MAXIM MAX11080GUU+

19-4584; Rev 0; 5/09
12-Channel, High-Voltage Battery-Pack
Fault Monitor
The MAX11080 is a battery-pack fault-monitor IC capable of monitoring up to 12 lithium-ion (Li+) battery
cells. This device is designed to provide an overvoltage or undervoltage fault indication when any of the
cells cross the user-selectable threshold for longer
than the set program-delay interval. The overvoltage
levels are pin selectable from +3.3V to +4.8V in 100mV
increments, and have a guaranteed accuracy of
±25mV over the entire temperature range. The undervoltage level is also user selectable from +1.6V to
+2.8V in 200mV increments. These levels are guaranteed to ±100mV over the entire temperature range.
Undervoltage detection can be disabled as one of the
user-configuration options.
The MAX11080 has a built-in level-shifter that allows up
to 31 MAX11080 devices to be connected in a daisychain fashion to reduce the number of interface signals
needed for large stacks of series batteries. Each cell is
monitored differentially and compared to the overvoltage and undervoltage thresholds. When any of the cells
exceed this threshold for longer than the set program
delay interval, the MAX11080 inhibits the heartbeat signal from being passed down the daisy chain. Built-in
comparator hysteresis prevents threshold chattering.
The MAX11080 is designed to be the perfect complement to the MAX11068 high-voltage measurement IC
for redundant fault-monitoring applications. This device
is offered in a 9.7mm x 4.4mm, 38-pin TSSOP package
with 0.5mm pin spacing. The package is lead-free and
RoHS compliant with an extended operating temperature range of -40°C to +105°C.
Applications
High-Voltage, Multicell-Series-Stacked Battery
Systems
Electric Vehicles
Features
o Up to 12-Cell Li+ Battery Voltage Fault Detection
o Operation from 6.0V to 72V
o Pin-Selectable Overvoltage Threshold from +3.3V
to +4.8V in 100mV Increments
±25mV Overvoltage-Detection Accuracy
o Pin-Selectable Undervoltage Threshold from
+1.6V to +2.8V in 200mV Increments
±100mV Undervoltage-Detection Accuracy
o 300mV Over/Undervoltage-Threshold Detection
Hysteresis
o Programmable Delay Time of Alarm Detection
from 3.0ms to 3.32s with an External Capacitor
o Daisy-Chained Alarm and Shutdown Functions
with Heartbeat Status Signal
Up to 31 Devices Can Be Connected
o Ultra-Low-Power Dissipation
Operating-Mode Current Drain: 80µA
Shutdown-Mode Current: 2µA
o Wide Operating Temperature Range from -40°C to
+105°C (AEC-Q100 Type 2)
o 9.7mm x 4.4mm, 38-Pin TSSOP Package
o Lead(Pb) Free and RoHS Compliant
Ordering Information
PART
MAX11080GUU+
TEMP RANGE
-40°C to +105°C
PIN-PACKAGE
38 TSSOP
MAX11080GUU/V+
-40°C to +105°C
38 TSSOP
+Denotes a lead(Pb)-free/RoHS-compliant package.
/V denotes an automotive qualified part.
Hybrid Electric Vehicles
Electric Bikes
Pin Configuration appears at end of data sheet.
High-Power Battery Backup
Solar Cell Battery Backup
Super-Cap Battery Backup
________________________________________________________________ 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
MAX11080
General Description
MAX11080
12-Channel, High-Voltage Battery-Pack
Fault Monitor
ABSOLUTE MAXIMUM RATINGS
ESD Rating
C_, REF, VAA, VDDU GNDU,
DCIN, SHDN, CP+, CP-, HV,
OVSEL_, UVSEL_, TOPSEL,
ALRMU, ALRML,
AGND, CD ..............................±2kV (Human Body Model, Note 3)
Continuous Power Dissipation (TA = +70°C)
38-Pin TSSOP
(derating 15.9mW/°C above +70°C) .........................1095.9mW
Operating Temperature Range .........................-40°C to +105°C
Storage Temperature Range .............................-55°C to +150°C
Junction Temperature (continuous) .................................+150°C
Lead Temperature (soldering, 10s) .................................+300°C
HV, VDDU, GNDU, DCIN to AGND.........................-0.3V to +80V
HV to DCIN and C12 ................................................-0.3V to +6V
C2–C12 to AGND ....................................-0.3V to (VDCIN + 0.6V)
Cn+1 to Cn, where n = 2 to 12...............................-0.3V to +80V
C1 to C0 ...................................................-0.3V to +20V (Note 1)
C1 to AGND ..............................-0.3V to (VDCIN + 0.6V) (Note 2)
C0 to AGND...........................................................-0.3V to +0.9V
SHDN, VAA to AGND ................................................-0.3V to +4V
VDDU to GNDU .........................................................-0.3V to +6V
OVSEL_, UVSEL_, TOPSEL to AGND ......-0.3V to (+VAA + 0.3V)
CD, ALRML to AGND ...............................-0.3V to (+VAA + 0.3V)
ALRMU to GNDU ...................................-0.3V to (+VDDU + 0.3V)
CP+ to AGND ...........................(GNDU - 0.3V) to (VDDU + 0.3V)
CP- to AGND...........................................-0.3V to (GNDU + 0.3V)
CP- to VDDU .......................................................................+0.3V
Note 1: The C1 to C0 differential input path is tolerant to 80V as long as the SHDN pin is deasserted.
Note 2: The C1 input is tolerant to a maximum VDCIN + 0.6V. If SHDN is asserted, 20V is the maximum rating.
Note 3: Human Body Model to Specification MIL-STD-883 Method 3015.7.
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
(TA = TMIN to TMAX, unless otherwise noted. VDCIN = VGNDu = +6.0V to +72V, typical values are at TA = +25°C, unless otherwise
specified from -40°C to +105°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
72
V
+1
µA
C_ INPUTS
Common-Mode Input Range
VCXIN
Any two inputs Cn to Cn+1 for full
threshold accuracy (Note 4)
1.5
Input Current
ICXIN
VCELL = 3.0V
-1
Overvoltage Threshold
VOV
+3.3
±5
Overvoltage-Threshold Accuracy
Undervoltage Threshold
VUV
+1.6
Undervoltage-Threshold
Accuracy
Comparator Hysteresis
0.05
±20
VHYS
+4.8
V
±25
mV
+2.8
V
±100
mV
300
mV
CD PIN
CD Current
ICD
VCD = 0.4V
CD Trip Voltage
VCD
Internal at comparator
1.23
V
Excluding CDLY variation
±20
%
Delay-Time Accuracy
4.35
6.1
7.65
µA
STATUS/CONTROL PORT
Shutdown Disable (SHDN High
Voltage)
SHDN/VIH
Shutdown Asserted (SHDN Low
Voltage)
SHDN/VIL
2
2.1
_______________________________________________________________________________________
V
0.6
V
12-Channel, High-Voltage Battery-Pack
Fault Monitor
(TA = TMIN to TMAX, unless otherwise noted. VDCIN = VGNDu = +6.0V to +72V, typical values are at TA = +25°C, unless otherwise
specified from -40°C to +105°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
VDDU Output High
VDDU
VOH
Output voltage of VDDU after the
20kΩ/200kΩ resistor-divider to SHDN
VDDU Output Low
VDDU
VOL
Output voltage of VDDU after the
20kΩ/200kΩ resistor-divider for SHDN
ALRML Output-Voltage High
ALRML
VOH
ISOURCE = 150µA
ALRML Output-Voltage Low
ALRML
VOL
ISINK = 150µA
ALRMU Input-Voltage High
ALRMU
VIH
Daisy-chained ALRMU signal as
coupled through a 3.3nF high-voltage
capacitor and a 150kΩ resistor as
referred to GNDU
ALRMU Input-Voltage Low
ALRMU
VIL
Daisy-chained ALRMU signal as
coupled through a 3.3nF high-voltage
capacitor and a 150kΩ resistor as
referred to GNDU
Alarm Voltage Output “Heartbeat”
Frequency
ALRML
fOUT
Heartbeat clock rate with no alarm
condition
4032
Heartbeat clock rate with no alarm
condition
Alarm Voltage Output Duty Cycle
TYP
MAX
GNDU
+ 2.4
UNITS
V
GNDU
+ 0.3
2.4
V
V
0.6
GNDU
+ 2.1
V
V
GNDU
+ 0.9
V
4157
Hz
49.0
51.0
%
6
72
V
4096
LINEAR REGULATOR (VAA)
Input Voltage Range
Output Voltage
VDCIN
VAAOUT
Short-Circuit Current
Power-On-Reset Trip Level
(Note 4)
3.0
3.3
VAARESET
Falling VAA
2.8
VAAVALID
Rising VAA
3.0
VAAHYS
Thermal Shutdown
6V < VDCIN < 72V, ILOAD = 0
IAASHORTCIRCUIT VAA = 0, 6V < VDCIN < 36V
TSHUT
Hysteresis on rising VAA
Rising temperature
3.6
V
50
mA
V
37
mV
+145
°C
POWER-SUPPLY REQUIREMENTS (DCIN)
Current Consumption
IDCIN
IGNDu Operating Mode
Operating mode, SHDN = 1, 12
battery cells, alarm inactive,
VDCIN = VGNDU = 36V
35
Shutdown mode, SHDN = 0, 12
battery cells, VDCIN = VGNDU = 36V
1.3
2
SHDN = 1, battery cells, alarm
inactive, VDCIN = VGNDU = 36V
35
40
40
µA
µA
LOGIC INPUTS AND OUTPUTS
Threshold Setting
VIH
UVSEL0/UVSEL1/UVSEL2, TOPSEL
VIL
OVSELO/OVSEL1/OVSEL2/OVSEL3
VAA 0.1
V
0.1
Note 4: Guaranteed by design and not production tested.
_______________________________________________________________________________________
3
MAX11080
ELECTRICAL CHARACTERISTICS (continued)
Typical Operating Characteristics
(TA = +25°C, unless otherwise noted.)
MAX
1.62
35
6.03
MAX11080 toc02
1.6V SET POINT
MAX11080 toc01
30
VCD = 0.4V
6.02
1.60
MEAN
1.59
1.58
1.57
CD CURRENT (µA)
25
1.61
DEVICE COUNT
20
15
6.00
5.99
10
5.98
5
5.97
1.55
5.96
0
-20
0
40
20
60
80
100
5.8
6.0
6.4
6.2
-40
6.6
40
20
60
80
100
TEMPERATURE (°C)
DCIN SUPPLY CURRENT vs. VDCIN
GNDU SUPPLY CURRENT
vs. GNDU VOLTAGE
OVERVOLTAGE CLEAR THRESHOLD
vs. TEMPERATURE
55
TA = +105°C
OVERVOLTAGE CLEAR THRESHOLD (V)
50
4.54
45
TA = +105°C
40
TA = +25°C
35
TA = -40°C
30
25
30
TA = +25°C
20
TA = -40°C
20
15
10
20
30
40
50
60
70
80
10
20
30
40
50
60
70
4.49
MIN
4.48
80
-40
-20
0
20
MEAN
4.798
MIN
4.794
4.792
1.94
1.6V SET POINT
1.92
MAX
1.90
1.88
MEAN
1.86
MIN
1.84
1.82
-40
-20
0
20
40
60
TEMPERATURE (°C)
80
40
100
60
TEMPERATURE (°C)
UNDERVOLTAGE CLEAR THRESHOLD (V)
MAX
4.802
MAX11080 toc07
4.8V SET POINT
OVERVOLTAGE SET THRESHOLD (V)
4.50
UNDERVOLTAGE CLEAR THRESHOLD
vs. TEMPERATURE
4.806
4.796
MEAN
4.51
VGNDU (V)
OVERVOLTAGE SET THRESHOLD
vs. TEMPERATURE
4.800
4.52
4.47
0
VDCIN (V)
4.804
4.8V SET POINT
MAX
4.53
-40
-20
0
20
40
60
80
100
TEMPERATURE (°C)
_______________________________________________________________________________________
MAX11080 toc08
IGNDU (µA)
50
0
0
CD PIN CURRENT (µA)
60
40
-20
TEMPERATURE (°C)
4.8V OVERVOLTAGE THRESHOLD
VCELL = VDCIN/12
70
5.6
5.4
MAX11080 toc04
-40
80
100
MAX11080 toc06
1.56
4
6.01
MIN
MAX11080 toc05
UNDERVOLTAGE SET THRESHOLD (V)
1.64
1.63
CD CHARGING CURRENT
vs. TEMPERATURE
CD CURRENT DISTRIBUTION
MAX11080 toc03
UNDERVOLTAGE SET THRESHOLD
vs. TEMPERATURE
IDCIN (µA)
MAX11080
12-Channel, High-Voltage Battery-Pack
Fault Monitor
12-Channel, High-Voltage Battery-Pack
Fault Monitor
PIN
NAME
1
DCIN
DC Power-Supply Input. DCIN supplies the internal 3.3V regulator. This pin should be connected as shown
in the application diagrams.
2
HV
High-Voltage Bias. HV is biased by the output of the charge pump to provide a DC supply above the DCIN
level. It is used internally to bias the cell-comparator circuitry. Bypass to DCIN with a 1µF capacitor.
3, 33
N.C.
No Connection
4
C12
Cell 12 Plus Connection. Top of battery module stack.
5
C11
Cell 12 Minus Connection and Cell 11 Plus Connection
6
C10
Cell 11 Minus Connection and Cell 10 Plus Connection
7
C9
Cell 10 Minus Connection and Cell 9 Plus Connection
8
C8
Cell 9 Minus Connection and Cell 8 Plus Connection
9
C7
Cell 8 Minus Connection and Cell 7 Plus Connection
10
C6
Cell 7 Minus Connection and Cell 6 Plus Connection
11
C5
Cell 6 Minus Connection and Cell 5 Plus Connection
12
C4
Cell 5 Minus Connection and Cell 4 Plus Connection
13
C3
Cell 4 Minus Connection and Cell 3 Plus Connection
14
C2
Cell 3 Minus Connection and Cell 2 Plus Connection
15
C1
Cell 2 Minus Connection and Cell 1 Plus Connection
16
C0
Cell 1 Minus Connection
17
UVSEL0
18
UVSEL1
19
UVSEL2
20
OVSEL0
21
OVSEL1
22
OVSEL2
23
OVSEL3
24
VAA
25, 29,
30, 32
AGND
Analog Ground. Should be connected to the negative terminal of cell 1.
SHDN
Active-Low Shutdown Input. This pin completely shuts down the MAX11080 internal regulator and
oscillators when the pin is less than 0.6V as referenced to AGND. The host controller should drive SHDN for
the first pack. SHDN for daisy-chained modules should be connected to the lower neighboring module’s
VDDU through a 20kΩ series resistor.
27
ALRML
Lower Port Alarm Output. This output is an alarm indicator for overvoltage, undervoltage, and setup faults.
The alarm signal is daisy chained and driven from the highest module down to the lowest. The alarm output
is nominally a clocked “heartbeat” signal that provides a 4kHz clock when no alarm is present. The ALRML
can also be configured as level signal and set to “low” for no alarm and “high” for alarm state. See the
TOPSEL Function section for details. This signal swings between VAA and AGND, and is active high in the
alarm state.
28
CD
26
FUNCTION
Undervoltage Threshold Select 2 to 0. Used to select one of eight undervoltage alarm threshold settings.
The parts have internal pulldown; these pins should only be tied to VAA or AGND to set the logic state.
Overvoltage Threshold Select 3 to 0. Used to select one of 16 overvoltage alarm threshold settings.
The parts have internal pulldown; these pins should only be tied to VAA or AGND to set the logic state.
+3.3V Analog Supply Output. Bypass with a 1µF capacitor to AGND.
Programmable Delay Time. Connect a capacitor from this pin to AGND to set the hold time required for a
fault condition before the alarm is set. The capacitor should be a ceramic capacitor in the 15nF to 16.5µF
range.
_______________________________________________________________________________________
5
MAX11080
Pin Description
MAX11080
12-Channel, High-Voltage Battery-Pack
Fault Monitor
Pin Description (continued)
6
PIN
NAME
FUNCTION
31
TOPSEL
Input to Indicate Topmost Device in the Daisy Chain. This pin should be connected to AGND for all devices
except the topmost. For the top device, this pin should be connected to VAA.
34
ALRMU
Upper Port Alarm Input. This input receives the ALRML output signal from an upper neighboring module. It
swings between VDDU and GNDU.
35
GNDU
Level-Shifted Upper Port Ground. Upper port-supply return and supply input for the charge pump and HV
supplies. This pin should be connected to the DCIN takeoff point on the battery stack as shown in the
application diagrams.
36
VDDU
Level-Shifted Upper Port Supply. Upper port-supply output for the daisy-chained bus. This is a regulated
output voltage from the internal charge pump that is level-shifted above the DCIN pin voltage level. It
should be bypassed with a 1µF capacitor to GNDU.
37, 38
CP-, CP+
Charge-Pump Capacitor. Negative/positive input for the internal charge pump. Connect a 0.01µF highvoltage capacitor between CP+ and CP-.
_______________________________________________________________________________________
12-Channel, High-Voltage Battery-Pack
Fault Monitor
MAX11080
HV
DCIN
C12
LDO
REGULATOR
CELL COMPARATORS
VAA
C11
UPPER
PORT
CELL COMPARATORS
C10
VDDU
ALRMU
GNDU
CELL COMPARATORS
C9
CELL COMPARATORS
LEVEL
SHIFT
C8
CP+
CP-
CELL COMPARATORS
C7
CELL COMPARATORS
C6
FAULT
FAULT
CELL COMPARATORS
LOWER
PORT
ALRML
SHDN
C5
CELL COMPARATORS
OVSEL3
C4
OVSEL2
CELL COMPARATORS
C3
CELL COMPARATORS
OVSEL1
FAULT-STATE
MACHINE
AND
CONTROL LOGIC
OVSEL0
TOPSEL
C2
CELL COMPARATORS
UVSEL2
C1
UVSEL1
CELL COMPARATORS
UVSEL0
C0
MAX11080
AGND
CD
Figure 1. Functional Diagram
_______________________________________________________________________________________
7
MAX11080
12-Channel, High-Voltage Battery-Pack
Fault Monitor
MODULE
N+1
CELL STACK
MODULE
N+1
GND REFERENCE
FUSE
MODULE-(N+1)
RDCIN
5kΩ
BUS BAR
MODULE+(N)
CDCIN
0.1µF
80V
CHV
1µF
6V
SMCJ70
HV
R13
DPROT
CELL 12
R12
VDDU
C12
GNDU
C11
CELL 11
R11
R10
C11
CELL 9
C10
R9
C9
R8
C8
MAX11080
C7
CELL 7
R7
R6
R5
CP
0.01µF
100V
CA
1µF
6V
ALRML
SHDN
RSHD
200kΩ
C5
C4
CELL 4
R4
C4
R3
OVSEL2
C3
OVSEL1
C2
CELL 2
R2
OVSEL0
C2
UVSEL2
C1
CELL 1
UVSEL1
UVSEL0
C1
C0
MODULE-(N)
TOPSEL
AGND
LOCAL
GROUND
BUS BAR
VAA
OVSEL3
C3
CELL 3
ISOLATOR
AND
CONTROL
INTERFACE
RSHD2
20kΩ
C6
C5
CELL 5
GNDU
SEE TEXT FOR GNDU
CONNECTION OPTIONS
C7
C6
CELL 6
GNDU
MODULE
N+1
C3DC
3.3nF
630V
GNDU
CP+
CPVAA
C8
CELL 8
R1DC
150kΩ
ALRML
GNDU
C9
5.6V
ALRMU
C10
CELL 10
SHDN
CDD
1µF
6V
DCIN
C12
DAISY-CHAIN BUS
TO UPPER MODULES
R2DC
20kΩ
CD
CDLY
15nF TO 16.5µF CERAMIC CAP
R2–R13 = 10kΩ
C1–C12 = 0.1µF/80V
MODULE
N-1
CELL STACK
MODULE
N-1
GNDU TAKEOFF
Figure 2. Application Circuit Diagram for a 12-Cell System
8
_______________________________________________________________________________________
JUMPER BANK
12-Channel, High-Voltage Battery-Pack
Fault Monitor
MAX11080
MODULE
N+1
CELL STACK
MODULE
N+1
GND REFERENCE
FUSE
MODULE-(N+1)
RDCIN
5kΩ
CDCIN
0.1µF
80V
BUS BAR
MODULE+(N)
CHV
1µF
6V
SMCJ70
HV
R11
DPROT
CELL 10
VDDU
C10
GNDU
C11
SHDN
CDD
1µF
6V
DCIN
C12
DAISY-CHAIN BUS
TO UPPER MODULES
R2DC
20kΩ
5.6V
R1DC
150kΩ
GNDU
MODULE
N+1
C3DC
3.3nF
630V
ALRMU
ALRML
GNDU
GNDU
C10
R10
C9
CELL 9
R9
C9
R8
C8
MAX11080
CPVAA
C8
CELL 8
GNDU
CP+
C7
CELL 7
R7
R6
ALRML
R5
SHDN
RSHD
200kΩ
C5
C4
CELL 4
R4
C4
R3
OVSEL2
C3
OVSEL1
C2
CELL 2
R2
OVSEL0
C2
UVSEL2
C1
CELL 1
UVSEL0
C0
TOPSEL
AGND
LOCAL
GROUND
BUS BAR
JUMPER BANK
UVSEL1
C1
MODULE-(N)
VAA
OVSEL3
C3
CELL 3
ISOLATOR
AND
CONTROL
INTERFACE
RSHD2
20kΩ
C6
C5
CELL 5
CA
1µF
6V
C7
C6
CELL 6
CP
0.01µF
100V
CD
CDLY
15nF TO 16.5µF CERAMIC CAP
R2–R11 = 10kΩ
C1–C10 = 0.1µF/80V
MODULE
N-1
CELL STACK
MODULE
N-1
GNDU TAKEOFF
Figure 3. Application Circuit Diagram for a 10-Cell System
_______________________________________________________________________________________
9
MAX11080
12-Channel, High-Voltage Battery-Pack
Fault Monitor
MODULE
N+1
CELL STACK
MODULE
N+1
GND REFERENCE
FUSE
MODULE-(N+1)
RDCIN
5kΩ
BUS BAR
MODULE+(N)
CDCIN
0.1µF
80V
CHV
1µF
6V
SMCJ70
HV
R9
DPROT
CELL 8
VDDU
C8
GNDU
C11
SHDN
CDD
1µF
6V
DCIN
C12
DAISY-CHAIN BUS
TO UPPER MODULES
R2DC
20kΩ
5.6V
R1DC
150kΩ
GNDU
MODULE
N+1
C3DC
3.3nF
630V
ALRMU
ALRML
GNDU
GNDU
C10
C9
MAX11080
GNDU
CP+
CPVAA
C8
R8
C7
CELL 7
R7
R6
ALRML
R5
SHDN
RSHD
200kΩ
C5
C4
CELL 4
R4
C4
R3
OVSEL2
C3
OVSEL1
C2
CELL 2
R2
OVSEL0
C2
UVSEL2
C1
CELL 1
UVSEL1
UVSEL0
C1
C0
MODULE-(N)
TOPSEL
AGND
LOCAL
GROUND
BUS BAR
VAA
OVSEL3
C3
CELL 3
ISOLATOR
AND
CONTROL
INTERFACE
RSHD2
20kΩ
C6
C5
CELL 5
CA
1µF
6V
C7
C6
CELL 6
CP
0.01µF
100V
CD
CDLY
15nF TO 16.5µF CERAMIC CAP
R2–R9 = 10kΩ
C1–C8 = 0.1µF/80V
MODULE
N-1
CELL STACK
MODULE
N-1
GNDU TAKEOFF
Figure 4. Application Circuit Diagram for an 8-Cell System
10
______________________________________________________________________________________
JUMPER BANK
MODULE N-1
CELL STACK
BUS BAR
MODULE-(N)
CELL 1
CELL 2
CELL 3
CELL 4
CELL 5
CELL 6
CELL 7
CELL 8
CELL 9
CELL 10
CELL 11
CELL 12
MODULE+(N)
BUS BAR
CDCIN1
D1
FUSE
C1Q750
(1206)
R26
BATTERY
CONNECTOR
DCIN
DCIN
HV
R25
C24
GNDU
R24
C23
CP+
C9
C10
R22
C21
LOCAL GROUND
R23
C22
R21
C20
R20
C19
R19
C18
MAX11080
R18
C17
R17
C16
R16
C15
R15
C14
C13
SHDN
C2
VDDU
C11
VAA
AGND
R1
R2
R3
R4
R5
R6
R7
R8
R9
R10
R11
R12
R13
REFER TO EACH DEVICE'S APPLICATION REFERENCE CIRCUITS FOR COMPONENTS AND VALUES NOT SHOWN ON THIS SIMPLIFIED SYSTEM-LEVEL SCHEMATIC.
DPROT1
SMCJ70
D2
RDCIN2
CPC8
MODULE-(N+1)
ALRML
C1
DPROT2
SMCJ70
C7
CDCIN2
C5
ALRMU
C12
UVSEL2
UVSEL1
UVSEL0
C4
OVSEL3
OVSEL2
OVSEL1
OVSEL0
C6
TOPSEL
C3
CD
C0
MODULE
N+1
GND REFERENCE
C0
C1
C2
C3
C4
C5
C6
C7
C8
C9
C10
C11
C12
AGND
REF
VDDU
GPIO0
GPIO1
GPIO2
GNDL
SHDN
ALRML
SDAL
SCLL
VDDL
VAA
CP-
CP+
GNDU
SDAU
SCLU
ALRMU
DCIN
ISOLATOR
AND
CONTROL
INTERFACE
FOR FIRST
MODULE
MAX11068
HV
DCIN
AUXIN2
AUXIN1
THRM
C0
C1
C2
C3
C4
C5
C6
C7
C8
C9
C10
C11
C12
GPIO
SDAL
SCLL
ALRML
(MAX11068)
ALRML
(MAX11080)
SHDN
MAX11080
MODULE
N+1
CELL STACK
12-Channel, High-Voltage Battery-Pack
Fault Monitor
Figure 5. Battery Module System with Redundant Fault-Detection Application Schematic
______________________________________________________________________________________
11
MAX11080
12-Channel, High-Voltage Battery-Pack
Fault Monitor
HV
VDDU
6V
DCIN
CP+
6V
ALRMU
80V
C12
80V
GNDU
80V
CPC1 TO C11
VAA
ALRML
SHDN
ESD DIODES
CD
MAX11080
TOPSEL
4V
4V
6V
OVSEL0/1/2/3
C0
UVSEL0/1/2
AGND
Figure 6. ESD Diode Diagram
Detailed Description
Figure 1 shows the functional diagram; Figure 2 shows
the application circuit diagram for a 12-cell system
while Figure 3 shows the application circuit design for a
10-cell system and Figure 4 for an 8-cell system. Figure
5 is the application schematic for the battery module
system with redundant fault detection.
Architectural Overview
The MAX11080 is a battery-pack fault-monitor IC capable of monitoring up to 12 Li+ battery cells. This device
is designed to provide an overvoltage or undervoltage
alarm indicator when any of the cells cross the userselectable threshold for longer than the configured
decision delay interval. The MAX11080 also incorporates a daisy-chain bus for use in high-voltage stackedbattery operation. The daisy-chain bus relays shutdown
12
and alarm communication across up to 31 stacked
modules without the need for isolation between each
module. This results in a simplified system with reduced
cost. The MAX11080 is ideal as an ultra-low-power,
redundant cell fault monitor that is the perfect complement to the MAX11068 high-voltage battery measurement IC. Both ICs in concert form a powerful Li+ battery
system monitor with redundant overvoltage and undervoltage fault detection.
Overvoltage and Undervoltage Fault
Detection
Figure 7 summarizes the fault-detection mechanism for
a set of differential cell inputs in the MAX11080.
First, the differential cell inputs are attenuated by a factor of four while being level-shifted and converted to a
single-ended voltage referenced to AGND. The ground-
______________________________________________________________________________________
12-Channel, High-Voltage Battery-Pack
Fault Monitor
CD pin. If the voltage at the CD pin reaches VCD, the
ALRML line is set to VAA (+2.4V minimum as referred to
AGND). Normally, the ALRML line is a heartbeat signal
with pulses occurring every 250µs. If all cell voltages
transition from out-of-range to in-range before the voltage at pin CD reaches VCD, an internal switch clamps
the CD pin to GND. This action discharges CDLY and,
because the delay had not yet expired, no alarm
occurs. Discharging CDLY ensures that the full delay
time occurs for the next overvoltage or undervoltage
event. Figure 8 summarizes the CDLY circuit.
VOV/4
VCELL/(4 x RSHIFT)
75mV
HYSTERESIS
HV
CELL
OUT-OF-RANGE
CN+1
+
RIN*
40MΩ
TYP
VCELL
RSHIFT
+
VCELL/4
75mV
HYSTERESIS
-
CN
OUT-OF-RANGE
11
AGND
CELLS 2-12
VUV/4
+
VCELL
6MΩ
TYP
2MΩ
TYP
UNDERVOLTAGE
COMPARATOR
ENABLE
VCELL/4
VSC/4
CELL 1
SHORT-CIRCUIT
DETECTOR
Figure 7. Cell Differential Input and Comparator Block Diagram
VAA
6kΩ
CD
ICD
6.1µA
OUT-OF-RANGE
ALARM
CELL OUT-OF-RANGE
1 TO 12
11
VCD
THRESHOLD
CDLY
Figure 8. CDLY Circuit Block Diagram
______________________________________________________________________________________
13
MAX11080
referenced voltage is then connected to a set of overvoltage and undervoltage comparators. The threshold
references for the comparators are set by the UVSEL_
and OVSEL_ input pins. When one of the cell voltages
exceeds VOV or is below VUV when VUV is enabled, the
internal cell out-of-range signal for the given cell is set
and logically ORed with the same signal for the other
cell positions to create an overall out-of-range signal.
When any cells are out-of-range as indicated by the
internal out-of-range signal, an internal current source
begins to charge the capacitor CDLY connected to the
MAX11080
12-Channel, High-Voltage Battery-Pack
Fault Monitor
Once the ALRML pin is forced high due to an alarm
(+2.4V minimum as referred to AGND), it transitions
back to a heartbeat signal only after all battery cells
meet the following condition:
(VOV - VHYS) > VCELL(ALL) > (VUV + VHYS)
The effective ICD value of the current source is 6.1µA
typical and the threshold voltage, VCD, is 1.23V typical.
The VCD threshold is specified at an internal node prior
to the resistor in series with the CD pin as shown in
Figure 8. The threshold voltage seen at the pin is
approximately 1.18V due to the drop associated with
the typical ICD value and the 6kΩ resistor. The
MAX11080 can operate with capacitor values from
15nF (3.0ms) to 16.5µF (3.32s). Each capacitor should
have a voltage tolerance of 5V minimum.
Examples of cell-voltage readings and their effect on
the alarm status are shown in Figures 9 and 10 for single- and multiple-cell systems. In the case where an
upper module is forwarding an active alarm condition
down the daisy chain, that condition continues to be
propagated toward the host regardless of the alarm
state of any lower module. Furthermore, to circumvent
the possibility of a short-circuited capacitor connected
to CD preempting the fault-time validation process, a
redundant built-in delay of 4s nominal is asserted as a
backup. If the VCD threshold is not reached within 4s of
an out-of-range event, the alarm becomes active.
Cell-Voltage Threshold Selection
The overvoltage and undervoltage threshold selection
is configured through the OVSEL_ and UVSEL_ inputs.
The overvoltage selection can be configured from 3.3V
to 4.8V in 100mV increments. The undervoltage threshold can be configured from 1.6V to 2.8V in 200mV
increments. The undervoltage detection can also be
disabled. See Tables 1 and 2 for the proper configuration settings.
Immunity to unintended changes in the threshold voltage setting (due to accidental pin-to-pin short circuits,
for example) is provided. The customer-programmed
selection is sensed and stored at power-up and any
subsequent change to the input pin status is ignored.
Programmable Delay Time
The alarm trigger delay time is calculated according to
the following equations:
tDLY = (VCD x CDLY)/ICD
CDLY = (tDLY x ICD)/VCD
Table 1. Overvoltage Threshold Selection
THRESHOLD (V)
14
OVERVOLTAGE SELECTION
OVSEL3
OVSEL2
OVSEL1
OVSEL0
3.3
0
0
0
0
3.4
0
0
0
1
3.5
0
0
1
0
3.6
0
0
1
1
3.7
0
1
0
0
3.8
0
1
0
1
3.9
0
1
1
0
4.0
0
1
1
1
4.1
1
0
0
0
4.2
1
0
0
1
4.3
1
0
1
0
4.4
1
0
1
1
4.5
1
1
0
0
4.6
1
1
0
1
4.7
1
1
1
0
4.8
1
1
1
1
______________________________________________________________________________________
12-Channel, High-Voltage Battery-Pack
Fault Monitor
MAX11080
VOV
VOV - VHYS
ANY
CELL
CELL
VOLTAGE
VCD
CD
ALRML
Figure 9. Single-Cell Overvoltage Detection Example
VOV
VOV - VHYS
CELL 12
CELL 11
CELL
VOLTAGE CELL N
CELL 1
VCD
CD
ALRML
Figure 10. Multiple-Cell Overvoltage Detection Example
______________________________________________________________________________________
15
MAX11080
12-Channel, High-Voltage Battery-Pack
Fault Monitor
Table 2. Undervoltage Threshold Selection
UNDERVOLTAGE SELECTION
THRESHOLD (V)
UVSEL2
UVSEL1
UVSEL0
Disabled
0
0
0
1.6
0
0
1
1.8
0
1
0
2.0
0
1
1
2.2
1
0
0
2.4
1
0
1
2.6
1
1
0
2.8
1
1
1
Internal Linear Regulator
The MAX11080 has an internal linear regulator for generating the internal supply from DCIN (Figure 11). The
regulator can accept a supply voltage on the DCIN pin
from +6.0V to +72V, which it regulates to 3.3V to run
the voltage-detection system, control logic, and lowside alarm-pulse interface. When the SHDN pin is not
active and a sufficient voltage is applied to DCIN, the
output of the regulator becomes active. The regulator is
paired with a power-on-reset (POR) circuit that senses
DCIN
+6.0V TO +72V
LINEAR
REGULATOR
its output voltage and holds the MAX11080 in a reset
state until the internal supply has reached a sustainable
threshold of +3.0V (±5%). The internal comparators
have built-in hysteresis that can reject noise on the supply line. Because secondary metal batteries are never
fully discharged to 0V, the MAX11080 is designed for a
hot-swap insertion of the battery cells. Once the POR
threshold is reached, approximately 1ms later the internal reset signal disables, the internal oscillator starts,
and the charge pump begins operating. The charge
INTERNAL +3.3V
VAA
SHDN
GNDU
REGULATOR
ENABLE
CHARGE
PUMP
DIE OVERTEMPERATURE
DETECT
BANDGAP
REFERENCE
VDDU
CHARGE-PUMP
ENABLE
35mV
HYSTERESIS
+3.3V TO GNDU
INTERNAL POR
POR THRESHOLD
+3.0V ±5%
POR
COMPARATOR
Figure 11. Internal Linear Regulator Block Diagram
16
______________________________________________________________________________________
12-Channel, High-Voltage Battery-Pack
Fault Monitor
racy and full operation of the MAX11080 are not guaranteed until a minimum of 6.0V is applied to the DCIN
pin.
The linear regulator also incorporates a thermal shutdown feature. If the MAX11080 die temperature rises
above +145°C, the device shuts down. After a thermal
shutdown, the die temperature must cool 15°C below
the shutdown temperature before the device restarts.
Figure 12 shows the linear regulator power-up sequence
and Figure 13 shows the low DCIN POR event.
POR ACTIVE
FAULT THRESHOLDS
READ
VOLTAGE APPLIED
TO DCIN
SHDN ACTIVE
POR INACTIVE
16kHz OSCILLATOR
ENABLED
FALLING DCIN
VOLTAGE
CHECK SHDN
CHARGE-PUMP
ENABLED
VAA > 2.8V
3ms DELAY
REGULATOR
ENABLED
CHECK VAA
VAA < 3.0V
TOP BOARD
IDENTIFIED
POR ACTIVE
OVERVOLTAGE
COMPARATOR
SELF-TEST
CHECK VAA
1ms DELAY
NUMBER OF CELLS
DETECTED
POR CLEARED
OSCILLATOR,
CHARGE PUMP,
DIGITAL LOGIC,
AND ALARM PULSE
DISABLED
MAX11080 FULLY
FUNCTIONAL
Figure 12. Linear Regulator Power-Up Sequence
Figure 13. Low DCIN POR Event
______________________________________________________________________________________
17
MAX11080
pump reaches regulation in approximately 3ms. The
MAX11080 associated with the top module in the battery pack is identified as detailed in the TOPSEL
Function section. This is followed by a self-test of the
overvoltage comparators and detection of the number
of cells connected. At this time in the power-on
sequence, the MAX11080 is ready for operation. When
the charge pump achieves regulation of 3.3V between
VDDU and GNDU, it switches to a standby mode until
the voltage drops by about 35mV. The specified accu-
MAX11080
12-Channel, High-Voltage Battery-Pack
Fault Monitor
FUSE
TOP OF CELL STACK
RDCIN
5kΩ
CDCIN
0.1µF
80V
TO DCIN INPUT
PBMB78AT3
SEE THE APPLICATION CIRCUIT DIAGRAMS (FIGURES 15 AND 16) FOR THE
PROPER CONNECTION LOCATION.
Figure 14. Battery Module Surge and Overvoltage Protection
Circuit
DCIN and GNDU Supply Connections
A surge voltage is produced by the electric motor during regenerative braking conditions. The MAX11080 is
designed to tolerate an absolute maximum of 80V
under this condition. The MAX11080 should be protected against higher voltages with an external voltage
suppressor such as the PBMB78AT3 on the DCIN connection point. This protection circuit also helps to
reduce power spikes that can occur during the insertion of the battery cells. During negative voltage excursions, the protection circuit stores enough charge to
power the regulator through the transient. Figure 14
shows the clamp configuration to protect the DCIN supply input.
The DCIN input contains a comparator circuit to detect
an open circuit on this pin for fault-management purposes. Whenever a nominal voltage of two silicon diode
drops appears between C12 and DCIN following the
power-up sequence, the ALRML output is asserted as a
fault indication. This voltage drop must appear for at
least the delay time set by CDLY to result in a fault. The
voltage drop from C12 to DCIN during normal operation
should be kept at no more than 0.5V to prevent erroneous tripping of the DCIN open-circuit comparator
under worst-case circumstances (lowest silicon diode
forward bias voltage). The diode DDCIN is used to supply the transient current demanded at startup by the
decoupling circuit. In parallel with this diode, RDCIN
provides the supply path during normal operation. It is
selected to be 5kΩ so that the maximum voltage drop
between C12 and DCIN is about 0.25V with nominal
supply currents.
High-power batteries are often used in noisy environments subject to high dV/dt or dI/dt supply noise and
EMI noise. For example, the supply noise of a power
18
inverter driving a high horse-power motor produces a
large square wave at the battery terminals, even though
the battery is also a high-power battery. Typically, the
battery dominates the task of absorbing this noise,
since it is impractical to put hundreds of farads at the
inverter.
The MAX11080 is designed with several mechanisms to
deal with extremely noisy environments. First, the major
power-supply inputs that see the full battery-stack voltage are 80V tolerant. This is high enough to handle the
large voltage changes on the battery stack that can
occur when the batteries transition between charge and
discharge conditions. Next, the linear regulator has
high PSRR to produce a clean low-voltage power supply for the internal circuitry. This allows DCIN to be connected directly to the stack voltage. Finally, GND U
serves two purposes. It supplies the internal charge
pump with its power and acts as the reference ground
for the upper alarm communication port. The charge
pump creates a secondary low-voltage supply that is
referenced to GNDU. Because the level-shifted supply
VDDU is referenced to GNDU, the entire upper alarm
communication port glides smoothly on GNDU and it is
effectively immune to noise on GNDU. The upper alarm
signal is internally shifted down to AGND level where it
is processed by the digital logic. There are two connection methods that can be used for GNDU depending on
application requirements.
For the top module in a system, or where GNDU cannot
be DC-coupled to the next higher module for other reasons, GNDU should be connected to the same location
as DCIN. This connection is valid as long as the voltage
difference between the top of Stack(n) and the bottom
of Stack(n+1) during worst-case conditions does not
exceed the margin of the alarm pin signaling levels.
When GNDU is not DC-coupled to the far side of the
bus bar, it can be AC-coupled to the far side to maintain alarm communication when the bus bar is open-circuit. In that case, the two sides of the AC-coupling
capacitor can be at different DC potentials, but the
alarm communication signal continues to be passed
across the capacitor connection. It is recommended
that an AC- or DC-coupled version of GNDU is paired
with the alarm signal through the communication bus
wiring, possibly by twisted pair wire, for maximum noise
immunity and minimum emissions.
The preferred connection to reject noise between modules is when a DC connection can be made from GNDU
to AGND of the next module. It is again recommended
that the DC-coupled GNDU signal is routed adjacent to
the alarm signal as part of the communication bus for
maximum noise immunity and minimum emissions.
______________________________________________________________________________________
12-Channel, High-Voltage Battery-Pack
Fault Monitor
MAX11080
MODULEN+1
MODULEN+1
DCIN
C12
GNDU
C12
C11
C11
C2
C2
C1
C1
C0
AGND
OPTIONAL
TO MAINTAIN
ALARM
COMMUNICATION
MODULEN
BUS BAR
C0
BUS BAR
DCIN
GNDU
AGND
COMMUNICATION
BUS
MODULEN
DCIN
DCIN
C12
C12
GNDU
GNDU
C11
C11
C2
C2
C1
C1
C0
C0
AGND
AGND
Figure 15. GNDU Connection: AC-Coupled to Next Module,
DC-Coupled to Present Module
Figure 16. GNDU Connection: DC-Coupled with the
Communication Bus
______________________________________________________________________________________
19
MAX11080
12-Channel, High-Voltage Battery-Pack
Fault Monitor
Shutdown Control
The SHDN pin connections of the MAX11080 operate in
a manner that allows the shutdown/wake-up command
to trickle up through the series of daisy-chained packs.
Because the internal linear regulator is powered down
during shutdown, the shutdown function must operate
when VAA is absent and it, therefore, cannot depend on
a Schmitt trigger input. A special low-current, high-voltage circuit is used to detect the state of the SHDN pin.
The shutdown pin has a +1.8V minimum threshold for
the inactive state. When SHDN > 1.8V, the MAX11080
turns on and begins regulating VDD U and VDD L. If
SHDN < 0.6V, the MAX11080 shuts down. For automatic shutdown when the pack is removed from the system, connect a 200kΩ resistor from SHDN to AGND.
Once SHDN is driven high, the power-up sequence follows that described for the internal linear regulator. The
SHDN signal of the next higher module should be connected to VDDU through a 20kΩ resistor pullup. This
connection ensures that the next module in the daisy
chain is enabled as VDDU of the lower module powers
up. This action propagates up the daisy chain until the
last battery module is enabled. The shutdown of a
VDD U supply pulls the connected SHDN pin of the
upper module toward GNDL and propagates the shutdown signal up the daisy chain.
A shutdown signal propagated from the first daisychain device to the last incurs a certain amount of
delay. A deasserted shutdown signal is not propagated
to the next higher module until the charge pump has
regulated the level-shifted upper port supply, VDDU, to
a value greater than the SHDN V IH level. This time
depends on both the charge-pump capacitor used and
the value of the VDDU decoupling capacitor. A typical
time delay of 10ms can be expected from the time the
SHDN pin reaches the deasserted state until VDD U
reaches its full specified value.
to leave unused. The example application circuits in this
document have chosen to populate the uppermost cell
position and group the unused inputs just under this cell.
At power-up, the part compares the voltage applied to
each cell input with a nominal cell-detection threshold
voltage of 0.7V. If the cell voltage is less than the celldetection threshold, undervoltage detection is disabled
for that cell input. If the voltage at the input is 0.7V or
greater, undervoltage detection is specified by the
state of the UVSEL_ inputs. Overvoltage detection is
always enabled for all cell-voltage inputs. The cell-connection detection occurs just before the MAX11080 is
fully functional as shown in Figure 12 under “Number of
Cells Detected.”
TOPSEL Function
The TOPSEL pin is used to indicate to a device whether
it is the top device in the daisy-chain stack. The top
daisy-chain device is responsible for generating the
heartbeat signal at the top of the ALRM_ pin bus. This
heartbeat propagates along the chain toward the host.
To designate a device as the top device, the TOPSEL
pin should be connected to VAA. For all other devices
in a daisy chain, this pin should be connected to
AGND. The TOPSEL pin has a weak internal pulldown
resistor, but this resistor should not be relied upon as
the sole means of setting the TOPSEL logic level. The
logic level of the TOPSEL pin is not latched internally at
startup and is continuously sampled during operation.
The ALRMU input should be connected to GNDU for the
top module as good design practice to prevent noise
pickup even though the input logic level is ignored.
For the single device application, the device enters the
“level” mode when the TOPSEL is connected to AGND.
The ALRML shows the level of AGND for no alarm state
and VAA for alarm state. ALRM U has to be tied to
GNDU for this mode. The following table summarizes
the operation of TOPSEL and ALRML:
C1 Input Absolute Maximum Rating
The C1 input is limited to VDCIN - 0.6V above AGND or
a maximum of 20V if the SHDN pin is asserted. If an
application requires that the 20V restriction be removed
during active shutdown, then a 4.0V zener diode can
be added from VAA to AGND. This protects VAA and
allows the C1 input to go to VDCIN - 0.6V regardless of
the SHDN state. It also allows the differential C1 to C0
voltage to range from -0.3V to +80V.
Cell-Connection Detection
An individual MAX11080 can be connected to as many
as 12 series-connected cells. To accommodate configurations with fewer cells, unused cell inputs must be shorted together. The designer can choose which cell inputs
20
TOPSEL
ALRMU
0
1
ALRML
No alarm
alarm
0
0
1
X
Heartbeat
1
Internal Self-Test
The MAX11080 performs an internal self-test during
power-up according to the linear regulator power-up
flowchart (Figure 12). Each overvoltage comparator is
tested for the ability to detect an internally generated
overvoltage test condition. This is done by using the
ground voltage level as the threshold reference in place
of the usual threshold level. Figure 8 shows the connec-
______________________________________________________________________________________
12-Channel, High-Voltage Battery-Pack
Fault Monitor
Failure Mode and Effects Analysis
High-voltage battery-pack systems can be subjected to
severe stresses during in-service fault conditions and
could experience similar conditions during the manufacturing and assembly process. The MAX11080 is
designed with high regard to these potential states.
Open and short circuits at the package level must be
readily detected for fault diagnosis and should be tolerated whenever possible. A number of circuits are
employed within the MAX11080 specifically to detect
such conditions and progress to a known device state.
Table 3 summarizes other conditions typical in a normal
manufacturing process along with their effect on the
MAX11080 device.
See Table 4 for the FEMA analysis of the MAX11080. If
the cell voltage is within the monitor range, the heartbeatsignal on the ALRML resumes once the fault condition (either open or short) is removed, unless specified.
Table 3. System Fault Modes
CONDITION
EFFECT
DESIGN RECOMMENDATION
Refer to the pin-level FMEA analysis
spreadsheet available from the factory
The built-in features of the MAX11080
should ensure low FMEA risk in most
cases.
Random connection of cells to IC—
no stack load
No effect
The series resistors on the cell inputs of
the MAX11080 as well as the internal
design ensure protection against random
power supply or ground connections.
Random connection of modules—
no stack load
No effect
Each module is referenced to its neighbor,
so no special connection order is
necessary.
Random connect/disconnect of
communication bus—no stack load;
AC- or DC-coupled
The level-shifted interface design of the
Communication from host to the first break MAX11080 ensures that the SHDN, GNDU,
in the daisy-chain bus
and ALRM_ communication bus can be
connected at any time with no load.
Random connect/disconnect of
communication bus—with stack load;
AC- or DC-coupled
The level-shifted interface design of the
MAX11080 ensures that the SHDN, GNDU,
Communication from host to the first break
ALRM_ communication bus can be
in the daisy-chain bus
connected at any time as long as the
power bus is properly connected.
Connect/disconnect module interconnect
(bus bar)—no stack load
No effect for DC- or AC-coupled
communication bus
A break in the power bus does not cause
a problem as long as there is no load on
the stack.
Removal/fault of module interconnect
(bus bar)—with stack load
No effect for AC-coupled communication
bus; device damage for DC-coupled bus
An AC-coupled bus with isolation on the
SHDN pin or a redundant bus-bar
connection should be used to protect
against this case.
Removal/fault of module interconnect
(bus bar)—with stack under charge
No effect for AC-coupled communication
bus; device damage for DC-coupled bus
An AC-coupled bus with isolation on the
SHDN pin or a redundant bus-bar
connection should be used to protect
against this case.
PCB or IC package open or short circuit—
no stack load
______________________________________________________________________________________
21
MAX11080
tion for this test-mode compare level. If all comparators
can detect the internally generated overvoltage test
event, part operation continues. If any comparator fails
to detect the internally generated overvoltage test
event, a fault is signaled using the ALRML pin. The
device must be power cycled to retest the comparators
and attempt to clear this fault condition.
MAX11080
12-Channel, High-Voltage Battery-Pack
Fault Monitor
Table 4. FEMA Analysis (Note 5)
PIN
NUMBER
NAME
1
DCIN
2
HV
3
4
5
6
7
22
N.C.
ACTION
EFFECT
Open (or Disconnected)
ALRML goes high (see Note 6).
Short to Pin 2
ALRML goes high.
Open (or Disconnected)
ALRML goes high.
Short to Pin 3
No effect.
Open (or Disconnected)
No effect.
Short to Pin 4
No effect.
Open (or Disconnected)
• If open occurs before power-up, the part works as if C12 does not exist
because the internal circuit detects the situation and assumes it is what the
application intended to do. The monitoring of C12 to C11 is disabled and is
not enabled even if the pin is reconnected.
• If open occurs after power-up, it is considered a zero voltage input. ALRML
goes high when the undervoltage is enabled.
Short to Pin 5
• If short occurs before power-up, the part works as if C12 does not exist
because the internal circuit detects the situation and assumes it is what the
application intended to do. The monitoring of C12 to C11 is disabled and is
not enabled even if the short is removed.
• If short occurs after power-up, the situation is treated as a zero voltage input
for C12 to C11. ALRML goes high when the undervoltage is enabled.
Open (or Disconnected)
ALRML goes high because it causes an overvoltage to the affected input pair
even if the overvoltage is set to the maximum.
Short to Pin 6
• If short occurs before power-up, the part works as if C11 does not exist
because the internal circuit detects the situation and assumes it is what the
application intended to do. The monitoring of C11 to C10 is disabled and is
not enabled even if the short is removed.
• If short occurs after power-up, the situation is treated as a zero voltage input
for C11 to C10. ALRML goes high when the undervoltage is enabled.
Open (or Disconnected)
ALRML goes high as it causes an overvoltage to the affected input pair even if
the overvoltage is set to the maximum.
Short to Pin 7
• If short occurs before power-up, the part works as if C10 does not exist
because the internal circuit detects the situation and assumes it is what the
application intended to do. The monitoring of C10 to C9 is disabled and is
not enabled even if the short is removed.
• If short occurs after power-up, the situation is treated as a zero voltage input
for C10 to C9. ALRML goes high when the undervoltage is enabled.
Open (or Disconnected)
ALRML goes high as it causes an overvoltage to the affected input pair even if
the overvoltage is set to the maximum.
Short to Pin 8
• If short occurs before power-up, the part works as if C9 does not exist
because the internal circuit detects the situation and assumes it is what the
application intended to do. The monitoring of C9 to C8 is disabled and is not
enabled even if the short is removed.
• If short occurs after power-up, the situation is treated as a zero voltage input
for C9 to C8. ALRML goes high when the undervoltage is enabled.
C12
C11
C10
C9
______________________________________________________________________________________
12-Channel, High-Voltage Battery-Pack
Fault Monitor
PIN
NUMBER
8
9
10
11
12
NAME
ACTION
EFFECT
Open (or Disconnected)
ALRML goes high as it causes an overvoltage to the affected input pair even if
the overvoltage is set to the maximum.
Short to Pin 9
• If short occurs before power-up, the part works as if C8 does not exist
because the internal circuit detects the situation and assumes it is what the
application intended to do. The monitoring of C8 to C7 is disabled and is not
enabled even if the short is removed.
• If short occurs after power-up, the situation is treated as a zero voltage input
for C8 to C7. ALRML goes high when the undervoltage is enabled.
Open (or Disconnected)
ALRML goes high as it causes an overvoltage to the affected input pair even if
the overvoltage is set to the maximum.
Short to Pin 10
• If short occurs before power-up, the part works as if C7 does not exist
because the internal circuit detects the situation and assumes it is what the
application intended to do. The monitoring of C7 to C6 is disabled and is not
enabled even if the short is removed.
• If short occurs after power-up, the situation is treated as a zero voltage input
for C7 to C6. ALRML goes high when the undervoltage is enabled.
Open (or Disconnected)
ALRML goes high as it causes an overvoltage to the affected input pair even if
the overvoltage is set to the maximum.
Short to Pin 11
• If short occurs before power-up, the part works as if C6 does not exist
because the internal circuit detects the situation and assumes it is what the
application intended to do. The monitoring of C6 to C5 is disabled and is not
enabled even if the short is removed.
• If short occurs after power-up, the situation is treated as a zero voltage input
for C6 to C5. ALRML goes high when the undervoltage is enabled.
Open (or Disconnected)
ALRML goes high as it causes an overvoltage to the affected input pair even if
the overvoltage is set to the maximum.
Short to Pin 12
• If short occurs before power-up, the part works as if C5 does not exist
because the internal circuit detects the situation and assumes it is what the
application intended to do. The monitoring of C5 to C4 is disabled and is not
enabled even if the short is removed.
• If short occurs after power-up, the situation is treated as a zero voltage input
for C5 to C4. ALRML goes high when the undervoltage is enabled.
Open (or Disconnected)
ALRML goes high as it causes an overvoltage to the affected input pair even if
the overvoltage is set to the maximum.
Short to Pin 13
• If short occurs before power-up, the part works as if C4 does not exist
because the internal circuit detects the situation and assumes it is what the
application intended to do. The monitoring of C4 to C3 is disabled and is not
enabled even if the short is removed.
• If short occurs after power-up, the situation is treated as a zero voltage input
for C4 to C3. ALRML goes high when the undervoltage is enabled.
C8
C7
C6
C5
C4
______________________________________________________________________________________
23
MAX11080
Table 4. FEMA Analysis (Note 5) (continued)
MAX11080
12-Channel, High-Voltage Battery-Pack
Fault Monitor
Table 4. FEMA Analysis (Note 5) (continued)
PIN
NUMBER
13
14
15
16
17
18
19
24
NAME
ACTION
EFFECT
Open (or Disconnected)
ALRML goes high as it causes an overvoltage to the affected input pair even if
the overvoltage is set to the maximum.
Short to Pin 14
• If short occurs before power-up, the part works as if C3 does not exist
because the internal circuit detects the situation and assumes it is what the
application intended to do. The monitoring of C3 to C2 is disabled and is not
enabled even if the short is removed.
• If short occurs after power-up, the situation is treated as a zero voltage input
for C5 to C4. ALRML goes high when the undervoltage is enabled.
Open (or Disconnected)
ALRML goes high as it causes an overvoltage to the affected input pair even if
the overvoltage is set to the maximum.
Short to Pin 15
• If short occurs before power-up, the part works as if C2 does not exist
because the internal circuit detects the situation and assumes it is what the
application intended to do. The monitoring of C2 to C1 is disabled and is not
enabled even if the short is removed.
• If short occurs after power-up, the situation is treated as a zero voltage input
for C2 to C1. ALRML goes high when the undervoltage is enabled.
Open (or Disconnected)
ALRML goes high as it causes an overvoltage to the affected input pair even if
the overvoltage is set to the maximum.
Short to Pin 16
ALRML goes high irrespective of whether undervoltage is enabled/disabled
and before and after power-up.
Open (or Disconnected)
ALRML goes high irrespective of whether undervoltage is enabled/disabled
and before and after power-up.
Short to Pin 17
• ALRML goes high if pin 17 is pulled high by VAA. The part consumes a large
current as VAA is shorted to AGND (connected to C0).
• If pin 17 is tied to AGND, there is no effect.
Open (or Disconnected)
The pin defaults to low due to the internal pulldown (see Note 7). The effect
depends on the intended undervoltage setting.
Short to Pin 18
• If pin 17 and pin 18 have the same intended value, there is no effect for the
short.
• If pin 17 and pin 18 have a different setting, the VAA is shorted to AGND.
ALRML goes low.
Open (or Disconnected)
The pin defaults to low due to the internal pulldown (see Note 7). The effect
depends on the intended undervoltage setting.
Short to Pin 19
• If pin 18 and pin 19 have the same intended value, there is no effect for the
short.
• If pin 18 and pin 19 have a different setting, the VAA is shorted to AGND.
ALRML goes low.
Open (or Disconnected)
The pin defaults to low due to the internal pulldown (see Note 7). The effect
depends on the intended undervoltage setting.
Short to Pin 20
• If pin 19 and pin 20 have the same intended value, there is no effect for the
short.
• If pin 19 and pin 20 have the different setting, the VAA is shorted to. AGND
ALRML goes low.
C3
C2
C1
C0
UVSEL0
UVSEL1
UVSEL2
______________________________________________________________________________________
12-Channel, High-Voltage Battery-Pack
Fault Monitor
PIN
NUMBER
20
21
22
23
NAME
Open (or Disconnected)
The pin defaults to low due to the internal pulldown (see Note 7). The effect
depends on the intended overvoltage setting.
Short to Pin 22
• If pin 21 and pin 22 have the same intended value, there is no effect for the
short.
• If pin 21 and pin 22 have a different setting, the VAA is shorted to AGND.
ALRML goes low.
Open (or Disconnected)
The pin defaults to low due to the internal pulldown (see Note 7). The effect
depends on the intended overvoltage setting.
Short to Pin 23
• If pin 22 and pin 23 have the same intended value, there is no effect for the
short.
• If pin 22 and pin 23 have a different setting, the VAA is shorted to AGND.
ALRML goes low.
Open (or Disconnected)
The pin defaults to low due to the internal pulldown (see Note 7). The effect
depends on the intended overvoltage setting.
Short to Pin 24
• If pin 23 is set high, there is no effect for the short.
• If pin 23 is set low, the VAA is shorted to AGND. ALRML goes low.
Open (or Disconnected)
ALRML goes high.
Short to Pin 25
ALRML goes low.
Open (or Disconnected)
VAA goes to approximately 100mV and ALRML is approximately 0.5V. There is
no heartbeat if there is a one before the opening.
Short to Pin 26
The device is in shutdown mode. ALRML is low.
Open (or Disconnected)
The pin is internally pulled down and the device goes to the shutdown mode.
ALRML is low.
Short to Pin 27
ALRML goes high and stays high even if the short is removed. The internal
detect circuit considers this a major failure and the part has to be repowered
up to come out of this state.
Open (or Disconnected)
The signal at the ALRML cannot be seen by the host.
Short to Pin 28
ALRML goes high and stays high even if the short is removed. The internal
detect circuit considers this a major failure and the part has to be repowered
up to come out of this state.
Open (or Disconnected)
The delay between the fault condition and alarm setting (ALRML goes high)
goes to the minimum. This means there is almost no delay.
Short to Pin 29
The delay between the fault condition and alarm setting (ALRML goes high) is
approximately 4s, which is set by the internal watchdog.
OVSEL3
AGND
28
Short to Pin 21
• If pin 20 and pin 21 have the same intended value, there is no effect for the
short.
• If pin 20 and pin 21 have a different setting, the VAA is shorted to AGND.
ALRML goes low.
OVSEL2
25
27
The pin defaults to low due to the internal pulldown (see Note 7). The effect
depends on the intended overvoltage setting.
OVSEL1
VAA
SHDN
ALRML
EFFECT
Open (or Disconnected)
OVSEL0
24
26
ACTION
CD
______________________________________________________________________________________
25
MAX11080
Table 4. FEMA Analysis (Note 5) (continued)
MAX11080
12-Channel, High-Voltage Battery-Pack
Fault Monitor
Table 4. FEMA Analysis (Note 5) (continued)
PIN
NUMBER
NAME
29
AGND
30
31
AGND
EFFECT
Open (or Disconnected)
No effect.
Short to Pin 30
No effect.
Open (or Disconnected)
No effect.
Short to Pin 31
If pin TOPSEL is set high (VAA), it causes the short between VAA and AGND.
ALRML is low.
There is no effect if TOPSEL is set low.
Open (or Disconnected)
If the part is the topmost device in the daisy chain, the ALRML is set high as
the state of TOPSEL is low (internally pulled down).
There are no other effects as the state of the pin stays the same (both low).
Short to Pin 32
No effect if TOPSEL is set low.
If TOPSEL is set high, it causes the short between VAA and AGND and ALRML
is low.
TOPSEL
32
AGND
33
N.C.
34
ACTION
Open (or Disconnected)
No effect.
Short to Pin 33
No effect.
Open (or Disconnected)
No effect.
Short to Pin 34
No effect.
Open (or Disconnected)
ALRMU is internally pulled up to VDDU. There is no effect to the topmost
device. Otherwise, the communication of the chain is broken and the alarm
signal from the parts close to the topmost device are not passed through.
Since ALRML is a reflection of ALRMU, the state of ALRML is high for the noalarm state.
Short to Pin 35
No effect for the topmost device. Otherwise, the communication of the chain is
broken and the alarm signal from the parts close to the topmost are not
passed through. Since ALRML is a reflection of ALRMU, the state of ALRML is
low for the no-alarm state.
Open (or Disconnected)
The ALRML goes high. VDDU floats down approximately 4V. (See Note 8.)
Short to Pin 36
The ALRML is high. (See Note 8).
Open (or Disconnected)
ALRML goes high. HV is approximately 0.4V below DCIN. (See Note 8.)
Short to Pin 37
ALRML goes high. VDDU is approximately 0.5V lower than GNDU.
(See Note 8.)
Open (or Disconnected)
ALRML goes high. VDDU and HV collapse.
Short to Pin 38
ALRML goes high. VDDU is approximately 0.5V lower than GNDU.
(See Note 8.)
Open (or Disconnected)
ALRML goes high. VDDU and HV collapse. (See Note 8.)
ALRMU
35
GNDU
36
VDDU
37
CP-
38
CP+
Note 5: If the cell voltage is within the monitor range, the heartbeat signal on the ALRML resumes once the fault condition is
removed.
Note 6: The voltage level of high is equal to VAA and low is equal to AGND.
Note 7: Even if the pin has internal pulldown, the pulldown is very weak and the pin should be tied to AGND for logic 0 setting.
Note 8: VDDU - GNDU = 3.3 - V and HV - DCIN = 3.6V for the typical configuration. When VDDU and HV collapse, VDDU - GNDU ≈
0 - V and HV - DCIN ≈ -0.4V.
26
______________________________________________________________________________________
12-Channel, High-Voltage Battery-Pack
Fault Monitor
Package Information
For the latest package outline information and land patterns, go
to www.maxim-ic.com/packages.
TOP VIEW
DCIN
1
HV
+
38
CP+
2
37
CP-
N.C.
3
36
VDDU
C12
4
35
GNDU
C11
5
34
ALRMU
C10
6
33
N.C.
C9
7
32
AGND
C8
8
31
TOPSEL
C7
9
30
AGND
C6
10
29
AGND
C5
11
28
CD
C4
12
27
ALRML
C3
13
26
SHDN
C2
14
25
AGND
C1
15
24
VAA
C0
16
23
OVSEL3
UVSEL0
17
22
OVSEL2
UVSEL1
18
21
OVSEL1
UVSEL2
19
20
OVSEL0
MAX11080
PACKAGE TYPE
PACKAGE CODE
DOCUMENT NO.
38 TSSOP
U38-1
21-0081
TSSOP
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 ____________________ 27
© 2009 Maxim Integrated Products
Maxim is a registered trademark of Maxim Integrated Products, Inc.
MAX11080
Pin Configuration