MAX6958AAEE+T - Maxim Integrated Products, Inc.

General Description

The MAX6958/MAX6959 compact multiplexed com-

mon-cathode display drivers interface microprocessors

to seven-segment numeric LED digits, or discrete LEDs

through an SMBus™- and I2C-compatible 2-wire serial

interface. The 2-wire serial interface uses fixed

0.8V/2.1V logic thresholds for compatibility with 2.5V

and 3.3V systems when the display driver is powered

from a 5V supply.

The MAX6958/MAX6959 drive up to four 7-segment

digits, with decimal points, plus four discrete LEDs, or

four 7-segment digits and eight discrete LEDs if the

digits’ decimal points are not used, or up to 36 discrete

LEDs. The MAX6959 also includes two input ports, one

or both of which may be configured as a key-switch

reader, which automatically scans and debounces a

matrix of up to eight switches. Key-switch status is

obtained by polling internal status registers or by con-

figuring the MAX6959 interrupt output.

Other on-chip features include a hexadecimal font for

seven-segment displays, multiplex scan circuitry,

anode and cathode drivers, and static RAM that stores

each digit. The peak segment current for the display

digits is set internally to 23mA. Display intensity is

adjusted using a 64-step internal digital brightness con-

trol. The MAX6958/MAX6959 include a low-power shut-

down mode, a scan-limit register that allows the user to

display from one to four digits, and a test mode, which

forces all LEDs on. The LED drivers are slew-rate-limit-

ed to reduce EMI.

The MAX6958/MAX6959 are available in 16-pin PDIP

and QSOP packages and are fully specified over the

-40°C to +125°C automotive temperature range.

Applications

Features

♦400kbps 2-Wire Serial Interface

♦3V to 5.5V Operation

♦Drive 4 Digits plus 4 or 8 Discrete LEDs

♦Drive Common-Cathode LED Digits

♦23mA Constant-Current LED Segment Drive

♦Hexadecimal Decode/No-Decode Digit Selection

♦64-Step Digital Brightness Control

♦Slew-Rate-Limited Segment Drivers Reduced EMI

♦Debounces Up to Eight Switches with n-Key

Rollover (MAX6959 Only)

♦IRQ Output When a Key Input Is Debounced

(MAX6959 Only)

♦20µA Low-Power Shutdown (Data Retained)

♦Automotive Temperature Range (-40°C to +125°C)

♦Compact 16-Pin PDIP and QSOP Packages

MAX6958/MAX6959

2-Wire Interfaced, 3V to 5.5V, 4-Digit,

9-Segment LED Display Drivers with Keyscan

________________________________________________________________ Maxim Integrated Products 1

Ordering Information

19-2634; Rev 1; 11/05

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.

Ordering Information continued at end of data sheet.

PART

TEMP

RANGE

SLAVE

ADDRESS

PIN-

PACKAGE

PKG

CODE

MAX6958AAEE

-40°C to

+125°C0111000

16 QS OP

E 16- 1

MAX6958AAPE

-40°C to

+125°C

0111000

16 DIP

P16-1

V+

DIG0–DIG3

SEG0–SEG8

SDA

SCL

IRQ/SEG9

INPUT1

µC

SDA

SCL

IRQ

INPUT2 GND

8 88 8

Key0

DIG0/SEG0

Key1

DIG1/SEG1

Key2

DIG2/SEG2

Key3

DIG3/SEG3

Key4

DIG4/SEG4

Key5

DIG5/SEG5

Key6

DIG6/SEG6

Key7

DIG7/SEG7

MAX6959

Typical Operating Circuit

SMBus is a trademark of Intel Corp.

Set-Top Boxes

Panel Meters

White Goods

Audio/Video Equipment

Vending Machines

Industrial Controls

Pin Configuration, Functional Diagram, and Typical

Application Circuit appear at end of data sheet.

MAX6958/MAX6959

2-Wire Interfaced, 3V to 5.5V, 4-Digit,

9-Segment LED Display Drivers with Keyscan

2_______________________________________________________________________________________

ABSOLUTE MAXIMUM RATINGS

DC ELECTRICAL CHARACTERISTICS

(V+ = 3V to 5.5V, TA= TMIN to TMAX, unless otherwise noted. Typical values are at V+ = 5V, TA= +25°C.) (Note 1)

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.

(Voltage with respect to GND.)

V+, SCL, SDA .......................................................-0.3V to +6V

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

Current

DIG0/SEG0–DIG3/SEG3 Sink Current ..........................275mA

DIG0/SEG0–SEG9 Source Current .................................30mA

SCL, SDA, INPUT1, INPUT2 ...........................................20mA

Continuous Power Dissipation (TA= +70°C)

16-Pin QSOP (derate at 8.34mW/°C above +70°C).....667mW

16-Pin DIP (derate at 10.5mW/°C above +70°C).........842mW

Operating Temperature Range

MAX695_ (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

PARAMETER

SYMBOL

CONDITIONS

MIN TYP MAX

UNITS

Operating Supply Voltage V+ 3 5.5 V

TA = +25°C 20 50

Shutdown Supply Current ISHDN Shutdown mode, all

digital inputs at V+

TA = TMIN to +85°C 125 µA

TA = +25°C 5.9 6.7

Operating Supply Current I+

Intensity set to full,

no display load

connected, INPUT1

and INPUT2 open

circuit

TA = TMIN to TMAX 7.5 mA

Display Scan Rate fSCAN 4 digits scanned TA = TMIN to TMAX

510 780 1050

Keyscan Debounce Time

tDEBOUNCE

TA = TMIN to TMAX

30.3

41 63 ms

TA = +25°C -19 -23 -29

VLED = 2.4V,

V+ = 4.5V to 5.5V TA = TMIN to TMAX -18 -30

TA = +25°C -16

-29.5

Segment Drive Source Current ISEG VLED = 2V,

V+ = 3V to 5.5V TA = TMIN to TMAX

-15.5 -30.5

Segment Current Slew Rate

∆ISEG/∆t

mA/µs

Segment Drive Current Matching

∆ISEG 4%

LOGIC INPUTS AND OUTPUTS

Input Leakage Current SCL

and SDA IIH, IIL -1 +1 µA

Logic High Input Voltage SCL,

SDA VIH 2.1 V

Logic Low Input Voltage SCL,

SDA VIL 0.8 V

Input Leakage Current INPUT1,

INPUT2

IINH, IINL

INPUT_ = V+ -1 +1 µA

Logic High Input Voltage INPUT1,

INPUT2 VINH 0.7 ✕

V+ V

Logic Low Input Voltage INPUT1,

INPUT2 VINL 0.3 ✕

V+ V

MAX6958/MAX6959

2-Wire Interfaced, 3V to 5.5V, 4-Digit,

9-Segment LED Display Drivers with Keyscan

_______________________________________________________________________________________ 3

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

Note 2: Guaranteed by design.

Note 3: 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 4: CB= total capacitance of one bus line in pF. tRand tFmeasured between 0.3V+ and 0.7V+.

Note 5: ISINK ≤6mA. CB= total capacitance of one bus line in pF. tRand tFmeasured between 0.3V+ and 0.7V+.

Note 6: Input filters on the SDA and SCL inputs suppress noise spikes less than 50ns.

DC ELECTRICAL CHARACTERISTICS (continued)

(V+ = 3V to 5.5V, TA= TMIN to TMAX, unless otherwise noted. Typical values are at V+ = 5V, TA= +25°C.) (Note 1)

PARAMETER

SYMBOL

CONDITIONS

MIN TYP MAX

UNITS

Pullup to V+ INPUT1, INPUT2

IPULLUP 26.5

µA

ISINK = 6mA, TA = -40°C to +85°C 0.4

IRQ/SEG9, SDA Output Low

Voltage VOLBK ISINK = 4mA, TA = TMIN to TMAX 0.4 V

SDA Output Low Voltage

VOL

(

SDA

)

ISINK = 6mA 0.4 V

TIMING CHARACTERISTICS

(V+ = 3V to 5.5V, TA= TMIN to TMAX, Figure 1, unless otherwise noted.) (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 Setup Time

tSU

STA

0.6 µs

STOP Condition Setup Time

tSU

STO

0.6 µs

Data Hold Time

tHD

DAT

(Note 3) 0.9 µs

Data Setup Time

tSU

DAT

100 ns

SCL Clock Low Period tLOW 1.3 µs

SCL Clock High Period tHIGH 0.6 µs

Rise Time of Both SDA and SCL

Signals, Receiving tR(Notes 2, 4) 20 +

0.1CB

300 ns

Fall Time of Both SDA and SCL

Signals, Receiving tF(Notes 2, 4) 20 +

0.1CB

300 ns

Fall Time of SDA Transmitting tF(Notes 2, 5) 20 +

0.1CB

250 ns

Pulse Width of Spike Suppressed

tSP (Note 6) 50 ns

Capacitive Load for Each Bus

Line CB

400

MAX6958/MAX6959

2-Wire Interfaced, 3V to 5.5V, 4-Digit,

9-Segment LED Display Drivers with Keyscan

4_______________________________________________________________________________________

Typical Operating Characteristics

(V+ = 5V, LED forward voltage = 2.4V, TA= +25°C, unless otherwise noted.)

SCAN RATE (fSCAN)

vs. TEMPERATURE

MAX6958/59 toc01

TEMPERATURE (°C)

SCAN RATE (Hz)

1008040 600 20-20

760

765

770

775

780

785

790

795

800

755

-40 120

5.5V

4.5V

KEYSCAN DEBOUNCE TIME (tDEBOUNCE)

vs. TEMPERATURE

MAX6958/59 toc02

TEMPERATURE (°C)

KEYSCAN DEBOUNCE TIME (ms)

100806040200-20

40.5

41.0

41.5

42.0

42.5

40.0

-40 120

4.5V

5.5V

SCAN RATE (fSCAN)

vs. SUPPLY VOLTAGE

MAX6958/59 toc03

SUPPLY VOLTAGE (V)

SCAN RATE (Hz)

5.04.54.03.5

765

770

775

780

785

790

760

3.0 5.5

KEYSCAN DEBOUNCE TIME (tDEBOUNCE)

vs. SUPPLY VOLTAGE

MAX6958/59 toc04

SUPPLY VOLTAGE (V)

KEYSCAN DEBOUNCE TIME (ms)

5.04.54.03.5

40.6

40.8

41.0

41.2

41.4

41.6

41.8

42.0

42.2

40.4

3.0 5.5

SEGMENT SOURCE CURRENT

vs. SUPPLY VOLTAGE

MAX6958/59 toc05

SUPPLY VOLTAGE (V)

SEGMENT SOURCE CURRENT (mA)

5.255.004.75

4.50 5.50

VLED = 2.4V

SEGMENT SOURCE CURRENT

vs. SUPPLY VOLTAGE

MAX6958/59 toc06

SUPPLY VOLTAGE (V)

SEGMENT SOURCE CURRENT (mA)

4.54.03.5

3.0 5.0 5.5

VLED = 2V

WAVEFORM AT DIG0/SEG0,

FULL INTENSITY

MAX6958/59 toc07

VDIG0/

SEG0

1V/div

200µs/div

INPUT PULLUP CURRENT

vs. TEMPERATURE

MAX6958/59 toc08

TEMPERATURE (°C)

INPUT PULLUP CURRENT (µA)

1008040 600 20-20

-40 120

5.5V

4.5V

Detailed Description

The MAX6958/MAX6959 serially interfaced display dri-

vers drive up to: four 7-segment digits plus four dis-

crete LEDs if the decimal points are used, or four

7-segment digits plus eight discrete LEDs if the deci-

mal points are not used, or 36 discrete LEDs. Table 1

lists the display connection scheme.

The MAX6958/MAX6959 include the hexadecimal font

map for seven-segment displays. The seven-segment

LED digits can be controlled directly or programmed to

use the hexadecimal font. Direct segment control

allows the MAX6958/MAX6959 to drive bar graphs and

discrete LED indicators.

The MAX6958/MAX6959 use a multiplexing scheme that

minimizes the connections between the driver and LED

display. The MAX6958/MAX6959 can drive monocolor

and bicolor single-digit type displays, and monocolor

dual-digit displays. Dual-digit displays internally

wire together the equivalent segments for each digit,

requiring only eight segment pins instead of 16. The

MAX6958/MAX6959 can also drive multidigit LED dis-

plays that have the segments individually pinned for

each digit.

To connect four single-digit displays to the MAX6958/

MAX6959, connect cathode outputs DIG0/SEG0–

DIG3/SEG3 to the cathodes of the four display digits as

shown in Table 1 (CC0–CC3). Drive eight additional

LEDs with SEG0 to SEG7. Four of the eight LEDs can

be the decimal point (DP) segments of the four dis-

plays, and the other four can be discrete LED indica-

tors.

To connect two dual-digit displays to the MAX6958/

MAX6959, connect cathode outputs DIG0/SEG0 and

DIG1/SEG1 to the cathodes of the first dual digit.

Connect DIG2/SEG2 and DIG3/SEG3 to the cathodes

of the second dual digit. SEG0 to SEG3 can only drive

discrete LEDs, not digit DP segments. SEG4 to SEG7

can drive the DP segments if required. Bicolor single-

digit displays are connected and treated as dual-digit

displays, each digit being one of the two colors.

MAX6958/MAX6959

2-Wire Interfaced, 3V to 5.5V, 4-Digit,

9-Segment LED Display Drivers with Keyscan

_______________________________________________________________________________________ 5

Pin Description

MAX6958

MAX6959

NAME FUNCTION

11SDA Serial Data I/O

22SCL Serial Clock Input

3—SEG9 Segment Output. Segment driver sourcing current to a display anode.

—3IRQ/SEG9 Interrupt or Segment Output. May be segment driver sourcing current to a display

anode, or open-drain interrupt output, or open-drain logic output.

4–7, 11–15

4–7, 11–15 DIGX, SEGX

Digit and Segment Drivers. Digit X outputs sink current from the display common

cathode when acting as digit drivers. Segment X drivers source current to the display

anodes. Segment/digit drivers are high impedance when turned off.

88GND Ground

9, 10 — N.C. No Connect. Connect to V+ or leave open.

—9INPUT1 General-Purpose Input Port 1 with Internal Pullup. May be configured as general-

purpose logic input or keyscan input. Connect to V+ or leave open if unused.

—10INPUT2 General-Purpose Input Port 2 with Internal Pullup. May be configured as general-

purpose logic input or keyscan input. Connect to V+ or leave open if unused.

16 16 V+ Positive Supply Voltage

DIG0/SEG0 DIG1/SEG1 DIG2/SEG2 DIG3/SEG3 SEG 4 SEG 5 SEG 6 SEG 7 SEG 8 SEG 9/IRQ

LED Digit 0 CC0 SEG 0 SEG g SEG f SEG e SEG d SEG c SEG b SEG a SEG 4

LED Digit 1 SEG 1 CC1 SEG g SEG f SEG e SEG d SEG c SEG b SEG a SEG 5

LED Digit 2 SEG g SEG f CC2 SEG 2 SEG e SEG d SEG c SEG b SEG a SEG 6

LED Digit 3 SEG g SEG f SEG 3 CC3 SEG e SEG d SEG c SEG b SEG a SEG 7

Table 1. Standard Driver Connection to LED Displays

MAX6958/MAX6959

Differences Between MAX6958

and MAX6959

The MAX6958/MAX6959 have the same LED drive

capability, four common-cathode digits of nine seg-

ments per digit. The MAX6959 additionally contains two

logic input ports, INPUT1 and INPUT2. Each input port

can be individually configured as either a general-pur-

pose input port that is read through the serial interface,

or as a keyscan input. In keyscan mode, the input is

used to read and automatically debounce four key

switches. A maximum of eight key switches can be

read if both INPUT1 and INPUT2 are assigned to

keyscanning.

The MAX6958's SEG9 output is preconfigured as the

9th LED segment output. The IRQ/SEG9 output on the

MAX6959 can be configured as either an open-drain

logic output or the 9th segment output. This logic out-

put serves as either a general-purpose logic output, set

through the serial interface, or an interrupt (IRQ) output

that alerts a microcontroller of debounced key-switch

events. Key-switch status can also be obtained by

polling the internal status registers at any time.

Use the Option bit in the configuration register to detect

whether a MAX6958 or MAX6959 is present. The option

bit allows host software to establish whether a high-end

front panel (using the MAX6959 for keyscan support) or

a low-end panel (using a MAX6958 and no key switch-

es) is fitted to a product.

Serial Interface

Serial Addressing

The MAX6958/MAX6959 operate as a slave that sends

and receives data through a 2-wire interface. The inter-

face uses a serial data line (SDA) and a serial clock line

(SCL) to achieve bidirectional communication between

master(s) and slave(s). A master, typically a microcon-

troller, initiates all data transfers to and from the

MAX6958/MAX6959, and generates the SCL clock that

synchronizes the data transfer (Figure 1).

The MAX6958/MAX6959 SDA line operates as both an

input and an open-drain output. A pullup resistor, typi-

cally 4.7kΩ, is required on the SDA bus. The MAX6958/

MAX6959 SCL line operates only as an input. A pullup

resistor, typically 4.7kΩ, is required on the SCL bus if

there are multiple masters on the 2-wire interface, or if

the master in a single-master system has an open-drain

SCL output.

Each transmission consists of a START condition

(Figure 2) sent by a master, followed by the MAX6958/

MAX6959 7-bit slave address plus R/Wbit (Figure 3), 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, it issues a

STOP (P) condition by transitioning the SDA from low to

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

transmission (Figure 2).

2-Wire Interfaced, 3V to 5.5V, 4-Digit,

9-Segment LED Display Drivers with Keyscan

6_______________________________________________________________________________________

tLOW

SDA

tLOW

tSU, DAT tHD, DAT

SCL

START

CONDITION

STOP

CONDITION

START

CONDITION

REPEATED START

CONDITION

tHIGH

tHD, STA

tSU, STA

tHD, STA tSU, STO

tBUF

Figure 1. 2-Wire Serial Interface Timing Details

SDA

START

CONDITION

SCL

STOP

CONDITION

Figure 2. Start and Stop Conditions

Bit Transfer

One data bit is transferred during each clock pulse.

The data on the SDA line must remain stable while SCL

is high (Figure 4).

Acknowledge

The acknowledge bit is a clocked 9th bit that the recipi-

ent uses to handshake receipt of each byte of data

(Figure 5). 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, such that the SDA line is sta-

ble low during the high period of the clock pulse. When

the master is transmitting to the MAX6958/MAX6959,

the MAX6958/MAX6959 generate the acknowledge bit

because the MAX6958/MAX6959 are the recipients.

When the MAX6958/MAX6959 are transmitting to the

master, the master generates the acknowledge bit

because the master is the recipient.

Slave Address

The MAX6958/MAX6959 have a 7-bit-long slave

address (Figure 3). The eighth bit following the 7-bit

slave address is the R/Wbit. Set the R/Wbit low for a

write command and high for a read command.

The MAX6958/MAX6959 are available in one of two

possible slave addresses (see Table 2 and Ordering

Information). The first 6 bits (MSBs) of the MAX6958/

MAX6959 slave address are always 011100. Slave

address bit A0 is internally hardwired to either GND in

the MAX695_A_, or V+ in the MAX695_B_. A maximum

of two MAX6958/MAX6959 devices can share a bus.

Message Format for Writing

A write to the MAX6958/MAX6959 comprises the trans-

mission of the MAX6958/MAX6959s’ slave address with

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

information. The first byte of information is the com-

mand byte, which determines the register that stores

the next byte written to the MAX6958/MAX6959. If a

STOP condition is detected after the command byte is

received, the MAX6958/MAX6959 take no further action

(Figure 6) beyond storing the command byte.

MAX6958/MAX6959

2-Wire Interfaced, 3V to 5.5V, 4-Digit,

9-Segment LED Display Drivers with Keyscan

_______________________________________________________________________________________ 7

SDA

SCL

01 A0

MSB LSB

R/W ACK11 0 0

Figure 3. Slave Address

SDA

DATA STABLE,

DATA VALID

CHANGE OF

DATA ALLOWED

SCL

Figure 4. Bit Transfer

SCL

START

CONDITION

SDA

289

CLOCK PULSE FOR

ACKNOWLEDGMENT

ACKNOWLEDGE

NOT ACKNOWLEDGE

Figure 5. Acknowledge

MAX6958/MAX6959 DEVICE ADDRESS

SLAVE ADDRESS

BIT A0

A6 A5 A4 A3 A2 A1

MAX695_A_

011100

MAX695_B_

011100

Table 2. MAX6958/MAX6959 Address Map

S A0SLAVE ADDRESS COMMAND BYTE

ACKNOWLEDGE FROM

MAX6958/MAX6959

R/W ACKNOWLEDGE FROM

MAX6958/MAX6959

D15 D14 D13 D12 D11 D10 D9 D8

COMMAND BYTE IS STORED ON RECEIPT OF STOP CONDITION

Figure 6. Command Byte Received

MAX6958/MAX6959

Bytes received after the command byte are data bytes.

The first data byte goes into the internal register of the

MAX6958/MAX6959 as selected by the command byte

(Figure 7).

The address pointer in the MAX6958/MAX6959 autoin-

crements after each data byte. If multiple data bytes

are transmitted before a STOP condition is detected,

these bytes are stored in subsequent MAX6958/

MAX6959 internal registers (Figure 8), unless the

address pointer has reached address 01111111. The

address pointer does not autoincrement once address

01111111 has been reached (Table 3).

Message Format for Reading

The MAX6958/MAX6959 are read using the internally

stored command byte as an address pointer the same

way the stored command byte is used as an address

pointer for a write. The pointer autoincrements after

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

(Table 3). A read is initiated by first configuring the

MAX6958/MAX6959s’ command byte with a write com-

mand (Figure 6). The master can now read n consecu-

tive bytes from the MAX6958/MAX6959. The master

acknowledges receipt of each read byte during the

acknowledge clock pulse. The master must acknowl-

edge all consecutive bytes received except the last

byte. The final read byte must be followed by a not

acknowledge from the master and then a stop condi-

tion (Figure 9). The first data byte is read from the reg-

ister addressed by the initialized command byte

(Figure 8). Reset the address pointer when performing

read-after-write verification because the stored byte

address is autoincremented after the write. The

address pointer does not autoincrement if it points to

Table 4 is the register address map.

2-Wire Interfaced, 3V to 5.5V, 4-Digit,

9-Segment LED Display Drivers with Keyscan

8_______________________________________________________________________________________

0SLAVE ADDRESS COMMAND BYTE DATA BYTE

ACKNOWLEDGE FROM

MAX6958/MAX6959

R/W 1 BYTE

AUTOINCREMENT MEMORY WORD ADDRESS

ACKNOWLEDGE FROM MAX6958/MAX6959 ACKNOWLEDGE FROM MAX6958/MAX6959

D15 D14 D13 D12 D11 D10 D9 D8 D1 D0D3 D2D5 D4D7 D6

HOW CONTROL BYTE AND DATA BYTE MAP INTO

MAX6958/MAX6959s' REGISTERS

S AA P

Figure 7. Command and Single Data Byte Received

0SLAVE ADDRESS COMMAND BYTE DATA BYTE

ACKNOWLEDGE FROM

MAX6958/MAX6959

R/W n BYTES

AUTOINCREMENT MEMORY WORD ADDRESS

ACKNOWLEDGE FROM MAX6958/MAX6959 ACKNOWLEDGE FROM MAX6958/MAX6959

D15 D14 D13 D12 D11 D10 D9 D8 D1 D0D3 D2D5 D4D7 D6

HOW CONTROL BYTE AND DATA BYTE MAP INTO

MAX6958/MAX6959s' REGISTERS

S AA P

Figure 8. n Data Bytes Received

1SLAVE ADDRESS FIRST DATA BYTE DATA BYTE

ACKNOWLEDGE FROM MAX6958/MAX6959

R/W n BYTES

AUTOINCREMENT MEMORY WORD ADDRESS

ACKNOWLEDGE FROM THE MASTER NOT ACKNOWLEDGE FROM MASTER

D15 D14 D13 D12 D11 D10 D9 D8 D1 D0D3 D2D5 D4D7 D6

HOW THE MAX6958/MAX6959 SENDS DATA

TO THE MASTER

S AA P

AUTOINCREMENT MEMORY WORD ADDRESS

Figure 9. Reading n Data Bytes from the MAX6958/MAX6959

Operation with Multiple Masters

If the MAX6958/MAX6959 are operated on a 2-wire

interface with multiple masters, a master reading the

MAX6958/MAX6959 should use a repeated start

between the write, which sets the MAX6958/MAX6959s’

address pointer, and the read(s) that takes the data

from the location(s) set by the address pointer. It is

possible for master 2 to take over the bus after master

1 has set up the MAX6958/MAX6959s’ address pointer

but before master 1 has read the data. If master 2 sub-

sequently changes the MAX6958/MAX6959s’ address

pointer, then master 1's delayed read may be from an

unexpected location.

Command Address Autoincrementing

Address autoincrementing allows the MAX6958/

MAX6959 to be configured with the shortest number of

transmissions by minimizing the number of times the

command byte needs to be sent. The address pointer

stored in the MAX6958/MAX6959 increments after each

data byte is written or read, unless the address equals

01111111 (Table 3).

Digit Type Registers

The MAX6958/MAX6959 store display data in five regis-

ters. The four digit registers each control the seven

numeric segments of a seven-segment digit, but not

the DP segments. The segments register controls eight

individual LEDs, which can be any mix of discrete LEDs

and any or all of the DP segments of the four 7-seg-

ment digits (Table 5) (Figure 10).

MAX6958/MAX6959

2-Wire Interfaced, 3V to 5.5V, 4-Digit,

9-Segment LED Display Drivers with Keyscan

_______________________________________________________________________________________ 9

COMMAND BYTE

ADDRESS RANGE

AUTOINCREMENT BEHAVIOR

00000000 to

01111110

Command byte address autoincrements

after byte read or written

01111111 Command byte address remains at

01111111 after byte written or read

Table 3. Command Address

Autoincrement Behavior

COMMAND ADDRESS

D15 D14 D13 D12 D11 D10 D9 D8

HEX

CODE

No-op 0 0 0 0 0 0 0 0 0x00

Decode mode 0 0 0 0 0 0 0 1 0x01

Intensity 0 0 0 0 0 0 1 0 0x02

Scan limit 0 0 0 0 0 0 1 1 0x03

Configuration 0 0 0 0 0 1 0 0 0x04

Factory reserved. Do not write to this register. 0 0 0 0 0 1 0 1 0x05

GPIO (MAX6959 only) 0 0 0 0 0 1 1 0 0x06

Display test 0 0 0 0 0 1 1 1 0x07

Read key debounced (MAX6959 only)

A write to this register is ignored. 000010000x08

Read key pressed (MAX6959 only)

A write to this register is ignored. 000011000x0C

Digit 0 0 0 1 0 0 0 0 0 0x20

Digit 1 0 0 1 0 0 0 0 1 0x21

Digit 2 0 0 1 0 0 0 1 0 0x22

Digit 3 0 0 1 0 0 0 1 1 0x23

Segments 0 0 1 0 0 1 0 0 0x24

Table 4. Register Address Map

Figure 10. Segment Labeling for 7-Segment Display

MAX6958/MAX6959

The digit registers and segments register use 1 bit to

set the state of one segment. Each bit is high to turn a

segment on, or low to turn it off (Table 6).

Decode-Mode Register

The decode-mode register sets hexadecimal code

(0–9, A–F) or no-decode operation for each digit. Each

bit in the register corresponds to one digit. Logic high

selects hexadecimal decoding while logic low bypass-

es the decoder. Digits can be set for decode or no

decode in any combination. Bit assignment and exam-

ples of the decode mode control register format are

shown in Table 7.

In hexadecimal code-decode mode, the decoder looks

only at the lower nibble of the data in the digit register

(D3–D0), disregarding bits D7–D4. Table 7 lists the hexa-

decimal code font. When no decode is selected, data

bits D7–D0 correspond to the segment lines of the

MAX6958/MAX6959. Table 8 shows the one-to-one pair-

ing of each data bit to the appropriate segment line.

Initial Power-Up

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

display is blanked, and the MAX6958/MAX6959 enter

shutdown mode (Table 9). At power-up, the MAX6958/

MAX6959 are initially set to scan four digits, do not

decode data in the digit registers or scan key switches

(MAX6959 only), and the intensity register is set to a

low value (4/64 intensity).

2-Wire Interfaced, 3V to 5.5V, 4-Digit,

9-Segment LED Display Drivers with Keyscan

10 ______________________________________________________________________________________

DIGIT/SEGMENT REGISTER

ADDRESS

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

Digit 0 0x20 X

SEG a SEG b SEG c SEG d SEG e SEG f

SEG g

Digit 1 0x21 X

SEG a SEG b SEG c SEG d SEG e SEG f

SEG g

Digit 2 0x22 X

SEG a SEG b SEG c SEG d SEG e SEG f

SEG g

Digit 3 0x23 X

SEG a SEG b SEG c SEG d SEG e SEG f

SEG g

Segments 0x24

SEG 7 SEG 6 SEG 5 SEG 4 SEG 3 SEG 2 SEG 1

SEG 0

Table 5. No-Decode Mode Data Bits and Corresponding Segment Lines

0Segment off

1Segment on

Table 6. No-Decode Mode Data Bits and

Corresponding Segment Lines

DECODE MODE ADDRESS

CODE (HEX)

D7 D6 D5 D4 D3 D2 D1 D0

HEX

CODE

Bit assignment for each digit

0x01 XXXX

Digit 3 Digit 2 Digit 1 Digit 0

—

No decode for digits 3–0 0x01 XXXX0000

0xX0

Hexadecimal decode for digit

0; no decode for digits 3–1 0x01 XXXX0001

0xX1

———————————

Hexadecimal decode for digits

2–0; no decode for digit 3 0x01 XXXX0111

0xX7

Hexadecimal decode for digit

3; no decode for digits 2–0 0x01 XXXX1000

0xX8

———————————

Hexadecimal decode for digits

3–0 0x01 XXXX1111

0xXF

Table 7. Decode-Mode Register Examples

MAX6958/MAX6959

2-Wire Interfaced, 3V to 5.5V, 4-Digit,

9-Segment LED Display Drivers with Keyscan

______________________________________________________________________________________ 11

7-SEGMENT

CHARACTER

D7–D4

D3 D2 D1 D0 a b c d e f g

0X00001111110

1X00010110000

2X00101101101

3X00111111001

4X01000110011

5X01011011011

6X01101011111

7X01111110000

8X10001111111

9X10011111011

AX10101110111

BX10110011111

CX11001001110

DX11010111101

EX11101001111

FX11111000111

Table 8. Seven-Segment Mapping Decoder for Hexadecimal Font

CODE (HEX) D7 D6 D5 D4 D3 D2 D1

Decode mode No decode for digits 3–0 0x01 X X X X 0000

Intensity 4/64 intensity 0x02 X X 0 00100

Scan limit Display 4 digits: 0 1 2 3 0x03 X X X X X X 1 1

Configuration Shutdown enabled 0x04 X X 0 X X X

D bit

GPIO*

IRQ/SEG9 is a segment output

(not IRQ or logic output);

INPUT2 and INPUT1 are logic

inputs; IRQ flag is clear

0x06 1 0 0 0 0 X X 0

Display test Normal operation 0x07 X X X XXXX0

Key debounced*

No key detected as debounced 0x08 0 0 0 00000

Key pressed* No key detected as pressed 0x0C 0 0 0 00000

Digit 0 Blank digit (because not decoded) 0x20 X 0 0 00000

Digit 1 Blank digit (because not decoded) 0x21 X 0 0 00000

Digit 2 Blank digit (because not decoded) 0x22 X 0 0 00000

Digit 3 Blank digit (because not decoded) 0x23 X 0 0 00000

Segments Blank segments 0x24 0 0 0 00000

Table 9. Initial Power-Up Register Status

*MAX6959 only.

MAX6958/MAX6959

Configuration Register

Use the configuration register to enter and exit shut-

down, check device type, and globally clear the digit

data (Tables 10–13). The S bit selects shutdown or nor-

mal operation (read/write). The D bit reports whether

the device is a MAX6958 or a MAX6959 (read only).

The R bit clears all the digit and segment data (data is

not stored-transient bit)

Scan-Limit Register

The scan-limit register sets the number of digits dis-

played, from one to four (Table 14). A bicolor digit is

connected as two monocolor digits. The scan-limit reg-

ister also limits the number of keys that can be

scanned. Since the number of scanned digits affects

the display brightness, the scan-limit register should

not be used to blank portions of the display (such as

leading zero suppression).

Intensity Register

An internal pulse-width modulator controlled by the

intensity register provides digital control of display

brightness. The modulator scales the average segment

current in 63 steps from a maximum of 63/64 down to

1/64 of the 23mA peak current. The minimum interdigit

blanking time is set to 1/64 of a cycle (Figure 11 and

Table 15).

2-Wire Interfaced, 3V to 5.5V, 4-Digit,

9-Segment LED Display Drivers with Keyscan

12 ______________________________________________________________________________________

MODE ADDRESS

CODE (HEX) D7 D6 D5 D4 D3 D2 D1

Configuration register 0x04 X X R X X X D S

Table 10. Configuration Register Format

MODE ADDRESS

CODE (HEX) D7 D6 D5 D4 D3 D2 D1

Shutdown mode 0x04 X X R X X X D 0

Normal operation 0x04 X X R X X X D 1

Table 11. Shutdown Control (S Data Bit D0) Format

MODE ADDRESS

CODE (HEX) D7 D6 D5 D4 D3 D2 D1

MAX6958 0x04 X X R X X X 0 S

MAX6959 0x04 X X R X X X 1 S

Table 12. Device Readback (D Data Bit D1) Format

MODE ADDRESS

CODE (HEX) D7 D6 D5 D4 D3 D2 D1

Digit and segment data are unaffected 0x04 X X 0 X X X D S

Digit and segment data are cleared 0x04 X X 1 X X X D S

Table 13. Global Clear Digit Data (R Data Bit D5) Format

SCAN LIMIT ADDRESS

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

HEX

CODE

Display digit 0 and segments 0, 4 0x03

XXXXXX00

0xX0

Display digits 0, 1 and segments 0, 1, 4, 5 0x03

XXXXXX01

0xX1

Display digits 0, 1, 2 and segments 0, 1, 2, 4, 5, 6

0x03

XXXXXX10

0xX2

Display digits 0, 1, 2, 3 and segments 0, 1, 2, 3, 4,

5, 6, 7 0x03

XXXXXX11

0xX3

Table 14. Scan-Limit Register Format

MAX6958/MAX6959

2-Wire Interfaced, 3V to 5.5V, 4-Digit,

9-Segment LED Display Drivers with Keyscan

______________________________________________________________________________________ 13

DUTY CYCLE

TYPICAL SEGMENT

CURRENT (mA)

ADDRESS

CODE (HEX)

HEX CODE

1/64 (min on) 0.36 0x02

00x00

2/64 0.72 0x02

10x01

3/64 1.08 0x02

00x02

4/64 1.44 0x02

10x03

5/64 1.80 0x02

00x04

6/64 2.16 0x02

10x05

——0x02

XX——————

—

60/64 21.56 0x02

10x3B

61/64 21.92 0x02

00x3C

62/64 22.28 0x02

10x3D

63/64 22.64 0x02

00x3E

63/64 (max on)

22.64 0x02

10x3F

Table 15. Global Intensity Register Format

1/64th

(MIN ON)

2/64th

3/64th

63/64th

61/64th

62/16th

63/64th

DIGIT 0 CATHODE

DRIVER INTENSITY

SETTINGS HIGH-Z

HIGH-Z

LOW

MINIMUM 5µs INTERDIGIT BLANKING INTERVAL

(MAX ON)

ANODE (LIT) CURRENT SOURCE ENABLED

HIGH-Z

ANODE (UNLIT)

HIGH-Z

DIGIT 1 DIGIT 2 DIGIT 3DIGIT 0 DIGIT 0

START OF

NEXT CYCLE

ONE COMPLETE 1.28ms MULTIPLEX CYCLE AROUND 4 DIGITS

DIGIT 0's 320µs MULTIPLEX TIMESLOT

Figure 11. Multiplex Timing Diagram

MAX6958/MAX6959

Ports and Key Scanning

(MAX6959 Only)

The MAX6959 features two input ports, INPUT1 and

INPUT2. These two ports can be used as general-pur-

pose logic inputs, or configured to perform automatic

keyscanning. Both ports have internal pullup resistors

enabled in shutdown and normal operation for both

general-purpose input mode and keyscanning mode.

The ports can be read using the 2-wire interface.

The keyscan logic uses one or both of the INPUT1 and

INPUT2 logic inputs (Figure 12). An interrupt output that

flags key presses is optional. The interrupt flag can be

read (polled) through the serial interface instead, allow-

ing IRQ/SEG9 to be used as an open-drain general-

purpose logic output or as a segment driver.

One small-signal diode is required per key switch when

more than one key is connected to INPUT1 or INPUT2.

The diodes prevent two simultaneous key switch

depressions from shorting digit drivers together. For

example, if KEY0 and KEY1 were pressed together

(Figure 12) and the diodes were not fitted, DIG0/SEG0

and DIG1/SEG1 would be shorted together and the

LED multiplexing would be incorrect. These diodes can

be common-anode dual diodes in SOT23 like BAW56.

A diode is not required for a single key connection to

INPUT1 or INPUT2. Therefore, up to two key switches

can be directly connected without adding diodes

(Figure 13).

Resistors R1 and R2 are required if the MAX6959 is

operated with V+ greater than 4V. R1 and R2 are

optional if V+ is between 3V and 4V.

The keyscanning circuit utilizes the LED’s common-

cathode driver outputs as the keyscan drivers. The out-

puts DIG0/SEG0 to DIG3/SEG3 pulse low for nominally

320µs sequentially as the displays are multiplexed. The

actual low time varies from 5µs to 315µs due to pulse-

width modulation from 1/64th to 63/64th for intensity

control. The timing diagram (Figure 14) shows the typi-

cal situation when all four LED cathode drivers are used.

The maximum eight keys can be scanned only if the

scan-limit register is set to scan the maximum four dig-

its. If fewer than four digits are driven, then only (2 x n)

switches can be scanned, where n is the number of dig-

its (1, 2, 3, or 4) set in the scan-limit register (Table 14).

The keyscan cycle loops continuously over time, with

all eight keys experiencing a full keyscanning

debounce over 41ms (Figure 14). A key press is

debounced and an interrupt issued if at least one key

that was not pressed in a previous cycle is found

pressed during both sampling periods. The keyscan

circuit detects any combination of keys pressed during

each debounce cycle (n-key rollover).

Port Configuration Register

(MAX6959 Only)

The port configuration register configures INPUT1,

INPUT2, and IRQ/SEG9 ports for the MAX6959 (Table 16).

IRQ/SEG9 can be set to either an LED segment output

(driving four multiplexed LED segments), or an open-

drain logic output. The open-drain logic output can be

configured as either an IRQ output controlled by the

keyscan circuitry, or as a general-purpose logic output

controlled through the 2-wire interface. Connect a

2-Wire Interfaced, 3V to 5.5V, 4-Digit,

9-Segment LED Display Drivers with Keyscan

14 ______________________________________________________________________________________

Key0

Key1

Key2

Key3

Key5

Key6

Key7

DIG0/SEG0

INPUT1

INPUT2

V+

IRQ/SEG9

DIG1/SEG1

DIG2/SEG2

DIG3/SEG3

MICROCONTROLLER INTERRUPT

Key4

39kΩ

4.7kΩ

Figure 12. Maximum Keyscan Configuration

Key4

INPUT1

INPUT2

V+

IRQ/SEG9

DIG0/SEG0

MICROCONTROLLER INTERRUPT

Key0

39kΩ

4.7kΩ

Figure 13. Keyscanning Two Keys Without Diodes

pullup resistor from IRQ/SEG9 to a voltage no greater

than 5.5V when configuring IRQ/SEG9 as an interrupt

or logic output.

INPUT1 and INPUT2 can be individually configured as

either general-purpose logic inputs or as keyscan

inputs. In either mode, the input structure is the same—

CMOS logic inputs with internal pullup resistors. The

pullups are always enabled, even in shutdown. Ensure

these inputs are either close to V+ or open circuit for

minimum shutdown supply current. If both INPUT1 and

INPUT2 are assigned to keyscan, then eight keys can

be debounced. If only INPUT1 or INPUT2 is assigned

to keyscan, then only four keys can be debounced.

MAX6958/MAX6959

2-Wire Interfaced, 3V to 5.5V, 4-Digit,

9-Segment LED Display Drivers with Keyscan

______________________________________________________________________________________ 15

DIG1/SEG1

DIG2/SEG2

DIG3/SEG3

DIG0/SEG0

THE FIRST HALF OF A 41ms KEYSCAN CYCLE THE SECOND HALF OF A 41ms KEYSCAN CYCLE

A B

START OF NEXT KEYSCAN CYCLE

INTERRUPT ASSERTED IF REQUIRED

KEY DEBOUNCED REGISTER UPDATED

1.28ms MULTIPLEX

CYCLE 1

INPUT2

INPUT1 Key0

FIRST TEST OF KEYS SECOND TEST OF KEYS

tDEBOUNCE

Key1 Key2 Key3

Key4 Key5 Key6 Key7

Key0 Key1 Key2 Key3

Key4 Key5 Key6 Key7

C D E

1.28ms MULTIPLEX

CYCLE 2

1.28ms MULTIPLEX

CYCLE 3

1.28ms MULTIPLEX

CYCLE 4

1.28ms MULTIPLEX

CYCLE 15

1.28ms MULTIPLEX

CYCLE 16

1.28ms MULTIPLEX

CYCLE 1

1.28ms MULTIPLEX

CYCLE 2

1.28ms MULTIPLEX

CYCLE 15

1.28ms MULTIPLEX

CYCLE 16

5µs TO 315µs DIGIT PERIOD

Figure 14. Keyscan Timing Diagram

MODE

ADDRESS

CODE

(HEX)

D7 D6 D5

D4 D3 D2 D1 D0

This is the bit assignment:

Read GPIO register 0x06

Read back

IRQ/SEG9

configuration

Read back

INPUT 2

configuration

Read back

INPUT 1

configuration

INPUT2

logic level

INPUT1

logic level

IRQ status

( 1 = i nter rup t)

Write GPIO register 0x06

Configure

IRQ/SEG9

output

Configure

INPUT 2:

0 = logic input

1 = keyscan

Configure

INPUT 1:

0 = logic input

1 = keyscan

XXX

Here are the IRQ/SEG9 allocation options, determined by the settings of D7, D6, D5:

IRQ/SEG9 is logic 0 output

0x06

000

XXXXX

IRQ/SEG9 is logic 1 output

0x06

001

XXXXX

IRQ/SEG9 is active-low

IRQ 0x06

010

XXXXX

IRQ/SEG9 is active-high

IRQ 0x06

011

XXXXX

IRQ/SEG9 is segment

driver 0x06

1XX

XXXXX

Table 16. Port Configuration Register Format

MAX6958/MAX6959

Key Debounced Register (MAX6959 Only)

The key debounced register shows which keys have

been detected as debounced by the keyscanning cir-

cuit (Table 17). Each bit in the register corresponds to

one key switch. The bit is set to 1 if the switch has been

correctly debounced since the last key debounced reg-

ister read operation.

Reading the key debounced register clears the register

(after the data has been read) so that future key presses

can be identified. If the key debounced register is not

read, the keyscan data accumulates. There is no FIFO

key has been pressed more than once, cannot be

determined unless the key debounced register is read

after each interrupt and before completion of the next

keyscan cycle.

Reading the key debounced register clears the IRQ

output. If a key is pressed and held down, the key is

reported as debounced (and an IRQ is issued) only

once. The key must be detected as released by the

keyscanning circuit before it is debounced again.

The key debounced register is read only. A write to

address 0x08 is ignored.

Key Pressed Register (MAX6959 Only)

The key pressed register shows which keys have been

detected as pressed by the keyscanning circuit during

the last test. Each bit in the register corresponds to one

key switch. The bit is set if the switch has been detect-

ed as pressed by the keyscanning circuit during the

last test. The bit is cleared if the switch has not been

detected as pressed by the keyscanning circuit during

the last test. Reading the key pressed register does not

clear either the key pressed register, or the key

debounced register, and does not clear the IRQ output.

The key pressed register is read only. A write to

address 0x0C is ignored.

Display Test Register

The display test register operates in two modes: normal

and display test (Table 19). Display test mode turns on

all LEDs by overriding, but not altering, all control and

digit registers (including the shutdown register) except

for the port configuration register. The duty cycle while

in display test mode is 28/64.

Applications Information

Driving Bicolor LEDs

Bicolor digits combine a red and a green die for each

display element, so that the element displays red or

green (or orange), depending on which die (or both) is

lit. The MAX6958/MAX6959 treat a bicolor digit as two

monocolor digits.

Low-Voltage Operation

The MAX6958/MAX6959 are guaranteed to drive a 23mA

segment current into 2.4V (or lower) LEDs when operat-

ed from a supply voltage of 4.5V to 5.5V. Operating the

MAX6958/MAX6959 from a supply voltage lower than

4.5V reduces the LED drive current. The drivers drive at

least 15.5mA segment current into 2V (or lower) LEDs

when operated from a 3V supply voltage.

2-Wire Interfaced, 3V to 5.5V, 4-Digit,

9-Segment LED Display Drivers with Keyscan

16 ______________________________________________________________________________________

WITH APPROPRIATE SWITCH NAMED BELOW

KEY DEBOUNCED REGISTER ADDRESS

CODE (HEX)

D7 D6 D5 D4 D3 D2 D1

Key debounced register 0x08

Key7 Key6 Key5 Key4 Key3 Key2 Key1

Key0

Table 17. Key Debounced Register Format

WITH APPROPRIATE SWITCH NAMED BELOW

KEY PRESSED REGISTER ADDRESS

CODE (HEX)

D7 D6 D5 D4 D3 D2 D1 D0

Key pressed register 0x0C

Key7 Key6 Key5 Key4 Key3 Key2 Key1 Key0

Table 18. Key Pressed Register Format

MODE ADDRESS

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

Normal operation 0x07 XXXXXXX0

Display test mode 0x07 XXXXXXX1

Table 19. Display Test Register

Computing Power Dissipation

Determine the MAX6958/MAX6959 upper-limit power

dissipation (PD) with the following equation:

PD= (V+ ✕I+) + (V+ - VLED) (DUTY ✕ISEG ✕N)

where:

V+ = supply voltage

I+ = operating supply current

DUTY = duty cycle set by intensity register

N = number of segments driven (worst case is nine)

VLED = LED forward voltage at ISEG

ISEG = peak segment current

PD= power dissipation, in mW if currents are in mA

Dissipation example:

ISEG = 23mA, N = 9, DUTY = 63/64, VLED = 2.2V,

V+ = 5.25V

PD= 5.25V (5.9mA) + (5.25V - 2.2V)

(63/64 ✕23mA ✕9) = 0.652W

For a 16-pin DIP package (TJA = 1/0.0105 = +95.2°C/W

from Absolute Maximum Ratings), the maximum

allowed ambient temperature TAis given by:

TJ(MAX) = TA+ (PD✕TJA) = +150°C

= TA+ (0.652 ✕95.2°C/W)

Therefore, TA= +87.9°C.

Power Supplies

The MAX6958/MAX6959 operate from a single 3V to

5.5V power supply. Bypass V+ with a 0.1µF capacitor

to GND, as close to the device as possible. Bypass V+

with an additional 10µF capacitor if the MAX6958/

MAX6959 are not close to the board input’s bulk

decoupling capacitor.

Chip Information

TRANSISTOR COUNT: 17,340

PROCESS: CMOS

MAX6958/MAX6959

2-Wire Interfaced, 3V to 5.5V, 4-Digit,

9-Segment LED Display Drivers with Keyscan

______________________________________________________________________________________ 17

Ordering Information (continued)

PART

TEMP

RANGE

SLAVE

ADDRESS

PIN-

PACKAGE

PKG

CODE

MAX6958BAEE

-40°C to

+125°C0111001

16 QSOP

E 16- 1

MAX6958BAPE

-40°C to

+125°C0111001

16 DIP

P16-1

MAX6959AAEE

-40°C to

+125°C0111000

16 QSOP

E 16- 1

MAX6959AAPE

-40°C to

+125°C0111000

16 DIP

P16-1

MAX6959BAEE

-40°C to

+125°C0111001

16 QSOP

E 16- 1

MAX6959BAPE

-40°C to

+125°C0111001

16 DIP

P16-1

CONFIGURATION

REGISTERS

DISPLAY RAM

AND HEX ROM

SCL

SDA 2-WIRE SERIAL INTERFACE

MULTIPLEX

LOGIC

4 LED DIGITS

KEYSCAN AND

LED

DRIVER

CURRENT

REFERENCE

MULTIPLEX

OSCILLATOR

PWM INTENSITY

CONTROL

PORT CONTROL

PORTS AND

KEYSCAN

IRQ

Functional Diagram

MAX6958/MAX6959

2-Wire Interfaced, 3V to 5.5V, 4-Digit,

9-Segment LED Display Drivers with Keyscan

18 ______________________________________________________________________________________

V+

DIG0–DIG3

SEG0–SEG9

SDA

SCL

INPUT1

µC

SDA

SCL

INPUT2

GND

9 99 9

Key0

DIG0/SEG0

Key1

DIG1/SEG1

Key2

DIG2/SEG2

Key3

DIG3/SEG3

Key4

DIG0/SEG0

Key5

DIG1/SEG1

Key6

DIG2/SEG2

Key7

DIG3/SEG3

MAX6959 0.1µF

39kΩ39kΩ

Typical Application Circuit

SDA V+

SEG8

SEG7

SEG6

SEG5

SEG4

(INPUT2)/N.C.

(INPUT1)/N.C.

TOP VIEW

MAX6958/

MAX6959

QSOP/DIP

SCL

(IRQ/SEG9) SEG9

DIG2/SEG2

DIG0/SEG0

DIG1/SEG1

DIG3/SEG3

GND

( ) MAX6959 ONLY

Pin Configuration

MAX6958/MAX6959

2-Wire Interfaced, 3V to 5.5V, 4-Digit,

9-Segment LED Display Drivers with Keyscan

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

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

21-0055

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