 X X X 0 0 0 1 0

-— — — — — — — — —

Key-scan INT is asserted at the end of every

29 debounce cycles, if new key(s) is

debounced

0x03 X X X 1 1 1 0 1

Key-scan INT is asserted at the end of every

30 debounce cycles, if new key(s) is

debounced

0x03 X X X 1 1 1 1 0

Key-scan INT is asserted at the end of every

31 debounce cycles, if new key(s) is

debounced

0x03 X X X 1 1 1 1 1

Power-up default setting 0x03 00000000

Table 11. Interrupt Register Format

Read-only register bits; write data is ignored. Reading the interrupt register does clear an alert event INT, but does not clear a key-

scan event INT. INT caused by key-scan event(s) is cleared when FIFO is emptied.

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

18 ______________________________________________________________________________________

CODE (hex) D7 D6 D5 D4 D3 D2 D1 D0

CONFIGURATION REGISTER 0x04 SHUTDOWN

KEY

SOUND

ENABLE

ALERT

SOUND

ENABLE

ALERT

INT

ENABLE

ALERT

INT

EVENT

SOUNDER

STATUS

T I M EO U T

EN A B L E

Serial interface bus timeout enabled 0x04 X X X X X X X 0

Serial interface bus timeout disabled 0x04 X X X X X X X 1

No active sounder output 0x04 X X X X X 0 0 X

Active sounder output set by serial

interface 0x04 X X X X X 0 1 X

Active sounder output set by key

debounce event 0x04 X X X X X 1 0 X

Active sounder output set by an alert

event 0x04 X X X X X 1 1 X

Alert input interrupt (if enabled) is

asserted according to key-scan

interrupt rules

0x04 X X X X 0 X X X

Alert input interrupt (if enabled) is

asserted immediately 0x04 X X X X 1 X X X

Alert input does not cause an

interrupt 0x04 X X X 0 X X X X

Falling edge of alert input causes

interrupt 0x04 X X X 1 X X X X

Alert input does not cause an

automatic sound 0x04 X X 0 X X X X X

Falling edge of alert input causes the

8-bit contents of the alert sound

sounder

0x04 X X 1 X X X X X

Debounce key(s) do not cause an

automatic sound 0x04 X 0 X X X X X X

Debounced key(s), including

autorepeated keys, cause the 8-bit

contents of the key-sound register

0x06 to be sent to the sounder

0x04 X 1 X X X X X X

Table 12. Configuration Register Format

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

______________________________________________________________________________________ 19

CODE (hex) D7 D6 D5 D4 D3 D2 D1 D0

CONFIGURATION REGISTER 0x04 SHUTDOWN

KEY

SOUND

ENABLE

ALERT

SOUND

ENABLE

ALERT

INT

ENABLE

ALERT

INT

EVENT

SOUNDER

STATUS

T IM EO U T

EN A B L E

Shutdown mode; key-scan and

sounder timing are disabled,

interrupts disabled, but alert input

can be read and port outputs (as

selected) can be changed

0x04 0 X X X X X X X

Operating mode; key scan is started,

and commands in sounder queue

are actioned

0x04 1 X X X X X X X

Power-up default setting 0x04 00000001

Table 12. Configuration Register Format (continued)

CODE (hex)

READ

WRITE D7 D6 D5 D4 D3 D2 D1 D0

READ PORT 7 PORT 6 PORT 5 PORT 4 PORT 3 PORT 2 INT

PORT

ALERT

INPUT

PORTS REGISTER 0x05

WRITE PORT 7 PORT 6 PORT 5 PORT 4 PORT 3 PORT 2 INT

PORT X

Clear port 2 low 0x05 Write X X X X X 0 X X

Set port 2 high (high

impedance) 0x05 Write X X X X X 1 X X

Clear port 3 low 0x05 Write X X X X 0 X X X

Set port 3 high (high

impedance) 0x05 Write X X X X 1 X X X

Clear port 4 low 0x05 Write X X X 0 X X X X

Set port 4 high (high

impedance) 0x05 Write X X X 1 X X X X

Clear port 5 low 0x05 Write X X 0 X X X X X

Set port 5 high (high

impedance) 0x05 Write X X 1 X X X X X

Clear port 6 low 0x05 Write X 0 X X X X X X

Set port 6 high (high

impedance) 0x05 Write X 1 X X X X X X

Table 13. Ports Register Format

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

20 ______________________________________________________________________________________

CODE (hex)

READ

WRITE D7 D6 D5 D4 D3 D2 D1 D0

READ PORT 7 PORT 6 PORT 5 PORT 4 PORT 3 PORT 2 INT

PORT

ALERT

INPUT

PORTS REGISTER 0x05

WRITE PORT 7 PORT 6 PORT 5 PORT 4 PORT 3 PORT 2 INT

PORT X

Clear port 7 low 0x05 Write 0 X X X X X X X

Set port 7 high (high

impedance) 0x05 Write 1 X X X X X X X

Clear INT port low;

this setting is ignored

unless the key-scan INT

functionality is disabled

by setting interrupt

00000

0x05 Write X X X X X X 0 X

Set INT port high (high

impedance); this setting

is ignored unless the

key-scan INT

functionality is disabled

by setting interrupt

00000

0x05 Write X X X X X X 1 X

Alert input level is low 0x05 Read X X X X X X X 0

Alert input level is high 0x05 Read X X X X X X X 1

Power-up default

setting 0x05 — 1111111X

Table 13. Ports Register Format (continued)

CODE (hex) D7 D6 D5 D4 D3 D2 D1 D0

This-8 bit value is passed to sounder controller when key(s)

debounced, if enabled in the configuration register; these 7

bits define duration and frequency only; sounder command

bit D0 is ignored and fixed internally at 1; if a key sound is

sent as 000xxxxx (continuous), then the command is stored

as 111xxxxx (1000 ms)

0x06 7-bit value (see Table 16 for functionality) 1

Power-up default setting 0x06 01010001

Table 14. Key-Sound Register Format

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

______________________________________________________________________________________ 21

CODE (hex) D7 D6 D5 D4 D3 D2 D1 D0

This 8-bit value is passed to sounder controller on the falling

edge of the alert input; these 7 bits define duration and

frequency only; sounder command bit D0 is ignored and

fixed internally at 1; if an alert sound is sent as 000xxxxx

(continuous), then the command is stored as 111xxxxx

(1000 ms)

0x07 7-bit value (see Table 16 for functionality) 1

Power-up default setting 0x07 10111011

Table 15. Alert Sound Register Format

SOUNDER REGISTER

READ

WRITE

DURATION FREQUENCY LEVEL BUFFER

No commands are active; OR output is GPO logic 0 Read 0 0 0 0 0 0 0 0

This current command is active, none are queued (so another

command may be sent) Read DURATION FREQUENCY LEVEL 0

This current command is active, and another command is in

the queue Read DURATION FREQUENCY LEVEL 1

Perform this command, terminating and clearing any previous

active command, command queue, and autoloop; new

command is now active, and queue is now empty

Write X X X X X X X 0

Add command to queue if not full; command replaces queued

command if queue is full Write X X X X X X X 1

Configure sounder output as general-purpose output, logic 0

(clear queue; sounder output active low with continuous

duration, ie, until a buffer = 0 command)

Write 0 0 0 0 0 0 0 0

Configure sounder output as general-purpose output, logic 1

(clear queue; sounder output active high with continuous

duration, ie, until a buffer = 0 command)

Write 0 0 0 0 0 0 1 0

Autoloop using the current two commands; the active

command is command 1, and the inactive command is

command 2; if no command is active, the oldest command is

reactivated as command 1, and the other command is re-

activated as command 2

Write 0 0 0 0 0 0 0 1

Autoloop is halted at the end of command 2, and output idles

as defined by command 2 Write 0 0 0 0 0 0 1 1

Table 16. Sounder Register Format

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

22 ______________________________________________________________________________________

SOUNDER REGISTER

READ

WRITE

DURATION FREQUENCY LEVEL BUFFER

Sounder output active low for sound duration;

queue cleared — Write 0 0 0 0 0

Sounder output active high for sound duration;

queue cleared — Write 0 0 0 1 0

Sound frequency is 523.25Hz, idles low Note C5 Write 0 0 1 0

Sound frequency is 587.33Hz, idles low Note D5 Write 0 0 1 1

Sound frequency is 659.26, idles low Note E5 Write 0 1 0 0

Sound frequency is 698.46Hz, idles low Note F5 Write 0 1 0 1

Sound frequency is 783.99Hz, idles low Note G5 Write 0 1 1 0

Sound frequency is 880Hz, idles low Note A5 Write 0 1 1 1

Sound frequency is 987.77Hz, idles low Note B5 Write 1 0 0 0

Sound frequency is 1046.5Hz, idles low Note C6 Write 1 0 0 1

Sound frequency is 1318.5Hz, idles low Note E6 Write 1 0 1 0

Sound frequency is 1568Hz, idles low Note G6 Write 1 0 1 1

Sound frequency is 1760Hz, idles low Note A6 Write 1 1 0 0

Sound frequency is 2093Hz, idles low Note C7 Write 1 1 0 1

Sound frequency is 2349.3Hz, idles low Note D7 Write 1 1 1 0

Sound frequency is 2637Hz, idles low Note E7 Write

DURATION

111 1

BUFFER

Sound duration is continuous; if an alert sound or

a key sound is programmed as 000xxxxx

(continuous), then the command is treated as

111xxxxx (1000 ms)

Write 0 0 0

Sound duration is 15625ms* Write 0 0 1

Sound duration is 3125ms* Write 0 1 0

Sound duration is 625ms* Write 0 1 1

Sound duration is 125ms* Write 1 0 0

Sound duration is 250ms* Write 1 0 1

Sound duration is 500ms* Write 1 1 0

Sound duration is 1000ms* Write 1 1 1

FREQUENCY LEVEL BUFFER

Power-up default setting —000000 0 0

Table 16. Sounder Register Format (continued)

Sound duration will be slightly longer than these times because each sound always completes a full cycle before stopping.

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

______________________________________________________________________________________ 23

Sounder Operation

When an alert sound or key sound is happening, the user

cannot write to the sounder. The MAX7347/MAX7348/

MAX7349 do not acknowledge a write to the sounder I2C

address. However, a read from the sounder will work cor-

rectly. An alert sound or key sound event terminates a

current user-programmed event and clears the queue. If

an alert sound or key sound event is currently being

processed, then a new alert sound or key sound event

will be put into the queue, replacing an existing queued

alert sound or key sound event, if one exists. User access

to the sounder is restored when the last alert sound or key

sound event is completed. Note this means that the buffer

bit (D0) for an alert sound or key sound command is

effectively ignored.

Shutdown

The MAX7347/MAX7348/MAX7349 are put into shut-

down mode by clearing bit D7 in the configuration reg-

ister (Table 12). In shutdown, the key-scan controller

and sounder controller are both disabled, and the

MAX7347/MAX7348/MAX7349 draw minimal current.

No additional supply current is drawn if any keys are

pressed. All switch matrix current sources are turned

off, and row outputs ROW0 to ROW7 and column out-

puts COL0 to COL7 become high impedance.

The alert input status may still be read in shutdown,

and an alert event can still cause an interrupt request if

this feature is enabled (Table 12). This means that alert

can be used for µC wakeup while the system sleeps

drawing minimum current.

Outputs configured as GPOs (COL2/PORT2 to

COL2/PORT7 and INT) may still be controlled in shut-

down and their output states can be changed under

software control at any time.

The sounder output may not be changed in shutdown,

even if it is effectively being used as a logic output. Writes

to the sounder during shutdown are ignored, and the

sounder FIFO is cleared on entering shutdown. However,

the sounder retains its output logic state for the duration

of shutdown, and so can be set low or high as desired by

writing 0x00 or 0x02, respectively, to the sounder register

(Table 12) before entering shutdown.

The MAX7347/MAX7348/MAX7349 may be taken out of

shutdown mode and put into operating mode by setting

bit D7 in the configuration register (Table 12). The key-

scan and sounder controller FIFOs are cleared, and key

monitoring starts. Note that rewriting the configuration

does not clear the FIFOs; the FIFOs are only cleared

when the MAX7347/MAX7348/MAX7349 are actually

coming out of shutdown.

Applications Information

Ghost-Key Elimination

Ghost keys are a phenomenon inherent with key-switch

matrices. When three switches located at the corners of

a matrix rectangle are pressed simultaneously, the

switch that is located at the last corner of the rectangle

(the ghost key) also appears to be pressed. This occurs

because the potentials at the two sides of the ghost-key

switch are identical due to the other three connections—

the switch is electrically shorted by the combination of

the other three switches (Figure 10). Because the key

appears to be pressed electrically, it is impossible for

software to detect which of the four keys is the ghost key.

The MAX7347/MAX7348/MAX7349 employ a proprietary

scheme that detects any three-key combination that

generates a fourth ghost key, and does not report any of

these four keys as being pressed. This means that

although ghost keys are never reported, many combina-

tions of three keys are effectively ignored when pressed

at the same time. Applications requiring three key com-

binations (such as <Ctrl><Alt><Del>) must ensure that

the 3 keys are not wired in positions that define the ver-

tices of a rectangle (Figure 11).

Low-EMI Operation

The MAX7347/MAX7348/MAX7349 use two techniques

to minimize EMI radiating from the key-switch wiring.

First, the voltage across the switch matrix never

exceeds 0.65V, irrespective of supply voltage V+. This

reduces the voltage swing at any node when a switch

is pressed to 0.65V maximum. Second, the keys are not

dynamically scanned, which would cause the key-

switch wiring to continuously radiate interference.

Instead, the keys are monitored for current draw (only

occurs when pressed), and debounce circuitry only

operates when one or more keys are actually pressed.

Power-Supply Considerations

The MAX7347/MAX7348/MAX7349 operate with a 2.4V

to 3.6V power-supply voltage. Bypass the power supply

to GND with a 0.047µF or higher ceramic capacitor as

close to the device as possible.

Switch On-Resistance

The MAX7347/MAX7348/MAX7349 are designed to be

insensitive to resistance either in the key switches or

the switch routing to and from the appropriate COLx

and ROWx up to 1kΩ. These controllers are therefore

compatible with low-cost membrane and conductive

carbon switches.

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

24 ______________________________________________________________________________________

Audio Transducers

The sounder output is designed to drive a standard, low-

cost piezo transducer directly without further buffering.

Piezo transducers appear as a capacitive load of typical-

ly 10nF. If a resistive or inductive sounder is used, such

as a small loudspeaker, fit a coupling capacitor between

the sounder output and the transducer. For example, if a

32Ωspeaker is used, connect the positive side of a 22µF

electrolytic capacitor to the sounder output, the negative

side of the capacitor to one end of the speaker, and the

other end of the speaker to GND.

The sounder output can also drive a power amplifier for

higher sound levels. In this case, it is usually desirable

to include a lowpass filter before the speaker to convert

the square-wave tones to something closer to a sinu-

soid. The recommended cutoff frequency of this filter is

around 3kHz. An example circuit is shown in Figure 12,

which uses the uncommitted op amp of the MAX4366

bridge power amplifier to implement a third-order

Chebyshev lowpass filter.

REGULAR KEY-PRESS

EVENT

GHOST-KEY

EVENT

KEY-SWITCH MATRIX

Figure 10. Ghost-Key Phenomenon

KEY-SWITCH MATRIX KEY-SWITCH MATRIX

EXAMPLES OF VALID THREE-KEY COMBINATIONS

Figure 11. Valid Three-Key Combinations

Chip Information

PROCESS: BiCMOS

21.5kΩ32.4kΩ

22nF

SOUNDER

OUTPUT

SHUTDOWN

2.61kΩ

68nF

21.5kΩ

220pF

IN-

IN+

SHDN

BIAS

10kΩ

50kΩ

VCC

OUT-

OUT+

0.22μF

16Ω

MAX4366

Figure 12. Third-Order Chebyshev Lowpass Filter and Output Stage

MAX7347/MAX7348/MAX7349

MAX7348

ROW0

ROW1

ROW2

ROW3

ROW4

ROW5

ROW6

ROW7

COL0

COL1

COL2/PORT2

GND

V+

COL3/PORT3

COL4/PORT4

AD0

SCL

SDA

INT

SCL

SDA

INT

3.3V

GND

V+

3.3V3.3V

SOUNDER

PIEZOELECTRIC

TRANSDUCER

KEY 0

KEY 1

KEY 2

KEY 3

KEY 4

KEY 5

KEY 6

KEY 7

KEY 8

KEY 9

KEY 10

KEY 11

KEY 12

KEY 13

KEY 14

KEY 15

KEY 16

KEY 17

KEY 18

KEY 19

KEY 20

KEY 21

KEY 22

KEY 23

Typical Application Circuit

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

______________________________________________________________________________________ 25

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

26 ______________________________________________________________________________________

V+

SCL

SDAROW3

ROW2

ROW1

ROW0

TOP VIEW

AD0

GND

SOUNDER

COL0ROW5

ROW4

COL4/PORT4

COL3/PORT3

COL1

COL2/PORT2ROW7

ROW6

MAX7348

QSOP

INT

ALERT

V+

SCLROW2

ROW1

ROW0

COL7/PORT7

TOP VIEW

SDA

AD0

GND

SOUNDERROW4

COL4/PORT4

COL3/PORT3

ROW3

COL0

COL1

COL2/PORT2

COL5/PORT5COL6/PORT6

ROW7

ROW6

ROW5

QSOP

MAX7349

INT

Pin Configurations

ROW0 V+

SCL

SDA

GND

COL0

COL1

COL2/PORT2

TOP VIEW

MAX7347

QSOP

INTROW1

ROW2

ROW5

ROW3

ROW4

ROW6

ROW7

MAX7349

12 3456

18 17 16 15 14 13

INT

ALERT

V+

COL7/PORT7

ROW1

ROW2

ROW3

COL3/PORT3

COL4/PORT4

ROW4

ROW5

SCL

SDA

GND

SOUNDER

COL0

ROW0

COL1

COL5/PORT5

COL2/PORT2

COL6/PORT6

ROW6

ROW7

AD0

TOP VIEW

TQFN-EP

+EP*

*EP = EXPOSED PADDLE

ROW3

ROW5

ROW2

SDA

COL0

SCL

V+

12 11 9

ROW0

ROW1

COL1

COL2/PORT2

ROW7

ROW6

EP*

*EP = EXPOSED PADDLE

MAX7347

ROW4 GND

INT

TQFN-EP

TOP VIEW

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

______________________________________________________________________________________ 27

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.)

QSOP.EPS

F11

21-0055

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

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

28 ______________________________________________________________________________________

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.)

24L QFN THIN.EPS

PACKAGE OUTLINE,

21-0139 2

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

MAX7347/MAX7348/MAX7349

2-Wire Interfaced Low-EMI Key Switch

and Sounder Controllers

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 ____________________

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

Revision History

Pages changed at Rev 5: 1, 2, 23, 29