MAXIM MAX6889ETJ

19-3595; Rev 1; 9/08
KIT
ATION
EVALU
E
L
B
A
IL
AVA
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
Features
The MAX6889/MAX6890/MAX6891 EEPROM-configurable, multivoltage supply sequencers/supervisors
monitor several voltage detector inputs and generalpurpose logic inputs and feature programmable outputs for highly configurable power-supply sequencing
applications. The MAX6889 features eight voltage
detector inputs and ten programmable outputs. The
MAX6890 features six voltage detector inputs and eight
programmable outputs, while the MAX6891 features
four voltage detector inputs and five programmable
outputs. Manual reset and margin disable inputs offer
additional flexibility.
o Eight (MAX6889), Six (MAX6890), or Four
(MAX6891) Configurable Input Voltage Detectors
High-Voltage Input (1.25V to 7.625V or
2.5V to 13.2V)
Six (MAX6889), Five (MAX6890), or Three
(MAX6891) Voltage Inputs (0.5V to 3.05V or
1V to 5.5V)
Additional (MAX6889) High-Voltage Input
(1.25V to 7.625V or 2.5V to 15.25V)
All voltage detectors offer a configurable threshold for
undervoltage detection. High-voltage input IN1 monitors
voltages from 2.5V to 13.2V in 50mV increments, or from
1.25V to 7.625V in 25mV increments. Inputs IN2–IN7
monitor voltages from 1V to 5.5V in 20mV increments or
from 0.5V to 3.05V in 10mV increments. High-voltage
input IN8 monitors voltages from 2.5V to 15.25V in 50mV
increments, or from 1.25V to 7.625V in 25mV increments.
o Configurable Watchdog Timer
Programmable output stages control power-supply
sequencing or system resets/interrupts. Programmable
output options include: active-high, active-low, open
drain, and weak pullup. Programmable timing delay
blocks configure each output to wait between 25µs and
1600ms before deasserting.
The MAX6889/MAX6890/MAX6891 feature a watchdog
timer for added flexibility. Program the watchdog timer
to assert one or more programmable outputs. The initial
and normal watchdog timeout periods are independently programmable from 6.25ms to 102.4s.
An SMBus™/I2C-compatible, 2-wire serial data interface programs and communicates with the configuration EEPROM, the configuration registers, and the
internal 512-bit user EEPROM.
The MAX6889/MAX6890/MAX6891 are available in
5mm x 5mm x 0.8mm thin QFN packages and are
specified to operate over the extended temperature
range (-40°C to +85°C).
o Four (MAX6889/MAX6890) or Three (MAX6891)
General-Purpose Logic Inputs
o Ten (MAX6889), Eight (MAX6890), or Five
(MAX6891) Programmable Outputs
Active-High, Active-Low, Open Drain, Weak
Pullup
Timing Delays from 25µs to 1600ms
o Margining Disable and Manual Reset Controls
o 512-Bit Internal User EEPROM
Endurance: 100,000 Erase/Write Cycles
Data Retention: 10 Years
o I2C/SMBus-Compatible Serial
Configuration/Communication Interface
o ±1% Threshold Accuracy
Ordering Information
PART
TEMP RANGE
PIN-PACKAGE
MAX6889ETJ
-40°C to +85°C
32 Thin QFN-EP*
MAX6890ETI
-40°C to +85°C
28 Thin QFN-EP*
MAX6891ETP
-40°C to +85°C
20 Thin QFN-EP*
*EP = Exposed pad.
Applications
Telecommunication/Central Office Systems
Networking Systems
Servers/Workstations
Pin Configurations and Typical Operating Circuit appear at
end of data sheet.
Base Stations
Storage Equipment
Multi-Microprocessor/Voltage Systems
SMBus is a trademark of Intel Corp.
________________________________________________________________ Maxim Integrated Products
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.
1
MAX6889/MAX6890/MAX6891
General Description
MAX6889/MAX6890/MAX6891
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
ABSOLUTE MAXIMUM RATINGS
(All voltages referenced to GND.)
IN2–IN7, VCC, SDA, SCL, A0, A1, GPI_
MR, MARGIN .........................................................-0.3V to +6V
IN1, PO_ .................................................................-0.3V to +14V
IN8 ..........................................................................-0.3V to +20V
DBP ..........................................................................-0.3V to +3V
Input/Output Current (all pins)..........................................±20mA
Continuous Power Dissipation (TA = +70°C)
20-Pin Thin QFN (derate 21.3mW/°C
above +70°C)..............................................................1702mW
28-Pin Thin QFN (derate 21.3mW/°C
above +70°C)..............................................................1702mW
32-Pin Thin QFN (derate 21.3mW/°C
above +70°C)..............................................................1702mW
Operating Temperature Range ...........................-40°C to +85°C
Maximum Junction Temperature .....................................+150°C
Storage Temperature Range .............................-65°C to +150°C
Lead Temperature (soldering, 10s) .................................+300°C
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
(VIN1 = 6.5V to 13.2V, VIN2–VIN7 = 2.7V to 5.5V, VIN8 = 10V, GPI_ = GND, MARGIN = MR = DBP, TA = -40°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.) (Notes 1, 2, 3)
PARAMETER
SYMBOL
VIN1
Operating Voltage Range
(Note 4)
CONDITIONS
MIN
TYP
MAX
Voltage on IN1 to ensure the device is fully
operational, IN2–IN8 = GND
4.0
13.2
Voltage on any one of IN2–IN5 or VCC to
ensure the device is fully operational,
IN1 = GND
2.7
5.5
UNITS
V
IN1 Supply Voltage (Note 4)
VIN1P
Minimum voltage on IN1 to guarantee that
the device is powered through IN1
6.5
V
Undervoltage Lockout
VUVLO
Minimum voltage on one of IN2–IN5 to
guarantee the device is EEPROM
configured
2.5
V
Digital Bypass Voltage
VDBP
No load
2.48
VIN1 = 13.2V, IN2–IN8 = GND, no load
Supply Current
Threshold Voltage Range
2
ICC
VTH
Writing to configuration registers or
EEPROM, no load
2.55
2.67
V
1
1.2
mA
1.1
1.5
mA
VIN1 (50mV increments)
2.5
13.2
VIN1 (25mV increments)
1.25
7.625
VIN2–VIN7 (20mV increments)
1.0
5.5
VIN2–VIN7 (10mV increments)
0.50
3.05
VIN8 (50mV increments)
2.50
15.25
VIN8 (25mV increments)
1.250
7.625
VIN2–VIN8 (high-Z mode in 3.3mV
increments)
0.167
1.017
_______________________________________________________________________________________
V
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
(VIN1 = 6.5V to 13.2V, VIN2–VIN7 = 2.7V to 5.5V, VIN8 = 10V, GPI_ = GND, MARGIN = MR = DBP, TA = -40°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.) (Notes 1, 2, 3)
PARAMETER
SYMBOL
CONDITIONS
TA = +25°C to
+85°C
(VIN_ falling)
IN2–IN7 Threshold Accuracy
TA = -40°C to
+85°C
(VIN_ falling)
TA = +25°C to
+85°C
(VIN_ falling)
IN1/IN8 Threshold Accuracy
Threshold Hysteresis
VTH-HYST
MAX
UNITS
-1
+1
%
VIN_ = 1V to 2.5V
(20mV increments)
-25
+25
mV
VIN_ = 1.25V to 3.05V
(10mV increments)
-1
+1
%
VIN_ = 0.5V to 1.25V
(10mV increments)
-12.5
+12.5
mV
VIN_ = 2.5V to 5.5V
(20mV increments)
-2
+2
%
VIN_ = 1V to 2.5V
(20mV increments)
-50
+50
mV
VIN_ = 1.25V to 3.05V
(10mV increments)
-2
+2
%
VIN_ = 0.5V to 1.25V
(10mV increments)
-25
+25
mV
VIN_ = 6.25V to 13.2V
(6.25V to 15.25V for IN8)
(50mV increments)
-1
+1
%
-62.5
+62.5
mV
VIN_ = 3.125V to 7.625V
(25mV increments)
-1
+1
%
VIN_ = 1.25V to 3.125V
(25mV increments)
-31.25
+31.25
mV
-2
+2
%
-125
+125
mV
VIN_ = 3.125V to 7.625V
(25mV increments)
-2
+2
%
VIN_ = 1.25V to 3.125V
(25mV increments)
-62.5
+62.5
mV
TA = +25°C to +85°C
-1
+1
TA = -40°C to 85°C
-2
+2
VIN_ = 2.5V to 6.25V
(50mV increments)
VIN_ = 2.5V to 6.25V
(50mV increments)
IN_ = 0.6V in high-Z
mode (VIN_ falling)
IN_ Threshold Accuracy
TYP
VIN_ = 2.5V to 5.5V
(20mV increments)
VIN_ = 6.25V to 13.2V
(6.25V to 15.25V for IN8)
(50mV increments)
TA = -40°C to
+85°C
(VIN_ falling)
MIN
0.3
%
% VTH
_______________________________________________________________________________________
3
MAX6889/MAX6890/MAX6891
ELECTRICAL CHARACTERISTICS (continued)
MAX6889/MAX6890/MAX6891
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
ELECTRICAL CHARACTERISTICS (continued)
(VIN1 = 6.5V to 13.2V, VIN2–VIN7 = 2.7V to 5.5V, VIN8 = 10V, GPI_ = GND, MARGIN = MR = DBP, TA = -40°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.) (Notes 1, 2, 3)
PARAMETER
SYMBOL
Reset-Threshold Temperature
Coefficient
∆VTH/°C
Threshold-Voltage Differential
Nonlinearity
VTH DNL
IN1 Input Leakage Current
IN2–IN7 Input Impedance
IN8 Input Impedance
IN2–IN8 Input Leakage Current
ILIN1
tPU
IN_ to PO_ Delay
tDPO
tRP
For VIN1 < the highest of VIN2–VIN5
IN2–IN8 in high-Z mode, VIN_ = 1.017V
100
Register contents
(Table 19)
400
555
kΩ
1400
kΩ
-50
ms
µs
25
80
1.719
010
5.625
6.25
6.875
011
22.5
25
27.5
100
45
50
55
101
180
200
220
110
360
400
440
111
1440
1600
1760
10
-1
PO_ Output Pullup Resistance
RPU
VPO_ = 2V
6.6
10
VIL
1.4
tMR
1
tDMR
VMR = 1.4V
5
VMARGIN = 1.4V
5
GPI_ Input Hysteresis
tDGPI_
GPI_ Pulldown Current
IGPI_
VGPI_ = 0.6V
5
Watchdog Input Pulse Width
tWDI
GPI_ configured as a watchdog input
50
µs
ms
0.4
V
40
µA
+1
µA
15.0
kΩ
0.6
VIH
MR Glitch Rejection
4
nA
3
1.5625
Output high impedance
GPI_ to PO_ Delay
+50
20
ILKG
IMARGIN
µA
1000
PO_ Output Open-Drain Leakage
Current
MARGIN to DBP Pullup Current
140
8
VCC < VUVLO, VPO = 0.8V
IMR
LSB
1.406
IPD
MR to DBP Pullup Current
+1
001
ISINK = 4mA, output asserted
MR to PO_ Delay
ppm/°C
000
VOL
UNITS
730
VIN_ falling or rising, 100mV overdrive
PO_ Output Initial Pulldown
Current
MR Input Pulse Width
MAX
290
VCC > VUVLO
PO_ Output Low
MR, MARGIN, GPI_ Input Voltage
TYP
-1
RIN8
ILIN2-LIN8
MIN
10
RIN2 to RIN7 VIN1 > 6.5V
Power-Up Delay
PO_ Timeout Period
CONDITIONS
V
µs
100
ns
2
µs
10
15
10
15
µA
µA
100
mV
200
ns
10
_______________________________________________________________________________________
15
µA
ns
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
(VIN1 = 6.5V to 13.2V, VIN2–VIN7 = 2.7V to 5.5V, VIN8 = 10V, GPI_ = GND, MARGIN = MR = DBP, TA = -40°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.) (Notes 1, 2, 3)
PARAMETER
Watchdog Timeout Period
SYMBOL
tWD
CONDITIONS
MIN
TYP
MAX
000
5.625
6.25
6.875
001
22.5
25
27.5
010
90
100
110
011
360
400
440
100
1.44
1.60
1.76
101
5.76
6.40
7.04
110
23.04
25.60
28.16
111
92.16
102.40
112.64
Register contents
(Table 21)
UNITS
ms
s
SERIAL INTERFACE LOGIC (SDA, SCL, A0, A1)
Logic-Input Low Voltage
VIL
Logic-Input High Voltage
VIH
2.0
Input Leakage Current
ILKG
-1
Output Low Voltage
VOL
Input/Output Capacitance
CI/O
0.8
V
+1
µA
0.4
V
V
ISINK = 3mA
10
pF
SERIAL INTERFACE TIMING CHARACTERISTICS (Figure 3)
(IN1 = GND, VIN2–VIN7 = 2.7V to 5.5V, VIN8 = 10V, GPI_ = GND, MARGIN = MR = DBP, TA = -40°C to +85°C, unless otherwise
noted. Typical values are at TA = +25°C.) (Notes 1, 2, 3)
PARAMETER
Serial Clock Frequency
SYMBOL
CONDITIONS
MIN
TYP
fSCL
MAX
UNITS
400
kHz
Clock Low Period
tLOW
1.3
µs
Clock High Period
tHIGH
0.6
µs
Bus-Free Time
tBUF
1.3
µs
START Setup Time
tSU:STA
0.6
µs
START Hold Time
tHD:STA
0.6
µs
STOP Setup Time
tSU:STO
0.6
µs
Data In Setup Time
tSU:DAT
100
Data In Hold Time
tHD:DAT
30
ns
900
ns
Receive SCL/SDA Minimum
Rise Time
tR
(Note 5)
20 + 0.1
x CBUS
ns
Receive SCL/SDA Maximum
Rise Time
tR
(Note 5)
300
ns
Receive SCL/SDA Minimum
Fall Time
tF
(Note 5)
20 + 0.1
x CBUS
ns
Receive SCL/SDA Maximum
Fall Time
tF
(Note 5)
300
ns
Transmit SDA Fall Time
tF
CBUS = 400pF
20 + 0.04
x CBUS
300
ns
_______________________________________________________________________________________
5
MAX6889/MAX6890/MAX6891
ELECTRICAL CHARACTERISTICS (continued)
SERIAL INTERFACE TIMING CHARACTERISTICS (Figure 3) (continued)
(IN1 = GND, VIN2–VIN7 = 2.7V to 5.5V, VIN8 = 10V, GPI_ = GND, MARGIN = MR = DBP, TA = -40°C to +85°C, unless otherwise
noted. Typical values are at TA = +25°C.) (Notes 1, 2, 3)
PARAMETER
SYMBOL
CONDITIONS
Pulse Width of Spike Suppressed
tSP
(Note 6)
EEPROM Byte Write Cycle Time
tWR
(Note 7)
MIN
TYP
MAX
UNITS
11
ms
50
ns
Note 1: 100% production tested at TA = +25°C and TA = +85°C. Specifications at TA = -40°C are guaranteed by design.
Note 2: Specifications are guaranteed for the stated global conditions. The device also meets the parameters specified when 0 <
VIN1 < 6.5V and at least one of VIN2–VIN5 is between 2.7V and 5.5V, while the remaining VIN2–VIN5 are between 0 and 5.5V.
Specifications are also guaranteed if VCC is externally supplied.
Note 3: Device may be supplied from any one of IN1 to IN5, or VCC (see the Powering the MAX6889/MAX6890/MAX6891 section).
Note 4: The internal supply voltage, measured at VCC, equals the maximum of IN2 to IN5 if VIN1 = 0V, or equals 5.4V if VIN1 > 6.5V.
For 4V < VIN1 < 6.5V and VIN2–VIN5 > 2.7V, the input that powers the device cannot be determined.
Note 5: CBUS = total capacitance of one bus line in pF. Rise and fall times are measured between 0.1 x VBUS and 0.9 x VBUS.
Note 6: Input filters on SDA, SCL, A0, and A1 suppress noise spikes < 50ns.
Note 7: An additional cycle is required when writing to configuration memory for the first time.
Typical Operating Characteristics
(VIN1 = 6.5V to 13.2V, VIN8 = 10V, VIN_ = 2.7V to 5.5V, GPI_ = GND, MARGIN = MR = DBP, TA = +25°C, unless otherwise noted.)
SUPPLY CURRENT
vs. SUPPLY VOLTAGE (IN2–IN5)
TA = +85°C
1.1
1.0
TA = +25°C
0.9
TA = -40°C
TA = +85°C
1.0
0.9
TA = +25°C
TA = -40°C
0.8
0.7
0.8
0.6
0.7
6.5
7.5
8.5
9.5
10.5
11.5
SUPPLY VOLTAGE (V)
12.5
13.5
1.3
MAX6889 toc03
MAX6889 toc02
1.1
SUPPLY CURRENT (mA)
1.2
6
1.2
MAX6889 toc01
1.3
NORMALIZED PO_ TIMEOUT PERIOD
vs. TEMPERATURE
NORMALIZED PO_ TIMEOUT PERIOD
SUPPLY CURRENT
vs. SUPPLY VOLTAGE (IN1)
SUPPLY CURRENT (mA)
MAX6889/MAX6890/MAX6891
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
1.2
1.1
1.0
0.9
0.8
0.7
2.5
3.0
3.5
4.0
4.5
SUPPLY VOLTAGE (V)
5.0
5.5
-40
-15
10
35
TEMPERATURE (°C)
_______________________________________________________________________________________
60
85
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
NORMALIZED WATCHDOG TIMEOUT PERIOD
vs. TEMPERATURE
22
20
18
16
14
12
1.005
1.000
0.995
0.990
0.985
-15
10
35
60
1.001
1.000
0.999
0.998
0.997
-15
10
35
60
85
-40
-15
10
35
60
TEMPERATURE (°C)
TEMPERATURE (°C)
TEMPERATURE (°C)
MAXIMUM IN_ TRANSIENT
vs. IN_ THRESHOLD OVERDRIVE
OUTPUT VOLTAGE LOW
vs. SINK CURRENT
OUTPUT VOLTAGE HIGH
vs. SOURCE CURRENT
500
MAX6889 toc07
200
175
450
400
150
PO_ ASSERTION OCCURS
ABOVE THIS LINE
75
300
VOH (mV)
100
VOL (mV)
350
125
250
200
150
50
100
25
50
0
0
10
100
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
1000
IN_ THRESHOLD OVERDRIVE (mV)
2.6
2.4
2.2
2.0
1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
0
WEAK PULLUP
0
0.04
0.08
0.12
0.16
0.20
85
0.24
IOUT (mA)
ISINK (mA)
MR TO PO_ PROPAGATION DELAY
vs. TEMPERATURE
MAX6889 toc10
2.20
MR TO PO_ PROPAGATION DELAY (µs)
1
MAX6889 toc06
1.002
0.995
-40
85
1.003
MAX6889 toc08
-40
1.004
0.996
0.980
10
MAXIMUM TRANSIENT DURATION (µs)
1.010
1.005
MAX6889 toc09
24
1.015
NORMALIZED IN_ THRESHOLD
vs. TEMPERATURE
NORMALIZED IN_ THRESHOLD
26
1.020
MAX6889 toc05
100mV OVERDRIVE
28
NORMALIZED WATCHDOG TIMEOUT PERIOD
IN_ TO PO_ PROPAGATION DELAY (µs)
30
MAX6889 toc04
IN_ TO PO_ PROPAGATION DELAY
vs. TEMPERATURE
2.15
2.10
2.05
2.00
1.95
1.90
1.85
1.80
-40
-15
10
35
60
85
TEMPERATURE (°C)
_______________________________________________________________________________________
7
MAX6889/MAX6890/MAX6891
Typical Operating Characteristics (continued)
(VIN1 = 6.5V to 13.2V, VIN8 = 10V, VIN_ = 2.7V to 5.5V, GPI_ = GND, MARGIN = MR = DBP, TA = +25°C, unless otherwise noted.)
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
MAX6889/MAX6890/MAX6891
Pin Description
PIN
MAX6889
1
2
1
2
MAX6891
1
2
NAME
FUNCTION
PO2
Programmable Output 2. Configurable, active-high, active-low, open-drain, or
weak pullup output. PO2 pulls low with a 10µA internal current sink for 1V < VCC
< VUVLO. PO2 assumes its programmed conditional output state when VCC
exceeds undervoltage lockout (UVLO) of 2.5V.
PO3
Programmable Output 3. Configurable, active-high, active-low, open-drain, or
weak pullup output. PO3 pulls low with a 10µA internal current sink for 1V < VCC
< VUVLO. PO3 assumes its programmed conditional output state when VCC
exceeds undervoltage lockout (UVLO) of 2.5V.
3
3
3
PO4
Programmable Output 4. Configurable, active-high, active-low, open-drain, or
weak pullup output. PO4 pulls low with a 10µA internal current sink for 1V < VCC
< VUVLO. PO4 assumes its programmed conditional output state when VCC
exceeds undervoltage lockout (UVLO) of 2.5V.
4
4
4
GND
Ground
PO5
Programmable Output 5. Configurable, active-high, active-low, open-drain, or
weak pullup output. PO5 pulls low with a 10µA internal current sink for 1V < VCC
< VUVLO. PO5 assumes its programmed conditional output state when VCC
exceeds undervoltage lockout (UVLO) of 2.5V.
PO6
Programmable Output 6. Configurable, active-high, active-low, open-drain, or
weak pullup output. PO6 pulls low with a 10µA internal current sink for 1V < VCC
< VUVLO. PO6 assumes its programmed conditional output state when VCC
exceeds undervoltage lockout (UVLO) of 2.5V.
PO7
Programmable Output 7. Configurable, active-high, active-low, open-drain, or
weak pullup output. PO7 pulls low with a 10µA internal current sink for 1V < VCC
< VUVLO. PO7 assumes its programmed conditional output state when VCC
exceeds undervoltage lockout (UVLO) of 2.5V.
PO8
Programmable Output 8. Configurable, active-high, active-low, open-drain, or
weak pullup output. PO8 pulls low with a 10µA internal current sink for 1V < VCC
< VUVLO. PO8 assumes its programmed conditional output state when VCC
exceeds undervoltage lockout (UVLO) of 2.5V.
PO9
Programmable Output 9. Configurable, active-high, active-low, open-drain, or
weak pullup output. PO9 pulls low with a 10µA internal current sink for +1V <
VCC < VUVLO. PO9 assumes its programmed conditional output state when VCC
exceeds undervoltage lockout (UVLO) of 2.5V.
PO10
Programmable Output 10. Configurable, active-high, active-low, open-drain, or
weak pullup output. PO10 pulls low with a 10µA internal current sink for 1V <
VCC < VUVLO. PO10 assumes its programmed conditional output state when VCC
exceeds undervoltage lockout (UVLO) of 2.5V.
5
6
7
8
9
10
11
8
MAX6890
5
6
7
8
—
—
9
5
—
—
—
—
—
6
MARGIN
Margin Input. MARGIN holds PO_ in its existing state when MARGIN is driven
low. Leave MARGIN unconnected or connect to DBP if unused. MARGIN
overrides MR if both assert at the same time. MARGIN is internally pulled up to
DBP through a 10µA current source.
_______________________________________________________________________________________
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
PIN
MAX6889
MAX6890
MAX6891
NAME
FUNCTION
12
10
7
MR
Manual Reset Input. MR is configurable to either assert PO_ into a programmed
state or to have no effect on PO_ when driving MR low (see Table 6). Leave MR
unconnected or connect to DBP if unused. MR is internally pulled up to DBP
through a 10µA current source.
13
11
8
SDA
Serial Data Input/Output (Open Drain). SDA requires an external pullup resistor.
14
12
9
SCL
Serial Clock Input. SCL requires an external pullup resistor.
15
13
10
A0
Address Input 0. Address inputs allow up to four (MAX6889/MAX6890) or two
(MAX6891) connections on one common bus. Connect A0 to GND or to the
serial-interface power supply.
16
14
—
A1
Address Input 1. Address inputs allow up to four MAX6889/MAX6890
connections on one common bus. Connect A1 to GND or to the serial-interface
power supply.
17
15
—
GPI4
General-Purpose Logic Input 4. An internal 10µA current source pulls GPI4 to
GND. Configure GPI4 to control watchdog timer functions or the programmable
outputs.
18
16
11
GPI3
General-Purpose Logic Input 3. An internal 10µA current source pulls GPI3 to
GND. Configure GPI3 to control watchdog timer functions or the programmable
outputs.
19
17
12
GPI2
General-Purpose Logic Input 2. An internal 10µA current source pulls GPI2 to
GND. Configure GPI2 to control watchdog timer functions or the programmable
outputs.
20
18
13
GPI1
General-Purpose Logic Input 1. An internal 10µA current source pulls GPI1 to
GND. Configure GPI1 to control watchdog timer functions or the programmable
outputs.
VCC
Internal Power-Supply Voltage. Bypass VCC to GND with a 1µF ceramic
capacitor. VCC supplies power to the internal circuitry. VCC is internally powered
from the highest of the monitored IN1–IN5 voltages. Do not use VCC to supply
power to external circuitry. To externally supply VCC, see the Powering the
MAX6889/MAX6890/MAX6891 section.
DBP
Internal Digital Power-Supply Voltage. Bypass DBP to GND with a 1µF ceramic
capacitor. DBP supplies power to the EEPROM memory, the internal logic
circuitry, and the programmable outputs. Do not use DBP to supply power to
external circuitry.
IN8
High-Voltage Input 8. Configure IN8 to detect voltage thresholds from 2.5V to
15.25V in 50mV increments, or 1.25V to 7.625V in 25mV increments. For
improved noise immunity, bypass IN8 to GND with a 0.1µF capacitor installed as
close to the device as possible.
IN7
Voltage Input 7. Configure IN7 to detect voltage thresholds between 1V and 5.5V
in 20mV increments, or 0.5V to 3.05V in 10mV increments. For improved noise
immunity, bypass IN7 to GND with a 0.1µF capacitor installed as close to the
device as possible.
21
22
23
24
19
20
—
—
14
15
—
—
_______________________________________________________________________________________
9
MAX6889/MAX6890/MAX6891
Pin Description (continued)
MAX6889/MAX6890/MAX6891
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
Pin Description (continued)
PIN
MAX6889
25
26
27
28
29
10
MAX6890
21
22
23
24
25
MAX6891
—
—
16
17
18
NAME
FUNCTION
IN6
Voltage Input 6. Configure IN6 to detect voltage thresholds between 1V and 5.5V
in 20mV increments, or 0.5V to 3.05V in 10mV increments. For improved noise
immunity, bypass IN6 to GND with a 0.1µF capacitor installed as close to the
device as possible.
IN5
Voltage Input 5. Configure IN5 to detect voltage thresholds between 1V and 5.5V
in 20mV increments, or 0.5V to 3.05V in 10mV increments. For improved noise
immunity, bypass IN5 to GND with a 0.1µF capacitor installed as close to the
device as possible.
IN4
Voltage Input 4. Configure IN4 to detect voltage thresholds between 1V and 5.5V
in 20mV increments, or 0.5V to 3.05V in 10mV increments. For improved noise
immunity, bypass IN4 to GND with a 0.1µF capacitor installed as close to the
device as possible.
IN3
Voltage Input 3. Configure IN3 to detect voltage thresholds between 1V and 5.5V
in 20mV increments, or 0.5V to 3.05V in 10mV increments. For improved noise
immunity, bypass IN3 to GND with a 0.1µF capacitor installed as close to the
device as possible.
IN2
Voltage Input 2. Configure IN2 to detect voltage thresholds between 1V and 5.5V
in 20mV increments, or 0.5V to 3.05V in 10mV increments. For improved noise
immunity, bypass IN2 to GND with a 0.1µF capacitor installed as close to the
device as possible.
30
26
19
IN1
High-Voltage Input 1. Configure IN1 to detect voltage thresholds from 2.5V to
13.2V in 50mV increments, or 1.25V to 7.625V in 25mV increments. For improved
noise immunity, bypass IN1 to GND with a 0.1µF capacitor installed as close to
the device as possible.
31
27
—
N.C.
No Connection. Not internally connected.
32
28
20
PO1
Programmable Output 1. Configurable, active-high, active-low, open-drain, or
weak pullup output. PO1 pulls low with a 10µA internal current sink for 1V < VCC
< VUVLO. PO1 assumes its programmed conditional output state when VCC
exceeds undervoltage lockout (UVLO) of 2.5V.
EP
EP
EP
GND
Exposed Paddle. Internally connected to GND. Connect exposed paddle to
GND or leave floating.
______________________________________________________________________________________
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
MR
MARGIN
GPI4 *
GPI3
GPI2
GPI1
2.55V LDO
OUTPUT
IN_
DETECTOR
IN1
OPEN-DRAIN OR
WEAK PULLUP
SWITCH
PO_ OUTPUT
10kΩ
5.4V
LDO
LO/
HI
PO1
10µA POWER-UP
PULLDOWN
PROGRAMMABLE ARRAY
VREF
TIMING BLOCK 1
TIMING BLOCK 2
PO2 OUTPUT
PO2
TIMING BLOCK 3
PO3 OUTPUT
PO3
TIMING BLOCK 4
PO4 OUTPUT
PO4
TIMING BLOCK 5
PO5 OUTPUT
PO5
IN6 DETECTOR
TIMING BLOCK 6
PO6 OUTPUT
PO6*
IN7**
IN7 DETECTOR
TIMING BLOCK 7
PO7 OUTPUT
PO7*
IN8**
IN8 DETECTOR
TIMING BLOCK 8
PO8 OUTPUT
PO8*
TIMING BLOCK 9
PO9 OUTPUT
PO9**
TIMING BLOCK 10
PO10 OUTPUT
PO10**
IN2
IN2 DETECTOR
IN3
IN3 DETECTOR
IN4
IN4 DETECTOR
IN5*
IN5 DETECTOR
IN6*
MAIN
OSCILLATOR
VIRTUAL
DIODES
EEPROM
CHARGE PUMP
CONFIG CONFIG
REGISTERS EEPROM
USER
EEPROM
2.55V
LDO
DBP
1µF
MAX6889
MAX6890
MAX6891
VCC
SDA
2-WIRE
INTERFACE
SCL
A0
A1
1µF
GND
* FOR MAX6889/MAX6890 ONLY.
** FOR MAX6889 ONLY.
______________________________________________________________________________________
11
MAX6889/MAX6890/MAX6891
Functional Diagram
MAX6889/MAX6890/MAX6891
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
LOGIC NETWORK
FOR PO_
COMPARATORS
IN _
OUTPUT
STAGES
PO_
MR, GPI_,
MARGIN
WATCHDOG
TIMER
SERIAL
INTERFACE
SDA,
SCL
GPI_
REGISTER BANK
EEPROM
(USER AND CONFIG)
BOOT
CONTROLLER
ANALOG
BLOCK
DIGITAL
BLOCK
Figure 1. Top-Level Block Diagram
Detailed Description
The MAX6889/MAX6890/MAX6891 EEPROM-configurable, multivoltage supply sequencers/supervisors
monitor several voltage detector inputs and generalpurpose logic inputs, and feature programmable outputs for highly-configurable power-supply sequencing
applications. The MAX6889 features eight voltage
detector inputs and ten programmable outputs. The
MAX6890 features six voltage detector inputs and eight
programmable outputs, while the MAX6891 features
four voltage detector inputs and five programmable
outputs. Manual reset and margin disable inputs simplify board-level testing during the manufacturing
process.
All voltage detectors provide configurable thresholds
for undervoltage detection. The high-voltage input (IN1)
monitors voltages from 1.25V to 7.625V in 25mV increments, or 2.5V to 13.2V in 50mV increments. Inputs
(IN2–IN7) monitor voltages from 0.5V to 3.05V in 10mV
increments, or 1.0V to 5.5V in 20mV increments. An
additional high-voltage input (IN8, MAX6889 only) monitors voltages from 1.25V to 7.625V in 25mV increments, or 2.5V to 15.25V in 50mV increments. To
12
monitor thresholds from 0.1667V to 1.0167V in 3.3mV
increments, the respective input voltage detector must
be programmed for high impedance (high-Z) and an
external voltage-divider must be connected.
The host controller communicates with the
MAX6889/MAX6890/MAX6891s’ internal 512-bit user
EEPROM, configuration EEPROM, and configuration
registers through an SMBus/I2C-compatible serial interface (see Figure 1).
Programmable output options include active-high, activelow, open drain, and weak pullup. Program each output
to assert on any voltage detector input, general-purpose
logic input, watchdog timer, or manual reset. Programmable timing delay blocks configure each output to wait
between 25µs and 1600ms before deasserting.
The MAX6889/MAX6890/MAX6891 feature a watchdog
timer for added flexibility. Program the watchdog timer to
assert one or more programmable outputs. Program the
watchdog timer to clear on a combination of one GPI_
input and one programmable output, one of the GPI_
inputs only, or one of the programmable outputs only.
The initial and normal watchdog timeout periods are
independently programmable from 6.25ms to 102.4s.
______________________________________________________________________________________
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
FEATURE
High-Voltage Input IN1
Positive Voltage Input
IN2–IN7 (MAX6889)
IN2–IN6 (MAX6890)
IN2–IN4 (MAX6891)
High-Voltage Input IN8
(MAX6889)
Programmable Outputs
PO1–PO10 (MAX6889)
PO1–PO8 (MAX6890)
PO1–PO5 (MAX6891)
General-Purpose Logic Inputs:
GPI1–GPI4
(MAX6889–MAX6890)
GPI1–GPI3 (MAX6891)
DESCRIPTION
• 2.5V to 13.2V threshold in 50mV increments.
• 1.25V to 7.625V threshold in 25mV increments.
• 1V to 5.5V threshold in 20mV increments.
• 0.5V to 3.05V threshold in 10mV increments.
• 0.1667V to 1.0167V threshold in 3.3mV increments in high-Z mode.
• 2.5V to 15.25V threshold in 50mV increments.
• 1.25V to 7.625V threshold in 25mV increments.
• 0.1667V to 1.0167V threshold in 3.3mV increments in high-Z mode.
• Active-high or active-low.
• Open-drain or weak pullup output.
• Dependent on MR, MARGIN, IN_, GPI_, and WD.
• Programmable reset timeout periods of 25µs, 1.5625ms, 6.25ms, 25ms, 50ms, 200ms, 400ms,
or 1.6s.
• Active-high or active-low logic levels.
• Configure GPI_ as inputs to the watchdog timer or the programmable output stages.
• Clear dependent on any combination of one GPI_ input and one programmable output, a GPI_
input only, or a programmable output only.
Watchdog Timer
• Initial watchdog timeout period of 6.25ms, 25ms, 100ms, 400ms, 1.6s, 6.4s, 25.6s, or 102.4s.
• Normal watchdog timeout period of 6.25ms, 25ms, 100ms, 400ms, 1.6s, 6.4s, 25.6s, or 102.4s.
• Watchdog enable/disable.
Manual Reset Input (MR)
• Forces PO_ into the active output state when MR = GND.
• PO_ deassert after MR releases high and the PO_ timeout period expires.
VCC Power Mode
Programs whether the device is powered from the highest IN_ input or from an external supply
connected to VCC.
Write Disable
Locks user EEPROM based on PO_.
Configuration Lock
Locks configuration registers and EEPROM.
Powering the
MAX6889/MAX6890/MAX6891
The MAX6889/MAX6890/MAX6891 derive power from
the voltage detector inputs: IN1–IN5 (MAX6889/
MAX6890), IN1–IN4 (MAX6891), or an external VCC
supply. A virtual diode-ORing scheme selects the positive input that supplies power to the device (see the
Functional Diagram). IN1 must be at least 4V, or one of
IN2–IN5 (MAX6889/MAX6890)/IN2–IN4 (MAX6891)
must be at least 2.7V to ensure device operation. An
internal LDO regulates IN1 down to 5.4V.
The highest input voltage on IN2–IN5 (MAX6889/
MAX6890)/IN2–IN4 (MAX6891) supplies power to the
device, unless VIN1 > 6.5V, in which case IN1 supplies
power to the device. For 4V < VIN1 < 6.5V and one of
VIN2–VIN5 > 2.7V, the input power source cannot be
determined due to the dropout voltage of the LDO.
Internal hysteresis ensures that the supply input that initially powered the device continues to power the device
when multiple input voltages are within 50mV of
each other.
VCC powers the analog circuitry. Bypass VCC to GND
with a 1µF ceramic capacitor installed as close to the
device as possible. The internal supply voltage, measured at VCC, equals the maximum of IN2–IN5 if VIN1 =
0V, or equals 5.4V when VIN1 > 6.5V. Do not use the
internally generated VCC to provide power to external
circuitry. Power cannot be supplied through highimpedance voltage detector inputs. To externally supply power through VCC:
______________________________________________________________________________________
13
MAX6889/MAX6890/MAX6891
Table 1. Programmable Features
MAX6889/MAX6890/MAX6891
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
1) Apply a voltage between 2.7V and 5.5V to one of
VCC or IN2–IN5.
2) Program the internal/external VCC power EEPROM
at AEh, Bit[2] = 1 (see Table 22).
3) Power down the device.
Subsequent power-ups and software reboots require
an externally supplied VCC to ensure the device is fully
operational.
The MAX6889/MAX6890/MAX6891 also generate a digital supply voltage (DBP) for the internal logic circuitry
and the EEPROM. Bypass DBP to GND with a 1µF
ceramic capacitor installed as close to the device as
possible. The nominal DBP output voltage is 2.55V. Do
not use DBP to provide power to external circuitry.
erwise the threshold exceeds the maximum operating
voltage of IN1.
IN2–IN7
The IN2–IN7 positive voltage detectors monitor voltages from 1V to 5.5V in 20mV increments, 0.5V to
3.05V in 10mV increments, or 0.1667V to 1.0167V in
3.3mV increments in high-Z mode. Use the following
equations to set the threshold voltages for IN_:
V − 1V
x = TH
for 1V to 5.5V range
0.02V
V − 0.5V
x = TH
for 0.5V to 3.05V range
0.1V
V − 0.1667V
x = TH
for 0.1667V to 1.0167V high − Z range
0.0033V
Inputs
The MAX6889/MAX6890/MAX6891 contain multiple
logic and voltage detector inputs. Each voltage detector input is monitored for undervoltage thresholds.
Table 1 summarizes these various inputs. Set the
threshold voltage for each voltage detector input with
registers 00h–07h. Each threshold voltage is an undervoltage threshold. Set the threshold range for each voltage detector with register 08h.
High-Voltage Input (IN1)
IN1 offers threshold voltages of 2.5V to 13.2V in 50mV
increments, or 1.25V to 7.625V in 25mV increments.
Use the following equations to set the threshold voltages for IN1:
V − 2.5V
x = TH
for 2.5V to 13.2V range
0.05V
V − 1.25V
x = TH
for 1.25V to 7.625V range
0.025V
where VTH is the desired threshold voltage and x is the
decimal code for the desired threshold (Table 2). For
the 2.5V to 13.2V range, x must equal 214 or less; oth-
where VTH is the desired threshold voltage and x is the
decimal code for the desired threshold (Table 3). For
the 1V to 5.5V range, x must equal 225 or less; otherwise the threshold exceeds the maximum operating
voltage of IN2–IN7.
High-Voltage Input (IN8)
Configure IN8 to detect positive thresholds from 2.5V to
15.25V in 50mV increments, 1.25V to 7.625V in 25mV
increments, or 0.1667V to 1.0167V in 3.3mV increments
in high-Z mode. Use the following equations to set the
threshold voltages for IN8:
V − 2.5V
x = TH
for 2.5V to 15.25V range
0.05V
V − 1.25V
x = TH
for 1.25V to 7.625V range
0.025V
V − 0.1667V
x = TH
for 0.1667V to 1.0167V high − Z range
0.0033V
where VTH is the desired threshold voltage and x is the
decimal code for the desired threshold (Table 4).
Table 2. IN1 Threshold Settings
REGISTER
ADDRESS
EEPROM
MEMORY
ADDRESS
BIT
RANGE
00h
80h
[7:0]
08h
88h
[0]
IN1 range selection. 0 = 2.5V to 13.2V range in 50mV increments. 1 = 1.25V to 7.625V
range in 25mV increments.
09h
89h
[0]
Must be set to “0” for normal operation
14
DESCRIPTION
IN1 undervoltage detector threshold (V1) (see equations in the Inputs section)
______________________________________________________________________________________
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
REGISTER
ADDRESS
EEPROM
BIT
MEMORY
RANGE
ADDRESS
DESCRIPTION
01h
81h
[7:0]
IN2 undervoltage detector threshold (V2) (see equations in the Inputs section)
02h
82h
[7:0]
IN3 undervoltage detector threshold (V3) (see equations in the Inputs section)
03h
83h
[7:0]
IN4 undervoltage detector threshold (V4) (see equations in the Inputs section)
04h
84h
[7:0]
IN5 (MAX6889/MAX6890 only) undervoltage detector threshold (V5) (see equations in the Inputs section)
05h
85h
[7:0]
IN6 (MAX6889/MAX6890 only) undervoltage detector threshold (V6) (see equations in the Inputs section)
06h
86h
[7:0]
IN7 (MAX6889 only) undervoltage detector threshold (V7) (see equations in the Inputs section)
08h
09h
88h
[1]
IN2 range selection, 0 = 1V to 5.5V range in 20mV increments, 1 = 0.5V to 3.05V range in
10mV increments
[2]
IN3 range selection, 0 = 1V to 5.5V range in 20mV increments, 1 = 0.5V to 3.05V range in
10mV increments
[3]
IN4 range selection, 0 = 1V to 5.5V range in 20mV increments, 1 = 0.5V to 3.05V range in
10mV increments
[4]
IN5 (MAX6889/MAX6890 only) range selection, 0 = 1V to 5.5V range in 20mV increments, 1 =
0.5V to 3.05V range in 10mV increments
[5]
IN6 (MAX6889/MAX6890 only) range selection, 0 = 1V to 5.5V range in 20mV increments, 1 =
0.5V to 3.05V range in 10mV increments
[6]
IN7 (MAX6889 only) range selection, 0 = 1V to 5.5V range in 20mV increments, 1 = 0.5V to
3.05V range in 10mV increments
[7]
Not used
[1]
IN2 input impedance. 0 = normal mode. 1 = high-Z mode, with a 0.1667V to 1.0167V range in
3.3mV increments.
[2]
IN3 input impedance. 0 = normal mode. 1 = high-Z mode, with a 0.1667V to 1.0167V range in
3.3mV increments.
[3]
IN4 input impedance. 0 = normal mode. 1 = high-Z mode, with a 0.1667V to 1.0167V range in
3.3mV increments.
[4]
IN5 input impedance. 0 = normal mode. 1 = high-Z mode, with a 0.1667V to 1.0167V range in
3.3mV increments.
[5]
IN6 input impedance. 0 = normal mode. 1 = high-Z mode, with a 0.1667V to 1.0167V range in
3.3mV increments.
[6]
IN7 input impedance. 0 = normal mode. 1 = high-Z mode, with a 0.1667V to 1.0167V range in
3.3mV increments.
89h
GPI1–GPI4
The GPI1–GPI4 (General-Purpose Input) programmable
logic inputs control power-supply sequencing (programmable outputs), reset/interrupt signaling, and
watchdog functions (see the Configuring the Watchdog
Timer section). Configure GPI1–GPI4 for active-low or
active-high logic (Table 5). GPI1–GPI4 internally pull
down to GND through a 10µA current sink.
MR
The manual reset (MR) input initiates a reset condition.
See Table 6 to program the PO_ outputs to assert when
MR is low. All affected programmable outputs remain
asserted (see the Programmable Outputs section) for
their PO_ timeout periods after MR releases high. An
internal 10µA current source pulls MR to DBP. Leave
MR unconnected or connect to DBP if unused.
______________________________________________________________________________________
15
MAX6889/MAX6890/MAX6891
Table 3. IN2–IN7 Threshold Settings
MAX6889/MAX6890/MAX6891
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
Table 4. IN8 Threshold Settings
REGISTER
ADDRESS
EEPROM
MEMORY
ADDRESS
BIT
RANGE
07h
87h
[7:0]
08h
88h
[7]
IN8 range selection.
0 = 2.5V to 15.25V range in 50mV increments.
1 = 1.25V to 7.625V range in 25mV increments.
09h
89h
[7]
IN8 input impedance. 0 = normal mode. 1 = high-Z mode, with a 0.1667V to 1.0167V
range in 3.3mV increments.
DESCRIPTION
IN8 undervoltage detector threshold (V8) (see equations in the Inputs section)
Table 5. GPI1–GPI4 Active Logic States
REGISTER
ADDRESS
28h
EEPROM
ADDRESS
A8h
BIT
RANGE
DESCRIPTION
[0]
GPI1. 0 = active-low, 1 = active-high.
[1]
GPI2. 0 = active-low, 1 = active-high.
[2]
GPI3. 0 = active-low, 1 = active-high.
[3]
GPI4 (MAX6889/MAX6890 only). 0 = active-low, 1 = active-high.
MARGIN
MARGIN allows system-level testing while power supplies exceed the normal ranges. Driving MARGIN low
forces the programmable outputs to hold the last state
while system-level testing occurs. Leave MARGIN
unconnected or connect to DBP if unused. An internal
10µA current source pulls MARGIN to DBP. The state of
each programmable output does not change while
MARGIN = GND. MARGIN overrides MR if both assert
at the same time.
Programmable Outputs
The MAX6889 features ten programmable outputs, the
MAX6890 features eight programmable outputs, and
the MAX6891 features five programmable outputs.
Selectable output stage configurations include: activelow or active-high, open drain, or weak pullup. During
power-up, the programmable outputs pull to GND with
an internal 10µA current sink for 1V < VCC < VUVLO.
The programmable outputs remain in their active states
until their respective PO timeout period expires, and all
of the programmed conditions are met for each output.
Any output programmed to depend on no condition
always remains in its active state (Table 17). An output
16
configured as active-high is considered asserted when
that output is logic-high.
The voltage monitors generate fault signals (logical 0) to
the MAX6889/MAX6890/MAX6891s’ logic array when an
input voltage is below the programmed undervoltage
threshold. For example, the PO3 (Table 9) programmable
output may depend on the IN1 undervoltage threshold,
and the state of GPI1. Write “1”s to R10h[0] and R11h[1]
to configure as indicated. IN1 must be above the undervoltage threshold (Table 2) and GPI1 must be inactive
(Table 5) to be a logic “1,” then PO3 deasserts. The logic
state of PO3, in this example, is equivalent to the logical
statement: “V1 · GPI1.”
Registers 0Ah through 27h configure each of the programmable outputs. Programmable timing blocks set
the PO_ timeout period from 25µs to 1600ms for each
programmable output. See Table 17 to set the active
state (active-high or active-low) for each programmable
output and Tables 18 and 19 to select the output stage
types, and PO_ timeout periods for each output. Each
programmable output allows a different set of conditions to assert each output as shown in Tables 7–16.
______________________________________________________________________________________
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
REGISTER
ADDRESS
EEPROM
MEMORY
ADDRESS
0Bh
8Bh
[5]
PO1. 0 = PO1 independent of MR, 1 = PO1 asserts when MR = low.
0Eh
8Eh
[5]
PO2. 0 = PO2 independent of MR, 1 = PO2 asserts when MR = low.
11h
91h
[5]
PO3. 0 = PO3 independent of MR, 1 = PO3 asserts when MR = low.
14h
94h
[5]
PO4. 0 = PO4/PO2 independent of MR, 1 = PO4 asserts when MR = low.
17h
97h
[5]
PO5. 0 = PO5 independent of MR, 1 = PO5 asserts when MR = low.
1Ah
9Ah
[5]
PO6 (MAX6889/MAX6890 only). 0 = PO6 independent of MR,
1 = PO6 asserts when MR = low.
1Dh
9Dh
[5]
PO7 (MAX6889/MAX6890 only). 0 = PO7 independent of MR,
1 = PO7 asserts when MR = low.
20h
A0h
[5]
PO8 (MAX6889/MAX6890 only). 0 = PO8 independent of MR,
1 = PO8 asserts when MR = low.
23h
A3h
[5]
PO9 (MAX6889 only). 0 = PO9 independent of MR, 1 = PO9 asserts when MR = low.
26h
A6h
[5]
PO10 (MAX6889 only). 0 = PO10 independent of MR, 1 = PO10 asserts when MR = low.
BIT
RANGE
MAX6889/MAX6890/MAX6891
Table 6. Programmable Output Behavior and MR
DESCRIPTION
Table 7. PO1 Output Dependency
REGISTER
ADDRESS
0Ah
0Bh
EEPROM
MEMORY
ADDRESS
8Ah
8Bh
BIT
OUTPUT ASSERTION CONDITIONS
[0]
1 = PO1 assertion depends on IN1 undervoltage threshold (Table 2)
[1]
1 = PO1 assertion depends on IN2 undervoltage threshold (Table 3)
[2]
1 = PO1 assertion depends on IN3 undervoltage threshold (Table 3)
[3]
1 = PO1 assertion depends on IN4 undervoltage threshold (Table 3)
[4]
1 = PO1 assertion depends on IN5 (MAX6889/MAX6890 only) undervoltage threshold
(Table 3)
[5]
1 = PO1 assertion depends on IN6 (MAX6889/MAX6890 only) undervoltage threshold
(Table 3)
[6]
1 = PO1 assertion depends on IN7 (MAX6890 only) undervoltage threshold (Table 3)
[7]
1 = PO1 assertion depends on IN8 (MAX6890 only) undervoltage threshold (Table 4)
[0]
1 = PO1 assertion depends on watchdog (Table 20)
[1]
1 = PO1 assertion depends on GPI1 (Table 5)
[2]
1 = PO1 assertion depends on GPI2 (Table 5)
[3]
1 = PO1 assertion depends on GPI3 (Table 5)
[4]
1 = PO1 assertion depends on GPI4 (MAX6889/MAX6890 only) (Table 5)
[5]
1 = PO1 asserts when MR = low (Table 6)
[7:6]
Not used
Note: Table 7 only applies to PO1. Write a “0” to a bit to make the PO1 output independent of the respective signal (IN_ thresholds,
WD, GPI_, or MR).
______________________________________________________________________________________
17
MAX6889/MAX6890/MAX6891
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
Table 8. PO2 Output Dependency
REGISTER
ADDRESS
0Dh
0Eh
EEPROM
MEMORY
ADDRESS
8Dh
8Eh
BIT
OUTPUT ASSERTION CONDITIONS
[0]
1 = PO2 assertion depends on IN1 undervoltage threshold (Table 2)
[1]
1 = PO2 assertion depends on IN2 undervoltage threshold (Table 3)
[2]
1 = PO2 assertion depends on IN3 undervoltage threshold (Table 3)
[3]
1 = PO2 assertion depends on IN4 undervoltage threshold (Table 3)
[4]
1 = PO2 assertion depends on IN5 (MAX6889/MAX6890 only) undervoltage threshold
(Table 3)
[5]
1 = PO2 assertion depends on IN6 (MAX6889/MAX6890 only) undervoltage threshold
(Table 3)
[6]
1 = PO2 assertion depends on IN7 (MAX6890 only) undervoltage threshold (Table 3)
[7]
1 = PO2 assertion depends on IN8 (MAX6890 only) undervoltage threshold (Table 4)
[0]
1 = PO2 assertion depends on watchdog (Table 20)
[1]
1 = PO2 assertion depends on GPI1 (Table 5)
[2]
1 = PO2 assertion depends on GPI2 (Table 5)
[3]
1 = PO2 assertion depends on GPI3 (Table 5)
[4]
1 = PO2 assertion depends on GPI4 (MAX6889/MAX6890 only) (Table 5)
[5]
1 = PO2 asserts when MR = low (Table 6)
[7:6]
Not used
Note: Table 8 only applies to PO2. Write a “0” to a bit to make the PO2 output independent of the respective signal (IN_ thresholds,
WD, GPI_, or MR).
18
______________________________________________________________________________________
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
REGISTER
ADDRESS
10h
11h
EEPROM
MEMORY
ADDRESS
90h
11h
BIT
OUTPUT ASSERTION CONDITIONS
[0]
1 = PO3 assertion depends on IN1 undervoltage threshold (Table 2)
[1]
1 = PO3 assertion depends on IN2 undervoltage threshold (Table 3)
[2]
1 = PO3 assertion depends on IN3 undervoltage threshold (Table 3)
[3]
1 = PO3 assertion depends on IN4 undervoltage threshold (Table 3)
[4]
1 = PO3 assertion depends on IN5 (MAX6889/MAX6890 only) undervoltage threshold
(Table 3)
[5]
1 = PO3 assertion depends on IN6 (MAX6889/MAX6890 only) undervoltage threshold
(Table 3)
[6]
1 = PO3 assertion depends on IN7 (MAX6890 only) undervoltage threshold (Table 3)
[7]
1 = PO3 assertion depends on IN8 (MAX6890 only) undervoltage threshold (Table 4)
[0]
1 = PO3 assertion depends on watchdog (Table 20)
[1]
1 = PO3 assertion depends on GPI1 (Table 5)
[2]
1 = PO3 assertion depends on GPI2 (Table 5)
[3]
1 = PO3 assertion depends on GPI3 (Table 5)
[4]
1 = PO3 assertion depends on GPI4 (MAX6889/MAX6890 only) (Table 5)
[5]
1 = PO3 asserts when MR = low (Table 6)
[7:6]
Not used
Note: Table 9 only applies to PO3. Write a “0” to a bit to make the PO3 output independent of the respective signal (IN_ thresholds,
WD, GPI_, or MR).
______________________________________________________________________________________
19
MAX6889/MAX6890/MAX6891
Table 9. PO3 Output Dependency
MAX6889/MAX6890/MAX6891
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
Table 10. PO4 Output Dependency
REGISTER
ADDRESS
13h
14h
EEPROM
MEMORY
ADDRESS
93h
14h
BIT
OUTPUT ASSERTION CONDITIONS
[0]
1 = PO4 assertion depends on IN1 undervoltage threshold (Table 2)
[1]
1 = PO4 assertion depends on IN2 undervoltage threshold (Table 3)
[2]
1 = PO4 assertion depends on IN3 undervoltage threshold (Table 3)
[3]
1 = PO4 assertion depends on IN4 undervoltage threshold (Table 3)
[4]
1 = PO4 assertion depends on IN5 (MAX6889/MAX6890 only) undervoltage threshold
(Table 3)
[5]
1 = PO4 assertion depends on IN6 (MAX6889/MAX6890 only) undervoltage threshold
(Table 3)
[6]
1 = PO4 assertion depends on IN7 (MAX6890 only) undervoltage threshold (Table 3)
[7]
1 = PO4 assertion depends on IN8 (MAX6890 only) undervoltage threshold (Table 4)
[0]
1 = PO4 assertion depends on watchdog (Table 20)
[1]
1 = PO4 assertion depends on GPI1 (Table 5)
[2]
1 = PO4 assertion depends on GPI2 (Table 5)
[3]
1 = PO4 assertion depends on GPI3 (Table 5)
[4]
1 = PO4 assertion depends on GPI4 (MAX6889/MAX6890 only) (Table 5)
[5]
1 = PO4 asserts when MR = low (Table 6)
[7:6]
Not used
Note: Table 10 only applies to PO4. Write a “0” to a bit to make the PO4 output independent of the respective signal (IN_ thresholds,
WD, GPI_, or MR).
20
______________________________________________________________________________________
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
REGISTER
ADDRESS
16h
17h
EEPROM
MEMORY
ADDRESS
96h
17h
BIT
OUTPUT ASSERTION CONDITIONS
[0]
1 = PO5 assertion depends on IN1 undervoltage threshold (Table 2)
[1]
1 = PO5 assertion depends on IN2 undervoltage threshold (Table 3)
[2]
1 = PO5 assertion depends on IN3 undervoltage threshold (Table 3)
[3]
1 = PO5 assertion depends on IN4 undervoltage threshold (Table 3)
[4]
1 = PO5 assertion depends on IN5 (MAX6889/MAX6890 only) undervoltage threshold
(Table 3)
[5]
1 = PO5 assertion depends on IN6 (MAX6889/MAX6890 only) undervoltage threshold
(Table 3)
[6]
1 = PO5 assertion depends on IN7 (MAX6890 only) undervoltage threshold (Table 3)
[7]
1 = PO5 assertion depends on IN8 (MAX6890 only) undervoltage threshold (Table 4)
[0]
1 = PO5 assertion depends on watchdog (Table 20)
[1]
1 = PO5 assertion depends on GPI1 (Table 5)
[2]
1 = PO5 assertion depends on GPI2 (Table 5)
[3]
1 = PO5 assertion depends on GPI3 (Table 5)
[4]
1 = PO5 assertion depends on GPI4 (MAX6889/MAX6890 only) (Table 5)
[5]
1 = PO5 asserts when MR = low (Table 6)
[7:6]
Not used
Note: Table 11 only applies to PO5. Write a “0” to a bit to make the PO5 output independent of the respective signal (IN_ thresholds,
WD, GPI_, or MR).
______________________________________________________________________________________
21
MAX6889/MAX6890/MAX6891
Table 11. PO5 Output Dependency
MAX6889/MAX6890/MAX6891
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
Table 12. PO6 (MAX6889/MAX6890 Only) Output Dependency
REGISTER
ADDRESS
19h
1Ah
EEPROM
MEMORY
ADDRESS
99h
9Ah
BIT
OUTPUT ASSERTION CONDITIONS
[0]
1 = PO6 assertion depends on IN1 undervoltage threshold (Table 2)
[1]
1 = PO6 assertion depends on IN2 undervoltage threshold (Table 3)
[2]
1 = PO6 assertion depends on IN3 undervoltage threshold (Table 3)
[3]
1 = PO6 assertion depends on IN4 undervoltage threshold (Table 3)
[4]
1 = PO6 assertion depends on IN5 undervoltage threshold (Table 3)
[5]
1 = PO6 assertion depends on IN6 undervoltage threshold (Table 3)
[6]
1 = PO6 assertion depends on IN7 (MAX6890 only) undervoltage threshold (Table 3)
[7]
1 = PO6 assertion depends on IN8 (MAX6890 only) undervoltage threshold (Table 4)
[0]
1 = PO6 assertion depends on watchdog (Table 20)
[1]
1 = PO6 assertion depends on GPI1 (Table 5)
[2]
1 = PO6 assertion depends on GPI2 (Table 5)
[3]
1 = PO6 assertion depends on GPI3 (Table 5)
[4]
1 = PO6 assertion depends on GPI4 (Table 5)
[5]
1 = PO4 asserts when MR = low (Table 6)
[7:6]
Not used
Note: Table 12 only applies to PO6 (MAX6889/MAX6890 only). Write a “0” to a bit to make the PO6 output independent of the
respective signal (IN_ thresholds, WD, GPI_, or MR).
Table 13. PO7 (MAX6889/MAX6890 Only) Output Dependency
REGISTER
ADDRESS
1Ch
1Dh
EEPROM
MEMORY
ADDRESS
9Ch
9Dh
BIT
OUTPUT ASSERTION CONDITIONS
[0]
1 = PO7 assertion depends on IN1 undervoltage threshold (Table 2)
[1]
1 = PO7 assertion depends on IN2 undervoltage threshold (Table 3)
[2]
1 = PO7 assertion depends on IN3 undervoltage threshold (Table 3)
[3]
1 = PO7 assertion depends on IN4 undervoltage threshold (Table 3)
[4]
1 = PO7 assertion depends on IN5 undervoltage threshold (Table 3)
[5]
1 = PO7 assertion depends on IN6 undervoltage threshold (Table 3)
[6]
1 = PO7 assertion depends on IN7 (MAX6890 only) undervoltage threshold (Table 3)
[7]
1 = PO7 assertion depends on IN8 (MAX6890 only) undervoltage threshold (Table 4)
[0]
1 = PO7 assertion depends on watchdog (Table 20)
[1]
1 = PO7 assertion depends on GPI1 (Table 5)
[2]
1 = PO7 assertion depends on GPI2 (Table 5)
[3]
1 = PO7 assertion depends on GPI3 (Table 5)
[4]
1 = PO7 assertion depends on GPI4 (Table 5)
[5]
1 = PO7 asserts when MR = low (Table 6)
[7:6]
Not used
Note: Table 13 only applies to PO7 (MAX6889/MAX6890 only). Write a “0” to a bit to make the PO7 output independent of the
respective signal (IN_ thresholds, WD, GPI_, or MR).
22
______________________________________________________________________________________
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
REGISTER
ADDRESS
1Fh
20h
EEPROM
MEMORY
ADDRESS
9Fh
A0h
BIT
OUTPUT ASSERTION CONDITIONS
[0]
1 = PO8 assertion depends on IN1 undervoltage threshold (Table 2)
[1]
1 = PO8 assertion depends on IN2 undervoltage threshold (Table 3)
[2]
1 = PO8 assertion depends on IN3 undervoltage threshold (Table 3)
[3]
1 = PO8 assertion depends on IN4 undervoltage threshold (Table 3)
[4]
1 = PO8 assertion depends on IN5 undervoltage threshold (Table 3)
[5]
1 = PO8 assertion depends on IN6 undervoltage threshold (Table 3)
[6]
1 = PO8 assertion depends on IN7 (MAX6890 only) undervoltage threshold (Table 3)
[7]
1 = PO8 assertion depends on IN8 (MAX6890 only) undervoltage threshold (Table 4)
[0]
1 = PO8 assertion depends on watchdog (Table 20)
[1]
1 = PO8 assertion depends on GPI1 (Table 5)
[2]
1 = PO8 assertion depends on GPI2 (Table 5)
[3]
1 = PO8 assertion depends on GPI3 (Table 5)
[4]
1 = PO8 assertion depends on GPI4 (Table 5)
[5]
1 = PO8 asserts when MR = low (Table 6)
[7:6]
MAX6889/MAX6890/MAX6891
Table 14. PO8 (MAX6889/MAX6890 Only) Output Dependency
Not used
Note: Table 14 only applies to PO8 (MAX6889/MAX6890 only). Write a “0” to a bit to make the PO8 output independent of the
respective signal (IN_ thresholds, WD, GPI_, or MR).
Table 15. PO9 (MAX6889 Only) Output Dependency
REGISTER
ADDRESS
22h
23h
EEPROM
MEMORY
ADDRESS
A2h
A3h
BIT
OUTPUT ASSERTION CONDITIONS
[0]
1 = PO9 assertion depends on IN1 undervoltage threshold (Table 2)
[1]
1 = PO9 assertion depends on IN2 undervoltage threshold (Table 3)
[2]
1 = PO9 assertion depends on IN3 undervoltage threshold (Table 3)
[3]
1 = PO9 assertion depends on IN4 undervoltage threshold (Table 3)
[4]
1 = PO9 assertion depends on IN5 undervoltage threshold (Table 3)
[5]
1 = PO9 assertion depends on IN6 undervoltage threshold (Table 3)
[6]
1 = PO9 assertion depends on IN7 undervoltage threshold (Table 3)
[7]
1 = PO9 assertion depends on IN8 undervoltage threshold (Table 4)
[0]
1 = PO9 assertion depends on watchdog (Table 20)
[1]
1 = PO9 assertion depends on GPI1 (Table 5)
[2]
1 = PO9 assertion depends on GPI2 (Table 5)
[3]
1 = PO9 assertion depends on GPI3 (Table 5)
[4]
1 = PO9 assertion depends on GPI4 (Table 5)
[5]
1 = PO9 asserts when MR = low (Table 6)
[7:6]
Not used
Note: Table 15 only applies to PO9 (MAX6889 only). Write a “0” to a bit to make the PO9 output independent of the respective signal
(IN_ thresholds, WD, GPI_, or MR).
______________________________________________________________________________________
23
MAX6889/MAX6890/MAX6891
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
Table 16. PO10 (MAX6889 Only) Output Dependency
REGISTER
ADDRESS
25h
26h
EEPROM
MEMORY
ADDRESS
A5h
A6h
BIT
OUTPUT ASSERTION CONDITIONS
[0]
1 = PO10 assertion depends on IN1 undervoltage threshold (Table 2)
[1]
1 = PO10 assertion depends on IN2 undervoltage threshold (Table 3)
[2]
1 = PO10 assertion depends on IN3 undervoltage threshold (Table 3)
[3]
1 = PO10 assertion depends on IN4 undervoltage threshold (Table 3)
[4]
1 = PO10 assertion depends on IN5 undervoltage threshold (Table 3)
[5]
1 = PO10 assertion depends on IN6 undervoltage threshold (Table 3)
[6]
1 = PO10 assertion depends on IN7 undervoltage threshold (Table 3)
[7]
1 = PO10 assertion depends on IN8 undervoltage threshold (Table 4)
[0]
1 = PO10 assertion depends on watchdog (Table 20)
[1]
1 = PO10 assertion depends on GPI1 (Table 5)
[2]
1 = PO10 assertion depends on GPI2 (Table 5)
[3]
1 = PO10 assertion depends on GPI3 (Table 5)
[4]
1 = PO10 assertion depends on GPI4 (Table 5)
[5]
1 = PO10 asserts when MR = low (Table 6)
[7:6]
Not used
Note: Table 16 only applies to PO10 (MAX6890 only). Write a “0” to a bit to make the PO10 output independent of the respective signal (IN_ thresholds, WD, GPI_, or MR).
Table 17. Programmable Output Active States
REGISTER
ADDRESS
EEPROM
MEMORY
ADDRESS
0Ch
8Ch
[1]
PO1
0 = active-low, 1 = active-high
0Fh
8Fh
[1]
PO2
0 = active-low, 1 = active-high
12h
92h
[1]
PO3
0 = active-low, 1 = active-high
15h
95h
[1]
PO4
0 = active-low, 1 = active-high
18h
98h
[1]
PO5
0 = active-low, 1 = active-high
1Bh
9Bh
[1]
PO6
MAX6889/MAX6890 only. 0 = active-low, 1 = active-high.
1Eh
9Eh
[1]
PO7
MAX6889/MAX6890 only. 0 = active-low, 1 = active-high.
21h
A1h
[1]
PO8
MAX6889/MAX6890 only. 0 = active-low, 1 = active-high.
24h
A4h
[1]
PO9
MAX6889 only. 0 = active-low, 1 = active-high.
27h
A7h
[1]
PO10
MAX6889 only. 0 = active-low, 1 = active-high.
24
BIT
RANGE
AFFECTED
OUTPUT
DESCRIPTION
______________________________________________________________________________________
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
Weak Pullup Output Configuration
The MAX6889/MAX6890/MAX6891s’ programmable outputs
have a pullup resistance (10kΩ, typ) connected to the internal 2.55V LDO output to provide weak pullup outputs.
Open-Drain Output Configuration
Connect an external pullup resistor from the programmable output to an external voltage when configured as
an open-drain output. Open-drain configured outputs
may be pulled up to 13.2V. Choose the pullup resistor
depending on the number of devices connected to the
open-drain output and the allowable current consumption. The open-drain output configuration allows wireORed connections, and provides flexibility in setting the
pullup current.
Configuring the Watchdog Timer
(Registers 29h–2Ah)
A watchdog timer monitors microprocessor software
execution for a stalled condition and resets the microprocessor if it stalls. The output of the watchdog timer
(one of the programmable outputs) connects to the reset
input or a nonmaskable interrupt of the microprocessor.
Registers 29h–2Ah configure the watchdog functionality of the MAX6889/MAX6890/MAX6891. Program the
watchdog timer to assert one or more programmable
outputs (see Tables 7–16). Program the watchdog timer
to reset on one of the GPI_ inputs, one of the programmable outputs, or a combination of one GPI_ input and
one programmable output.
The watchdog timer features independent initial and
normal watchdog timeout periods. The initial watchdog
timeout period applies immediately after power-up,
after a software reboot, after a reset event takes place,
or after enabling the watchdog timer. The initial watchdog timeout period allows the microprocessor to per-
form its initialization process. If no pulse occurs during
the initial watchdog timeout period, the microprocessor
is taking too long to initialize, indicating a potential
problem.
The normal watchdog timeout period applies after the
initial watchdog timeout period occurs. The normal
watchdog timeout period monitors a pulsed output of
the microprocessor that indicates when normal processor behavior occurs. If no pulse occurs during the normal watchdog timeout period, this indicates that the
processor has stopped operating or is stuck in an infinite execution loop.
Register 2Ah programs the initial and normal watchdog
timeout periods, and enables or disables the watchdog
timer. See Tables 20 and 21 for a summary of the
watchdog behavior.
Configuration Lock
Lock the configuration register bank and configuration
EEPROM contents after initial programming by setting
the lock bit high (see Table 22). Locking the configuration prevents write operations to all registers except the
configuration lock register. Clear the lock bit to reconfigure the device.
Internal/External VCC Power
The MAX6889/MAX6890/MAX6891 can generate an
internal VCC, or VCC can be externally supplied (see
Table 22). To internally generate VCC from the highest
voltage on IN1–IN5 set register 2Eh and EEPROM
address AEh Bit[2] = 0. To use an externally supplied,
always-on V CC ensure register 2Eh and EEPROM
address AEh Bit[2] =1 (see the Powering the MAX6889/
MAX6890/MAX6891 section).
Write Disable
A unique write-disable feature protects the MAX6889/
MAX6890/MAX6891 from inadvertent user-EEPROM
writes. As input voltages that power the serial interface,
a microprocessor, or any other writing-devices fall,
unintentional data may be written onto the data bus.
The user-EEPROM write-disable function (see Table 23)
ensures that unintentional data does not corrupt the
MAX6889/MAX6890/MAX6891 EEPROM data.
______________________________________________________________________________________
25
MAX6889/MAX6890/MAX6891
Output Stage Configurations
Independently configure each programmable output as
active-high or active-low (Table 17). Additionally, configure each programmable output as open drain or weak
pullup (Table 18). Finally, set the PO_ timeout period for
each programmable output (Table 19). The programmable outputs can sink up to 4mA.
MAX6889/MAX6890/MAX6891
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
Table 18. Programmable Output Stage Options
REGISTER
ADDRESS
EEPROM
MEMORY
ADDRESS
0Ch
8Ch
[0]
PO1
0 = weak pullup, 1 = open drain
0Fh
8Fh
[0]
PO2
0 = weak pullup, 1 = open drain
12h
92h
[0]
PO3
0 = weak pullup, 1 = open drain
15h
95h
[0]
PO4
0 = weak pullup, 1 = open drain
18h
98h
[0]
PO5
0 = weak pullup, 1 = open drain
1Bh
9Bh
[0]
PO6
MAX6889/MAX6890 only. 0 = weak pullup, 1 = open drain.
BIT
RANGE
AFFECTED
OUTPUT
DESCRIPTION
1Eh
9Eh
[0]
PO7
MAX6889/MAX6890 only. 0 = weak pullup, 1 = open drain.
21h
A1h
[0]
PO8
MAX6889/MAX6890 only. 0 = weak pullup, 1 = open drain.
24h
A4h
[0]
PO9
MAX6889 only. 0 = weak pullup, 1 = open drain.
27h
A7h
[0]
PO10
MAX6889 only. 0 = weak pullup, 1 = open drain.
Table 19. PO_ Timeout Periods
REGISTER
ADDRESS
EEPROM
MEMORY
ADDRESS
0Ch
8Ch
[4:2]
PO1
0Fh
8Fh
[4:2]
PO2
12h
92h
[4:2]
PO3
15h
95h
[4:2]
PO4
18h
98h
[4:2]
PO5
1Bh
9Bh
[4:2]
PO6 (MAX6889/MAX6890)
26
BIT
RANGE
AFFECTED OUTPUTS
1Eh
9Eh
[4:2]
PO7 (MAX6889/MAX6890)
21h
A1h
[4:2]
PO8 (MAX6889/MAX6890)
24h
A4h
[4:2]
PO9 (MAX6889 only)
27h
A7h
[4:2]
PO10 (MAX6889 only)
DESCRIPTION
000 = 25µs
001 = 1.5625ms
010 = 6.25ms
011 = 25ms
100 = 50ms
101 = 200ms
110 = 400ms
111 = 1600ms
______________________________________________________________________________________
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
MAX6889/MAX6890/MAX6891
Table 20. Watchdog Inputs
REGISTER
ADDRESS
29h
EEPROM
MEMORY
ADDRESS
A9h
BIT
RANGE
DESCRIPTION
[1:0]
Watchdog Input Selection:
00 = GPI1 input
01 = GPI2 input
10 = GPI3 input
11 = GPI4 input (MAX6889/MAX6890 only). Selects GPI3 on MAX6891.
[5:2]
Watchdog Internal Input Selection:
0000 = PO1
0001 = PO2
0010 = PO3
0011 = PO4
0100 = PO5
0101 = PO6 (MAX6889/MAX6890 only)
0110 = PO7 (MAX6889/MAX6890 only)
0111 = PO8 (MAX6889/MAX6890 only)
1000 = PO9 (MAX6889 only)
1001 = PO10 (MAX6889 only)
[1011] to [1111] = WD is not affected by PO_
[7:6]
Watchdog Dependency on Inputs:
00 = Watchdog not dependent on any input
01 = Watchdog clear depends on selected GPI_ input only
01 = Watchdog clear depends on selected PO_ input only
11 = Watchdog clear depends on both selected GPI_ and PO_ inputs
______________________________________________________________________________________
27
MAX6889/MAX6890/MAX6891
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
Table 21. Watchdog Timeout Period Selection
REGISTER
ADDRESS
2Ah
EEPROM
MEMORY
ADDRESS
BIT
RANGE
DESCRIPTION
[2:0]
Normal Watchdog Timeout Period:
000 = 6.25ms
001 = 25ms
010 = 100ms
011 = 400ms
100 = 1.6s
101 = 6.4s
110 = 25.6s
111 = 102.4s
[5:3]
Initial Watchdog Timeout Period (immediately following power-up, reset event, or enabling
watchdog):
000 = 6.25ms
001 = 25ms
010 = 100ms
011 = 400ms
100 = 1.6s
101 = 6.4s
110 = 25.6s
111 = 102.4s
AAh
[6]
Watchdog Enable
0 = Disables watchdog timer
1 = Enables watchdog timer
[7]
Not used
Table 22. Configuration Lock and Internal/External VCC Power Register
REGISTER
ADDRESS
2Eh
EEPROM
MEMORY
ADDRESS
BIT
RANGE
[0]
0 = Configuration unlocked
1 = Configuration locked
[1]
Not used
[2]
Internal/External VCC Power:
0 = VCC internally generated
1 = VCC externally supplied
AEh
[7:3]
28
DESCRIPTION
Not used
______________________________________________________________________________________
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
MAX6889/MAX6890/MAX6891
Table 23. Write Disable Register
REGISTER
ADDRESS
2Ch
2Dh
EEPROM
MEMORY
ADDRESS
BIT
RANGE
DESCRIPTION
[0]
0 = Write is not disabled if PO1 asserts
1 = Write disabled if PO1 asserts
[1]
0 = Write is not disabled if PO2 asserts
1 = Write disabled if PO2 asserts
[2]
0 = Write is not disabled if PO3 asserts
1 = Write disabled if PO3 asserts
[3]
0 = Write is not disabled if PO4 asserts
1 = Write disabled if PO4 asserts
[4]
0 = Write is not disabled if PO5 asserts
1 = Write disabled if PO5 asserts
[5]
0 = Write is not disabled if PO6 asserts
1 = Write disabled if PO6 asserts
[6]
0 = Write is not disabled if PO7 asserts
1 = Write disabled if PO7 asserts
[7]
0 = Write is not disabled if PO8 asserts
1 = Write disabled if PO8 asserts
[0]
0 = Write is not disabled if PO9 asserts
1 = Write disabled if PO9 asserts
[1]
0 = Write is not disabled if PO10 asserts
1 = Write disabled if PO10 asserts
ACh
ADh
[7:2]
Not used
Configuring the
MAX6889/MAX6890/MAX6891
The MAX6889/MAX6890/MAX6891 factory-default configuration sets all registers to 0h, except bits in Tables
17 and 18, which are set to 1h. Factory-default configuration sets all PO_’s as active-high, open drain (all outputs are high impedance until the device is configured
by the user). Each device requires configuration before
full power is applied to the system. To configure the
MAX6889/MAX6890/MAX6891, first apply an input voltage to IN1, or one of IN2–IN5 or VCC (see the Powering
the MAX6889/MAX6890/MAX6891 section). VIN1 > 4V,
or one of VIN2–VIN5 or VCC > 2.7V to ensure device
operation. Next, transmit data through the serial interface. Use the block write protocol to quickly configure
the device. Write to the configuration registers first to
ensure the device is configured properly. After completing the setup procedure, use the read word or
block read protocol to read back the data from the configuration registers. Lastly, use the write byte or block
write protocol to write this data to the EEPROM registers. After completing the EEPROM register configuration, apply full power to the system to begin normal
operation. The nonvolatile EEPROM stores the latest
configuration upon removal of power. Write 0s to all
EEPROM registers to clear the memory.
Software Reboot
A software reboot allows the user to restore the EEPROM
configuration to the volatile registers without cycling the
power supplies. Use the send byte command with data
byte C4h to initiate a software reboot. The 3ms (max)
power-up delay also applies after a software reboot.
Configuration EEPROM
The configuration EEPROM addresses range from 80h
to AEh. Write data to the configuration EEPROM to automatically set up the MAX6889/MAX6890/MAX6891 upon
power-up. Data is transferred from the configuration
EEPROM to the configuration registers when V CC
exceeds UVLO during power-up or after a software
______________________________________________________________________________________
29
MAX6889/MAX6890/MAX6891
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
User EEPROM
reboot. After VCC exceeds UVLO, an internal 1MHz
clock starts after a 5µs delay, and data transfer begins.
Data transfer disables access to the configuration registers and EEPROM. The data transfer from EEPROM to
configuration registers takes 3ms (max). Read configuration EEPROM data at any time after power-up or software reboot. Write commands to the configuration
EEPROM are allowed at any time after power-up or software reboot, unless the configuration lock bit is set (see
Table 22). The maximum cycle time to write a single
byte is 11ms (max).
The 512-bit, user-EEPROM addresses range from 40h to
7Fh (see Figure 2). Store software revision data, board
revision data, and other data in these registers. The maximum cycle time to write a single byte is 11ms (max).
Configuration Register Bank and EEPROM
The configuration registers can be directly modified
through the serial interface without modifying the
EEPROM, after the power-up procedure terminates and
the configuration EEPROM data has been loaded into the
configuration register bank. Use the write byte or block
write protocols to write directly to the configuration registers. Changes to the configuration registers take effect
immediately and are lost upon power removal.
At device power-up, the register bank loads configuration data from the EEPROM. Configuration data may be
directly altered in the register bank during application
development, allowing maximum flexibility. Transfer the
new configuration data byte-by-byte to the configuration EEPROM with the write byte protocol. The next
device power-up or software reboot automatically loads
the new configuration.
00h
REGISTER BANK
37h
RESERVED
40h
USER EEPROM
SMBus/I2C-Compatible Serial Interface
The MAX6889/MAX6890/MAX6891 feature an I2C/SMBuscompatible 2-wire serial interface consisting of a serial
data line (SDA) and a serial clock line (SCL). SDA and
SCL facilitate bidirectional communication between the
MAX6889/MAX6890/MAX6891 and the master device at
clock rates up to 400kHz. Figure 3 shows the 2-wire interface timing diagram. The MAX6889/MAX6890/MAX6891
are transmit/receive slave-only devices, relying upon a
7Fh
80h
CONFIGURATION
EEPROM
AEh
Figure 2. Memory Map
SDA
tBUF
tSU:DAT
tSU:STA
tHD:DAT
tLOW
tHD:STA
tSU:STO
SCL
tHIGH
tHD:STA
tR
tF
START
CONDITION
REPEATED START
CONDITION
STOP
CONDITION
Figure 3. Serial-Interface Timing Details
30
______________________________________________________________________________________
START
CONDITION
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
SCL is a logic input, while SDA is an open-drain
input/output. SCL and SDA both require external pullup
resistors to generate the logic-high voltage. Use 4.7kΩ
resistors for most applications.
Bit Transfer
Each clock pulse transfers one data bit. The data on
SDA must remain stable while SCL is high (Figure 4),
otherwise the MAX6889/MAX6890/MAX6891 register a
START or STOP condition (Figure 5) from the master.
SDA and SCL idle high when the bus is not busy.
Start and Stop Conditions
A master device signals the beginning of a transmission
with a START (S) condition (Figure 5) by transitioning
SDA from high to low while SCL is high. The master
device issues a STOP (P) condition (Figure 5) by transitioning SDA from low to high while SCL is high. A STOP
condition frees the bus for another transmission. The bus
remains active if a REPEATED START condition is generated, such as in the read byte or block read protocol
(see Figure 8). Both SCL and SDA are high when the bus
is not busy.
SDA
Early STOP Conditions
The MAX6889/MAX6890/MAX6891 recognize a STOP
condition at any point during transmission except if a
STOP condition occurs in the same high pulse as a
START condition. This condition is not a legal I2C format. At least one clock pulse must separate any START
and STOP condition.
Repeated START Conditions
A REPEATED START (SR) condition may indicate a
change of data direction on the bus. Such a change
occurs when a command word is required to initiate a
read operation (see Figure 8). SR may also be used
when the bus master is writing to several I2C devices
and does not want to relinquish control of the bus. The
MAX6889/MAX6890/MAX6891 serial interface supports
continuous write operations with or without an SR condition separating them. Continuous read operations
require SR conditions because of the change in direction
of data flow.
Acknowledge
The acknowledge bit (ACK) is the 9th bit attached to any
8-bit data word. The receiving device always generates
an ACK. The MAX6889/MAX6890/MAX6891 generate an
ACK when receiving an address or data by pulling SDA
low during the 9th clock period (Figure 6). When transmitting data, such as when the master device reads data
back from the MAX6889/MAX6890/MAX6891, the
MAX6889/MAX6890/MAX6891 wait for the master device
to generate an ACK. Monitoring ACK allows for detection
of unsuccessful data transfers. An unsuccessful data
transfer occurs if the receiving device is busy or if a system fault has occurred. In the event of an unsuccessful
SDA
SCL
SCL
DATA LINE STABLE, CHANGE OF
DATA ALLOWED
DATA VALID
Figure 4. Bit Transfer
S
P
START
CONDITION
STOP
CONDITION
Figure 5. Start and Stop Conditions
______________________________________________________________________________________
31
MAX6889/MAX6890/MAX6891
master device to generate a clock signal. The master
device (typically a microcontroller) generates SCL and initiates data transfer on the bus.
A master device communicates to the MAX6889/
MAX6890/MAX6891 by transmitting the proper address
followed by command and/or data words. Each transmit sequence is framed by a START (S) or REPEATED
START (SR) condition and a STOP (P) condition. Each
word transmitted over the bus is 8 bits long and is
always followed by an acknowledge pulse.
MAX6889/MAX6890/MAX6891
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
data transfer, the bus master should reattempt communication at a later time. The MAX6889/MAX6890/
MAX6891 generate a NACK after the command byte
during a software reboot, while writing to the EEPROM,
or when receiving an illegal memory address.
Slave Address
SA7 through SA4 represent the standard 2-wire interface address (1010) for devices with EEPROM. SA3
and SA2 correspond to the A1 and A0 address inputs
of the MAX6889/MAX6890/MAX6891 (hardwired as
logic-low or logic-high). SA0 is a read/write flag bit (0 =
write, 1 = read).
The A0 and A1 address inputs allow up to four
MAX6889/MAX6890 to connect to one bus, while the
A0 address input allows up to two MAX6891s to con-
nect to one bus. Connect A0 and A1 to GND or to the
2-wire serial-interface power supply (see Figure 7).
The MAX6889/MAX6890 slave address conforms to the
following table:
SA7 (MSB) SA6 SA5 SA4 SA3 SA2 SA1 SA0 (LSB)
1
0
1
0
A1
A0
X
X = Don’t Care
The MAX6891 slave address conforms to the following
table:
SA7 (MSB) SA6 SA5 SA4 SA3 SA2 SA1 SA0 (LSB)
1
0
1
0
0
A0
X
X = Don’t Care
START
CONDITION
CLOCK PULSE FOR ACKNOWLEDGE
2
1
SCL
8
9
SDA BY
TRANSMITTER
S
SDA BY
RECEIVER
Figure 6. Acknowledge
SDA
START
1
MSB
0
1
0
A1
A0
X
R/W
LSB
SCL
Figure 7. Slave Address
32
R/W
______________________________________________________________________________________
ACK
R/W
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
1) The master sends a Start condition.
2) The master sends the 7-bit slave address and a
write bit (low).
3) The addressed slave asserts an ACK on SDA.
4) The master sends an 8-bit data byte.
5) The addressed slave asserts an ACK on SDA.
6) The master sends a Stop condition.
Write Byte
The write byte protocol allows the master device to write
a single byte in the register bank or in the EEPROM
(configuration or user) (see Figure 8). The Write Byte
procedure follows:
1) The master sends a Start condition.
2) The master sends the 7-bit slave address and a
write bit (low).
3) The addressed slave asserts an ACK on SDA.
4) The master sends an 8-bit command code.
5) The addressed slave asserts an ACK on SDA.
6) The master sends an 8-bit data byte.
7) The addressed slave asserts an ACK on SDA.
8) The master sends a Stop condition.
In order to write a single byte to the register bank, only
the 8-bit command code and a single 8-bit data byte
are sent. The command code must be in the range of
00h to 2Eh. The data byte is written to the register bank
if the command code is valid. The slave generates a
NACK at step 5 if the command code is invalid or any
internal operations are ongoing.
In order to write a single byte of data to the user or configuration EEPROM, the 8-bit command code and a single 8-bit data byte are sent. The following 8-bit data
byte is written to the addressed EEPROM location.
Block Write
The block write protocol allows the master device to
write a block of data (1 to 16 bytes) to the EEPROM or
to the register bank (see Figure 8). The destination
address must already be set by the send byte protocol
and the command code must be C0h. If the number of
bytes to be written causes the address pointer to
exceed 2Fh for the configuration register or B7h for the
configuration EEPROM, the address pointer stops
incrementing, overwriting the last memory address with
the remaining bytes of data. Only the last data byte
sent is stored in B7h (as 2Fh is read only and a write
causes no change in the content). If the number of
bytes to be written exceeds the address pointer 7Fh for
the user EEPROM, the address pointer stops incrementing and continues writing exceeding data to the
last address. Only the last data is actually written to
7Fh. The block write procedure follows:
1) The master sends a Start condition.
2) The master sends the 7-bit slave address and a
write bit (low).
3) The addressed slave asserts an ACK on SDA.
4) The master sends the 8-bit command code for
block write (C0h).
5) The addressed slave asserts an ACK on SDA.
6) The master sends the 8-bit byte count (1 to 16
bytes) N.
7) The addressed slave asserts an ACK on SDA.
8) The master sends 8 bits of data.
9) The addressed slave asserts an ACK on SDA.
10) Repeat steps 8 and 9 N – 1 times.
11) The master generates a Stop condition.
______________________________________________________________________________________
33
MAX6889/MAX6890/MAX6891
Send Byte
The send byte protocol allows the master device to
send one byte of data to the slave device (see Figure
8). The send byte presets a register pointer address for
a subsequent read or write. The slave sends a NACK
instead of an ACK if the master tries to send an
address that is not allowed or if the device is writing
data to EEPROM or is booting. If the master sends C0h,
the data is ACK. This could be the start of the block
write protocol, and the slave expects the following data
bytes. If the master sends a Stop condition, the internal
address pointer does not change. If the master sends
C1h, this signifies that the block read protocol is
expected, and a repeated Start condition should follow.
The device reboots if the master sends C4h. The send
byte procedure follows:
MAX6889/MAX6890/MAX6891
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
Read Byte
The read byte protocol allows the master device to
read the register or an EEPROM location (user or configuration) content of the MAX6889/MAX6890/MAX6891
(see Figure 8). The read byte procedure follows:
1) The master sends a Start condition.
2) The master sends the 7-bit slave address and a
write bit (low).
3) The addressed slave asserts an ACK on the data
line.
4) The master sends 8 data bits.
5) The active slave asserts an ACK on the data line.
6) The master sends a repeated Start condition.
7) The master sends the 7-bit slave ID plus a read bit
(high).
8) The addressed slave asserts an ACK on the data
line.
9) The slave sends 8 data bits.
10) The master asserts a NACK on the data line
11) The master generates a Stop condition.
Note that once the read has been done, the internal
pointer is increased by one, unless a memory boundary
is hit.
If the device is busy or if the address is not an allowed
one, the command code is NACKed and the internal
address pointer is not altered. The master must then
interrupt the communication issuing a STOP condition.
Block Read
The block read protocol allows the master device to read
a block of 16 bytes from the EEPROM or register bank
(see Figure 8). Read fewer than 16 bytes of data by issuing an early STOP condition from the master, or by generating a NACK with the master. Previous actions through
the serial interface predetermines the first source
address. It is suggested to use a send byte protocol,
before the block read, to set the initial read address. The
block read protocol is initiated with a command code of
C1h. The block read procedure follows:
1) The master sends a Start condition.
2) The master sends the 7-bit slave address and a
write bit (low).
3) The addressed slave asserts an ACK on SDA.
34
4) The master sends 8 bits of the block read command (C1h).
5) The slave asserts an ACK on SDA, unless busy.
6) The master generates a repeated Start condition.
7) The master sends the 7-bit slave address and a
read bit (high).
8) The slave asserts an ACK on SDA.
9) The slave sends the 8-bit byte count (16).
10) The master asserts an ACK on SDA.
11) The slave sends 8 bits of data.
12) The master asserts an ACK on SDA.
13) Repeat steps 8 and 9 15 times.
14) The master generates a Stop condition.
Address Pointers
Use the send byte protocol to set the register address
pointers before read and write operations. For the configuration registers, valid address pointers range from
00h to 2Fh. Register addresses outside of this range
result in a NACK being issued from the MAX6889/
MAX6890/MAX6891. When using the block write protocol, the address pointer automatically increments after
each data byte, except when the address pointer is
already at 2Fh. If the address pointer is already 2Fh,
and more data bytes are being sent, these subsequent
bytes overwrite address 2Fh repeatedly. No data will
be left in 2Fh as this is a read-only address.
For the configuration EEPROM, valid address pointers
range from 80h to B7h (even if they are only meaningful
up to AEh). When using the block write protocol, the
address pointer automatically increments after each
data byte, except when the address pointer is already
at B7h. If the address pointer is already B7h, and more
data bytes are being sent, these subsequent bytes
overwrite address B7h repeatedly, leaving only the last
sent data byte stored at this register address.
For the user EEPROM, valid address pointers range
from 40h to 7Fh. As for the configuration EEPROM,
block write and block read protocols can also be used.
The internal address pointer will auto-increment up to
the user-EEPROM boundary 7Fh where the pointer will
stop incrementing. When writing, only the last data written will be stored in 7Fh.
______________________________________________________________________________________
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
S
MAX6889/MAX6890/MAX6891
SEND BYTE FORMAT
READ BYTE FORMAT
ADDRESS
WR
7 bits
0
ACK
DATA
ACK
P
S
ADDRESS
8 bits
Slave Address–
equivalent to chipselect line of a 3wire interface.
WR
7 bits
Data Byte–presets the
internal address pointer
or represents a command.
ACK
DATA
ACK
SR
ADDRESS
WR
7 bits
1
8 bits
0
Slave Address–
equivalent to chipselect line of a
3-wire interface.
Data Byte—presets
the internal address
pointer.
ACK
DATA
ACK
P
8 bits
Data Byte–data read
from the preset register
(or EEPROM) address.
Slave Address—
equivalent to chipselect line of a
3-wire interface.
WRITE BYTE FORMAT
S
ADDRESS
WR
7 bits
0
ACK
COMMAND
ACK
DATA
8 bits
Slave Address–
equivalent to chipselect line of a 3wire interface.
ACK
P
8 bits
Command Byte–
selects register
EEPROM location you
are writing to.
Data Byte–data goes into the
register (or EEPROM location)
set by the command byte.
BLOCK WRITE FORMAT
S
ADDRESS
WR
ACK
0
7 bits
BYTE
COUNT= N
COMMAND ACK
DATA BYTE
1
8 bits
C0h
Slave Address–
equivalent to chipselect line of a 3wire interface.
ACK
ACK
DATA BYTE
...
8 bits
Command Byte–
prepares device
for block
write operation.
ACK
DATA BYTE
N
8 bits
ACK
P
8 bits
Data Byte–first data goes into the address preset
with a previous "Set Address" and the following data
in the following locations.
BLOCK READ FORMAT
S
ADDRESS
WR
7 bits
0
Slave Address–
equivalent to chipselect line of a 3wire interface.
S = Start condition.
P = Stop condition.
ACK
COMMAND
ACK
SR
C1h
Command Byte–
prepares device
for block
operation.
ADDRESS
WR
7 bits
1
Slave Address–
equivalent to chipselect line of a 3wire interface.
BYTE
COUNT = N
ACK
8 bits
ACK
DATA BYTE
ACK
1
8 bits
DATA BYTE
...
8 bits
ACK
DATA BYTE
ACK
N
P
8 bits
Data Byte–data comes from the address set by a
previous "send byte".
Shaded = Slave transmission.
SR = Repeated start condition.
Figure 8. SMBus/I2C Protocols
Applications Information
Configuration Download at Power-up
The configuration of the MAX6889/MAX6890/MAX6891
(undervoltage thresholds, PO_ timeout periods, watchdog behavior, programmable output conditions and
configurations, etc.) depends on the contents of the
EEPROM. The EEPROM is comprised of buffered latches that store the configuration. The local volatile memory latches lose their contents at power-down. Therefore,
at power-up, the device configuration must be restored
by downloading the contents of the EEPROM (non-
volatile memory) to the local latches. This download
occurs in a number of steps:
1) Programmable outputs go high impedance with no
power applied to the device.
2) When VCC exceeds 1V, all programmable outputs are
weakly pulled to GND through a 10µA current sink.
3) When V CC exceeds UVLO, the configuration
EEPROM starts to download its contents to the
volatile configuration registers. The programmable
outputs assume their programmed conditional output state when VCC exceeds UVLO.
______________________________________________________________________________________
35
MAX6889/MAX6890/MAX6891
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
4) Any attempt to communicate with the device prior to
this download completion results in a NACK being
issued from the MAX6889/MAX6890/MAX6891.
Forcing Programmable Outputs High
During Power-up
A weak, 10µA pulldown current holds all programmable
outputs low during power-up until VCC exceeds the
undervoltage-lockout (UVLO) threshold. Applications
requiring a guaranteed high programmable output for
VCC down to GND require external pullup resistors to
maintain the logic state until VCC exceeds UVLO. Use
20kΩ resistors for most applications.
Uses for General-Purpose Inputs (GPI_)
Watchdog Timer
Program GPI_ as an input to the watchdog timer in the
MAX6889/MAX6890/MAX6891. The GPI_ input must
toggle within the watchdog timeout period; otherwise
any programmable output dependent on the watchdog
timer will assert.
Additional Manual Reset Functions
The programmable outputs allow a set of conditions to
assert the output. Program the set of conditions to
depend on one of the GPI_ inputs. Any output that
depends on GPI_ asserts when GPI_ is held in its
active state, effectively acting as a manual reset input.
Other Fault Signals from µC
Connect a general-purpose output from a µC to one of
the GPI_ inputs to allow interrupts to assert any output
of the MAX6889/MAX6890/MAX6891. Configure one of
the programmable outputs to assert on whichever GPI_
input connects to the general-purpose output of the µC.
Layout and Bypassing
For better noise immunity, bypass each of the voltage
detector inputs to GND with 0.1µF capacitors installed
as close to the device as possible. Bypass VCC and
DBP to GND with 1µF capacitors installed as close to the
device as possible. VCC (when not externally supplied)
and DBP are internally generated voltages and should
not be used to supply power to external circuitry.
Configuration Latency Period
A delay of less than 5µs occurs between writing to the
configuration registers and the time when these
changes actually take place, unless when changing
one of the voltage detector’s thresholds. Changing a
voltage detector threshold typically takes 150µs. When
changing EEPROM contents, a software reboot or
cycling of power is required for these changes to transfer to volatile memory.
Chip Information
PROCESS: BiCMOS
Register Map
REGISTER
ADDRESS
EEPROM
MEMORY
ADDRESS
READ/
WRITE
00h
80h
R/W
IN1 undervoltage detector threshold (Table 2)
01h
81h
R/W
IN2 undervoltage detector threshold (Table 3)
02h
82h
R/W
IN3 undervoltage detector threshold (Table 3)
03h
83h
R/W
IN4 undervoltage detector threshold (Table 3)
04h
84h
R/W
IN5 undervoltage detector threshold (MAX6889/MAX6890 only) (Table 3)
05h
85h
R/W
IN6 undervoltage detector threshold (MAX6889/MAX6890 only) (Table 3)
06h
86h
R/W
IN7 undervoltage detector threshold (MAX6889 only) (Table 3)
07h
87h
R/W
IN8 undervoltage detector threshold (MAX6889 only) (Table 4)
08h
88h
R/W
Threshold range selection (Tables 2, 3, and 4)
09h
89h
R/W
High-Z mode selection (Tables 2, 3, and 4)
0Ah
8Ah
R/W
PO1 input selection (Table 7)
0Bh
8Bh
R/W
PO1 input selection (Table 7)
0Ch
8Ch
R/W
PO1 timeout period, programmable output polarity, and output type selection
(Tables 17, 18, and 19)
0Dh
8Dh
R/W
PO2 input selection (Table 8)
0Eh
8Eh
R/W
PO2 input selection (Table 8)
36
DESCRIPTION
______________________________________________________________________________________
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
MAX6889/MAX6890/MAX6891
Register Map (continued)
REGISTER
ADDRESS
EEPROM
MEMORY
ADDRESS
READ/
WRITE
0Fh
8Fh
R/W
PO2 timeout period and output type selection (Tables 17, 18, and 19)
10h
90h
R/W
PO3 input selection (Table 9)
11h
91h
R/W
PO3 input selection (Table 9)
12h
92h
R/W
PO3 timeout period and output type selection (Tables 17, 18, and 19)
13h
93h
R/W
PO4 input selection (Table 10)
14h
94h
R/W
PO4 input selection (Table 10)
15h
95h
R/W
PO4 timeout period and output type selection (Tables 17, 18, and 19)
16h
96h
R/W
PO5 input selection (Table 11)
17h
97h
R/W
PO5 input selection (Table 11)
18h
98h
R/W
PO5 timeout period and output type selection (Tables 17, 18, and 19)
19h
99h
R/W
PO6 (MAX6889/MAX6890) input selection (Table 12)
1Ah
9Ah
R/W
PO6 (MAX6889/MAX6890) input selection (Table 12)
1Bh
9Bh
R/W
PO6 (MAX6889/MAX6890) timeout period and output type selection (Tables 17, 18, and 19)
1Ch
9Ch
R/W
PO7 (MAX6889/MAX6890) input selection (Table 13)
1Dh
9Dh
R/W
PO7 (MAX6889/MAX6890) input selection (Table 13)
1Eh
9Eh
R/W
PO7 (MAX6889/MAX6890) timeout period and output type selection (Tables 17, 18, and 19)
1Fh
9Fh
R/W
PO8 (MAX6889/MAX6890) input selection (Table 14)
20h
A0h
R/W
PO8 (MAX6889/MAX6890) input selection (Table 14)
21h
A1h
R/W
PO8 (MAX6889/MAX6890) timeout period and output type selection (Tables 17, 18, and 19)
22h
A2h
R/W
PO9 (MAX6889 only) input selection (Table 15)
23h
A3h
R/W
PO9 (MAX6889 only) input selection (Table 15)
24h
A4h
R/W
PO9 (MAX6889 only) timeout period and output type selection (Tables 17, 18, and 19)
25h
A5h
R/W
PO10 (MAX6889 only) input selection (Table 16)
26h
A6h
R/W
PO10 (MAX6889 only) input selection (Table 16)
27h
A7h
R/W
PO10 (MAX6889 only) timeout period and output type selection (Tables 17, 18, and 19)
28h
A8h
R/W
GPI_ input polarity selection
WD input selection and clear dependency (Table 20)
DESCRIPTION
29h
A9h
R/W
2Ah
AAh
R/W
2Bh
ABh
—
2Ch
ACh
R/W
2Dh
ADh
R/W
User EEPROM write disable (Table 23)
2Eh
AEh
R/W
Configuration lock and internal/external VCC power (Table 22)
WD initial and normal timeout duration and disable (Table 21)
Reserved. Should not be overwritten.
User EEPROM write disable (Table 23)
______________________________________________________________________________________
37
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
IN1
IN2
IN3
IN4
IN5
IN6
PO1
N.C.
IN1
IN2
IN3
IN4
IN5
TOP VIEW
N.C.
32
31
30
29
28
27
26
25
28
27
26
25
24
23
22
PO2
1
24
IN7
PO3
2
23
IN8
PO4
3
22
DBP
GND
4
21
VCC
PO5
5
20
GPI1
PO6
6
19
GPI2
PO7
7
18
PO8
8
17
16
MR
SDA
SCL
A0
A1
DBP
PO4
3
19
VCC
GND
4
18
GPI1
PO5
5
17
GPI2
GPI3
PO6
6
16
GPI3
GPI4
PO7
7
15
GPI4
MAX6890
*EXPOSED PAD
8
9
10
11
12
13
14
A1
15
20
A0
14
2
SCL
13
PO3
SDA
12
IN6
MR
11
21
PO8
10
MARGIN
PO9
9
PO10
*EXPOSED PAD
1
MARGIN
MAX6889
PO2
IN2
IN3
IN4
TOP VIEW
IN1
(5mm x 5mm THIN QFN)
*EXPOSED PAD INTERNALLY CONNECTED TO GND.
PO1
(5mm x 5mm THIN QFN)
*EXPOSED PAD INTERNALLY CONNECTED TO GND.
20
19
18
17
16
PO2
1
15
DBP
PO3
2
14
VCC
PO4
3
13
GPI1
GND
4
12
GPI2
PO5
5
11
GPI3
MAX6891
7
8
9
10
SCL
A0
MARGIN
6
SDA
*EXPOSED PAD
MR
TOP VIEW
PO1
MAX6889/MAX6890/MAX6891
Pin Configurations
(5mm x 5mm THIN QFN)
*EXPOSED PAD INTERNALLY CONNECTED TO GND.
38
______________________________________________________________________________________
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
12V
12V
DC-DC
1
5V
DC-DC
3
DC-DC
2
3.3V
2.5V
RPU
IN1
PO1
IN2
PO2
MARGIN
SDA
MR
VCC
MAX6891
DBP
GND
12V SUPPLY
GPI2
SDA
SCL
SCL
PO4
RESET
PO5
GPI1
(WD)
A0
NMI, WD ALERT
LOGIC OUTPUT
GPI3
12V BUS INPUT
tPO1
PO1
µP
IN4
PO3
IN3
RPU
ENABLE 5V DC-DC CONVERTER
5V SUPPLY
5V OUTPUT
tPO2
PO2
ENABLE 2.5V DC-DC CONVERTER
2.5V SUPPLY
2.5V OUTPUT
tPO3
PO3
3.3V SUPPLY
PO4
ENABLE 3.3V DC-DC CONVERTER
3.3V OUTPUT
tPO4
SYSTEM RESET
Package Information
For the latest package outline information and land patterns, go to www.maxim-ic.com/packages.
PACKAGE TYPE
PACKAGE CODE
DOCUMENT NO.
20 TQFN
T2055-5
21-0140
28 TQFN
T2855-8
21-0140
32 TQFN
T3255-4
21-0140
______________________________________________________________________________________
39
MAX6889/MAX6890/MAX6891
Typical Operating Circuit
MAX6889/MAX6890/MAX6891
EEPROM-Programmable, Octal/Hex/Quad,
Power-Supply Sequencers/Supervisors
Revision History
PAGES
CHANGED
REVISION
NUMBER
REVISION
DATE
0
2/05
Initial release
—
1
9/08
Added specifications to Electrical Characteristics.
4
DESCRIPTION
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.
40 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 2008 Maxim Integrated Products
is a registered trademark of Maxim Integrated Products, Inc.