MAXIM MAX7360ETL+

19-4566; Rev 0; 4/09
TION KIT
EVALUA BLE
A
IL
A
AV
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
Features
The MAX7360
peripheral provides microprocessors with management of up to 64 key switches,
with an additional eight LED drivers/GPIOs that feature
constant-current, PWM intensity control, and rotary
switch control options.
S Integrated ESD Protection
The key-switch drivers interface with metallic or resistive
switches with on-resistances up to 5kI. Key inputs
are monitored statically, not dynamically, to ensure
low-EMI operation. The MAX7360 features autosleep
and autowake modes to further minimize the power
consumption of the device. The autosleep feature puts
the device in a low-power state (1FA typ) after a sleep
timeout period. The autowake feature configures the
MAX7360 to return to normal operating mode from sleep
upon a keypress.
S Rotary Switch-Capable Input Pair (PORT6, PORT7)
The key controller debounces and maintains a FIFO of
keypress and release events (including autorepeat, if
enabled). An interrupt (INTK) output can be configured
to alert keypresses, as they occur, or at maximum rate.
S +1.62V to +3.6V Operation
There are eight open-drain I/O ports, which can be used
to drive LEDs. The maximum constant-current level for
each open-drain port is 20mA. The intensity of the LED
on each open-drain port can be individually adjusted
through a 256-step PWM control. An input port pair
(PORT6, PORT7) can be configured to accept 2-bit gray
code inputs from a rotary switch. In addition, if not used
for key-switch control, up to six column pins can be used
as general-purpose open-drain outputs (GPOs) for LED
drive or logic control.
The MAX7360 is offered in a 40-pin (5mm x 5mm) thin
QFN package with an exposed pad, and a small 36-bump
wafer level package (WLP) for cell phones, pocket PCs,
and other portable consumer electronic applications. The
MAX7360 operates over the -40NC to +85NC extended
temperature range.
Q8kV IEC 61000-4-2 Contact Discharge
Q15kV IEC 61000-4-2 Air-Gap Discharge
S +14V Tolerant, Open-Drain I/O Ports Capable of
Constant-Current LED Drive
S 256-Step PWM Individual LED Intensity Control
S Individual LED Blink Rates and Common LED
Fade In/Out Rates from 256ms to 4096ms
S FIFO Queues Up to 16 Debounced Key Events
S User-Configurable Key Debounce (9ms to 40ms)
S Keyscan Uses Static Matrix Monitoring for Low
EMI Operation
S Monitors Up to 64 Keys
S Key-Switch Interrupt (INTK) on Each Debounced
Event/FIFO Level, or End of Definable Time Period
S Port Interrupt (INTI) for Input Ports for Special-Key
Functions
S 400kbps, +5.5V Tolerant 2-Wire Serial Interface
with Selectable Bus Timeout
S Four I2C Address Choices
Ordering Information
PART
MAX7360ETL+
MAX7360EWX+**
Simplfied Block Diagram
Cell Phones
Handheld Games
Portable Consumer Electronics
Printers
PIN-PACKAGE
40 TQFN-EP*
36 WLP
+Denotes a lead(Pb)-free/RoHS-compliant package.
*EP = Exposed pad.
**Future product—contact factory for availability.
Applications
PDAs
TEMP RANGE
-40°C to +85°C
-40°C to +85°C
+1.8V
TO
FC
SCL
SDA
INTI
INTK
PORT7
PORT6
MAX7360
Instrumentation
AD0
ROTARY
SWITCH
+14V
PORT0
ROW_(8x)
COL_(8x)
8x8
Pin Configurations appear at end of data sheet.
________________________________________________________________ Maxim Integrated Products 1
For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642,
or visit Maxim’s website at www.maxim-ic.com.
MAX7360
General Description
I2C-interfaced
MAX7360
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
ABSOLUTE MAXIMUM RATINGS
VCC to GND.............................................................. -0.3V to +4V
COL0–COL7, ROW0–ROW7 to GND....................... -0.3V to +4V
SDA, SCL, AD0, INTI, INTK to GND......................... -0.3V to +6V
PORT0–PORT7 to GND.......................................... -0.3V to +16V
All Other Pins to GND................................. -0.3V to (VCC + 0.3V)
DC Current on PORT0–PORT7, COL2–COL7.....................25mA
GND Current........................................................................80mA
Continuous Power Dissipation (TA = +70NC)
40-Pin TQFN (derate 22.2mW/NC above +70NC).......1777mW
36-Bump WLP (derate 21.7mW/NC above +70NC).....1739mW
Junction-to-Case Thermal Resistance (BJC) (Note 1)
40-Pin TQFN...................................................................2NC/W
36-Bump WLP.................................................................... N/A
Junction-to-Ambient Thermal Resistance (BJA) (Note 1)
40-Pin TQFN.................................................................45NC/W
36-Bump WLP..............................................................46NC/W
Operating Temperature Range........................... -40NC to +85NC
Junction Temperature......................................................+150NC
Storage Temperature Range............................. -65NC to +150NC
ESD Protection
Human Body Model (RD = 1.5kI, CS = 100pF)
All Pins..............................................................................Q2kV
IEC61000-4-2 (RD = 330I, CS = 150pF)
Contact Discharge
ROW0–ROW7, COL0–COL7, PORT0–PORT7 to GND.....Q8kV
Air-Gap Discharge
ROW0–ROW7, COL0–COL7, PORT0–PORT7 to GND...Q15kV
Lead Temperature (soldering, 10s)
40-Pin TQFN.................................................................+300NC
36-Bump WLP............................................................ (Note 2)
Note 1:Package thermal resistances were obtained using the method described in JEDEC specification JESD51-7, using a single-
.layer board. For detailed information on package thermal considerations, refer to www.maxim-ic.com/thermal-tutorial.
Note 2:Refer to Pb-free solder-reflow requirements described in J-STD-020, Rev D.1, or any other paste supplier specification.
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.
ELECTRICAL CHARACTERISTICS
(VCC = +1.62V to +3.6V, TA = -40NC to +85NC, unless otherwise noted. Typical values are at VCC = +3.3V, TA = +25NC.) (Notes 3, 4)
PARAMETER
Operating Supply Voltage
External Supply Voltage
PORT0–PORT7
Operating Supply Current
SYMBOL
CONDITIONS
VCC
MIN
TYP
MAX
UNITS
1.62
3.3
3.6
V
14
V
VPORT_
ICC
All key switches open, oscillator running,
COL2–COL7 configured as key switches,
VPORT_ = VCC
34
50
FA
34 +
20 x N
N keys pressed
Sleep-Mode Supply Current
ISL
1.3
3
FA
Key-Switch Source Current
IKEY
20
35
FA
Key-Switch Source Voltage
VKEY
0.43
0.5
V
5
kI
2
2.4
ms
0.5
V
Key-Switch Resistance
Startup Time from Shutdown
RKEY
Output Low Voltage
COL2–COL7
VOL
Oscillator Frequency (PWM
Clock)
fOSC
Oscillator Frequency Variation
Key-Scan Frequency
(Note 5)
tSTART
DfOSC
fKEY
ISINK = 10mA
TA = +25NC, VCC = +2.61V
125
TA = TMIN - TMAX, VCC P 3.6V
102
164
-6
+8.5
TA = +25NC
Derived from oscillator clock
128
64
2 _______________________________________________________________________________________
131
kHz
%
kHz
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
(VCC = +1.62V to +3.6V, TA = -40NC to +85NC, unless otherwise noted. Typical values are at VCC = +3.3V, TA = +25NC.) (Notes 3, 4)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
GPIO SPECIFICATIONS
Input High Voltage
PORT0–PORT7
VIH
Input Low Voltage
PORT0–PORT7
VIL
Input Leakage Current
PORT0–PORT7
IIN
Output Low Voltage
PORT0–PORT7
VOL
0.7 x
VCC
V
0.3 x
VCC
VIN P VCC
-0.25
+0.25
VCC < VIN
-1
+5
ISINK < 20mA
0.6
Input Capacitance
PORT0–PORT7
20
10mA Port Sinking Current
PORT0–PORT7
VCC = +1.62V to +3.6V, TA = +25NC
8.55
VCC = +3.3V, VOL = +1V
8.67
20mA Port Sinking Current
PORT0–PORT7
VCC = +1.62V to +3.6V, TA = +25NC
19.40
VCC = +3.3V, VOL = +1V
19.55
Port Sink Current Variation
VCC = +3.3V, VOL = +1V, TA = +25NC,
20mA output mode
Output Logic-Low Voltage
INTI, INTK
ISINK = 10mA
PWM Frequency
fPWM
Derived from oscillator clock
FA
V
pF
11.52
9.76
V
10.51
21.33
mA
mA
20
20.69
+Q1.5
+Q2.4
%
0.6
V
500
Hz
SERIAL-INTERFACE SPECIFICATIONS
Input High Voltage
SDA, SCL, AD0
VIH
Input Low Voltage
SDA, SCL, AD0
VIL
Input Leakage Current
SDA, SCL, AD0
IIN
Output Low Voltage
SDA
VOL
Input Capacitance
SDA, SCL, AD0
CIN
I2C TIMING SPECIFICATIONS
SCL Serial-Clock Frequency
Bus Free Time Between a STOP
and START Condition
fSCL
0.7 x
VCC
V
0.3 x
VCC
VIN P VCC
-0.25
+0.25
VIN > VCC
-0.5
+0.5
ISINK = 6mA
0.6
10
Bus timeout disabled
0
V
FA
V
pF
400
kHz
tBUF
1.3
Fs
Hold Time (Repeated) START
Condition
tHD, STA
0.6
Fs
Repeated START Condition
Setup Time
tSU, STA
0.6
Fs
STOP Condition Setup Time
tSU, STO
0.6
Fs
_______________________________________________________________________________________ 3
MAX7360
ELECTRICAL CHARACTERISTICS (continued)
MAX7360
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
ELECTRICAL CHARACTERISTICS (continued)
(VCC = +1.62V to +3.6V, TA = -40NC to +85NC, unless otherwise noted. Typical values are at VCC = +3.3V, TA = +25NC.) (Notes 3, 4)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
(Note 6)
MAX
UNITS
0.9
Fs
Data Hold Time
tHD, DAT
Data Setup Time
tSU, DAT
100
ns
SCL Clock Low Period
tLOW
1.3
Fs
SCL Clock High Period
tHIGH
0.7
Fs
Rise Time of Both SDA and SCL
Signals, Receiving
tR
(Notes 5, 7)
20 +
0.1Cb
300
ns
Fall Time of Both SDA and SCL
Signals, Receiving
tF
(Notes 5, 7)
20 +
0.1Cb
300
ns
tF, TX
(Notes 5, 8)
20 +
0.1Cb
250
ns
Pulse Width of Spike Suppressed
tSP
(Notes 5, 9)
50
Capacitive Load for Each Bus
Line
Cb
(Note 5)
Fall Time of SDA Signal,
Transmitting
ns
400
pF
Note 3: All parameters are tested at TA = +25NC. Specifications over temperature are guaranteed by design.
Note 4: All digital inputs at VCC or GND.
Note 5: Guaranteed by design.
Note 6: 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 7: Cb = total capacitance of one bus line in pF. tR and tF measured between +0.8V and +2.1V.
Note 8: ISINK P 6mA. Cb = total capacitance of one bus line in pF. tR and tF measured between +0.8V and +2.1V.
Note 9: Input filters on the SDA, SCL, and AD0 inputs suppress noise spikes less than 50ns.
4 _______________________________________________________________________________________
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
TA = -40NC
50
100
TA = -40°C
50
0
5
15
0
5
0
20
18.3
TA = -40NC, +85NC
18.2
18.1
18.0
TA = +25NC
TA = +85NC
17.9
17.8
TA = -40NC
17.7
17.6
15
20
3.2
25
2.0
2.4
3.2
2.8
SUPPLY VOLTAGE (V)
TA = +25NC
TA = +85NC
5
VCC = 3.0V
20
SINK CURRENT (mA)
TA = -40NC
0
2.0
OUTPUT VOLTAGE (V)
2.5
TA = +85NC
0.5
1.6
TA = +25NC
TA = +85NC
10
3.0
2.8
2.4
3.2
3.6
CONSTANT-CURRENT GPIO OUTPUT
SINK CURRENT vs. OUTPUT VOLTAGE
TA = -40NC
15
2.0
SUPPLY VOLTAGE (V)
25
VCC = 3.6V
20
TA = -40NC
15
TA = +25NC
TA = +85NC
10
5
0
1.5
TA = +25NC
1.0
3.6
5
1.0
1.5
CONSTANT-CURRENT GPIO OUTPUT
SINK CURRENT vs. OUTPUT VOLTAGE
MAX7360 toc07
20
2.0
0
CONSTANT-CURRENT GPIO OUTPUT
SINK CURRENT vs. OUTPUT VOLTAGE
VCC = 2.4V
TA = -40NC
TA = -40NC, +25NC
1.6
3.6
2.5
MAX7360 toc09
2.8
3.0
17.4
SUPPLY VOLTAGE (V)
0.5
10
MAX7360 toc06
VCOL0 = O
SINK CURRENT (mA)
2.4
2.0
MAX7360 toc05
18.4
17.5
0
5
0
SHUTDOWN SUPPLY CURRENT (A)
TA = -40NC
20
SINK CURRENT (mA)
15
SHUTDOWN SUPPLY CURRENT
vs. SUPPLY VOLTAGE
25
10
10
KEY-SWITCH SOURCE CURRENT
vs. SUPPLY VOLTAGE
TA = +25NC
15
TA = -40°C
SUPPLY CURRENT
vs. SUPPLY VOLTAGE
35
25
100
SINK CURRENT (mA)
TA = +85NC
1.6
TA = +25°C
SINK CURRENT (mA)
40
15
150
SINK CURRENT (mA)
AUTOSLEEP = OFF
30
TA = +85°C
50
0
20
KEY-SWITCH SOURCE CURRENT (A)
45
10
MAX7360 toc04
0
SUPPLY CURRENT (A)
TA = +25°C
VCC = 3.6V
200
OUTPUT VOLTAGE (mV)
100
TA = +85°C
150
250
MAX7360 toc08
OUTPUT VOLTAGE (mV)
TA = +25NC
150
VCC = 3.0V
200
OUTPUT VOLTAGE (mV)
TA = +85NC
GPO OUTPUT LOW VOLTAGE
vs. SINK CURRENT (COL2–COL7)
MAX7360 toc02
VCC = 2.4V
200
250
MAX7360 toc01
250
GPO OUTPUT LOW VOLTAGE
vs. SINK CURRENT (COL2–COL7)
MAX7360 toc03
GPO OUTPUT LOW VOLTAGE
vs. SINK CURRENT (COL2–COL7)
0
0
0.5
1.0
1.5
2.0
OUTPUT VOLTAGE (V)
2.5
3.0
0
0.5
1.0
1.5
2.0
2.5
3.0
OUTPUT VOLTAGE (V)
_______________________________________________________________________________________ 5
MAX7360
Typical Operating Characteristics
(VCC = +2.5V, TA = +25NC, unless otherwise noted.)
MAX7360
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
Pin Description
PIN
NAME
FUNCTION
TQFN
WLP
1
A6
ROW0
Row Input from Key Matrix. Leave ROW0 unconnected or connect to GND if unused.
2
B6
ROW1
Row Input from Key Matrix. Leave ROW1 unconnected or connect to GND if unused.
3
C4
ROW2
Row Input from Key Matrix. Leave ROW2 unconnected or connect to GND if unused.
Row Input from Key Matrix. Leave ROW3 unconnected or connect to GND if unused.
4
C6
ROW3
5, 15, 25,
35
B4, C5, D2,
E4
GND
6
D6
ROW4
Row Input from Key Matrix. Leave ROW4 unconnected or connect to GND if unused.
7
D5
ROW5
Row Input from Key Matrix. Leave ROW5 unconnected or connect to GND if unused.
8
E6
ROW6
Row Input from Key Matrix. Leave ROW6 unconnected or connect to GND if unused.
9
D4
ROW7
Row Input from Key Matrix. Leave ROW7 unconnected or connect to GND if unused.
10, 20, 27,
30, 40
C2
N.C.
11
F6
COL0
Column Output to Key Matrix. Leave COL0 unconnected if unused.
12
E5
COL1
Column Output to Key Matrix. Leave COL1 unconnected if unused.
13
F5
COL2
Column Output to Key Matrix. Leave COL2 unconnected if unused. COL2 can be
configured as a GPO (see Table 9 in the Register Tables section).
14
F4
COL3
Column Output to Key Matrix. Leave COL3 unconnected if unused. COL3 can be
configured as a GPO (see Table 9 in the Register Tables section).
16
F3
COL4
Column Output to Key Matrix. Leave COL4 unconnected if unused. COL4 can be
configured as a GPO (see Table 9 in the Register Tables section).
17
E3
COL5
Column Output to Key Matrix. Leave COL5 unconnected if unused. COL5 can be
configured as a GPO (see Table 9 in the Register Tables section).
18
F2
COL6
Column Output to Key Matrix. Leave COL6 unconnected if unused. COL6 can be
configured as a GPO (see Table 9 in the Register Tables section).
19
F1
COL7
Column Output to Key Matrix. Leave COL7 unconnected if unused. COL7 can be
configured as a GPO (see Table 9 in the Register Tables section).
21
E2
SDA
I2C-Compatible, Serial-Data I/O
22
E1
SCL
I2C-Compatible, Serial-Clock Input
23
D3
INTK
Active-Low Key-Switch Interrupt Output. INTK is open drain and requires a pullup
resistor.
Ground
No Connection. Not internally connected. Leave unconnected.
6 _______________________________________________________________________________________
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
PIN
NAME
FUNCTION
TQFN
WLP
24
D1
INTI
Active-Low GPI Interrupt Output. INTI is open drain and requires a pullup resistor.
26
C1
VCC
Positive Supply Voltage. Bypass VCC to GND with a 0.1FF or higher ceramic capacitor.
28
B1
AD0
Address Input. AD0 selects up to four device slave addresses (Table 3).
29
A1
I.C.
Internally Connected. Connect to GND for normal operation.
31
B2
PORT0
GPIO Port. Open-drain I/O rated at +14V. PORT0 can be configured as a constantcurrent output.
32
A2
PORT1
GPIO Port. Open-drain I/O rated at +14V. PORT1 can be configured as a constantcurrent output.
33
B3
PORT2
GPIO Port. Open-drain I/O rated at +14V. PORT2 can be configured as a constantcurrent output.
34
A3
PORT3
GPIO Port. Open-drain I/O rated at +14V. PORT3 can be configured as a constantcurrent output.
36
A4
PORT4
GPIO Port. Open-drain I/O rated at +14V. PORT4 can be configured as a constantcurrent output.
37
C3
PORT5
GPIO Port. Open-drain I/O rated at +14V. PORT5 can be configured as a constantcurrent output.
38
A5
PORT6
GPIO Port. Open-drain I/O rated at +14V. PORT6 Can be configured as a constantcurrent output, or a rotary switch input.
39
B5
PORT7
GPIO Port. Open-drain I/O rated at +14V. PORT7 can be configured as a constantcurrent output, or a rotary switch input.
—
—
EP
Exposed Pad (TQFN only). EP is internally connected to GND. Connect EP to a ground
plane to increase thermal performance.
_______________________________________________________________________________________ 7
MAX7360
Pin Description (continued)
MAX7360
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
Functional Block Diagram
LED ENABLE
PWM
GPIO
LOGIC
GPIO ENABLE
GPIO INPUT
PORT GPIO
AND
CONSTANTCURRENT
LED DRIVE
MAX7360
PORT0
PORT1
PORT2
PORT3
PORT4
PORT5
PORT6
PORT7
ROTARY
COLUMN ENABLE
128kHz
OSCILLATOR
GPO ENABLE
CURRENT DETECT
CURRENT
SOURCE
COLUMN
DRIVES
INTI
INTK
SDA
SCL
AD0
I2C
INTERFACE
CONTROL
REGISTERS
FIFO
KEY
SCAN
ROW ENABLE
BUS
TIMEOUT
POR
OPENDRAIN
ROW
DRIVES
COL0
COL1
COL2*
COL3*
COL4*
COL5*
COL6*
COL7*
ROW0
ROW1
ROW2
ROW3
ROW4
ROW5
ROW6
ROW7
*GPO
Detailed Description
The MAX7360 is a microprocessor peripheral low-noise
key-switch controller that monitors up to 64 key switches
with optional autorepeat, and key events that are
presented in a 16-byte FIFO. The MAX7360 also features
eight open-drain GPIOs configured for digital I/O or
constant-current output for LED applications up to +14V.
The MAX7360 features an automatic sleep mode and
automatic wakeup that further reduce supply current
consumption. The MAX7360 can be configured to enter
sleep mode after a programmable time following a key
event. The FIFO content is maintained and can be read
in sleep mode. The MAX7360 does not enter autosleep
when a key is held down. The autowake feature takes
the MAX7360 out of sleep mode following a keypress
event. Enable/disable autosleep and autowake through
the configuration register (Table 8).
To prevent overloading the microprocessor with too
many interrupts, interrupt requests are issued on a
programmable number of FIFO entries, and/or after a
set period of time (Table 10). The key-switch status is
checked by reading the key-switch FIFO. A 1-byte read
access returns both the next key event in the FIFO (if
there is one) and the FIFO status. INTK functions as an
open-drain general-purpose output (GPO) capable of
driving an LED if key-switch interrupts are not required.
Up to six of the key-switch outputs function as opendrain GPOs capable of driving additional LEDs when
the application requires fewer keys to be scanned. For
each key-switch output used as a GPO, the number of
monitored key switches reduces by eight.
Initial Power-Up
On power-up, all control registers are set to power-up
values and the MAX7360 is in sleep mode (Table 1).
8 _______________________________________________________________________________________
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
ADDRESS
CODE
(hex)
READ/
WRITE
POWER-UP
VALUE (hex)
REGISTER
FUNCTION
0x00
Read only
0x3F
Keys FIFO
0x01
R/W
0x0A
Configuration
0x02
R/W
0xFF
Debounce
0x03
R/W
0x00
Interrupt
0x04
R/W
0xFE
GPO
0x05
R/W
0x00
Key repeat
0x06
R/W
0x07
Sleep
DESCRIPTION
Read FIFO key-scan data out
Power-down, key-release enable, autowakeup, and I2C timeout enable
Key debounce time settling and GPO enable
Key-switch interrupt INTK frequency setting
COL2–COL7 and INTK GPO control
Delay and frequency for key repeat
Idle time to autosleep
0x40
R/W
0x00
GPIO global configuration
0x41
R/W
0x00
GPIO control
0x42
R/W
0x00
GPIO debounce
PORT0–PORT7 debounce time setting
PORT0–PORT7 constant-current output setting
0x43
R/W
0xC0
GPIO constantcurrent setting
0x44
Rotary switch, GPIO standby, GPIO reset, fade
PORT0–PORT7 input/output control
R/W
0x00
GPIO output mode
0x45
R/W
0x00
Common PWM
0x46
R/W
0x00
Rotary switch configuration
0x48
Read only
0x00
I2C timeout flag
0x49
Read only
0xFF
GPIO input register
PORT0–PORT7 input values
0x4A
Read only
0x00
Rotary switch count
Switch cycles since last read
0x50
R/W
0x00
PORT0 PWM
PORT0 individual duty-cycle setting
0x51
R/W
0x00
PORT1 PWM
PORT1 individual duty-cycle setting
0x52
R/W
0x00
PORT2 PWM
PORT2 individual duty-cycle setting
0x53
R/W
0x00
PORT3 PWM
PORT3 individual duty-cycle setting
0x54
R/W
0x00
PORT4 PWM
PORT4 individual duty-cycle setting
0x55
R/W
0x00
PORT5 PWM
PORT5 individual duty-cycle setting
0x56
R/W
0x00
PORT6 PWM
PORT6 individual duty-cycle setting
0x57
R/W
0x00
PORT7 PWM
PORT7 individual duty-cycle setting
0x58
R/W
0x00
PORT0 configuration
PORT0 interrupt, PWM mode control and blink period setting
0x59
R/W
0x00
PORT1 configuration
PORT1 interrupt, PWM mode control and blink period setting
PORT2 configuration
PORT2 interrupt, PWM mode control and blink period setting
0x5A
PORT0–PORT7 output mode control
Common PWM duty-cycle setting
Rotary switch interrupt frequency and debounce time setting
I2C timeout since last POR
R/W
0x00
0x5B
R/W
0x00
PORT3 configuration
PORT3 interrupt, PWM mode control and blink period setting
0x5C
R/W
0x00
PORT4 configuration
PORT4 interrupt, PWM mode control and blink period setting
0x5D
R/W
0x00
PORT5 configuration
PORT5 interrupt, PWM mode control and blink period setting
0x5E
R/W
0x00
PORT6 configuration
PORT6 interrupt, PWM mode control and blink period setting
R/W
0x00
PORT7 configuration
PORT7 interrupt, PWM mode control and blink period setting
0x5F
_______________________________________________________________________________________ 9
MAX7360
Table 1. Register Address Map and Power-Up Condition
MAX7360
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
Table 2. Key-Switch Mapping
PIN
ROW0
COL0
KEY 0
COL1
KEY 8
COL2*
KEY 16
COL3*
KEY 24
COL4*
KEY 32
COL5*
KEY 40
COL6*
KEY 48
COL7*
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
*These columns can be configured as GPOs.
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-scan controller debounces and maintains a FIFO
of keypress and release events (including autorepeated
keypresses, if autorepeat is enabled). Table 2 shows the
key-switch order. The user-programmable key-switch
debounce time, and autosleep timer, is derived from the
64kHz clock, which in turn is derived from the 128kHz
oscillator. Time delay for autorepeat and key-switch
interrupt is based on the key-switch debounce time.
Keys FIFO Register (0x00)
The keys FIFO register contains the information pertaining
to the status of the keys FIFO, as well as the key events
that have been debounced (see Table 7 in the Register
Tables section). Bits D0–D5 denote which of the 64 keys
have been debounced and the keys are numbered as in
Table 1.
and determines how INTK is deasserted. Write to bit D7
to put the MAX7360 into sleep mode or operating mode.
Autosleep and autowake, when enabled, also change the
status of D7 (see Table 8 in the Register Tables section).
Debounce Register (0x02)
The debounce register sets the time for each debounce
cycle, as well as setting whether the GPO ports are
enabled or disabled. Bits D0–D4 set the debounce time
in increments of 1ms starting at 9ms and ending at 40ms
(see Table 9 in the Register Tables section). Bits D5, D6,
and D7 set which of the GPO ports is enabled. Note the
GPO ports are enabled only in the combinations shown
in Table 9, from all disabled to all enabled.
Reading the key-scan FIFO clears the interrupt INTK
depending on the setting of bit D5 in the configuration
register (0x01).
Key-Switch Interrupt Register (0x03)
The interrupt register contains information related to the
settings of the interrupt request function, as well as the
status of the INTK output, which can also be configured
as a GPO. If bits D0–D7 are set to 0x00, the INTK output
is configured as a GPO that is controlled by bit D1 in the
port register. There are two types of interrupts, the FIFObased interrupt and time-based interrupt. Set bits D0–D4
to assert interrupts at the end of the selected number of
debounce cycles following a key event (see Table 10 in
the Register Tables section). This number ranges from
1–31 debounce cycles. Setting bits D7, D6, and D5 set
the FIFO-based interrupt when there are 4–16 key events
stored in the FIFO. Both interrupts can be configured
simultaneously and INTK asserts depending on which
condition is met first. INTK deasserts depending on the
status of bit D5 in the configuration register.
Configuration Register (0x01)
The configuration register controls the I2C bus timeout
feature, enables key-release detection, enables autowake,
Ports Register (0x04)
The ports register sets the values of PORT2–PORT7
and the INTK port, when configured, as open-drain
D7 indicates if there is more data in the FIFO, except
when D5:D0 indicate key 63 or key 62. When D5:D0
indicate key 63 or key 62, the host should read one more
time to determine whether there is more data in the FIFO.
Use key 62 and key 63 for rarely used keys. D6 indicates
if it is a keypress or release event, except when D5:D0
indicate key 63 or key 62.
10 �������������������������������������������������������������������������������������
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
Autorepeat Register (0x05)
The MAX7360 autorepeat feature notifies the host that at
least one key has been pressed for a continuous period.
The autorepeat register enables or disables this feature,
sets the time delay after the last key event before the key
repeat code (0x7E) is entered into the FIFO, and sets
the frequency at which the key-repeat code is entered
into the FIFO thereafter. Bit D7 specifies whether the
autorepeat function is enabled with 0 denoting autorepeat
disabled, and 1 denoting autorepeat enabled. Bits D0–
D3 specify the autorepeat delay in terms of debounce
cycles ranging from 8–128 debounce cycles (see Table
12 in the Register Tables section). Bits D4, D5, and D6
specify the autorepeat rate or frequency ranging from
4–32 debounce cycles.
When autorepeat is enabled, holding the key pressed
results in a key-repeat event that is denoted by 0x7E. The
key being pressed does not show up again in the FIFO.
Only one autorepeat code is entered into the FIFO,
regardless of the number of keys pressed. The
autorepeat code continues to be entered in the FIFO at
the frequency set by bits D4–D1 until another key event
is recorded. Following the key-release event, if any keys
are still pressed, the MAX7360 restarts the autorepeat
sequence.
Autosleep Register (0x06)
Autosleep puts the MAX7360 in sleep mode to draw
minimal current. When enabled, the MAX7360 enters
sleep mode if no keys are pressed for the autosleep time
(see Table 13 in the Register Tables section).
Key-Switch Sleep Mode
In sleep mode, the MAX7360 draws minimal current.
Switch-matrix current sources are turned off and pulled
up to VCC. When autosleep is enabled, key-switch
inactivity for a period longer than the autosleep time
puts the part into sleep mode (FIFO data is maintained).
Writing a 1 to D7, or a keypress, can take the MAX7360
out of sleep mode. Bit D7 in the configuration register
gives the sleep-mode status and can be read any time.
The FIFO data is maintained while in sleep mode.
Autowake
Keypresses initiate autowake and the MAX7360 goes into
operating mode. Keypresses that autowake the MAX7360
are not lost. When a key is pressed while the MAX7360
is in sleep mode, all analog circuitry, including switchmatrix current sources, turn on in 2ms. The initial key
needs to be pressed for 2ms plus the debounce time to
be stored in the FIFO. Write a 0 to D1 in the configuration
register (0x01) to disable autowakeup.
GPIOs
The MAX7360 has eight GPIO ports with LED control
functions. The ports can be used as logic inputs, logic
outputs, or constant-current PWM LED drivers. In
addition, PORT7 and PORT8 can function as a rotary
switch input pair. When in PWM mode, the ports are set
up to start their PWM cycle in 45N phase increments. This
prevents large current spikes on the LED supply voltage
when driving multiple LEDs.
GPIO Global Configuration Register (0x40)
The GPIO global configuration register controls the main
settings for the eight GPIOs (see Table 14 in the Register
Tables section).
Bit D7 enables PORT[7:6] as inputs for a rotary switch.
Bit D5 enables interrupt generation for I2C timeouts.
D4 is the main enable/shutdown bit for the GPIOs. D3
functions as a software reset for the GPIO registers (0x40
to 0x5F). Bits D[2:0] set the fade in/out time for the GPIOs
configured as constant-current sinks.
GPIO Control Register (0x41)
The GPIO control register configures each port as either
an input or an output (see Table 15 in the Register Tables
section). All GPIOs allow individual configurations,
and power up as inputs. Enabling rotary switch mode
automatically sets D7 and D6 as inputs. The ports
consume additional current if their inputs are left undriven.
GPIO Debounce Configuration Register (0x42)
The GPIO debounce configuration register sets the
amount of time a GPIO must be held for the MAX7360
to register a logic transition (see Table 16 in the
Register Tables section). The GPIO debounce setting
is independent of the key-switch debounce setting. Five
bits (D[4:0]) set 32 possible debounce times from 9ms
up to 40ms.
______________________________________________________________________________________ 11
MAX7360
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 (see Table 11 in
the Register Tables section).
MAX7360
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
GPIO Constant-Current Setting Register (0x43)
The GPIO constant-current setting register sets the global
constant-current amount (see Table 17 in the Register
Tables section). Bits D1 and D0 set the global current
values from 5mA up to 20mA.
GPIO Output Mode Register (0x44)
The GPIO output mode register sets an output as either
a constant-current or non-constant-current output for
PORT[7:0] (see Table 18 in the Register Tables section).
Outputs are configured as constant-current outputs by
default to prevent accidental loading of an LED across
an unregulated output. The constant-current circuits
automatically turn off when not in use to reduce current
consumption.
Common PWM Register (0x45)
The common PWM register stores the common constantcurrent output PWM duty cycle (see Table 19 in the
Register Tables section). The values stored in this register
translate over to a PWM duty cycle in the same manner
as the individual PWM registers (0x50 to 0x57). Ports can
use their own individual PWM value, or the common PWM
value. Write to this register to change the duty cycle of
several ports at once.
Rotary Switch Configuration Register (0x46)
The rotary switch configuration register stores rotary
switch settings for PORT7 and PORT6 (see Table 20 in
the Register Tables section). D7 determines whether
switch counts or a time delay will trigger an interrupt
if enabled. D[6:4] set the count or time amount to wait
before sending an interrupt. Bits D[3:0] set the debounce
cycle time for the rotary switch inputs. Debounce time
ranges from 0 to 15ms.
I2C Timeout Flag Register (0x48) (Read Only)
The I2C timeout flag register contains a single bit (D0),
which indicates if an I2C timeout has occurred (see Table
21 in the Register Tables section). Read this register to
clear an I2C timeout initiated interrupt.
GPIO Input Register (0x49) (Read Only)
The GPIO input register contains the input data for all of
the GPIOs (see Table 22 in the Register Tables section).
Ports configured as outputs are read as high. There is
one debounce period delay prior to detecting a transition
on the input port. This prevents a false interrupt from
occurring when changing a port from an output to an
input. The GPIO input register reports the state of all
input ports regardless of any interrupt mask settings.
Ports configured as an input have a 2FA internal pullup
to VCC for PORT[5:0] and a 10FA internal pullup to VCC
for PORT[7:6].
Rotary Switch Count Register (0x4A) (Read Only)
The MAX7360 keeps a count of the rotary switch rotations
in two’s compliment format (see Table 23 in the Register
Tables section). The register values wrap around as the
count value switches from a positive to a negative value
and back again. The count resets to zero after an I2C
read to this register.
PORT0–PORT7 Individual PWM Ratio Registers
(0x50 to 0x57)
Each port has an individual PWM ratio register (0x50 to
0x57, see Table 24 in the Register Tables section). Use
values 0x00 to 0xFE in these registers to configure the
number of cycles out of 256 the output sinks current
(LED is on), from 0 cycles to 254 cycles. Use 0xFF to
have an output continuously sink current (always on).
For applications requiring multiple ports to have the
same intensity, program a particular port’s configuration
register (0x58 to 0x5F) to use the common PWM register
(0x45). New PWM settings take place at the beginning of
a PWM cycle, to allow changes from common intensity to
individual intensity with no interruption in the PWM cycle
PORT0–PORT7 Configuration Registers
(0x58 to 0x5F)
Registers 0x58 to 0x5F set individual configurations for
each port (see Table 25 in the Register Tables section).
Bits D7 and D6 determine the interrupt settings for the
inputs. Interrupts can assert upon detection of a logic
transition, a rising edge, or not at all. D5 sets the port’s
PWM setting to either the common or individual PWM
setting. Bits D[4:2] enable and set the ports’ individual
blink period from 0 to 4096ms. Bits D1 and D0 set a port’s
blink duty cycle.
Fading
Set the fade cycle time in the GPIO global configuration
register (0x40) to a non-zero value to enable fade in/out (see
Table 14 in the Register Tables section). Fade in increases
an LED’s PWM intensity in 16 even steps from zero to its
stored value. Fade out decreases an LED’s PWM intensity in
16 even steps from its current value to zero. Fading occurs
automatically in any of the following scenarios:
1) Change the common PWM register value from any
value to zero to cause all ports using the common
PWM register settings to fade out. No ports using
individual PWM settings are affected.
2) Change the common PWM register value to any value
from zero to cause all ports using the common PWM
register settings to fade in. No ports using individual
PWM settings are affected.
3) Put the part out of shutdown to cause all ports to
fade in. Changing an individual PWM intensity during
12 �������������������������������������������������������������������������������������
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
Set registers 0x58 to 0x5F for individual GPI-based
interrupts. If multiple sources generate the interrupt, all
the related status registers must be read to clear INTI.
4) Put the part into shutdown to cause all ports to fade
out. Changing an individual PWM intensity during
fade out automatically cancels that port’s fade and
immediately turns off.
Rotary Switch
The MAX7360 can accept a 2-bit rotary switch inputs on
PORT6 and PORT7. Rotation of the switch in a clockwise
direction increments the count. Enable rotary switch
mode from the GPIO global configuration register (0x40).
Several settings for PORT6 and PORT7 occur during
rotary switch mode:
Blink
Each port has its own blink control settings through
registers 0x58 to 0x5F (see Table 25 in the Register Tables
section). The blink period ranges from 0 (blink disabled)
to 4.096s. Settable blink duty cycles range from 6.25%
to 50%. All blink periods start at the same PWM cycle for
synchronized blinking between multiple ports.
1) Each port has a 10FA pullup to VCC.
2) Register 0x46 sets the debounce time.
3) A debounced rising edge on PORT6 while PORT7 is
high decreases the count.
GPIO Port Interrupts (INTI)
Three possible sources generate INTI: I2C timeout,
GPIOs configured as inputs, and the rotary switch
(registers 0x48, 0x49, and 0x4A). Read the respective
data/status registers for each type of interrupt to clear
INTI. Set register 0x46 for rotary switch-based interrupts.
4) A debounced rising edge on PORT6 while PORT7 is
low increases the count.
For more details, see Figure 1.
Serial Interface
Figure 2 shows the 2-wire serial interface timing details.
PORT7
Serial Addressing
INCREMENT
The MAX7360 operates as a slave that sends and
receives data through an I2C-compatible 2-wire interface.
The interface uses a serial-data line (SDA) and a serialclock line (SCL) to achieve bidirectional communication
between master(s) and slave(s). A master (typically a
microcontroller) initiates all data transfers to and from the
MAX7360 and generates the SCL clock that synchronizes
the data transfer.
PORT6
PORT7
DECREMENT
PORT6
ROTARY SWITCH
DEBOUNCE
The MAX7360’s SDA line operates as both an input and
an open-drain output. A pullup resistor, typically 4.7kI,
Figure 1. Rotary Switch Input Signal Timing
tR
SDA
tSU, DAT
tLOW
tSU, STA
tF
tF,TX
tBUF
tHD, STA
tHD, DAT
tSU, STO
tHIGH
SCL
tHD, STA
tR
tF
START
CONDITION
REPEATED
START CONDITION
STOP
CONDITION
START
CONDITION
Figure 2. 2-Wire Serial Interface Timing Details
______________________________________________________________________________________ 13
MAX7360
fade in automatically cancels that port’s fade and
immediately output at its newly programmed intensity.
MAX7360
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
is required on SDA. The MAX7360’s SCL line operates
only as an input. A pullup resistor is required on SCL 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
3) sent by a master, followed by the MAX7360 7-bit slave
address plus R/W bit, a register address byte, one or
more data bytes, and finally, 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 transmission
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 SDA from low to high while
SCL is high. The bus is then free for another transmission.
Acknowledge
The acknowledge bit is a clocked 9th bit (Figure 4), 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; therefore, the SDA line is stable low during
the high period of the clock pulse. When the master is
transmitting to the MAX7360, the MAX7360 generates the
acknowledge bit because the MAX7360 is the recipient.
When the MAX7360 is transmitting to the master, the
master generates the acknowledge bit because the
master is the recipient.
Table 3. 2-Wire Interface Address Map
Bit Transfer
One data bit is transferred during each clock pulse
(Figure 4). The data on SDA must remain stable while
SCL is high.
PIN AD0
DEVICE ADDRESS
A7
A6
A5
A4
A3
A2
A1
A0
GND
0
1
1
1
0
0
0
R/W
VCC
0
1
1
1
0
1
0
R/W
SDA
0
1
1
1
1
0
0
R/W
SCL
0
1
1
1
1
1
0
R/W
SDA
SCL
S
P
START
CONDITION
STOP
CONDITION
Figure 3. START and STOP Conditions
SDA
SCL
DATA LINE STABLE;
DATA VALID
CHANGE OF DATA
ALLOWED
Figure 4. Bit Transfer
14 �������������������������������������������������������������������������������������
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
CLOCK PULSE FOR
ACKNOWLEDGE
1
SCL
SDA
BY
TRANSMITTER
SDA
BY
RECEIVER
MAX7360
START
CONDITION
2
8
9
S
Figure 5. Acknowledge
SDA
0
1
1
1
A3
A2
A1
MSB
R/W
ACK
LSB
SCL
Figure 6. Slave Address
COMMAND BYTE IS STORED ON RECEIPT OF
ACKNOWLEDGE CONDITION
ACKNOWLEDGE FROM MAX7360
S
SLAVE ADDRESS
0
D7
D6
A
D5
D4
D3
D2
D1
D0
COMMAND BYTE
R/W
A
P
ACKNOWLEDGE FROM MAX7360
Figure 7. Command Byte Received
ACKNOWLEDGE FROM MAX7360
ACKNOWLEDGE FROM MAX7360
D7
D6
D5
D4
D3
D2
D1
D0
D7
D6
D5
D4
D3
D2
D1
D0
ACKNOWLEDGE FROM MAX7360
S
SLAVE ADDRESS
0
A
COMMAND BYTE
A
DATA BYTE
A
P
1 BYTE
R/W
AUTOINCREMENT
COMMAND BYTE ADDRESS
Figure 8. Command and Single Data Byte Received
Slave Addresses
The MAX7360 has a 7-bit long slave address (Figure
6). The bit following a 7-bit slave address is the R/W bit,
which is low for a write command and high for a read
command.
The first 4 bits (MSBs) of the MAX7360 slave address
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/W bit. The AD0 input can be connected to any of four
signals (GND, VCC, SDA, or SCL), giving four possible
slave address pairs and allowing up to four MAX7360
devices to share the bus. Because SDA and SCL are
dynamic signals, care must be taken to ensure that AD0
transitions no sooner than the signals on SDA and SCL.
The MAX7360 monitors the bus continuously, waiting for a
START condition, followed by its slave address. When the
MAX7360 recognizes its slave address, it acknowledges
and is then ready for continued communication.
Bus Timeout
The MAX7360 features a 20ms minimum bus timeout
on the 2-wire serial interface, largely to prevent the
MAX7360 from holding the SDA I/O low during a read
transaction should the SCL lock up for any reason before
a serial transaction is completed. Bus timeout operates
by causing the MAX7360 to internally terminate a serial
______________________________________________________________________________________ 15
MAX7360
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
ACKNOWLEDGE FROM MAX7360
ACKNOWLEDGE FROM MAX7360
D7
D6
D5
D4
D3
D2
D1
D0
D7
D6
D5
D4
D3
D2
D1
D0
ACKNOWLEDGE FROM MAX7360
S
SLAVE ADDRESS
0
A
COMMAND BYTE
A
DATA BYTE
A
P
N BYTES
R/W
AUTOINCREMENT
COMMAND BYTE ADDRESS
Figure 9. N Data Bytes Received
Table 4. Autoincrement Rules
REGISTER
FUNCTION
ADDRESS
CODE (hex)
AUTOINCREMENT
ADDRESS (hex)
Keys FIFO
0x00
0x00
Autoshutdown
0x06
0x00
All other key switch
0x01 to 0x05
Addr + 0x01
All other GPIO
0x40 to 0x5F
Addr + 0x01
transaction, either read or write, if SCL low exceeds
20ms. After a bus timeout, the MAX7360 waits for a valid
START condition before responding to a consecutive
transmission. This feature can be enabled or disabled
under user control by writing to the configuration register
(Table 8 in the Register Tables section).
Message Format for Writing
the Key-Scan Controller
A write to the MAX7360 comprises the transmission of the
slave address with the R/W bit 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 MAX7360 is to be written by the next
byte, if received. If a STOP condition is detected after the
command byte is received, the MAX7360 takes no further
action (Figure 7) beyond storing the command byte.
Any bytes received after the command byte are data bytes.
The first data byte goes into the internal register of the
MAX7360 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
MAX7360 internal registers, because the command byte
address generally autoincrements (Table 4).
Message Format for Reading
the Key-Scan Controller
The MAX7360 is 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 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
MAX7360’s command byte by performing a write (Figure
6). The master can now read n consecutive bytes from
the MAX7360, with the first data byte being read from
the register addressed by the initialized command byte.
When performing read-after-write verification, remember
to reset the command byte’s address, because the stored
command byte address is generally autoincremented
after the write (Figure 9, Table 4).
Operation with Multiple Masters
When the MAX7360 is operated on a 2-wire interface with
multiple masters, a master reading the MAX7360 uses a
repeated start between the write that sets the MAX7360’s
address pointer, and the read(s) that takes the data
from the location(s). This is because it is possible for
master 2 to take over the bus after master 1 has set up
the MAX7360’s address pointer, but before master 1
has read the data. If master 2 subsequently resets the
MAX7360’s address pointer, master 1’s read can be from
an unexpected location.
Command Address Autoincrementing
Address autoincrementing allows the MAX7360 to be
configured with fewer transmissions by minimizing the
number of times the command address needs to be sent.
The command address stored in the MAX7360 generally
increments after each data byte is written or read (Table
4). Autoincrement only works when doing a multiburst
read or write.
Applications Information
Reset from I2C
After a catastrophic event such as ESD discharge or
microcontroller reset, use bit D7 of the configuration
register (0x01) as a software reset for the key-switch
state (the key-switch register values and FIFO remain
unaffected). Use bit D4 of the GPIO global configuration
register (0x40) as a software reset for the GPIOs.
16 �������������������������������������������������������������������������������������
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
MAX7360
REGULAR KEYPRESS
EVENT
EXAMPLES OF VALID THREE-KEY COMBINATIONS
GHOST-KEY
EVENT
KEY-SWITCH MATRIX
KEY-SWITCH MATRIX
KEY-SWITCH MATRIX
Figure 11. Valid Three-Key Combinations
Figure 10. Ghost-Key Phenomenon
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 to
detect which of the four keys is the ghost key.
The MAX7360 employs a proprietary scheme that detects
any three-key combination that generates a fourth ghost
key, and does not report the third key that causes a
ghost-key event. This means that although ghost keys
are never reported, many combinations of three keys
are effectively ignored when pressed at the same time.
Applications requiring three-key combinations (such
as <Ctrl><Alt><Del>) must ensure that the three keys
are not wired in positions that define the vertices of a
rectangle (Figure 11). There is no limit on the number of
keys that can be pressed simultaneously as long as the
keys do not generate ghost-key events and FIFO is not full.
Low-EMI Operation
The MAX7360 uses two techniques to minimize EMI
radiating from the key-switch wiring. First, the voltage
across the switch matrix never exceeds +0.55V if not in
sleep mode, independent of supply voltage VCC. This
reduces the voltage swing at any node when a switch
is pressed to +0.55V maximum. Second, the keys are
not dynamically scanned, which would cause the keyswitch 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.
Switch On-Resistance
The MAX7360 is designed to be insensitive to resistance,
either in the key switches, or the switch routing to and
from the appropriate COL_ and ROW_ up to 4kI (max).
These controllers are therefore compatible with low-cost
membrane and conductive carbon switches.
Hot Insertion
The INTI, INTK, SCL, and AD0 inputs and SDA remain
high impedance with up to +3.6V asserted on them when
the MAX7360 powers down (VCC = 0). I/O ports (PORT0–
PORT7) remain high impedance with up to +14V asserted
on them when not powered. Use the MAX7360 in hotswap applications.
Staggered PWM
The LED’s on-time in each PWM cycle are phase
delayed 45N into eight evenly spaced start positions.
Optimize phasing when using fewer than eight ports as
constant-current outputs by allocating the ports with the
most appropriate start positions. For example, if using
four constant-current outputs, choose PORT0, PORT2,
PORT4, and PORT6 because their PWM start positions
are evenly spaced. In general, choose the ports that
spread the PWM start positions as evenly as possible.
This optimally spreads out the current demand from the
ports’ load supply.
INTK/INTI
There are two interrupt outputs, INTK and INTI. Each
interrupt operates independently from the other. See
the Key-Switch Interrupt Register (0x03) and the GPIO
Port Interrupts (INTI) sections for additional information
regarding these two interrupts.
Power-Supply Considerations
The MAX7360 operates with a +1.62V to +3.6V powersupply voltage. Bypass the power supply to GND with a
0.1FF or higher ceramic capacitor as close as possible
to the device.
______________________________________________________________________________________ 17
MAX7360
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
ESD Protection
All of the MAX7360 pins meet the 2kV Human Body Model
ESD tolerances. Key-switch inputs and GPIOs meet IEC
61000-4-2 ESD protection. The IEC test stresses consist
of 10 consecutive ESD discharges per polarity, at the
maximum specified level and below (per IEC 61000-4-2).
Test criteria include:
1) The powered device does not latch up during the
ESD discharge event.
2) The device subsequently passes the final test used
for prescreening.
Tables 5 and 6 are from the IEC 61000-4-2: Edition 1.1
1999-05: Electromagnetic compatibility (EMC) Testing
and measurement techniques—Electrostatic discharge
immunity test
Table 5. ESD Test Levels
1A—CONTACT
DISCHARGE
1B—AIR-GAP DISCHARGE
LEVEL
TEST
VOLTAGE (kV)
LEVEL
TEST
VOLTAGE (kV)
1
2
1
2
2
4
2
4
3
6
3
8
4
8
4
10
X
Special
X
Special
X = Open level. The level has to be specified in the
dedicated equipment specification. If higher voltages
than those shown are specified, special test equipment
could be needed.
Table 6. ESD Waveform Parameters
LEVEL
INDICATED
VOLTGE
(kV)
FIRST PEAK OF
CURRENT
DISCHARGE ±10%
(A)
RISE TIME (tr) WITH
DISCHARGE SWITCH
(ns)
CURRENT (±30%)
AT 30ns
(A)
CURRENT
(±30%) AT 60ns
(A)
1
2
7.5
0.7 to 1
4
2
2
4
15
0.7 to 1
8
4
3
6
22.5
0.7 to 1
12
6
4
8
30
0.7 to 1
16
8
18 �������������������������������������������������������������������������������������
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
Table 7. Keys FIFO Register Format (0x00)
SPECIAL FUNCTION
KEYS FIFO REGISTER DATA
D7
D6
D5
D4
D3
D2
D1
D0
FIFO
empty
flag
Key
release
flag
X
X
X
X
X
X
FIFO is empty.
0
0
1
1
1
1
1
1
FIFO is overflow. Continue to read data in FIFO.
0
1
1
1
1
1
1
1
Key 63 is pressed. Read one more time to
determine whether there is more data in FIFO.
1
0
1
1
1
1
1
1
Key 63 is released. Read one more time to
determine whether there is more data in FIFO.
1
1
1
1
1
1
1
1
Key repeat. Indicates the last data in FIFO.
0
0
1
1
1
1
1
0
Key repeat. Indicates more data in FIFO.
0
1
1
1
1
1
1
0
Key 62 is pressed. Read one more time to
determine whether there is more data in FIFO.
1
0
1
1
1
1
1
0
Key 62 is released. Read one more time to
determine whether there is more data in FIFO.
1
1
1
1
1
1
1
0
The key number indicated by D5:D0 is a key
event. D7 is always for a key press of key 62
and key 63. When D7 is 0, the key read is the
last data in the FIFO. When D7 is 1, there is
more data in the FIFO. When D6 is 1, key data
read from FIFO is a key release. When D6 is 0,
key data read from FIFO is a key press.
______________________________________________________________________________________ 19
MAX7360
Register Tables
MAX7360
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
Table 8. Configuration Register Format (0x01)
REGISTER
BIT
D7
D6
DESCRIPTION
Sleep
FUNCTION
X
(when 0x40
D4 = 1)
Key-switch operating mode. Key switches always remain active
when constant-current PWM is enabled (bit 4 of register 0x40 is
high) regardless of autosleep, autowakeup, or an I2C write to this bit.
0
(when 0x40
D4 = 0)
Key-switch sleep
mode. The entire
chip is shut down.
1
(when 0x40
D4 = 0)
Key-switch operating
mode
Reserved
When constant-current PWM is disabled
(bit 4 of register 0x40 is low), I2C write,
autosleep, and autowakeup all can change
this bit. This bit can be read back by I2C
any time for current status.
0
0
—
0
0
INTK cleared when FIFO is empty
1
INTK cleared after host read. In this mode, I2C should read the
FIFO until interrupt condition is removed or further INT may be lost.
0
0
D5
Interrupt
D4
Reserved
0
—
Key-release
enable
0
Disable key releases
1
Enable key releases
D2
Reserved
0
—
D1
Autowakeup
enable
0
Disable keypress wakeup
1
Enable keypress wakeup
D0
Timeout
disable
0
I2C timeout enabled
1
I2C timeout disabled
D3
DEFAULT
VALUE
VALUE
1
0
1
0
Table 9. Debounce Register Format (0x02)
REGISTER DATA
REGISTER DESCRIPTION
D7
D6
D5
Debounce time is 9ms
PORTS ENABLE
X
X
X
Debounce time is 10ms
X
X
X
Debounce time is 11ms
X
X
Debounce time is 12ms
X
X
D4
D3
D2
D1
D0
0
DEBOUNCE TIME
0
0
0
0
0
0
0
0
1
X
0
0
0
1
0
X
0
0
0
1
1
.
.
.
Debounce time is 37ms
X
X
X
1
1
1
0
0
Debounce time is 38ms
X
X
X
1
1
1
0
1
Debounce time is 39ms
X
X
X
1
1
1
1
0
Debounce time is 40ms
X
X
X
1
1
1
1
1
GPO ports disabled (full key-scan functionality)
0
0
0
X
X
X
X
X
GPO port 7 enabled
0
0
1
X
X
X
X
X
GPO ports 7 and 6 enabled
0
1
0
X
X
X
X
X
20 �������������������������������������������������������������������������������������
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
REGISTER DATA
REGISTER DESCRIPTION
D7
D6
D5
GPO ports 7, 6, and 5 enabled
PORTS ENABLE
0
1
1
GPO ports 7, 6, 5, and 4 enabled
1
0
0
GPO ports 7, 6, 5, 4, and 3 enabled
1
0
GPO ports 7, 6, 5, 4, 3, and 2 enabled
1
1
Power-up default setting
1
1
1
D4
D3
D2
D1
D0
X
DEBOUNCE TIME
X
X
X
X
X
X
X
X
X
1
X
X
X
X
X
X
X
X
X
X
X
1
1
1
1
1
D2
D1
D0
Table 10. Key-Switch Interrupt Register Format (0x03)
REGISTER DATA
REGISTER DESCRIPTION
D7
D6
D5
INTK used as GPO
FIFO-BASED INTK
0
0
0
FIFO-based INTK disabled
0
0
0
INTK asserts every debounce cycle
0
0
INTK asserts every 2 debounce cycles
0
0
D4
D3
0
TIME-BASED INTK
0
0
0
0
0
0
0
0
1
0
0
0
0
1
0
0
Not all zero
.
.
.
INTK asserts every 29 debounce cycles
0
0
0
1
1
1
0
1
INTK asserts every 30 debounce cycles
0
0
0
1
1
1
1
0
INTK asserts every 31 debounce cycles
0
0
0
1
1
1
1
1
0
0
0
0
0
Not all zero
Time-based INTK disabled
INTK asserts when FIFO has 2 key events
0
0
1
0
0
0
0
0
INTK asserts when FIFO has 4 key events
0
1
0
0
0
0
0
0
INTK asserts when FIFO has 6 key events
0
1
1
0
0
0
0
0
1
0
0
0
0
0
0
0
.
.
.
INTK asserts when FIFO has 16 key events
1
Both time-based and FIFO-based interrupts
active
Power-up default setting
1
Not all zero
0
0
Not all zero
0
0
0
0
______________________________________________________________________________________ 21
MAX7360
Table 9. Debounce Register Format (0x02) (continued)
MAX7360
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
Table 11. Ports Register Format (0x04)
REGISTER
DESCRIPTION
BIT
VALUE
FUNCTION
0
Clear port 7 low
1
Set port 7 high (high impedance)
0
Clear port 6 low
1
Set port 6 high (high impedance)
0
Clear port 5 low
1
Set port 5 high (high impedance)
0
Clear port 4 low
1
Set port 4 high (high impedance)
0
Clear port 3 low
1
Set port 3 high (high impedance)
0
Clear port 2 low
1
Set port 2 high (high impedance)
INTK Port
Control
0
Clear port INTK low
1
Reserved
0
Set port INTK high (high impedance)
—
D7
PORT 7 Control
D6
PORT 6 Control
D5
PORT 5 Control
D4
PORT 4 Control
D3
PORT 3 Control
D2
PORT 2 Control
D1
D0
22 �������������������������������������������������������������������������������������
DEFAULT
VALUE
1
1
1
1
1
1
1
0
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
REGISTER DATA
REGISTER DESCRIPTION
D7
ENABLE
D6
D5
D4
D3
AUTOREPEAT RATE
X
X
D2
D1
D0
AUTOREPEAT DELAY
Autorepeat is disabled
0
X
Autorepeat is enabled
1
X
X
X
X
AUTOREPEAT RATE
Key-switch autorepeat delay is 8 debounce
cycles
1
X
X
X
0
0
0
0
Key-switch autorepeat delay is 16 debounce
cycles
1
X
X
X
0
0
0
1
Key-switch autorepeat delay is 24 debounce
cycles
1
X
X
X
0
0
1
0
AUTOREPEAT DELAY
.
.
.
Key-switch autorepeat delay is 112 debounce
cycles
1
X
X
X
1
1
0
1
Key-switch autorepeat delay is 120 debounce
cycles
1
X
X
X
1
1
1
0
Key-switch autorepeat delay is 128 debounce
cycles
1
X
X
X
1
1
1
1
Key-switch autorepeat frequency is 4
debounce cycles
1
0
0
0
X
X
X
X
Key-switch autorepeat frequency is 8
debounce cycles
1
0
0
1
X
X
X
X
Key-switch autorepeat frequency is 12
debounce cycles
1
0
1
0
X
X
X
X
.
.
.
Key-switch autorepeat frequency is 32
debounce cycles
1
1
1
1
X
X
X
X
Power-up default setting
0
0
0
0
0
0
0
0
______________________________________________________________________________________ 23
MAX7360
Table 12. Autorepeat Register Format (0x05)
MAX7360
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
Table 13. Autosleep Register Format (0x06)
REGISTER
REGISTER DATA
RESERVED
AUTOSLEEP REGISTER
AUTOSHUTDOWN TIME
D7
D6
D5
D4
D3
D2
D1
D0
0
0
0
0
0
0
0
0
8192
0
0
0
0
0
0
0
1
4096
0
0
0
0
0
0
1
0
2048
0
0
0
0
0
0
1
1
1024
0
0
0
0
0
1
0
0
512
0
0
0
0
0
1
0
1
256
0
0
0
0
0
1
1
0
256
0
0
0
0
0
1
1
1
Power-up default settings
0
0
0
0
0
1
1
1
No Autosleep
Autosleep for (ms)
Table 14. GPIO Global Configuration Register (0x40)
REGISTER
BIT
DESCRIPTION
VALUE
D7
PORT6/PORT7
rotary switch
0
PORT6/PORT7 operate as GPIOs
1
PORT6/PORT7 operate as a rotary switch input
D6
Reserved
0
—
Disabled
D5
I C timeout
interrupt
enable
0
1
INTI is asserted when I2C bus times out. INTI is deasserted when a
read is performed on the I2C timeout flag register (0x48).
0
PWM, constant-current circuits, and GPIs are shut down. GPO
values depend on their setting. Register 0x41 to 0x5F values are
stored and cannot be changed. The entire part is shut down if the
key switches are in sleep mode (D7 of register 0x01).
2
D4
GPIO enable
1
0
D3
D[2:0]
GPIO reset
Fade in/out
time
1
FUNCTION
DEFAULT
VALUE
0
0
0
0
Normal GPIO operation. PWM, constant-current circuits, and GPIOs are
enabled regardless of key-switch sleep mode state (see Table 8).
Normal operation
Return all GPIO registers (registers 0x40 to 0x5F) to their POR value.
This bit is momentary and resets itself to 0 after the write cycle.
000
No fading
XXX
PWM intensity ramps up (down) between the common PWM value
and 0% duty cycle in 16 steps over the following time period:
D[2:0] = 001 = 256ms
D[2:0] = 010 = 512ms
D[2:0] = 011 = 1024ms
D[2:0] = 100 = 2048ms
D[2:0] = 101 = 4096ms
D[2:0] = 110/111 = Undefined
24 �������������������������������������������������������������������������������������
0
000
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
REGISTER
BIT
DESCRIPTION
D7
PORT7
D6
PORT6
D5
PORT5
D4
PORT4
D3
PORT3
D2
PORT2
D1
PORT1
D0
PORT0
VALUE
DEFAULT
VALUE
FUNCTION
0
Port is an input
1
Port is an output
0
Port is an input
1
Port is an output
0
Port is an input
1
Port is an output
0
Port is an input
1
Port is an output
0
Port is an input
1
Port is an output
0
Port is an input
1
Port is an output
0
Port is an input
1
Port is an output
0
Port is an input
1
Port is an output
0
0
0
0
0
0
0
0
Table 16. GPIO Debounce Configuration Register (0x42)
REGISTER DATA
REGISTER DESCRIPTION
D7
D6
D5
D4
D3
RESERVED
D2
D1
D0
DEBOUNCE TIME
Power-up default setting
debounce time is 9ms
0
0
0
0
0
0
0
0
Debounce time is 10ms
0
0
0
0
0
0
0
1
Debounce time is 11ms
0
0
0
0
0
0
1
0
Debounce time is 12ms
0
0
0
0
0
0
1
1
.
.
.
Debounce time is 37ms
0
0
0
1
1
1
0
0
Debounce time is 38ms
0
0
0
1
1
1
0
1
Debounce time is 39ms
0
0
0
1
1
1
1
0
Debounce time is 40ms
0
0
0
1
1
1
1
1
______________________________________________________________________________________ 25
MAX7360
Table 15. GPIO Control Register (0x41)
MAX7360
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
Table 17. GPIO Constant-Current Setting Register (0x43)
REGISTER
BIT
DESCRIPTION
D[7:6]
Reserved
11
D[5:2]
Reserved
0000
D[1:0]
VALUE
Constantcurrent setting
DEFAULT
VALUE
FUNCTION
Set always as 11
11
—
0000
00
Constant current is 5mA
01
Constant current is 6.67mA
10
Constant current is 10mA
11
Constant current is 20mA
00
Table 18. GPIO Output Mode Register (0x44)
REGISTER
BIT
DESCRIPTION
D7
PORT7
D6
PORT6
D5
PORT5
D4
PORT4
D3
PORT3
D2
PORT2
D1
PORT1
D0
PORT0
VALUE
DEFAULT
VALUE
FUNCTION
0
Port is a constant-current open-drain output
1
Port is a non-constant-current open-drain output
0
Port is a constant-current open-drain output
1
Port is a non-constant-current open-drain output
0
Port is a constant-current open-drain output
1
Port is a non-constant-current open-drain output
0
Port is a constant-current open-drain output
1
Port is a non-constant-current open-drain output
0
Port is a constant-current open-drain output
1
Port is a non-constant-current open-drain output
0
Port is a constant-current open-drain output
1
Port is a non-constant-current open-drain output
0
Port is a constant-current open-drain output
1
Port is a non-constant-current open-drain output
0
Port is a constant-current open-drain output
1
Port is a non-constant-current open-drain output
0
0
0
0
0
0
0
0
Table 19. Common PWM Register (0x45)
REGISTER DATA
REGISTER DESCRIPTION
D7
D6
D5
D4
D3
D2
D1
D0
COMMON PWM
Power-up default setting (common
PWM ratio is 0/256)
0
0
0
0
0
0
0
0
Common PWM ratio is 1/256
0
0
0
0
0
0
0
1
Common PWM ratio is 2/256
0
0
0
0
0
0
1
0
Common PWM ratio is 3/256
0
0
0
0
0
0
1
1
.
.
.
26 �������������������������������������������������������������������������������������
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
REGISTER DATA
REGISTER DESCRIPTION
D7
D6
D5
D4
D3
COMMON PWM
1
1
D2
D1
D0
Common PWM ratio is 252/256
1
1
1
1
0
0
Common PWM ratio is 253/256
1
1
1
1
1
1
0
1
Common PWM ratio is 254/256
1
1
1
1
1
1
1
0
Common PWM ratio is 256/256
(100% duty cycle)
1
1
1
1
1
1
1
1
D1
D0
Table 20. Rotary Switch Configuration Register (0x46)
REGISTER DATA
REGISTER DESCRIPTION
No debounce time
Debounce time is 1ms
Debounce time is 2ms
Debounce time is 3ms
D7
INT
TYPE
X
X
X
X
D6
D5
D4
D3
COUNTS/CYCLES
X
X
X
X
D2
DEBOUNCE CYCLE TIME
X
X
X
X
X
X
X
X
0
0
0
0
0
0
0
0
0
0
1
1
0
1
0
1
.
.
.
Debounce time is 15ms
X
X
X
X
1
1
1
1
No interrupt generated by rotary switch
X
0
0
0
0
0
0
0
0
0
1
1
0
1
0
1
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
INTI asserted when rotary switch count = ±1
INTI asserted when rotary switch count = ±2
INTI asserted when rotary switch count = ±3
.
.
.
INTI asserted when rotary switch count = ±7
0
1
1
1
X
X
X
X
INTI asserted 25ms after first debounced event
1
0
0
1
X
X
X
X
INTI asserted 50ms after first debounced event
1
0
1
0
X
X
X
X
INTI asserted 75ms after first debounced event
1
0
1
1
X
X
X
X
.
.
.
INTI asserted 175ms after first debounced event
1
1
1
1
X
X
X
X
Power-up default setting
0
0
0
0
0
0
0
0
______________________________________________________________________________________ 27
MAX7360
Table 19. Common PWM Register (0x45) (continued)
MAX7360
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
Table 21. I2C Timeout Flag Register (0x48) (Read Only)
REGISTER
BIT
DESCRIPTION
VALUE
D[7:1]
Reserved
0000000
D0
I2C timeout flag
DEFAULT
VALUE
FUNCTION
—
0000000
0
No I2C timeout has occurred since last read or POR
1
I2C timeout has occurred since last read or POR. This bit is reset to
zero when a read is performed on this register. I2C timeouts must
be enabled for this function to work (see Table 8).
0
Table 22. GPIO Input Register (0x49) (Read Only)
REGISTER
BIT
DESCRIPTION
D7
PORT7
D6
PORT6
D5
PORT5
D4
PORT4
D3
PORT3
D2
PORT2
D1
PORT1
D0
PORT0
VALUE
DEFAULT
VALUE
FUNCTION
0
Port is input low
1
Port is input high
0
Port is input low
1
Port is input high
0
Port is input low
1
Port is input high
0
Port is input low
1
Port is input high
0
Port is input low
1
Port is input high
0
Port is input low
1
Port is input high
0
Port is input low
1
Port is input high
0
Port is input low
1
Port is input high
0
0
0
0
0
0
0
0
Table 23. Rotary Switch Count Register (0x4A) (Read Only)
REGISTER DATA
REGISTER DESCRIPTION
D7
D6
D5
D4
D3
D2
D1
D0
X
X
X
CYCLE COUNT
Cycle count in two’s complement (see the
Rotary Switch Configuration (0x46) section)
X
X
X
X
X
28 �������������������������������������������������������������������������������������
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
REGISTER DATA
REGISTER DESCRIPTION
D7
D6
D5
D4
D3
D2
D1
D0
PORT PWM
Power-up default setting (port PWM ratio is
0/256)
0
0
0
0
0
0
0
0
PORT PWM ratio is 1/256
0
0
0
0
0
0
0
1
PORT PWM ratio is 2/256
0
0
0
0
0
0
1
0
PORT PWM ratio is 3/256
0
0
0
0
0
0
1
1
.
.
.
PORT PWM ratio is 252/256
1
1
1
1
1
1
0
0
PORT PWM ratio is 253/256
1
1
1
1
1
1
0
1
PORT PWM ratio is 254/256
1
1
1
1
1
1
1
0
PORT PWM ratio is 256/256 (100% duty cycle)
1
1
1
1
1
1
1
1
Table 25. PORT0–PORT7 Configuration Registers (0x58 to 0x5F)
REGISTER
BIT
DESCRIPTION
D7
Interrupt mask
D6
Edge/level
detect
D5
D[4:2]
Common PWM
Blink period
VALUE
0
Interrupt is not masked
1
Interrupt is masked. PORT7 interrupt mask is ignored when the
device is configured for rotary switch input.
0
Rising edge-triggered
interrupts
1
Rising or falling edgetriggered interrupts
0
Port uses individual PWM intensity register to set the PWM ratio
1
Port uses common PWM intensity register to set the PWM ratio
Blink-on time
Interrupts only occur when the GPIO
port is configured as an input
000
Port does not blink
001
Port blink period is 256ms
010
Port blink period is 512ms
011
Port blink period is 1024ms
100
Port blink period is 2048ms
101
Port blink period is 4096ms
110/111
D[1:0]
FUNCTION
DEFAULT
VALUE
0
0
0
000
Undefined
00
LED is on for 50% of the blink period
01
LED is on for 25% of the blink period
10
LED is on for 12.5% of the blink period
11
LED is on for 6.25% of the blink period
00
______________________________________________________________________________________ 29
MAX7360
Table 24. PORT0–PORT7 Individual PWM Ratio Registers (0x50 to 0x57)
Pin Configurations
TOP VIEW
BUMPS IN BOTTOM
MAX7360
I.C.
PORT1
PORT3
PORT4
PORT6
ROW0
A1
A2
A3
A4
A5
A6
AD0
PORT0
PORT2
GND
PORT7
ROW1
B1
B2
B3
B4
B5
B6
VCC
N.C.
PORT5
ROW2
GND
ROW3
C1
C2
C3
C4
C5
C6
INTI
GND
INTK
ROW7
ROW5
ROW4
D1
D2
D3
D4
D5
D6
SCL
SDA
COL5
GND
COL1
ROW6
E1
E2
E3
E4
E5
E6
COL7
COL6
COL4
COL3
COL2
COL0
F1
F2
F3
F4
F5
F6
SDA
SCL
INTK
INTI
GND
VCC
N.C.
AD0
TOP VIEW
I.C.
N.C.
WLP
(2.67mm x 2.67mm)
30 29 28 27 26 25 24 23 22 21
PORT0 31
20 N.C.
PORT1 32
19 COL7
PORT2 33
18 COL6
PORT3 34
17 COL5
16 COL4
GND 35
MAX7360
PORT4 36
15 GND
14 COL3
PORT5 37
13 COL2
PORT6 38
EP*
PORT7 39
6
7
8
9
10
ROW7
N.C.
ROW3
5
ROW6
4
ROW5
3
ROW4
2
GND
1
ROW2
11 COL0
ROW1
N.C. 40
12 COL1
+
ROW0
MAX7360
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
TQFN
*EP = EXPOSED PAD, CONNECT EP TO GROUND.
30 �������������������������������������������������������������������������������������
I2C-Interfaced Key-Switch Controller and LED
Driver/GPIOs with Integrated ESD Protection
+3.3V
+14V
+14V
+1.8V
COL7
VCC
COL6
PORT0
COL5
PORT1
COL4
PORT2
MAX7360
KEY 0
KEY 8
KEY 16
KEY 24
KEY 32
KEY 40
KEY 1
KEY 9
KEY 17
KEY 25
KEY 33
KEY 41
KEY 2
KEY 10
KEY 18
KEY 26
KEY 34
KEY 42
KEY 3
KEY 11
KEY 19
KEY 27
KEY 35
KEY 43
KEY 4
KEY 12
KEY 20
KEY 28
KEY 36
KEY 44
KEY 5
KEY 13
KEY 21
KEY 29
KEY 37
KEY 45
KEY 6
KEY 14
KEY 22
KEY 30
KEY 38
KEY 46
KEY 7
KEY 15
KEY 23
KEY 31
KEY 39
KEY 47
COL3
PORT3
COL2
PORT4
COL1
PORT5
COL0
PORT6
ROW7
PORT7
ROW6
+3.3V
ROW5
VCC
µC
GND
SDA
SDA
ROW4
SCL
SCL
ROW3
INTI
INTI
ROW2
INTK
INTK
ROW1
AD0
GND
ROW0
Chip Information
PROCESS: BiCMOS
Package Information
For the latest package outline information and land patterns, go
to www.maxim-ic.com/packages.
PACKAGE TYPE
PACKAGE CODE
DOCUMENT NO.
40 TQFN-EP
T4055+1
21-0140
36 WLP
W362A2+1
21-0301
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
© 2009
Maxim Integrated Products 31
Maxim is a registered trademark of Maxim Integrated Products, Inc.
MAX7360
Typical Application Circuit