TI BQ78PL114RGZR

bq78PL114
www.ti.com .................................................................................................................................... SLUS850A – SEPTEMBER 2008 – REVISED SEPTEMBER 2008
PowerLAN™ Master Gateway Battery Management Controller
With PowerPump™ Cell Balancing Technology
FEATURES
APPLICATIONS
• Designed for Managing up to 12 Series Cell
Battery Systems
• SmartSafety Features:
– Prevention: Optimal Cell Management
– Diagnosis: Improved Sensing of Cell
Problems
– Fail Safe: Detection of Event Precursors
• Rate-of-Change Detection of All Important Cell
Characteristics:
– Voltage
– Impedance
– Cell Temperature
• PowerPump Technology Transfers Charge
Efficiently From Cell to Cell During All
Operating Conditions, Resulting in Longer
Run Time and Cell Life
• High-Resolution 18-Bit Integrating Delta-Sigma
Coulomb Counter for Precise Charge-Flow
Measurements and Gas Gauging
• Multiple Independent Δ-Σ ADCs: One-per-Cell
Voltage, Plus Separate Temperature, Current,
and Safety
• Simultaneous, Synchronous Measurement of
Pack Current and Individual Cell Voltages
• Very Low Power Consumption: < 250 µA
Active, < 150 µA Standby, < 40 µA Ship, and
< 1-µA Undervoltage Shutdown
• Accurate, Advanced Temperature Monitoring
of Cells and MOSFETs With up to Six Sensors
• Fail-Safe Operation of Pack Protection
Circuits: Up to Three Power MOSFETs and
One Secondary Safety Output (Fuse)
• Fully Programmable Voltage, Current, Balance,
and Temperature-Protection Features
• External Inputs for Auxiliary MOSFET Control
• Smart Battery System 1.1 Compliant via
SMBus or SPI Interface With SHA-1
Authentication Option
•
1
23
•
•
Portable Medical Instruments and Test
Equipment
Mobility Devices (E-Bike)
Uninterruptible Power Supplies and Hand-Held
Tools
DESCRIPTION
The bq78PL114 master gateway battery controller is
part of a complete Li-Ion control, monitoring, and
safety solution designed for large series cell strings.
The bq78PL114, along with PowerLAN cell monitors,
provides
complete
battery
system
control,
communications, and safety functions for a structure
of three to 12 series cells. This PowerLAN system
provides simultaneous, synchronized voltage and
temperature measurements using one-ADC-per-cell
technology. Voltage measurements are also
synchronized with pack current measurements,
eliminating
system-induced
noise
from
measurements. This allows the precise, continuous,
real-time calculation of cell impedance under all
operating conditions, even during widely fluctuating
load conditions.
PowerPump technology transfers charge between
cells to balance their voltage and capacity. Balancing
is possible during all battery modes: charge,
discharge, and rest. Highly efficient charge-transfer
circuitry nearly eliminates energy loss while providing
true real-time balance between cells, resulting in
longer run-time and improved cycle life.
Temperature is sensed by up to six external sensors.
This permits accurate temperature monitoring of each
cell individually. Firmware is then able to compensate
for the temperature-induced effects on capacity,
impedance, and OCV on a cell-by-cell basis, resulting
in superior charge/ discharge and balancing control.
External MOSFET control inputs provide userdefinable direct hardware control over MOSFET
states. Smart control prevents excessive current
through MOSFET body diodes. Auxiliary inputs can
be used for enhanced safety and control in large
multicell arrays.
1
2
3
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas
Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
PowerLAN, PowerPump, bqWizard are trademarks of Texas Instruments.
All other trademarks are the property of their respective owners.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2008, Texas Instruments Incorporated
bq78PL114
SLUS850A – SEPTEMBER 2008 – REVISED SEPTEMBER 2008 .................................................................................................................................... www.ti.com
These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
DESCRIPTION (CONTINUED)
The bq78PL114 is completely user-configurable, with parametric tables in flash memory to suit a variety of cell
chemistries, operating conditions, safety controls, and data reporting needs. It is easily configured using the
supplied bqWizard™ graphical user interface (GUI). The device is fully programmed and requires no algorithm or
firmware development.
P-LAN
PRE
V3
Voltage
PUMP3
Balance
Temp
XT3
V2
Voltage
PUMP2
Balance
Temp
XT2
V1
Voltage
PUMP1
Balance
Temp
XT1
CHG
FLASH
First-Level Safety
and
FET Control
DSG
EFCID
EFCIC
SPROT
RISC
CPU
SRAM
XT4
CELL 4
Balance
Temp
CELL 3
PUMP4
CELL 2
Voltage
Second-Level
Safety
CSBAT
Coulomb Counter
CCBAT
CSPACK
Current A/D
CELL 1
V4
PowerLAN
Communication
Link
RSTN
Reset
Logic
VLDO1
Watchdog
GPIO
Internal
Oscillator
SMBus
CCPACK
6
LED1–5,
LEDEN
SMBCLK
SMBDAT
SPI-DI
2.5 V LDO
Core / CPU
Measure
Internal
Temperature
SPI
SPI-DO
SPI-CLK
SELECT
I/O
Safety
B0320-02
Figure 1. bq78PL114 Internal Block Diagram
2
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–
Pack
Positive
SMBus
Pack
Negative
+
Pack Protection
Circuits and Fuse
Example 8-cell configuration shown
PowerLAN
Communication
Link
RSENSE
PowerLAN
Master Gateway
Battery Controller
bq78PL114
bq76PL102 Cell
Monitor With
PowerPump
Balancing
bq76PL102 Cell
Monitor With
PowerPump
Balancing
B0332-01
Figure 2. Example PowerLAN Multicell System Implementation
ORDERING INFORMATION (1)
Product
Cell Configuration (2)
bq78PL114
3 to 8 series cells
bq78PL114
(PREVIEW)
bq78PL114
(PREVIEW)
(1)
(2)
(3)
3 to 10 series cells
Package
QFN-48, 7-mm
× 7-mm
Package
Designator
RGZ
Temperature
Range
Ordering Number
Quantity,
Transport
Media
bq78PL114RGZT
250, tape and
reel
bq78PL114RGZR
2500, tape and
reel
bq78PL114S10RGZT (3)
250, tape and
reel
bq78PL114S10RGZR (3)
2500, tape and
reel
bq78PL114S12RGZT (3)
250, tape and
reel
bq78PL114S12RGZR (3)
2500, tape and
reel
–40°C to 85°C
3 to 12 series cells
Authentication options are also available; contact TI for additional information.
For configurations consisting of more than four series cells, additional bq76PL102 parts must be used.
Some historical data storage limits exist for the S10 and S12 versions.
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bq78PL114
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AVAILABLE OPTIONS
V1
XT1
XT2
V2
VLDO2
V3
XT3
XT4
V4
SMBDAT
SMBCLK
46
45
44
43
42
41
40
39
38
37
DSG
47
1
VSS
CHG
48
bq78PL114
RGZ Package
(Top View)
36
LED5
2
35
LED4
PRE
3
34
LED3
EFCIC
4
33
LED2
EFCID
5
32
LED1
CCBAT
6
31
LEDEN
Thermal Pad
24
RSTN
P-LAN
25
23
12
P4N
OSCO
22
SPI-CLK
P4S
26
21
11
P3N
OSCI
20
SPI-DI
P3S
27
19
10
SDI3
CSPACK
18
SPI-DO
SDO2
28
17
9
P2N
CSBAT
16
SELECT
P2S
29
15
8
P1N
VLDO1
14
SPROT
SDI1
30
13
7
SDO0
CCPACK
P0023-16
Figure 3. bq78PL114 Pinout
TERMINAL FUNCTIONS
NAME
NO.
TYPE
(1)
DESCRIPTION
CCBAT
6
IA
Coulomb counter input (sense resistor), connect to battery negative
CCPACK
7
IA
Coulomb counter input (sense resistor), connect to pack negative
CHG
1
O
Charge MOSFET control (active-high, enables current flow)
CSBAT
9
IA
Current sense input (safety), connect to battery negative
CSPACK
10
IA
Current sense input (safety), connect to pack negative
DSG
2
O
Discharge MOSFET control (active-high, low opens MOSFET)
EFCIC
4
I
External charge MOSFET control input
External discharge MOSFET control input
EFCID
5
I
LED1
32
IO
LED1 – active-low
LED2
33
IO
LED2 – active-low
LED3
34
IO
LED3 – active-low
LED4
35
IO
LED4 – active-low
LED5
36
IO
LED5 – active-low
LEDEN
31
IO
LEDEN – common-anode drive (active-high)
OSCI
11
I
External oscillator input (optional)
OSCO
12
O
External oscillator output (optional)
(1)
4
I – input, IA – analog input, O – output, OA – analog output, P – power
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TERMINAL FUNCTIONS (continued)
NO.
TYPE (1)
P1N
15
O
Charge-balance gate drive, cell 1 north
P2S
16
O
Charge-balance gate drive, cell 2 south
P2N
17
O
Charge-balance gate drive, cell 2 north
P3N
21
O
Charge-balance gate drive, cell 3 north
P3S
20
O
Charge-balance gate drive, cell 3 south
P4N
23
O
Charge-balance gate drive, cell 4 north
P4S
22
O
Charge-balance gate drive, cell 4 south
P-LAN
24
IO
PowerLAN I/O to external bq76PL10x nodes
PRE
3
O
Pre-Charge MOSFET control (active-high.)
RSTN
25
I
Device reset, active-low
SDI1
14
I
Connect to SDO0 via a capacitor
SDI3
19
I
Internal PowerLAN connection – connect to SDO2
SDO0
13
O
Requires 100-kΩ pullup resistor to VLDO1
SDO2
18
O
Internal PowerLAN connection – connect to SDI3
SELECT
29
O
Auxiliary SPI control output
SMBCLK
37
IO
SMBus clock signal
SMBDAT
38
IO
SMBus data signal
SPI-CLK
26
IO
SPI port clock (2)
SPI-DI
27
I
SPI master-out-slave-in
(2)
SPI-DO
28
O
SPI master-in-slave-out
(2)
SPROT
30
O
Secondary protection output, active-high (FUSE)
V1
47
IA
Cell-1 positive input
V2
44
IA
Cell-2 positive input
V3
42
IA
Cell-3 positive input
V4
39
IA
Cell-4 positive input
VLDO1
8
P
Internal LDO-1 output, bypass with capacitor
VLDO2
43
P
Internal LDO-2 output, bypass with capacitor
VSS
48
IA
Cell-1 negative input
XT1
46
IA
External temperature-sensor-1 input
XT2
45
IA
External temperature-sensor-2 input
XT3
41
IA
External temperature-sensor-3 input
XT4
40
IA
External temperature-sensor-4 input
–
–
P
Thermal pad. Connect to VSS
NAME
(2)
DESCRIPTION
(2)
SPI functionality requires a firmware option, consult the factory for additional information.
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bq78PL114
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ABSOLUTE MAXIMUM RATINGS (1)
over operating free-air temperature range (unless otherwise noted)
RANGE
UNITS
TA
Operating free-air temperature (ambient)
–40 to 85
°C
Tstg
Storage temperature
–65 to 150
°C
V4–V3
Maximum cell voltage
–0.5 to 5.0
V
V3–V2
Maximum cell voltage
–0.5 to 5.0
V
V2–V1
Maximum cell voltage
–0.5 to 5.0
V
V1–VSS
Maximum cell voltage
–0.5 to 5.0
V
Voltage on LED1–LED5, CCBAT,
CCPACK, CSBAT, CSPACK, XT1, XT2,
OSCI, OSCO, SDIx, SDOx, SPROT,
P-LAN
Maximum voltage on any I/O pin
(VSS – 0.5) to
(VLDO1 + 0.5)
V
Voltage on XT3, XT4, LEDEN
Maximum voltage range
(V2 – 0.5) to
(VLDO2 + 0.5)
V
EFCIC, EFCID
With respect to VSS
–0.5 to 5.5
V
Voltage on SMBCLK, SMBDAT
With respect to VSS
–0.5 to 6
V
Voltage on PRE, CHG, DSG
With respect to VSS
–0.5 to (VLDO1 + 0.5)
V
Current through PRE, CHG, DSG,
LED1–LED5, P-LAN
Maximum current source/sink
20
mA
VLDO1 maximum current
Maximum current draw from VLDO
20
mA
ESD tolerance
JEDEC, JESD22-A114 human-body model, R = 1500 Ω, C =
100 pF
2
kV
Lead temperature, soldering
Total time < 3 seconds
300
°C
(1)
6
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 under Recommended Operating
Conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
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ELECTRICAL CHARACTERISTICS
TA = –40°C to 85°C (unless otherwise noted)
DC Characteristics
PARAMETER
VCELL
(1)
TEST CONDITIONS
MIN
TYP
MAX
Operating range
Cells balanced
IDD
Operating-mode current
Measure / report state
250
µA
ISTBY
Standby-mode current
SMBCLK = SMBDAT = L
100
µA
ISHIP
Ship-mode current
30
µA
IECUV
Extreme cell under voltage
shutdown current
All cells < 2.7 V and any cell < ECUV set
point
VOL
General I/O pins
IOL < 4 mA
VOH (2)
General I/O pins
IOH < –4 mA
VIL
General I/O pins
VIH
General I/O pins
(1)
(2)
2.3
4.5
UNIT
0
V
1
µA
0.5
V
VLDO1 – 0.1
V
0.25 VLDO1
0.75 VLDO1
V
V
Device remains operational to 1.85 V with reduced accuracy and performancce.
Does not apply to SMBus pins.
Voltage-Measurement Characteristics
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
Measurement range
TYP
MAX
2.5
Resolution
4.5
<1
25°C
Accuracy
V
mV
±5
0°C to 60°C
UNIT
mV
±10
Current-Sense Characteristics
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
Measurement range (1)
MIN
TYP
MAX
–0.2
0.2
UNIT
V
Input offset
TA = 25°C
±50
µV
Offset drift
TA = 0°C to 60°C
0.5
µV/°C
18
µV
Resolution
Full-scale error (2)
TA = 25°C
Full-scale error drift
TA = 0°C to 60°C
(1)
(2)
±0.1%
50
PPM/°C
Default range. Corresponds to ±10 A using a 10-mΩ sense resistor. Other gains and ranges are available (eight options).
After calibration. Accuracy is dependent on system calibration and temperature coefficient of sense resistor.
Coulomb-Counter Characteristics (1)
(2)
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
Resolution
TYP
Intergral nonlinearity
0.008%
Snap-to-zero (deadband)
±100 (3)
(1)
(2)
(3)
MAX
5
UNIT
nVh
µV
Shares common input with Current Sense section
After calibration. Accuracy is dependent on system calibration and temperature coefficient of sense resistor.
Corresponds to 20 mA using 5-mΩ sense resistor
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Current-Sense (Safety) Characteristics (1)
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
Measurement range
Short-circuit detection
Resolution
(1)
TYP
–0.312
MAX
UNIT
0.312
V
10
Overcurrent detection, charge and discharge
mV
1.25
Post calibration: Dependent on system calibration and temperature coefficient of sense resistor. Uncertainty 1.5 LSB.
Internal Temperature-Sensor Characteristics (1)
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
Measurement range
Resolution
Accuracy
(1)
TYP
–30
(1)
–30° to 85°
MAX
85
UNIT
°C
0.1
°C
±1
°C
After calibration.
External Temperature-Sensor(s) Typical Characteristics (1)
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
Measurement range (2)
TYP
–40
90
Resolution
0.2
Accuracy (3)
(1)
(2)
(3)
MAX
25°
±1
0° to 85°
±2
UNIT
°C
°C
°C
Typical for dual diode (MMBD4148 or equivalent) external sensor using recommended circuit.
Range of diode sensors may exceed operational limits of IC and battery cells.
Typical behavior after calibration, final result dependent on specific component characteristics.
SMBus Characteristics (1)
over operating free-air temperature range (unless otherwise noted)
PARAMETER
VIL
Input low voltage
VIH
Input high voltage
VOL
Output low voltage
CI
Capacitance, each I/O pin
fSCL
SCLK nominal clock frequency
RPU (2)
Pullup resistors for SCLK, SDATA
(1)
(2)
8
TEST CONDITIONS
350-µA sink current
MIN
TYP
MAX
UNIT
0
0.8
V
2.1
5.5
V
0
0.4
V
10
pF
TA = 25°C
100
kHz
VBUS 5 V nominal
13.3
45.3
VBUS 3 V nominal
2.4
6.8
kΩ
SMBus timing and signals meet the SMBus 2.0 specification requirements under normal operating conditions. All signals are measured
with respect to PACK-negative.
Pullups are typically implemented external to battery pack, and are selected to meet SMBus requirements.
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RPRE
+
PACK+
PRE
CHG
DSG
Level-Shift Circuits
SDI1
SDO2
SDO0
Cell Balancing
Circuits
CELL 6
V2
V1
bq76PL102
SDI3
VLDO1
RSTN
P-LAN
CELL 5
SPROT
V4
bq78PL114
PowerLAN
Gateway Battery LED1–LED5
Management
Controller
Aux FET
Control
EFCIC
VLDO2
EFCID
V2
SPI-CLK
SPI-DO
SPI-DI
V1
SELECT
CELL 1
SPI
CELL 2
V3
5
ESD Protection
CELL 3
Cell Balancing Circuits
CELL 4
SMBus
XT1–XT4
SMBCLK
CSPACK
CCPACK
CCBAT
CSBAT
Thermal Pad
CRFI
SMBDAT
VSS
Temperature
Sensor (typ.)
One of 4 external
sensors shown
–
Typical six-cell configuration shown.
Additional cells added via PowerLAN connection.
Some components omitted for clarity.
PACK–
RSENSE
S0342-02
Figure 4. bq78PL114 Simplified Example Circuit Diagram
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bq78PL114
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FEATURE SET
Primary (First-Level) Safety Features
The bq78PL114 implements a breadth of system protection features which are easily configured by the
customer. First-level protections work by controlling the MOSFET switches. These include:
• Battery cell over/undervoltage protection
• Pack over/undervoltage protection
• Charge and discharge overcurrent protection
• Short-circuit protection
• External MOSFET control inputs (EFCIx) with programmable polarity
• Up to four external temperature inputs for accurate cell and MOSFET monitoring
• Watchdog timer protection
• Brownout detection and protection against extreme pack undervoltage
Secondary (Second-Level) Safety Features
The bq78PL114 can detect more serious system faults and activate the SPROT pin, which can be used to open
an in-line chemical fuse to permanently disable the pack. Secondary optional features include
• Fully independent of first-level protections
• SmartSafety algorithms for early detection of potential faults
– Temperature abnormalities (variances, extremes, rate of change, etc.)
– Disconnected cell voltage inputs
– Cell imbalance exceeds safety limits
– Impedance rise due to cell or weld strap fault
• MOSFET failure or loss of MOSFET control
• Safety overvoltage, pack and cell
• Safety overtemperature, limits for both charge and discharge
• Safety overcurrent, charge and discharge
• Failed current measurement, voltage measurement, or temperature measurement
Charge Control Features
• Meets SMBus 2.0 and Smart Battery System (SBS) Specification 1.1 requirements
• Active cell balancing using patented PowerPump technology, which eliminates unrecoverable capacity loss
due to normal cell imbalance
• Balancing-current monitoring to detect cell problems
• Simultaneous, synchronous measurement of all cell voltages in a pack
• Simultaneous, synchronous measurement of pack current with cell voltages
• Reports target charging current and/or voltage to an SBS Smart Charger
• Reports the chemical state-of-charge for each cell and pack
• Supports precharging and zero-volt charging with separate MOSFET control
• Programmable, Chemistry-specific parameters
• Fault reporting
Gas Gauging
• The bq78PL114 accurately reports battery cell and pack state-of-charge (SOC). No full charge/discharge
cycle is required for accurate reporting.
• State-of-charge is reported via SMBus and optional LED display.
• 18-bit integrating delta-sigma ADC coulomb counter, with programmable snap-to-zero value
LED Display
• The bq78PL114 drives a three- to five-egment LED display in response to a pushbutton (LEDEN) input signal.
Each LED pin can sink up to 10 mA.
10
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Lifetime Data Logging (Readable via SMBus or SPI)
• Recording of faults, events, anomalies, minimum and maximum values
• Maximum/minimum temperature
• Maximum/minimum pack voltage
• Maximum/minimum cell voltages
• Maximum charge and discharge currents
Forensic Data Logging (Readable via SMBus or SPI)
• Last known full capacity of each cell
• Cycle count and/or cumulative number of ampere-hours delivered by the battery
• Battery pack status: being charged, discharged, or at rest
• Balancing effort required by each bank of cells to maintain balance
• Information for each cell bank for period leading up to failure
• Last 10 failures causing first-level safety action
• Forensic data up-loadable to host CPU via SMBus or SPI
• Forensic data recording of anomalies and events
Power Modes
• Normal Mode: The bq78PL114 performs measurements and calculations, makes decisions, and updates
internal data approximately once per second. All safety circuitry is fully functional in this mode.
• Standby Mode: The bq78PL114 performs as in normal mode, but at a dramatically reduced rate to lower
power consumption at times when the host computer is inactive or the battery system is not being used. All
safety circuitry remains fully functional in this mode.
• Ship Mode: The bq78PL114 disables (opens) all the protection MOSFETs, and continues to monitor
temperature and voltage, but at a reduced measurement rate to dramatically lower power consumption.
Environmental data is saved in flash as a part of the historical record. Safety circuitry is disabled in this mode.
The device does not enter this power state as a part of normal operation; it is intended for use after factory
programming and test. Entry occurs only after a unique SMBus or SPI command is issued. Exit occurs when
the SMBus or SPI lines return to an active state.
• Extreme Cell Undervoltage (ECUV) Shutdown Mode: In this mode, the bq78PL114 draws minimal current
and the charge and discharge protection MOSFETs are disabled (opened). The precharge MOSFET remains
enabled when a charge voltage is present. Safety circuitry is disabled in this mode. The device does not enter
this mode as a part of normal operation; it enters this state during extreme cell undervoltage conditions
(ECUV). The ECUV threshold is fully programmable below 2.7V.
STATE
CURRENT
DRAW (Typ)
OVERCURRENT
PROTECTION
ENTRY CONDITION
EXIT CONDITION
Active
< 250 µA
Fully active
Normal operation as determined by
firmware
Firmware directed to the following
operating modes
Standby
< 150 µA
Fully active
No load current flowing for
predetermined time
Load activity
Ship
< 40 µA
Not active
Protected SMBus or SPI command
SMBus or SPI becomes active
< 1 µA
Not active
(precharge
enabled)
Enabled when Vcell < ECUV
Vcell charge above ECUV recovery
threshold (2.7 V/cell typical)
Extreme cell
undervoltage
OPERATION
The bq78PL114 battery management controller serves as the master controller for a Li-Ion battery system
consisting of up to 12 cells in series. Any number may be connected in parallel; other system or safety issues
limit the number of parallel cells. The bq78PL114 provides extraordinarily precise state-of-charge gas gauging
along with first and second level pack safety functions. Voltage and current measurements are performed
synchronously and simultaneously for all cells in the system, allowing a level of precision not previously possible
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11
bq78PL114
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in battery management. Temperature is measured by up to four additional external temperature sensors, for a
total of five independent measurement points. (Additional cell temperature sensors are available in remote
bq76PL102 dual-cell battery monitors.) Coulomb counting is captured continuously by a dedicated 18-bit
integrating delta-sigma ADC in the bq78PL114. The CPU in the bq78PL114 is also responsible for system data
calculations, black-box forensic data storage, and communicating parameters via the SMBus or SPI interface.
PowerLAN Communication Link
PowerLAN technology is Texas Instruments’ patented serial network and protocol designed specifically for
battery management in a multicell system environment. The PowerLAN link is used to initiate and report
measurements of cell voltage and temperature, and control cell balancing. The bq78PL114 serves as the master
controller of the PowerLAN link and can interface to multiple bq76PL102 dual-cell battery monitors, which
measure and balance additional cells. The bq78PL114 monitors the first three or four cells, and bq76PL102s can
be added to monitor more series cells.
The PowerLAN link isolates voltages from adjacent bq76PL102 devices to permit high-voltage stack assembly
without compromising precision and accuracy. The PowerLAN link is expandable to support up to 12 cells in
series. Each bq76PL102 handles voltage and temperature measurements, as well as balancing for two cells. The
PowerLAN link provides high ESD tolerance and high immunity to noise generated by nearby digital circuitry or
switching currents. Each bq76PL102 has both a PowerLAN input and PowerLAN output: Received data is
buffered and retransmitted, permitting high numbers of nodes without loss of signal fidelity. Signals are
capacitor-coupled between nodes, providing dc isolation.
Safety
Unique in the battery-management controller market, the bq78PL114 simultaneously measures voltage and
current using independent and highly accurate delta-sigma ADCs. This technique removes virtually all systemic
noise from measurements, which are made during all modes of battery operation: charge, discharge, and rest.
The bq78PL114 also directs all connected bq76PL102 dual-cell battery monitors to measure each cell voltage
simultaneously with the bq78PL114 measurements. Battery impedance and self-discharge characteristics are
thus measured with an unprecedented level of accuracy in real time. The bq78PL114 applies this precise
information to SmartSafety algorithms to detect certain anomalies and conditions which may be indicative of
internal cell faults, before they become serious problems.
The bq78PL114 uses its enhanced measurement system to detect system faults including cell under- and
overvoltage, cell under- and overtemperature, system overvoltage, and system overcurrent. First-level safety
algorithms first attempt to open the MOSFET safety switches. If this fails, second-level safety algorithms activate
the SPROT output, normally used to open a fuse and provide permanent, hard protection for the systems.
External MOSFET control inputs with programmable polarity can also be used to operate the safety MOSFETs
under control of user supplied circuitry. The bq78PL114 continuously monitors these inputs. If any MOSFET fails
to open when commanded; the 2nd level safety algorithms also activate the SPROT output. All first- and
second-level safety algorithms have fully programmable time delays to prevent false triggering.
Cell Balancing
Patented PowerPump cell balancing technology drastically increases the useful life of battery packs by
eliminating the cycle life fade of multi-cell packs due to cell imbalance. PowerPump technology efficiently
transfers charge from cell to cell, rather than simply bleeding off charging energy as heat as is typically done with
resistive-bleed balancing circuits. Balancing is configurable and may be performed during any battery operational
modes: charge, discharge, or rest. Compared to resistive bleed balancing, virtually no energy is lost as heat. The
actual balance current is externally scalable and can range from 10 mA to 1 A (100 mA typical) depending on
component selection and system or cell requirements.
A variety of techniques, such as simple terminal voltage, terminal voltage corrected for impedance and
temperature effects, or state-of-charge balancing, is easily implemented by the bq78PL114. In some cases,
chemistry-specific algorithms are available. By tracking the balancing required by individual cells, overall battery
safety is enhanced, often allowing early detection of soft shorts or other cell failures. Balancing is achieved
between all cells within the pack as dynamically determined by the bq78PL114.
12
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Outputs
Charge Control
The CHG and PRE outputs are ordinarily used to drive MOSFET transistors controlling charge to the cell stack.
Charge or precharge mode is selected based on the present cell voltage compared to the user-definable cell
precharge, undervoltage, and temperature thresholds. When below these limits, the PRE signal is active and the
CHG signal is inactive. This turns on the precharge MOSFET and is used to charge a depleted system through a
current-limiting series resistor. When all cell voltages are above the limit and the temperature is above the charge
temperature minimum, then the CHG output also becomes active and enables the charge MOSFET to turn on,
providing a high-current path between charger and battery cells.
The CHG and PRE MOSFET control outputs are both disabled (low) when any cell reaches the safety cutoff limit
or temperature threshold. During active charging modes (and above cell voltage thresholds), the discharge
MOSFET is also enabled to avoid excessive heating of the body diode. Similarly, the charge MOSFET is active
during discharge, provided current flow is in the correct direction and no safety violations are present.
The CHG and PRE outputs are intended to drive buffer transistors acting as inverting level shifters.
Discharge Control
The DSG output operates similarly to control-system discharging. It is enabled (high) by default. If a cell voltage
falls below a programmable threshold, or excessive current or other safety related fault is sensed, the DSG
output is disabled (low) to prevent damage to the cells.
All facets of safely charging and discharging the cell stack are controlled by user-definable parameters which
provide precise control over MOSFET states. Both system and cell over- and undervoltage limits are provided, as
well as programmable hysteresis to prevent oscillation. Temperature and current thresholds are also provided,
each with independent timers to prevent nuisance activations.
LEDEN
LEDEN is a dual-function pin. One function is to provide output current to the LED display array. It also serves as
an input that monitors for closure of a state-of-charge indicator (SOCi) push-button switch.
LED SOCi Outputs
LED1–LED5 are current-sinking outputs designed to drive low-current LEDs. The LEDs can be activated by the
LEDEN pin via a pushbutton switch. They can be configured (using SBS parameters) to operate in bar or dot
mode and to use three to five LEDs to represent state-of-charge information.
Inputs
Current Measurement
Current is monitored by four separate ADCs. All use the same very low-value sense resistor, typically
10 milliohms in series with the pack negative connection. CCBAT and CCPACK connections to
resistor use an R/C filter for noise reduction. (CSBAT and CSPACK are direct connections used for
safety.) It is possible to use even lower values for the sense resistor in very high-current designs by
external circuitry. Contact Texas Instruments directly for details.
either 5 or
the sense
secondary
employing
A 14-bit delta-sigma ADC is used to measure current flow accurately in both directions. The measurements are
taken simultaneously and synchronously with all the cell voltage measurements, even those cells measured by
bq76PL102 dual-cell battery monitors.
Coulomb Counting
A dedicated coulomb counter is used to measure charge flow with 18 bit precision in both directions by a
calibrated, integrating delta-sigma ADC. This allows the bq78PL114 to keep very accurate state-of-charge (SOC)
information and battery statistics. A small deadband is applied to further reduce noise effects. The coulomb
counter is unique in that it continues to accumulate (integrate) current flow in either direction even as the rest of
the internal microcontroller is placed in a very low power state, further lowering power consumption without
compromising system accuracy.
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bq78PL114
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Safety Current
Two additional ADCs are used to directly monitor for overcurrent or short-circuit current conditions, independently
of the internal function. This provides a direct and rapid response to insure pack integrity and safe operation by
opening the appropriate MOSFETs. These functions are implemented in hardware, and do not require firmware
for functionality.
Voltage Measurement
Voltage measurement is performed by four independent delta-sigma ADCs which operate simultaneously and
are triggered synchronously so that all voltages are read at precisely the same moment. The bq78PL114
coordinates the attached bq76PL102 dual-cell battery monitors so they also perform their cell voltage
measurements in sync with the bq78PL114 voltage and current measurements. Voltage measurements are
converted with better than 1 mV of resolution, providing superior accuracy. One-ADC-per-cell technology means
that voltage is also measured simultaneously with current, permitting accurate, real-time cell impedance
calculation during all operating conditions. This technique also provides greatly enhanced noise immunity and
filtering of the input signal without signal loss.
Temperature Measurement
XT1–XT4 are dedicated temperature inputs. Each external sensor consists of a low-cost silicon diode (dual diode
in one package is recommended) and capacitor combination. XT1, multiplexed with the LED1 and LED2 inputs,
is used to measure cells 1 and 3. XT2, multiplexed with the LED1 and LED2 inputs, is used to measure cells 2
and 4. XT3 is a dedicated IC-temperature sensor, which should be placed near the bq78PL114 IC. XT4 is
dedicated to protection-MOSFET temperature and governed by safety rules. The sensor attached to XT4 should
be placed near the pack-disconnect MOSFETs. Temperatures for cells 5 and above are measured by external
bq76PL102(s), and the temperature data is received by the bq78PL114 over the PowerLAN link for processing.
The bq78PL114 can report all of these temperatures individually and as an average. A single internal, integrated
silicon sensor is also supplied in the bq78PL114.
Note that additional external temperature sensors can be added using bq76PL102 dual-cell battery monitors
operating on the PowerLAN link. Each bq76PL102 contains one internal temperature monitor and two additional
external temperature-sensor inputs (in addition to the two cell-voltage measurements and cell balancing).
EFCIx
The external MOSFET control inputs are for user control of MOSFETs based on external circuitry and conditions.
The polarity of the input signal is user programmable. Two modes of operation are possible. The first mode is
used to implement additional hardware safety inputs, and is used to force the protection MOSFETs to an OFF
state. The polarity of the input signals is programmable. The inputs can also be used to control the MOSFETs
directly through hardware, with no firmware operation required.
COMMUNICATIONS
SMBus
The bq78PL114 uses the industry-standard Smart Battery System’s two-wire System Management Bus (SMBus)
communications protocol for all external communication. SMBus version 2.0 is supported by the bq78PL114, and
includes clock stretching, bus fault time-out detection, and optional packet error checking (PEC). For additional
information, see the www.smbus.org and www.sbs-forum.org Web sites.
SPI
The bq78PL114 provides a standard serial peripheral interface (SPI) port consisting of SELECT, SPI-DI, SPI-DO,
and SPI-CLK signals. This port may be operated as a master or slave SPI port. A typical system configuration
uses the bq78PL114 as a SPI slave device so that a host controller could access the various battery data using
the industry-standard Smart Battery Data specification for content.
Alternatively, the SPI port may be operated as a master to allow the bq78PL114 to write selected system data to
another device for use in an autonomous application.
Contact Texas Instruments for additional SPI options and details.
14
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Smart Battery Data (SBData)
The data content and formatting of the bq78PL114 information conforms to the Smart Battery System’s (SBS)
Smart Battery Data specification, version 1.1. See the SBS/SMBus site at www.sbs-forum.com for further
information regarding these specifications.
This SBS Data (SBData) specification defines read/write commands for accessing data commonly required in
laptop computer applications. The commands are generic enough to be useful in most applications.
Because the bq78PL114 provides a wealth of control and battery information beyond the SBData standard, new
command codes have been defined by Texas Instruments. In addition, new battery data features, such as
state-of-health, use newly defined extended SBData command codes. Standard SMBus protocols are used,
although additional data values beyond those defined by the Smart Battery Data specification are employed. (For
example, the bq78PL114 typically is used in a multicell battery system and may report individual cell voltages for
up to 12 cells. The SBData command set only defines four cell-voltage registers.)
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bq78PL114
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SBS Standard Data Parameter List (Abridged) (1)
(2)
Command
Data Type
Descripotion
00
R/W word (unsigned)
Manufacturer Access
01
R/W word (unsigned)
Remaining Capacity Alarm Level
02
R/W word (unsigned)
Remaining Time Alarm Level
03
R/W word (unsigned)
Battery Mode
04
R/W word (unsigned)
At Rate value used in AtRate calculations
05
Read word (unsigned)
At Rate Time to Full
06
Read word (unsigned)
At Rate Time to Empty
07
Read word (Boolean)
At Rate OK
08
Read word (unsigned)
Pack Temperature (maximum of all individual cells)
09
Read word (unsigned)
Pack Voltage (sum of individual cell readings)
0A
Read word (unsigned)
Pack Current
0B
Read word (unsigned)
Average Pack Current
0C
Read word (unsigned)
Max Error
0D
Read word (unsigned)
Relative State of Charge
0E
Read word (unsigned)
Absolute State of Charge
0F
Read word (unsigned)
Remaining Pack Capacity
10
Read word (unsigned)
Full Charge Capacity
11
Read word (unsigned)
Run Time to Empty
12
Read word (unsigned)
Average Time to Empty
13
Read word (unsigned)
Average Time to Full
14
Read word (unsigned)
Charging Current
15
Read word (unsigned)
Charging Voltage
16
Read word (unsigned)
Battery Status
17
Read word (unsigned)
Cycle Count
18
Read word (unsigned)
Design Capacity
19
Read word (unsigned)
Design Voltage
1A
Read word (unsigned)
Specification Information
1B
Read word (unsigned)
Manufacture Date
1C
Read word (unsigned)
Serial Number
1D–1F
Reserved
20
Read block (string)
Pack Manufacturer Name (31 characters maximum)
21
Read block (string)
Pack Device Name (31 characters maximum)
22
Read block (string)
Pack Chemistry
23
Read block (string)
Manufacturer Data
24–2E
Reserved
2F
R/W Block
30–3B
Reserved
3C
R/W word (unsigned)
Optional Manufacturer Function 4 (Vcell 4)
3D
R/W word (unsigned)
Optional Manufacturer Function 3 (Vcell 3)
3E
R/W word (unsigned)
Optional Manufacturer Function 2 (Vcell 2)
3F
R/W word (unsigned)
Optional Manufacturer Function 1 (Vcell 1)
40–45
Unused
46–47
Reserved
48–4F
Unused
50–55
Reserved
(1)
(2)
16
Optional Manufacturer Function 5
Parameters 0x00–0x3F are compatible with the SBDATA specification.
By default, the bq78PL114 initially responds to the SBData slave address <0001 011R/W> (0x16, 0x17).
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Command
Data Type
56–57
Unused
58–5A
Reserved
5B–5F
Unused
60–62
Reserved
63–6F
Unused
70
Reserved
71–FF
Unused
Descripotion
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Product Folder Link(s): bq78PL114
17
-
+
-
+
-
+
CELL1
CELL2
CELL3
22uF
C1
22uF
C2
MA21D3800L
2K
R10
D10
D9
MA21D3800L
4.7uH
L1
D5
MA21D3800L
2K
R9
R30
R29
20K
20K
FDC6327C
Q1-A
FDC6327C
Q1-B
20K
20K
FDC6327C
Q2-A
FDC6327C
Q2-B
R11
R12
Keep this connection to BATT- as short and Low Z as possible.
C30
22uF
L2
4.7uH
D6
MA21D3800L
3300pF
C13
3300pF
C12
3300pF
C15
3300pF
C14
10uF
C5
VLDO1
BZT52C12-7-F
12.0 VDC
Q8
560K
R40
200K
R41
0.1uF
C38
VSS
0.1uF
C43
C11
1000pF
10uF
C28
P4N
P4S
P3N
P3S
P2N
P2S
P1N
VSS
V1
V2
V3
V4
VLDO2
25
8
RSTN
VLDO1
24
P-LAN
19
SDI3
18
SDO2
14
SDI1
13
SDO0
23
22
21
20
17
16
15
48
47
44
42
39
43
1000pF
C45
MMBD4148SE
TEMP-PCB
Used for Device Temp.
VSS
Vcebr=65V
BC846ALT1G
Q9
9
star ground point located at R3
10K
R44
1000pF
VSS
1.0uF
C39
1.0uF
C40
1.0uF
C41
C46
1000pF
MMBD4148SE
TEMP-FETS
Used for Safety Events
S
C27
100K
R5
G
D
3
PRE
CSBAT
MMBFJ201
30K
R45
1.0M
R46
C3
R3
0.005R
4.7K
1.0uF R27
C7
1000pF
resistance
R59
26
38
37
28
27
OSCO
12
OSCI 11
SMBDAT
SMBCLK
SPI-DO
SPI-DI
SPI-CLK
5
EFCID
4
EFCIC
29
31
33
32
36
35
34
40
XT4
41
XT3
45
XT2
46
XT1
1.0M
LED5
LED4
LED3
LED2
LED1
LEDEN
SELECT
C61
0.1uF
CCPACK
C60
CSPACK
0.1uF
equivalent
4.7K
R28
6
2
bq78PL114
U4
CHG
1
CCBAT
DSG
30
SPROT
ZR1
TAB
Product Folder Link(s): bq78PL114
49
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7
18
10
Q10
100R
R49
R50
D24
D25
D26
D27
D23
Q12
100R
30K
R58
1.0M
R43
1.0M
R25
1.0M
R6
VSS
VLDO1
Q17
1.0M
R60
1.0M
R51
1.0M
R19
Vcebr=65V
BC846ALT1G
200K
R56
R1
Z1
S1
0.1uF
C4
BSS138
Q14
VSS
R54
5.6VDC
100R
R55
FDV304P
Q16
G
R18
MMBFJ201
Vcebr=65V
BC846ALT1G
S
D
100R
Q15
Q11
100K
30K
R52
560K
R53
Q13
ZR2
T2 = CELL 2 TEMP.
1000pF
T2
C8
C16
1000pF
1000pF
MMBD4148SE
T3
T1
TEMP-PCB = TEMP. OF U4
SMBUS-PORT
1
2
3
4
PACK-
TEMP-FETS = FET TEMP. & USED FOR SAFETY.
T3 = CELL 3 TEMP.
C6
MMBD4148SE
MMBD4148SE
0.1uF
C42
0.1uF
C50
T1 = CELL 1 TEMP.
1.0M
R17
BZT52C12-7-F
12.0 VDC
S001
PACK+
bq78PL114
SLUS850A – SEPTEMBER 2008 – REVISED SEPTEMBER 2008 .................................................................................................................................... www.ti.com
REFERENCE SCHEMATIC (3 Series Cells)
Copyright © 2008, Texas Instruments Incorporated
+
-
+
-
+
-
+
-
+
-
+
-
+
-
+
-
CELL1
CELL2
CELL3
CELL4
CELL5
CELL6
CELL7
CELL8
22uF
C1
22uF
C2
C19
22uF
C23
22uF
C25
22uF
C34
22uF
C30
22uF
C47
22uF
L5
L3
L1
D10
MA21D3800L
2K
R10
4.7uH
D9
MA21D3800L
MA21D3800L
2K
R9
D5
D6
MA21D3800L
4.7uH
L2
D7
MA21D3800L
2K
R13
4.7uH
D8
MA21D3800L
MA21D3800L
2K
R16
D11
D12
MA21D3800L
4.7uH
L4
D13
MA21D3800L
2K
R31
4.7uH
D14
MA21D3800L
MA21D3800L
2K
R34
D15
D16
MA21D3800L
4.7uH
L6
D17
MA21D3800L
2K
R37
4.7uH
L7
MA21D3800L D18
R30
R29
20K
20K
FDC6327C
Q1-A
FDC6327C
Q1-B
20K
20K
FDC6327C
Q2-A
FDC6327C
Q2-B
20K
20K
FDC6327C
Q3-A
FDC6327C
Q3-B
20K
20K
FDC6327C
Q4-A
FDC6327C
Q4-B
20K
20K
FDC6327C
Q5-A
FDC6327C
Q5-B
20K
20K
FDC6327C
Q6-A
FDC6327C
Q6-B
20K
20K
FDC6327C
Q7-A
FDC6327C
Q7-B
R11
R12
R14
R15
R20
R24
R32
R33
R35
R36
R38
R39
C35
3300pF
C13
3300pF
C12
3300pF
C15
3300pF
C14
3300pF
C18
3300pF
C17
3300pF
C22
3300pF
C21
3300pF
C24
3300pF
C20
3300pF
C33
3300pF
C32
3300pF
C36
3300pF
V1
V2
U3
15
V1
8
P2N
7
P2S
6
P1N
5
P1S
12
15
VPP
VLDO
VLDO
VPP
2
16
9
SDO
4
SDI
14
T1
13
T2
BQ76PL102
C53
1000pF
2
16
9
SDO
4
SDI
14
T1
13
T2
BQ76PL102
C56
C9
10uF
C10
T5
C48
1000pF
C52
MMBD4148SE
1000pF
C49
10uF
T7
MMBD4148SE
1000pF
Keep this connection to BATT- as short and Low Z as possible.
C29
10uF
10uF
C51
C54
10uF
10uF
C55
V2
8
P2N
7
P2S
6
P1N
5
P1S
12
U2
C57
1000pF
VSS
TAB
TMD
TCK
TDI
1
17
11
10
3
VSS
TAB
TMD
TCK
TDI
1
17
11
10
3
1000pF
T6
MMBD4148SE
T8
MMBD4148SE
10uF
C5
VLDO1
BZT52C12-7-F
12.0 VDC
Q8
560K
R40
200K
R41
0.1uF
C38
C28
VSS
0.1uF
C43
C11
1000pF
10uF
VLDO2
P4N
P4S
P3N
P3S
P2N
P2S
P1N
VSS
V1
V2
V3
V4
25
8
RSTN
VLDO1
24
P-LAN
19
SDI3
18
SDO2
14
SDI1
13
SDO0
23
22
21
20
17
16
15
48
47
44
42
39
43
1000pF
C45
MMBD4148SE
TEMP-PCB
Used for Device Temp.
VSS
Vcebr=65V
BC846ALT1G
Q9
9
star ground point located at R3
10K
R44
1000pF
VSS
1.0uF
C39
1.0uF
C40
1.0uF
C41
1.0uF
C44
C46
1000pF
MMBD4148SE
TEMP-FETS
Used for Safety Events
S
D
C27
100K
R5
G
MMBFJ201
3
PRE
CSBAT
ZR1
R45
30K
R3
0.005R
4.7K
1.0uF R27
C7
1000pF
C3
resistance
equivalent
4.7K
R28
6
CCPACK
C61
38
37
28
27
26
OSCO
12
OSCI 11
SMBDAT
SMBCLK
SPI-DO
SPI-DI
SPI-CLK
5
EFCID
4
EFCIC
29
31
33
32
36
35
34
40
XT4
41
XT3
45
XT2
46
XT1
1.0M
R59
LED5
LED4
LED3
LED2
LED1
LEDEN
SELECT
0.1uF
CSPACK
C60
0.1uF
1.0M
R46
bq78PL114
U4
CHG
2
DSG
1
CCBAT
30
SPROT
IRF4905PBF
TAB
49
Product Folder Link(s): bq78PL114
7
Copyright © 2008, Texas Instruments Incorporated
10
Q10
100R
R49
R50
D24
D25
D26
D27
D23
Q12
100R
30K
R58
1.0M
R43
1.0M
R25
1.0M
R6
VSS
VLDO1
Q17
200K
1.0M
R51
1.0M
R19
Vcebr=65V
BC846ALT1G
R56
IRF4905PBF
S
D
R1
100K
R55
Z1
R54
S1
0.1uF
100R
5.6VDC
100R
Q14
Q15
G
ZR2
1.0M
R17
R18
VSS
T1 = CELL 1 TEMP.
C6
C37
1000pF
1000pF
T2
C8
C16
1000pF
1000pF
MMBD4148SE
T3
MMBD4148SE
T1
TEMP-PCB = TEMP. OF U4
SMBUS-PORT
1
2
3
4
PACK-
TEMP-FETS = FET TEMP. & USED FOR SAFETY.
T8 = CELL 8 TEMP.
T7 = CELL 7 TEMP.
T6 = CELL 6 TEMP.
T5 = CELL 5 TEMP.
T4 = CELL 4 TEMP.
T3 = CELL 3 TEMP.
T2 = CELL 2 TEMP.
T4
MMBD4148SE
MMBD4148SE
0.1uF
C42
0.1uF
C50
BZT52C12-7-F
12.0 VDC
Vcebr=65V
BC846ALT1G
Q16
MMBFJ201
BSS138
C4
30K
R52
FDV304P
1.0M
R60
Q11
STB16NF06LT4
560K
R53
Q13
S002
PACK+
bq78PL114
www.ti.com .................................................................................................................................... SLUS850A – SEPTEMBER 2008 – REVISED SEPTEMBER 2008
REFERENCE SCHEMATIC (8 Series Cells)
Submit Documentation Feedback
19
PACKAGE OPTION ADDENDUM
www.ti.com
1-Oct-2008
PACKAGING INFORMATION
Orderable Device
Status (1)
Package
Type
Package
Drawing
Pins Package Eco Plan (2)
Qty
BQ78PL114RGZR
ACTIVE
QFN
RGZ
48
2500
TBD
Call TI
Call TI
BQ78PL114RGZT
ACTIVE
QFN
RGZ
48
250
TBD
Call TI
Call TI
Lead/Ball Finish
MSL Peak Temp (3)
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in
a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check
http://www.ti.com/productcontent for the latest availability information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements
for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered
at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and
package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS
compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame
retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder
temperature.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is
provided. TI bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the
accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and continues to take
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incoming materials and chemicals. TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited
information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI
to Customer on an annual basis.
Addendum-Page 1
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