TI1 BQ28Z560DRZR-R1 Single cell li-ion battery gas gauge Datasheet

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bq28z560-R1 Single Cell Li-Ion Battery Gas Gauge and Protection
Check for Samples: bq28z560-R1
FEATURES
1
•
23
•
•
A Comprehensive Single Cell Li-Ion Battery
Manager Integrates All Essential Functions:
– Gas Gauge
– Low-Side N-CH FET Protection Control
– JEITA/Enhanced Charging
– Authentication
Impedance Track™ Gas Gauging
Protection Functions Help to Prevent:
– Short-Circuit
– Overcurrent Charge and Discharge
– Overvoltage Charge (Overcharge)
– Undervoltage (Over-Discharge)
•
•
•
•
Firmware Control of Discharge FET
SHA-1/HMAC Battery Authentication
I2C™ Communications Interface or HDQ
Single Wire
12-pin, 2.5-mm x 4.0-mm SON Package
APPLICATIONS
•
•
•
•
•
Tablet PCs
Slates
Digital Still and Video Cameras
Handheld Terminals
MP3 or Multimedia Players
DESCRIPTION
The Texas Instruments bq28z560-R1 device is a battery gas gauge with current and voltage protection, and
secure, SHA-1/HMAC authentication for single-cell Li-Ion battery packs. Designed for battery pack integration,
the bq28z560-R1 requires host microcontroller firmware support for implementation. A system processor
communicates with the bq28z560-R1 using one of two options: an I2C™ serial interface or an HDQ single-wire
configuration to obtain remaining battery capacity, system run-time predictions, and other critical battery
information.
The bq28z560-R1 uses the accurate Texas Instruments Impedance Track™ gas gauging algorithm to report the
status of the cell. The gauge provides information such as state-of-charge (%), run-time to empty (min.), charge
time to full (min.), battery voltage (V), and pack temperature (°C).
The bq28z560-R1 features integrated support for secure battery pack authentication, using the SHA-1/HMAC
authentication algorithm.
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.
Impedance Track is a trademark of Texas Instruments.
I2C is a trademark of NXP B.V. Corporation.
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.
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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.
ORDERING INFORMATION (1)
TA
–40°C to 85°C
(1)
PART NUMBER
PACKAGE
TAPE AND REEL QUANTITY
bq28z560-R1DRZR
12-pin, 2.5-mm × 4.0-mm
SON
3000
bq28z560-R1DRZT
250
For the most current package and ordering information, see the Package Option Addendum at the end of this document, or visit the
device product folder on ti.com (www.ti.com).
THERMAL INFORMATION
bq28z560-R1
THERMAL METRIC (1)
SON
UNITS
12 PINS
θJA
Junction-to-ambient thermal resistance (2)
θJC(top)
Junction-to-case(top) thermal resistance
θJB
Junction-to-board thermal resistance
ψJT
Junction-to-top characterization parameter
ψJB
Junction-to-board characterization parameter
θJC(bottom)
(1)
(2)
(3)
(4)
(5)
(6)
(7)
2
186.4
(3)
90.4
(4)
110.7
(5)
Junction-to-case(bottom) thermal resistance
96.7
(6)
(7)
°C/W
90
n/a
For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953.
The junction-to-ambient thermal resistance under natural convection is obtained in a simulation on a JEDEC-standard, high-K board, as
specified in JESD51-7, in an environment described in JESD51-2a.
The junction-to-case (top) thermal resistance is obtained by simulating a cold plate test on the package top. No specific JEDECstandard test exists, but a close description can be found in the ANSI SEMI standard G30-88.
The junction-to-board thermal resistance is obtained by simulating in an environment with a ring cold plate fixture to control the PCB
temperature, as described in JESD51-8.
The junction-to-top characterization parameter, ψJT, estimates the junction temperature of a device in a real system and is extracted
from the simulation data for obtaining θJA, using a procedure described in JESD51-2a (sections 6 and 7).
The junction-to-board characterization parameter, ψJB, estimates the junction temperature of a device in a real system and is extracted
from the simulation data for obtaining θJA , using a procedure described in JESD51-2a (sections 6 and 7).
The junction-to-case (bottom) thermal resistance is obtained by simulating a cold plate test on the exposed (power) pad. No specific
JEDEC standard test exists, but a close description can be found in the ANSI SEMI standard G30-88.
Spacer
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TYPICAL APPLICATION
FUSE
PACK+
SCL
SDA
100 Ω
COUT 2
11
VM 3
510 Ω
0.1 µF
5M
CELLN
SRN
8
5V6
13
PWPD
0.1 µF
CHG
100 Ω
100 Ω
D
S
5V6
7 SRP
6
0.1 µF
PACK–
CELLP
9 TS
4
0.1 µF
5M
SDA
10
VREG 5
VSS
100 Ω
S
10 mΩ
0.1 µF
BAT
VREG
100 Ω
SCL
0.47 µF
12
100 Ω
100 k
GPIO
DOUT 1
VREG
DSG
BC847BPDXV6
12k
5k
Figure 1. Application—CFET
FUSE
PACK+
SCL
SDA
VREG
3.3K
12
COUT 2
11
0.1 µF
VREG
5M
4
9
5
8
VSS 6
5M
0.1 µF
100 Ω
SDA
100 Ω
D
S
CHG
100 Ω
CELLP
TS
5V6
SRN
5V6
5V6
CELLN
7 SRP
13
PWPD
0.1 µF
0.1 µF
PACK–
VREG
S
0.1 µF
510 Ω
10
SCL
100 Ω
BAT
3
100 Ω
100 Ω
VM
GPIO
0.47 µF
DOUT 1
100 Ω
100 Ω
ALERT
10 mΩ
DSG
Figure 2. Application—ALERT
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PIN DETAILS
DRZ Package
(Top View)
DOUT
1
12
GPIO
COUT
2
11
SCL
VM
3
10
SDA
Thermal Pad
BAT
4
9
TS
VREG
5
8
SRN
VSS
6
7
SRP
Table 1. Pin Descriptions
PIN
NUMBER
PIN
NAME
I/O (1)
1
DOUT
IA
The output of the gate drive for discharge FET
2
COUT
IA
The output of the gate drive for charge FET
3
VM
IA
Analog input pin connected to the PACKN through a 510-Ω resistor. Overcurrent and short-circuit
protection circuits use the voltage across VM and VSS to detect if excessive charge or discharge
current is flowing through the protection FETs.
4
BAT
IA
Cell voltage measurement input. ADC input. Connect a 0.1-µF ceramic capacitor to VSS.
5
VREG
P
2.5-V output voltage of the internal integrated LDO. Connect a 0.1-µF ceramic capacitor to VSS.
6
VSS
P
Device ground
7
SRP
IA
Analog input pin connected to the internal coulomb counter where SRP is nearest the CELL–
connection. Connect to a 5-mΩ to 20-mΩ sense resistor.
8
SRN
IA
Analog input pin connected to the internal coulomb counter where SRN is nearest the PACKN
connection. Connect to a 5-mΩ to 20-mΩ sense resistor.
9
TS
IA
Pack thermistor voltage sense (use 103AT-type thermistor), ADC input
10
SDA
I/O
Serial Data interface for SMBus
11
SCL
I
Serial Clock interface for SMBus
12
GPIO
I/O
General Purpose control output for configuration as CFET control OR Alert output OR HDQ interface
13
PWPD
I/O
Thermal Pad. Connect to VSS externally on PCB.
(1)
4
DESCRIPTION
IA = Input Analog, OA = Output Analog, P = Power Connection
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BLOCK DIAGRAM
PACK+
PACK–
VM
Oscillator
VREG
0.1 µF
SDA
Overload
Comparator
Linear
Regulator 2 .5 V
510
Short Circuit
Comparator
Vss
VM
0.1 µF
+
BAT
DOUT
Over Discharge
Comparator
Oscillator
System Clock
COUT
VSS
Overcharge
Comparator
Reset*
TEST
BAT
Protection
Logic Control
SRN
Event
(RA0)
0.1 µF
VREG
Interrupt
Controller
VSS
LI-Ion Cell
0.1 µF
BAT
TEST
Overcharge
Current
Comparator
BAT
3k
GPIO
Input/Output
System Clocks
VSS
10k
TS
Analog Front End
Delta-Sigma ADC
AND
Integrating
Coulomb Counter
Data (8-bit)
CoolRISC
CPU
DMAddr (16-bit)
AD0–3 (RC0–3)
0.47µF
SRP
100
0.1 µF
0.1µF
0.1 µF
SRN
10 mΩ
100
System I/O (13-bit)
PMAddr
(15-bit)
DATA
PMInst
(22-bit)
Program Memory
16 k x 22 FLASH
AND
6 k x 22 Mask ROM
Data Memory
1k x 8 SRAM
AND
1k x 8 FLASH
Peripherals
Communications
I 2 C (slave)
SDA
100
100
100
5V6
100
SDA
SCL
SCL
5V6
Figure 3. Block Diagram
ABSOLUTE MAXIMUM RATINGS
All voltages are referenced to the VSS pin. Over operating free-air temperature range (unless otherwise noted)
PARAMETER
(1)
VALUE
UNIT
–0.3 to 12
V
VM terminal voltage (Pin 3)
VBAT – 32 to VBAT + 0.3
V
COUT terminal input voltage (Pin 2)
VBAT – 32 to VBAT + 0.3
V
VDOUT
DOUT terminal input voltage (Pin 1)
VSS – 0.3 to VBAT + 0.3
V
VIOD
All other pins (Pins 5, 7, 8, 9, and 12)
–0.3 to 6
V
VBAT
Input voltage, BAT (Pin 4)
VVM
VCOUT
VSDATA
SDA (Pin 10)
VSS – 0.3 to VBAT + 0.3
V
VSCLK
SCL (Pin 11)
VSS – 0.3 to VBAT + 0.3
V
ESD
Human body model
±2
kV
ESD
Machine model
±200
V
TA
Operating free-air temperature range
–40°C to 85
°C
Tstg
Storage temperature range
–65°C to 150
°C
(1)
Stresses beyond those listed under “absolute maximum ratings” may cause permanent damage to the device. These are stress ratings
only and functional operation of the device at these or any other conditions beyond those indicated under “recommended operating
conditions” is not implied. Exposure to absolute–maximum–rated conditions for extended periods may affect device reliability.
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RECOMMENDED OPERATING CONDITIONS
TA = 25ºC, VBAT = 3.6 V (unless otherwise noted)
PARAMETER
VBAT
IBAT
TEST CONDITIONS
BAT pin 4 input
MIN
TYP
2.45
NORMAL operating mode
Gas gauge in NORMAL mode. ILOAD > Sleep
Current
141
Low-power
Gas gauge in SLEEP mode. ILOAD < Sleep
Current
70
Sleep
Gas gauge in FULLSLEEP mode. ILOAD <
Sleep Current
31
Hibernate
Gas gauge in HIBERNATE mode. ILOAD <
Hibernate Current
16
Shutdown
Gas gauge in SHUTDOWN mode
1
MAX
UNIT
5.5
V
µA
ISS
Maximum current
20
CREG
Regulator output capacitor
CBAT
VBAT input filter capacitor
0.1
µF
RPACKN
Resistor from VM to
PACKN
510
Ω
0.1
mA
µF
RPU_
SDA pull up resistor
3.3
kΩ
VPU_
SDA pull up voltage
1.8
1.3
4.2
V
VIL_
SDA, SCL OR GPIO Input
voltage low
–0.3
0.6
V
VIH_
SDA, SCL OR GPIO Input
voltage high
1.2
6
V
VOL_
SDA or GPIO output
voltage low
IOL = 3 mA (open drain)
0
0.4
V
CI
Capacitance for each I/O
pin
SDA and SCL input capacitance
10
pF
tPUCD
Power Up Communication
Delay
VAI2
Input voltage range (SRP,
SRN)
250
VSS – 0.25
ms
0.25
V
BATTERY PROTECTION
TA = –40 to +85ºC, VBAT =1.5 V to 5.5 V; Typical values stated, where TA = 25ºC and VBAT =3.6 V (unless otherwise noted)
PARAMETER
TEST CONDITION
MIN
NOM
MAX
UNIT
1.2
V
50
100
kΩ
13.0
26.0
kΩ
0.5
V
VST
Minimum operating voltage for
0 V charging
VST = VBAT – VM
RSHORT
Overcurrent release resistance
VBAT = 4.0 V, VM = 1 V
30
RDS
DS pin pull-down resistance
VBAT = 4.0 V
6.5
VOL1
COUT Low Level Output voltage
(referenced to VM)
IOL = 30 µA, VBAT = 4.5 V
0.4
VOH1
COUT High Level Output voltage
(referenced to VM)
IOH = 30 µA, VBAT = 4.0 V
VOL2
DOUT Low Level Output voltage
(referenced to Vss)
IOL = 30 µA, VBAT = 2.0 V
VOH2
DOUT High Level Output voltage
(referenced to Vss)
IOH = 30 µA, VBAT = 4.0 V
VDET1
Overcharge detection
VREL1
6
Overcharge release voltage
3.4
3.7
0.2
V
0.5
3.4
3.7
TA = 25˚C detection voltage
4.230
4.250
4.270
TA = –10 to 60˚C
4.225
4.250
4.275
TA = –40 to 85˚C
4.200
4.250
4.300
TA = 25˚C
4.040
4.070
4.100
TA = –10 to 60˚C
4.025
4.070
4.115
TA = –40 to 85˚C
4.010
4.070
4.130
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V
V
V
V
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BATTERY PROTECTION (continued)
TA = –40 to +85ºC, VBAT =1.5 V to 5.5 V; Typical values stated, where TA = 25ºC and VBAT =3.6 V (unless otherwise noted)
PARAMETER
TEST CONDITION
MIN
NOM
MAX
UNIT
tDET1
Overcharge detection delay time
VBAT = 3.5 V ≥ 4.5 V
0.60
1.00
1.50
s
tREL1
Overcharge release delay time
VBAT = 4.5 V ≥ 3.5 V
4.8
8.0
12.0
ms
TA = 25˚C
2.265
2.300
2.335
VDET2
Over-discharge detection voltage
TA = –10 to 60˚C
2.242
2.300
2.358
TA = –40 to 85˚C
2.220
2.300
2.380
tDET2
Over-discharge detection delay
time
VBAT = 3.5 V ≥ 2.00 V
14.4
24.0
36.0
ms
tREL2
Over-discharge release delay
time
VBAT = 3 V
VM = 3 V ≥ 0 V
2.4
4.0
6.0
ms
VDET3
Overcurrent detection voltage on
discharge
VBAT = 4 V
0.130
0.150
0.170
V
VDET4
Overcurrent detection voltage on
charging
VBAT = 4 V
–0.137
–0.112
–0.087
V
tOCD
Overcurrent detection delay time
VBAT = 3 V
VM = 0 V ≥ 1V
7.2
12.0
18.0
ms
tOCR
Overcurrent release delay time
VBAT = 3 V
VM = 3 V ≥ 0 V
2.4
4.0
6.0
ms
VSHORT
Short detection voltage
VBAT = 4 V, RPACKN = 510 Ω
VBAT – 1.2
VBAT –
0.9
VBAT – 0.6
V
tSHORT
Short detection delay time
VBAT = 3 V
VM = 0V ≥ 3 V
200
400
800
µs
V
VOLTAGE REGULATOR
TA = –40 to +85ºC, VBAT =1.5 V to 5.5 V; Typical values stated, where TA = 25ºC and VBAT =3.6 V (unless otherwise noted)
PARAMETER
VREG
Output voltage
ΔVLINE
Line regulation
ΔVLOAD
Load regulation
VDO
Dropout voltage
ΔVREG/ΔT
Output voltage temperature
coefficient
ΔVLINE
Current limit
VOFF
Regulator off voltage
tVOFF
Regulator off voltage delay time
MIN
TYP
MAX
UNIT
2.7 V < VBAT < 5.5 V, IOUT = 16 mA
TEST CONDITIONS
2.45
2.50
2.55
V
2.45 V < VBAT < 2.7 V, IOUT = 3 mA
2.40
2.7 V < VBAT < 5.5 V, IOUT = 16 mA
100
200
mV
VREG = 2.45 V, 100 µA < IOUT < 3 mA
30
50
VBAT = 2.7 V, 3 mA < IOUT < 16 mA
30
50
VBAT = 2.45 V, IOUT = 3 mA
30
50
VBAT = 2.7 V, IOUT = 16 mA
30
50
VBAT = 3.5 V, IOUT = 100 µA
100
mV
mV
ppm/°C
VBAT = 3.5 V, IREG = 2.0 V
16
VBAT = 3.5 V, IREG = 0 V
10
35
60
7.0
8.0
9.0
V
50
100
µs
MIN
TYP
MAX
UNIT
2.125
2.200
2.275
V
75
125
175
mV
VBAT = 3.6 V → 5.5 V, Rload = 100 Ω
VREG = 2.5 V → 2.3 V, Cload = 0.1 µF,
TA = 25°C
130
mA
POWER-ON RESET
TA = –40 to +85ºC; Typical Values at TA = 25ºC (unless otherwise noted)
PARAMETER
VIT+
TEST CONDITIONS
Positive-going battery voltage input
No external loading on VREG
at VREG
VHYS
No external loading on VREG
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INTERNAL TEMPERATURE SENSOR CHARACTERISTICS
TA = –40 to +85ºC, VBAT = 2.7 V to 5.5 V; Typical values stated, where TA = 25ºC and VBAT = 3.6 V (unless otherwise noted)
PARAMETER
GTEMP
TEST CONDITIONS
MIN
Temperature sensor voltage gain
TYP
MAX
–2.0
UNIT
mV/°C
HIGH FREQUENCY OSCILLATOR
TA = –40 to +85ºC, VBAT = 2.7 V to 5.5 V; Typical values stated, where TA = 25ºC and VBAT = 3.6 V (unless otherwise noted)
PARAMETER
TEST CONDITIONS
f(OSC)
Operating frequency
f(EIO)
Frequency error
t(SXO)
(1)
(2)
(3)
Start-up time
(1) (2)
,
MIN
TYP
MAX
2.097
UNIT
MHz
TA = 0°C to 60°C
–2.0
0.38
2.0
%
TA = –20°C to 70°C
–3.0
0.38
3.0
%
TA = –40°C to 85°C
–4.5
0.38
4.5
%
2.5
5
ms
(3)
The frequency error is measured from 2.097 MHz.
The frequency drift is included and measured from the trimmed frequency at VCC = 2.5 V, TA = 25°C.
The startup time is defined as the time it takes for the oscillator output frequency to be ±3%.
LOW FREQUENCY OSCILLATOR
TA = –40 to +85ºC, VBAT = 2.7 V to 5.5 V; Typical values stated, where TA = 25ºC and VBAT = 3.6 V (unless otherwise noted)
PARAMETER
TEST CONDITIONS
f(LOSC)
Operating frequency
f(LEIO)
Frequency error
t(LSXO)
(1)
(2)
(3)
Start-up time
(1) (2)
,
MIN
TYP
MAX
32.768
UNIT
kHz
TA = 0°C to 60°C
–1.5
0.25
1.5
%
TA = –20°C to 70°C
–2.5
0.25
2.5
%
TA = –40°C to 85°C
–4.0
0.25
4.0
%
500
μs
(3)
The frequency drift is included and measured from the trimmed frequency at VCC = 2.5 V, TA = 25°C.
The frequency error is measured from 32.768 kHz.
The startup time is defined as the time it takes for the oscillator output frequency to be ±3%.
INTEGRATING ADC (COULOMB COUNTER) CHARACTERISTICS
TA = –40 to +85ºC, VBAT = 2.7 V to 5.5 V; Typical values stated, where TA = 25ºC and VBAT = 3.6 V (unless otherwise noted)
PARAMETER
VIN(SR)
tCONV(SR)
VSR = V(SRN) – V(SRP)
Conversion time
Single conversion
Resolution
VOS(SR)
Input offset
INL
Integral non-linearity error
ZIN(SR)
Effective input resistance (1)
Ilkg(SR)
Input leakage current (1)
(1)
TEST CONDITIONS
Input voltage range, V(SRN) and
V(SRP)
MIN
TYP
–0.125
MAX
UNIT
0.125
V
15
bits
1
14
s
10
±0.007
µV
±0.034
2.5
FSR
MΩ
0.3
µA
Specified by design. Not production tested.
ADC (TEMPERATURE AND CELL VOLTAGE) CHARACTERISTICS
TA = –40 to +85ºC, VBAT = 2.7 V to 5.5 V; Typical values stated, where TA = 25ºC and VBAT = 3.6 V (unless otherwise noted)
PARAMETER
VIN(ADC)
tCONV(ADC)
VOS(ADC)
8
TEST CONDITIONS
Input voltage range
MIN
TYP
–0.2
Conversion time
Resolution
14
Input offset
1
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MAX
UNIT
1
V
125
ms
15
bits
mV
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ADC (TEMPERATURE AND CELL VOLTAGE) CHARACTERISTICS (continued)
TA = –40 to +85ºC, VBAT = 2.7 V to 5.5 V; Typical values stated, where TA = 25ºC and VBAT = 3.6 V (unless otherwise noted)
PARAMETER
Z(ADC1)
Effective input resistance (TS)
Effective input resistance (BAT)
Z(ADC2)
MIN
(1)
TYP
Input leakage current
MAX
UNIT
8
bq28z560-R1 not measuring cell voltage
MΩ
8
MΩ
bq28z560-R1 measuring cell voltage
Ilkg(ADC)
(1)
TEST CONDITIONS
(1)
100
(1)
kΩ
0.3
µA
Specified by design. Not production tested.
DATA FLASH MEMORY CHARACTERISTICS
TA = –40 to +85ºC, VBAT = 2.7 V to 5.5 V; Typical values stated, where TA = 25ºC and VBAT = 3.6 V (unless otherwise noted)
PARAMETER
Data retention
tDR
TEST CONDITIONS
Flash programming write-cycles
(1)
TYP
Word programming time
ICCPROG
Flash-write supply current
MAX
UNIT
10
Years
20,000
Cycles
(1)
tWORDPROG
(1)
MIN
(1)
(1)
5
2
ms
10
mA
Specified by design. Not production tested.
HDQ COMMUNICATION TIMING CHARACTERISTICS
TA = –40 to +85ºC, VBAT = 2.7 V to 5.5 V; Typical values stated, where TA = 25ºC and VBAT = 3.6 V (unless otherwise noted).
Capacitance on GPIO is 10 pF unless otherwise specified (1).
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
μs
t(CYCH)
Cycle time, host to bq28z560-R1
190
t(CYCD)
Cycle time, bq28z560-R1 to host
190
250
μs
t(HW1)
Host sends 1 to bq28z560-R1
0.5
50
μs
t(DW1)
bq28z560-R1 sends 1 to host
32
50
μs
t(HW0)
Host sends 0 to bq28z560-R1
86
145
μs
t(DW0)
bq28z560-R1 sends 0 to host
80
145
μs
t(RSPS)
Response time, bq28z560-R1 to
host
190
950
μs
t(B)
Break Time
190
μs
t(BR)
Break Recovery Time
40
μs
t(RISE)
HDQ Line Rising Time to Logic 1
(1.2 V)
(1)
205
950
ns
Parameters specified by worst-case test program execution in FAST mode.
1.2V
t(BR)
t (B)
t(RISE)
(b) HDQ line rise time
(a) Break and Break Recovery
t (DW1)
t (HW1)
t(DW0)
t (CYCD)
t(HW0)
t(CYCH)
(d) Gauge Transmitted Bit
(c) Host Transmitted Bit
Break
7-bit address
1-bit
R/W
8-bit data
t (RSPS)
(e) Gauge to Host Response
Figure 4. HDQ Timing
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I2C SERIAL COMMUNICATION TIMING CHARACTERISTICS
TA = –40 to +85ºC, VBAT = 2.7 V to 5.5 V; Typical values stated, where TA = 25ºC and VBAT = 3.6 V (unless otherwise noted).
Capacitance on serial interface pins SCL and SDA are 10 pF unless otherwise specified (1).
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
300
ns
300
ns
tr
SCL/SDA rise time
tf
SCL/SDA fall time
tw(H)
SCL pulse width (high)
600
ns
tw(L)
SCL pulse width (low)
1.3
μs
tsu(STA)
Setup for repeated start
600
ns
td(STA)
Start to first falling edge of SCL
600
ns
tsu(DAT)
Data setup time
1
μs
th(DAT)
Data hold time
0
ns
tsu(STOP)
Setup time for stop
600
ns
t(BUF)
Bus free time between stop and
start
1.3
μs
f(SCL)
Clock frequency
(1)
100
kHz
Parameters specified by worst-case test program execution in FAST mode.
t su (STA)
tw(H)
tw(L)
tf
tr
t(BUF)
SCL
SDA
td (STA)
tr
th(DAT)
tsu (DAT)
tf
REPEATED
START
t su(STOP)
STOP
START
Figure 5. I2C Serial Communication Timing
I2C BUS COMMUNICATION
The 2-wire communication bus supports a slave-only device in a single- or multi-slave configuration with a singleor multi-master configuration. The device can be part of a shared bus by the unique setting of the 7-bit slave
address. The 2-wire communication is bi-directional, consisting of a serial data line (SDA) and serial clock line
(SCL). In RECEIVE mode, the SDA terminal operates as an input; whereas, when the device is returning data to
the master, the SDA operates as an open drain output with an external resistive pull-up. The master device
controls the initiation of the transaction on the bus line.
Data Transfer: Each data bit is transferred during an SCL clock cycle (transition from low-to-high and then highto-low). The data signal on the SDA (logic level) must be stable during the high period of the SCL clock pulse. A
change in the SDA logic when SCL is high is interpreted as a START or STOP control signal. If a transfer is
interrupted by a STOP condition, the partial byte transmission shall not be latched. Only the prior messages
transmitted and acknowledged are latched.
Data Format: The data is an 8-bit format with the most significant bit (MSB) first, and the least significant bit
(LSB) followed by an Acknowledge bit. If the slave cannot receive or transmit any byte of data until it services a
priority interrupt, it can pull the SCL line low to force the master device into wait state. The slave, once ready to
resume data transfer, can release the SCL line (get out of wait state).
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Bus Idle: The bus is considered idle or busy when no master device has control of this device. The SDA and
SCL lines are high when the bus is idle. The appropriate method to go into the STOP condition is to ensure the
bus returns to idle state.
START (S) and STOP (P) Conditions: To initiate communications, the master device transitions the SDA line
from high-to-low when the SCL is high. Conversely, to STOP the communication, the SDA goes low-to-high
when the SCL is high. To continue communication without terminating one transaction and beginning another, a
repeated START (Sr) method can be used without a STOP condition being initiated. These are the only
conditions (START or STOP) when SDA transitions when SCL is high.
Acknowledge Bits: An Acknowledge bit (A) is required after each data transfer byte to ensure correct
communications. This occurs when the receiving device pulls the SDA low before the rising edge of the
acknowledge-related clock pulse (ninth pulse) and keeps it low until the SCL returns low. There is also a NoAcknowledge bit (N), which occurs when the receiver releases the SDA line (high) before the rising edge of
acknowledge-related clock pulse, and maintains the SDA line high until SCL returns low. The Acknowledge bit
indicates if a successful data transfer has occurred between the master and slave device. Monitoring this bit also
indicates an unsuccessful data transfer due to the receiving device being busy or as a system fault occurrence.
Communication Format
A START command immediately followed by a STOP command is an illegal format.
MSB
S
Slave Address
R/W
A
Data
A
P
S = START Command
R/W = Read from slave device ("1") or Write to slave device ("0")
A = Acknowledge bit
P = STOP Command
Slave Address = 7-bit address field for register address
Data = 8-bit data field
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GENERAL DESCRIPTION
The bq28z560-R1 accurately predicts the battery capacity and other operational characteristics of a single Li-Ion
based rechargeable cell, while also providing a state-of-the-art protection function against short circuit,
overcurrent, and overvoltage. The device can be integrated by a system processor to provide cell information,
such
as
state-of-charge
(SOC),
Remaining
Capacity,
and
Full
Charge
Capacity
(FCC).
NOTE
FORMATTING CONVENTIONS IN THIS DOCUMENT:
Commands: Italics
RemainingCapacity()
with
parentheses
and
no
breaking
spaces;
for
example,
Data Flash: Italics, bold, and breaking spaces; for example, Design Capacity
Register Bits and Flags: Brackets only; for example, [TDA]
Data Flash Bits: Italics and bold; for example, [NR]
Modes and States: All capitals; for example, SEALED mode
DATA ACQUISITION
Cell Voltage
The bq28z560-R1 samples the single cell voltage from the BAT input terminal. The cell voltage is sampled and
updated every 1 s in NORMAL mode. To ensure accurate cell measurement, the VSS ground connection of the
bq28z560-R1 should be connected to the negative terminal of the single cell and not to the positive side of the
sense resistor.
Charge Measurement
The device samples the charge into and out of the single cell using a low-value sense resistor. The resistor
(typically 5 mΩ to 20 mΩ) is connected between SRP and SRN to form a differential input to an integrating ADC
(coulomb counter). Charge activity is detected when VSR = VSRP – VSRN is positive and discharge activity is
detected when VSR = VSRP – VSRN is negative. This data is integrated over a period of time using an internal
counter, and updates RemainingCapacity with charge and discharge amounts every 1 s in NORMAL mode.
Current Measurement
The device has a FIFO buffer, which uses the last four coulomb counter readings to calculate the current. The
current is updated every 1 s in NORMAL mode.
CELL DETECTION
Internal Short Detection
The device can detect an internal battery short by setting the [SE_ISD] bit in Pack Configuration Register B. The
bq28z560-R1 compares the self-discharge current calculated based on StateOfCharge() in RELAX mode and
AverageCurrent() measured in the system. The self-discharge is measured at 1-hour intervals. When the battery
SelfDischargeCurrent() is less than a predefined ISD Current threshold, the ISD flag bit is set high.
Tab Disconnection Detection
The bq28z560-R1 detects tab disconnection by change in StateOfHealth(). This feature is enabled by setting the
[SE_TDD] bit in Pack Configuration Register B. The [TDD] bit is set in the flag register when the ratio of current
StateOfHealth() divided by the previous StateOfHealth() reported is less than TDD SOH percent.
TEMPERATURE MEASUREMENT AND THE TS INPUT
The bq28z560-R1 measures external temperature via the TS pin in order to supply battery temperature status
information to the gas gauging algorithm and charger-control sections of the gauge. Alternatively, the gauge can
also measure internal temperature via its on-chip temperature sensor. Refer to the Pack Configuration[TEMPS]
control bit.
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Regardless of which sensor is used for measurement, a system processor can request the current battery
temperature by calling the Temperature() function. The temperature information is updated every 1 s in NORMAL
mode.
The bq28z560-R1 external temperature sensing is optimized with the use of a high accuracy negative
temperature coefficient (NTC) thermistor with R25 = 10 KΩ ± 1% and B25/85 = 3435 KΩ ± 1% (such as Semitec
103AT for measurement). REFERENCE SCHEMATIC shows additional circuit information on connecting this
thermistor to the bq28z560-R1.
OVERTEMPERATURE INDICATION
Overtemperature: Charge
If during charging Temperature() reaches the threshold of OT Chg for a period of OT Chg Time and
AverageCurrent() > Chg Current Threshold, then based on System Configuration the following occurs:
• If the GPIO is set for CFET control, the GPIO output will transition low and with the associated external
circuitry the CHG FET is turned OFF. When the temperature falls to OT Chg Recovery, the GPIO will
transition high again and allow the charge FET to turn on.
• If OT Chg Time = 0, the feature is completely disabled.
• If GPIO is configured as Alert output and if the OTC_EN bit in the Alert Configuration register is set to 1, the
Alert pin (Pin 12) will transition low to signify a fault has occurred. The polarity of the alert output can be
selected by setting the ALRT_POL bit in the Alert Configuration register. The fault is cleared on read.
Overtemperature: Discharge
If during discharging Temperature() reaches the threshold of OT Dsg for a period of OT Dsg Time, and
AverageCurrent() ≤ –Dsg Current Threshold, then based on system Configuration the following occurs:
• If the above condition is satisfied, then the Dsg FET is turned off. When the temperature falls to OT Dsg
Recovery, the Dsg FET is turned on.
• If OT Dsg Time = 0, the feature is completely disabled.
• If GPIO is configured as Alert output and if the OTD_EN bit in the Alert Configuration register is set to 1, the
Alert pin (Pin 12) will transition low to signify a fault has occurred. The polarity of the alert output can be
selected by setting the ALRT_POL bit in the Alert Configuration register. The fault is cleared on read.
PROTECTION
Overcharge Detector
When charging a battery, if the VBAT voltage becomes greater than the overcharge detection voltage
(VDET1 = 4.25 V typ) for a period up to the overcharge detection delay time (tDET1 = 1.00 s typ), the bq28z560-R1
detects the overcharge state of the battery, and the COUT pin transitions to a low level. This prohibits charging
the battery by turning off the external charge control N-channel MOSFET.
In the overcharge state, if a charger is removed and a load is connected, the external charge control MOSFET
conducts the load current through its parasitic body diode. If the VBAT voltage becomes lower than the
overcharge release voltage (VREL1 = 4.07 V typ) for a period up to the overcharge release delay time
(tREL1 = 8 ms typ), the COUT pin transitions to a high level, enabling charge of the battery by turning on the
external charge control N-channel MOSFET.
Over-Discharge Detector
When discharging a battery, if the VBAT voltage becomes lower than the over-discharge detection voltage
(VDET2 = 2.3 V typ) for a period up to the over-discharge detection delay time (tDET2 = 24 ms typ), the bq28z560R1 detects the over-discharge state of the battery, and the DOUT pin transitions to a low level. This prohibits
discharging the battery by turning off the external discharge control N-channel MOSFET.
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In the over-discharge state, if a charger is connected, the external discharge control MOSFET conducts the
charge current through its parasitic body diode. If the VBAT voltage becomes greater than the over-discharge
detection voltage (VDET2 = 2.3 V typ) for a period up to the overcharge release delay time (tREL2 = 4 ms typ), the
DOUT pin transitions to a high-level enabling discharge of the battery by turning on the external discharge control
N-channel MOSFET. After detecting over-discharge, the device stops all operations and enters standby, which
reduces the current consumed by the IC to its lowest mode (standby current).
Overcharge
BAT
Normal
Normal
Over-Discharge
Shutdown
Normal
VDET1
VREL1
DOUT
VDET2
BAT
COUT
V
SS
BAT
VSS
VM
PACK–
BAT
V
DET3
VSS
PACK –
t
t
DET1
Charger
Connected
tDET2
REL1
Load
Connected
tREL2
Charger
Connected
Discharge Overcurrent Detector and Short-Circuit Detector
If the voltage across both protection MOSFETs (VM – VSS) becomes higher than the discharge overcurrent
detection voltage (VDET3 = 0.150 V typ) for a period of up to the discharge overcurrent detection delay time
(tDET3 = 12 ms typ), the bq28z560-R1 detects the discharge overcurrent state of the battery and the DOUT pin
transitions to a low level. This prohibits discharging the battery by turning off the external discharge control Nchannel MOSFET.
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Additionally, if the voltage across both protection MOSFETs (VM – VSS) becomes higher than the short-circuit
voltage (VSHORT = VBAT – 0.9 V typ) for a period up to the discharge short-circuit detection delay time
(tSHORT = 400 µs typ), the bq28z560-R1 detects short-circuit of the battery and the DOUT pin transitions to a low
level. This prohibits discharging the battery by turning off the external discharge control N-channel MOSFET.
In both the discharge overcurrent and short-circuit states, an internal discharge overcurrent release resistor (20
kΩ typ) is turned on (switched in between VM and VSS), allowing the VM pin to be pulled down to the VSS
potential if the load is released. If the VM – VSS voltage becomes lower than the discharge overcurrent detection
voltage (VDET3 = 0.150 V typ) for a period up to the discharge overcurrent release delay time (tREL3 = 4 ms typ),
the discharge overcurrent release resistor is turned off and the DOUT pin transitions to a high level, enabling
discharge of the battery by turning on the external discharge control N-channel MOSFET.
Discharge
Overcurrent
BAT
Normal
Discharge
Overcurrent
Normal
Normal
VDET1
VREL1
DOUT
VDET2
BAT
COUT
VSS
BAT
VSS
VM
PACK–
BAT
VSHORT
VDET3
VSS
tOCD
Load
Connected
tOCR
Load
Disconnected
tSHORT
t OCR
Load Short
Circuit
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Charge Overcurrent Detector
If the voltage across both protection MOSFETs (VM – VSS) becomes more negative than the charge overcurrent
detection voltage (VDET4 = –0.112 V typ) for a period up to the charge overcurrent detection delay time (tDET4 =
12 ms typ) due to an abnormal charging current or abnormal charging voltage, the bq28z560-R1 detects the
overcurrent charge state of the battery and the COUT pin transitions to a low level. This prohibits charging the
battery by turning off the external charge control N-channel MOSFET. The bq28z560-R1 releases from the
charge overcurrent detection state on by detecting the connection of a load for a period up to the overcharge
release delay time (tREL4 = 4 ms typ).
Table 2. Hardware Control Due to Fault Detection
Fault Condition
Overcharge Voltage
Protection
DOUT
ON
COUT
OFF
Delay
(typ)
Comment
1s
Once BATHI occurs for longer than the specified duration (1 s typ), the CHG FET is
turned OFF, and bus communication is not valid, the system will support power to the
load with current flow through the CHG FET parasitic diode. This can cause the cell to
discharge. Once the cell voltage reaches the overcharge release voltage for the
specified duration (8 ms typ) the CHG FET is turned ON and bus communication is valid.
Overcurrent
Protection During
Charging
ON
OFF
12 ms
If the cell is being charged with excessive current, the threshold will be based on a
hardware limit measurement of –112 mV typ across the CHG + DSG FET (VM – Vss) for
a duration longer than 12 ms (typ), the CHG FET is turned OFF and bus communication
is not valid. This will prevent further charging of the cell. The setting of the CHG bit in the
control Status register is dependent on the OC bit setting in the Flags Bit Definition
register selection.
The FET bit in the Control between the charger is removed and cell voltage falls below
the threshold for greater than 8 ms (typ). COUT is turned back ON. Once the host MCU
takes corrective action OR if the battery charger is removed AND there is a load
detected for a period of 4 ms (typ), the CHG FET is turned ON bus communication is
valid.
Over Discharging
Voltage Protection
OFF
ON
24 ms
If the cell voltage falls to lower than 2.3 V for a duration of 24 ms (typ), the DSG FET is
turned OFF, and bus communication is not valid. The system requires if the charger is
connected and cell voltage rises above threshold for greater than 4 ms (typ). DOUT is
turned back ON and bus communication is valid.
12 ms
If the cell is being discharged with excessive current, the threshold will be based on a
hardware limit measurement of 150 mV typ across the DSG + CHG FET ( VM – Vss) for
a duration longer than 12 ms (typ), the DSG FET is turned OFF, and bus communication
is not valid. This prevents further discharging of the cell, and the DSG bit in the Control
Status register will be set. If the drop across the DSG + CHG FET is less than the
threshold OR there is no load detected for a duration of 4 ms (typ), the DSG FET is
turned ON and bus communication is valid.
400 µs
Detection of cell short circuit is measured at VM input. Shorted cell detection is VBAT –
0.9 V for greater than 400 µs at VM terminal, and the DSG FET is turned OFF, and bus
communication is not valid. The DSG bit in the control Status register will be set. The
system will turn the DSG FET ON if the voltage at VM is below 150 mV OR no load is
detected.
Overcurrent
Protection During
Discharging
Short-Circuit
Protection
OFF
OFF
ON
ON
Gas Gauge Control of Discharge DOUT Pin
Firmware Control of DOUT for Protection
The gas gauge firmware can override the hardware-based protection by forcing DOUT low to turn OFF the
discharge FET. However, the firmware cannot override the hardware protection to force discharge.
The following conditions can enable firmware to force DOUT low:
1. BATLOW—Undervoltage protection using CUV settings. If the cell voltage drops below the firmware setting
the DOUT pin transitions to a low to turn off the discharge FET. The Discharge FET is turned back on once
the cell voltage rises above the set hysteresis.
2. OCD condition—If the average discharge current is greater than the set OCD current, the DOUT pin
transitions low to turn of the Discharge FET. The Discharge FET is turned back on once the average current
decreases below the set level.
3. OTD condition—The DOUT will transition low if the discharge current is flowing and the temperature is above
th set OTD threshold.
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4. The HOST_DISCONNECT (DSG FET OFF) subcommand—This feature is useful for the system to disable
the discharge FET from the battery pack if it fails to authenticate.
The conditions stated above are ignored if there is charge current flow (body diode protection).
Gas Gauge Control of Charge FET
Firmware Control of Charge FET for Protection
The gas gauge firmware control of the charge FET is achieved by using the GPIO with external circuitry.
Typically the COUT pin is high and so to override this, the GPIO pin transitions low and the CHG FET gate drive
is pulled low to turn OFF the Charge FET. The output of the GPIO pin will be released once the fault condition is
removed.
The following parameters can be controlled through firmware (GPIO pin) providing the set thresholds are within
the range of the hardware limits set by the protector.
1. BATHI—Overvoltage protection using COV settings. If the cell voltage exceeds the firmware setting the
GPIO output transitions low to turn off the Charge FET. The Charge FET is turned back on once the cell
voltage decays below the set hysteresis (GPIO output transitions high).
2. OCC condition—If the average current is greater than the set OCC current, the GPIO output transitions low
to turn of the Charge FET. The Charge FET is turned back on once the average current decreases to the set
level.
3. OTC condition—The CFET output will transition low if the charge current is flowing and the temperature is
above the set OTC threshold or Charge Inhibit Temperature Hi. Alternatively, the CFET will not be allowed to
turn ON if the temperature is above the set OTC or Charge Inhibit Temperature Hi thresholds and charge
inhibit flag is set.
The conditions stated above are ignored if there is discharge current flow (body diode protection).
4. Taper Current (TC) condition—This condition can also be used to turn OFF the Charge FET when the
[ChgFetTerm]bit (Bit 2/0x04) in Operation Configuration C is set and the gauge detects primary charge
termination. The CHG FET would turn ON once RSOC < TCA clear%.
Zero Voltage Charging
When the cell voltage is 0 V and if the charger voltage is above the minimum operating voltage for 0 V charging
(1.2 V max), the COUT output transitions to a high level and charge current can flow.
FET Control Protection
Figure 6 shows an overview of the FET Control Protection operation.
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Shutdown
CHG: OFF
DSG: OFF
VREG: OFF
Attach a Charge
Short-Circuit
Protection
CHG: ON
DSG: OFF
VREG: ON
Overcurrent Protection
During Discharging
CHG: ON
DSG: OFF
VREG: ON
CHG: OFF
DSG: ON
VREG: ON
CHG: ON
DSG: OFF
VREG: OFF
VBAT > 2.3 V
for a period of
t > 4.0 ms
VBAT < 2.3 V
for a period of t > 24 ms
VM > 0.15 V for a period
of 12 ms
Normal
CHG: ON
DSG: ON
VREG: ON
VM < 0.15 V or
No Load detected
for a period of 4.0 ms
VM < –0.112 V
for a period of 12 ms
Overcurrent Protection
During Charging
Over-Discharge
Protection
VM > VBAT – 0.9 V
for a period of t > 400 µs
VM < 0.15 V
or
No Load detected
No Charger
Charger removed and
Load detected
for a period of 4.0 ms
VBAT > 4.25 V
for a period
of 1.0 s
VBAT < 4.07 V
for a period of 8.0 ms
Overcharge
Voltage Protection
CHG: OFF
DSG: ON
VREG: ON
Figure 6. FET Control Protection
NOTE
When the CHG FET or DSG FET is turned OFF due to fault conditions, bus
communication is not valid. The bus communication will only be activated by removal of
the fault condition (see Table 2).
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Regulator
Regulator out voltage is fixed at typically 2.5 V with a minimum output capacitance of 0.1 µF (0.47 µF typ). There
is an internal current limit designed for 60 mA (typ) when output is shorted to GND. When VBAT is over 8.0 V
(typ), the regulator is turned off for the safety of the package dissipation.
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DATA COMMANDS
STANDARD DATA COMMANDS
The bq28z560-R1 uses a series of 2-byte standard commands to enable system reading and writing of battery
information. Each standard command has an associated command-code pair, as indicated in Table 3. Each
protocol has specific means to access the data at each Command Code. DataRAM is updated and read by the
gauge only once per second. Standard commands are accessible in normal operation mode.
Table 3. Standard Commands
COMMAND CODE
UNITS
SEALED
ACCESS
CNTL
0x00 / 0x01
N/A
R/W
NAME
Control()
AtRate()
AR
0x02 / 0x03
mA
R/W
AtRateTimeToEmpty()
ARTTE
0x04 / 0x05
Minutes
R
Temperature()
TEMP
0x06 / 0x07
0.1K
R
Voltage()
VOLT
0x08 / 0x09
mV
R
Flags()
FLAGS
0x0a / 0x0b
N/A
R
NominalAvailableCapacity()
NAC
0x0c / 0x0d
mAh
R
FullAvailableCapacity()
FAC
0x0e / 0x0f
mAh
R
RemainingCapacity()
RM
0x10 / 0x11
mAh
R
FullChargeCapacity()
FCC
0x12 / 0x13
mAh
R
AI
0x14 / 0x15
mA
R
TimeToEmpty()
TTE
0x16 / 0x17
Minutes
R
TimeToFull()
TTF
0x18 / 0x19
Minutes
R
SI
0x1a / 0x1b
mA
R
STTE
0x1c / 0x1d
Minutes
R
AverageCurrent()
StandbyCurrent()
StandbyTimeToEmpty()
MaxLoadCurrent()
MaxLoadTimeToEmpty()
AvailableEnergy()
AveragePower()
TTEatConstantPower()
Internal_Temp()
CycleCount()
MLI
0x1e / 0x1f
mA
R
MLTTE
0x20 / 0x21
Minutes
R
AE
0x22 / 0x23
mWhr /
cWhr
R
AP
0x24 / 0x25
mW / cW
R
TTECP
0x26 / 0x27
Minutes
R
INTTEMP
0x28 / 0x29
0.1°K
R
CC
0x2a / 0x2b
Counts
R
StateOfCharge()
SOC
0x2c / 0x2d
%
R
StateOfHealth()
SOH
0x2e / 0x2f
% / num
R
PassedCharge()
PCHG
0x34 / 0x35
mAh
R
DOD0()
DOD0
0x36 / 0x37
HEX#
R
SelfDischargeCurrent()
SDSG
0x38 / 0x39
mA
R
Control(): 0x00/0x01
Issuing a Control() command requires a subsequent 2-byte subcommand. These additional bytes specify the
particular control function desired. The Control() command allows the system to control specific features of the
bq28z560-R1 during normal operation and additional features when the bq28z560-R1 is in different access
modes, as described in Table 4.
Table 4. Control() Subcommands
CNTL DATA
SEALED
ACCESS
CONTROL_STATUS
0x0000
Yes
Reports the status of DF Checksum, Hibernate, IT, etc.
DEVICE_TYPE
0x0001
Yes
Reports the device type of 0x0541 (indicating bq28z560-R1)
CNTL FUNCTION
20
DESCRIPTION
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Table 4. Control() Subcommands (continued)
CNTL DATA
SEALED
ACCESS
FW_VERSION
0x0002
Yes
HW_VERSION
0x0003
Yes
Reports the hardware version of the device type
Reserved
0x0004
No
Not to be used
RESET_DATA
0x0005
No
Returns reset data
Reserved
0x0006
No
Not to be used
PREV_MACWRITE
0x0007
No
Returns previous MAC command code
CHEM_ID
0x0008
Yes
Reports the chemical identifier of the Impedance Track configuration
BOARD_OFFSET
0x0009
No
Forces the device to measure and store the board offset
CC_OFFSET
0x000A
No
Forces the device to measure and internal CC offset
CC_OFFSET_SAVE
0x000B
No
Forces the device to store the internal CC offset
DF_VERSION
0x000C
Yes
Reports the data flash version on the device
SET_FULLSLEEP
0x0010
No
Set the [FULLSLEEP] bit in Control Status register to 1
SET_HIBERNATE
0x0011
Yes
Forces CONTROL_STATUS [HIBERNATE] to 1
CLEAR_HIBERNATE
0x0012
Yes
Forces CONTROL_STATUS [HIBERNATE] to 0
SET_SHUTDOWN
0x0013
Yes
Forces CONTROL_STATUS [SHUTDOWN] to 1. SET_SHUTDOWN
enables the system to enter into SHUTDOWN mode.
CLEAR_SHUTDOWN
0x0014
Yes
Forces CONTROL_STATUS [SHUTDOWN] to 0
SET_HDQINTEN
0x0015
Yes
Forces CONTROL_STATUS [HDQIntEn] to 1
CLEAR_HDQINTEN
0x0016
Yes
Forces CONTROL_STATUS [HDQIntEn] to 0
STATIC_CHEM_CHKSUM
0x0017
Yes
Calculates chemistry checksum
HOST_DISCONNECT
0x0018
Yes
Forces the DOUT pin low to disable discharge
HOST_CONNECT
0x0019
Yes
Clears DSGFETOFF, allowing DOUT to go high if no other conditions force
it low
SEALED
0x0020
No
Places the bq28z560-R1 in SEALED ACCESS mode
IT_ENABLE
0x0021
No
Enables the Impedance Track algorithm
CAL_ENABLE
0x002d
No
Toggle bq28z560-R1 CALIBRATION mode
RESET
0x0041
No
Forces a full reset of the bq28z560-R1
EXIT_CAL
0x0080
No
Exit bq28z560-R1 CALIBRATION mode
ENTER_CAL
0x0081
No
Enter bq28z560-R1 CALIBRATION mode
OFFSET_CAL
0x0082
No
Reports internal CC offset in CALIBRATION mode
CNTL FUNCTION
DESCRIPTION
Reports the firmware version on the device type
CONTROL_STATUS: 0x0000
Instructs the gas gauge to return status information to Control addresses 0x00/0x01. The status word includes
the following information.
Table 5. CONTROL_STATUS Flags
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
High Byte
DSGFETOFF
FAS
SS
CALMODE
CCA
BCA
CSV
HDQIntEn
Low Byte
SHUTDOWN
HIBERNATE
FULLSLEEP
SLEEP
LDMD
RUP_DIS
VOK
QEN
DSGFETOFF = State bit indicating the DISCHARGE FET has been disabled by HOST (HOST DISCONNECT).
FAS = Status bit indicating the bq28z560-R1 is in FULL ACCESS SEALED state. Active when set.
SS = Status bit indicating the bq28z560-R1 is in the SEALED state. Active when set.
CALMODE = Status bit indicating the calibration function is active. True when set. Default is 0.
CCA =
Status bit indicating the bq28z560-R1 coulomb counter Calibration routine is active. The CCA routine takes place
approximately 1 minute after the initialization and periodically as gauging conditions change. Active when set.
BCA = Status bit indicating the bq28z560-R1 Board Calibration routine is active. Active when set.
CSV = Status bit indicating a valid data flash checksum has been generated. Active when set.
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HDQIntEn = Status bit indicating the HDQ interrupt function is active. True when set. Default is 0.
SHUTDOWN = Status bit indicating the bq28z560-R1 is in SHUTDOWN mode. True when set. Default is 0.
HIBERNATE = Status bit indicating a request for entry into HIBERNATE from SLEEP mode has been issued. True when set. Default is
0. Control bit when set will put the bq28z560-R1 into the lower power state of SLEEP mode. It is not possible to monitor
this bit.
FULLSLEEP =
Status bit indicating the bq28z560-R1 is in FULLSLEEP mode. True when set. The state can be detected by monitoring
the power used by the bq28z560-R1 because any communication will automatically clear it.
SLEEP = Status bit indicating the bq28z560-R1 is in SLEEP mode. True when set.
LDMD = Status bit indicating the bq28z560-R1 Impedance Track algorithm using CONSTANT POWER mode. True when set.
Default is 0 (CONSTANT CURRENT mode).
RUP_DIS = Status bit indicating the bq28z560-R1 Ra table updates are disabled. True when set.
VOK = Status bit indicating cell voltages are OK for Qmax updates. True when set.
QEN = Status bit indicating the bq28z560-R1 Qmax updates are enabled. True when set.
Control(): 0x00/0x01
Issuing a Control() command requires a subsequent 2-byte subcommand. These additional bytes specify the
particular control function desired. The Control() command allows the system to control specific features of the
bq28z560-R1 during normal operation and additional features when the device is in access modes, as described
in Table 6.
Table 6. Control() Subcommands
CNTL FUNCTION
CNTL DATA
SEALED ACCESS
DESCRIPTION
SET_FULLSLEEP
0x0010
Yes
Sets the [FULLSLEEP] bit in Control Status register to 1
SET_HIBERNATE
0x0011
Yes
Forces CONTROL_STATUS [HIBERNATE] to 1
CLEAR_HIBERNATE
0x0012
Yes
Forces CONTROL_STATUS [HIBERNATE] to 0
SET_SHUTDOWN
0x0013
Yes
Forces CONTROL_STATUS [SHUTDOWN] to 1
CLEAR_SHUTDOWN
0x0014
Yes
Forces CONTROL_STATUS [SHUTDOWN] to 0
HOST_DISCONNECT
0x0018
Yes
Forces the DOUT pin low to disable discharge.
HOST_CONNECT
0x0019
Yes
Clears DSGFETOFF allowing DOUT to go high if no
other conditions force it low
DEVICE_TYPE: 0x0001
Instructs the gas gauge to return the device type to addresses 0x00/0x01.
FW_VERSION: 0x0002
Instructs the gas gauge to return the firmware version to addresses 0x00/0x01. The bq28z560-R1 firmware
version return is 0x0214.
HW_VERSION: 0x0003
Instructs the gas gauge to return the hardware version to addresses 0x00/0x01. For bq28z560-R1, 0x0060 is
returned. For a firmware upgrade from bq28z560-R1, 0x0000 or 0x0060 is returned.
RESET_DATA: 0x0005
Instructs the gas gauge to return the number of resets performed to addresses 0x00/0x01.
PREV_MACWRITE: 0x0007
Instructs the gas gauge to return the previous command written to addresses 0x00/0x01. The value returned is
limited to less than 0x0020.
CHEM_ID: 0x0008
Instructs the gas gauge to return the chemical identifier for the Impedance Track configuration to addresses
0x00/0x01.
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BOARD_OFFSET: 0x0009
Instructs the gas gauge to calibrate board offset. During board offset calibration the [BCA] bit is set.
CC_OFFSET: 0x000A
Instructs the gas gauge to calibrate coulomb counter offset. During calibration the [CCA] bit is set.
CC_OFFSET_SAVE: 0x000B
Instructs the gas gauge to save the calibration coulomb counter offset after calibration.
DF_VERSION: 0x000C
Instructs the gas gauge to return the data flash version to addresses 0x00/0x01.
SET_FULLSLEEP: 0x0010
Instructs the gas gauge to set the FULLSLEEP bit in the Control Status register to 1. This allows the gauge to
enter the FULLSLEEP power mode after the transition to SLEEP power state is detected. In FULLSLEEP mode,
less power is consumed by disabling an oscillator circuit used by the communication engines. For HDQ
communication, one host message will be dropped. For I2C communications, the first I2C message will incur a
6–8 ms clock stretch while the oscillator is started and stabilized. A communication to the device in FULLSLEEP
forces the device back to SLEEP mode.
SET_HIBERNATE: 0x0011
Instructs the gas gauge to force the CONTROL_STATUS [HIBERNATE] bit to 1. This enables the gauge to enter
the HIBERNATE power mode after the transition to SLEEP power state is detected and the required conditions
are met. The [HIBERNATE] bit is automatically cleared upon exiting from HIBERNATE mode.
CAUTION
Do not use the Control() subcommand SET_HIBERNATE to disable HIBERNATE
mode. To disable HIBERNATE mode, Hibernate Voltage and Current must be set to 0
in the data flash.
If HIBERNATE mode is initiated, always ensure that the bus line is pulled high by an
external resistor. It is important to prevent the bus line from being pulled low by an
external signal on the line when in HIBERNATE mode; otherwise, the device may latch
and a cold power cycle is required.
CLEAR_HIBERNATE: 0x0012
Instructs the gas gauge to force the CONTROL_STATUS [HIBERNATE] bit to 0. This prevents the gauge from
entering the HIBERNATE power mode after the transition to SLEEP power state is detected. It can also be used
to force the gauge out of HIBERNATE mode.
SET_SHUTDOWN: 0x0013
Sets the CONTROL_STATUS [SHUTDOWN] bit to 1, thereby enabling the gas gauge to enter SHUTDOWN
mode, depending on whether the conditions are met for gas gauge shutdown or not. The delay for shutdown is
1 s, providing there is no charging current detected.
CLEAR_SHUTDOWN: 0x0014
Disables the shutdown by setting this bit to 1, thereby forcing CONTROL_STATUS [SHUTDOWN] to 0.
SET_HDQINTEN: 0x0015
Instructs the gas gauge to set the CONTROL_STATUS [HDQIntEn] bit to 1. This enables the HDQ Interrupt
function. When this subcommand is received, the device will detect any of the interrupt conditions and assert the
interrupt at 1-s intervals until the CLEAR_HDQINTEN command is received or the count of HDQHostIntrTries
has lapsed (default 3).
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CLEAR_HDQINTEN: 0x0016
Instructs the gas gauge to set the CONTROL_STATUS [HDQIntEn] bit to 0. This disables the HDQ Interrupt
function.
STATIC_CHEM_DF_CHKSUM: 0x0017
Instructs the gas gauge to calculate chemistry checksum as a 16-bit unsigned integer sum of all static chemistry
data. The most significant bit (MSB) of the checksum is masked yielding a 15-bit checksum. This checksum is
compared with the value stored in the data flash Static Chem DF Checksum. If the value matches, the MSB will
be cleared to indicate a pass. If it does not match, the MSB will be set to indicate failure.
DSG FET OFF (HOST_DISCONNECT): 0x0018
Instructs the gas gauge to force the protection DOUT pin to a low level. This prohibits discharging the battery by
turning off the external discharge control N-channel MOSFET.
DSG FET ON (HOST_CONNECT): 0x0019
Instructs the gas gauge to release the DOUT high if no other conditions exist to force the pin low. This allows
discharging the battery by turning on the external discharge control N-channel MOSFET.
SEALED: 0x0020
Instructs the gas gauge to transition from UNSEALED state to SEALED state. The gas gauge should always be
set to SEALED state for use in customers' end equipment.
IT ENABLE: 0x0021
This command forces the gas gauge to begin the Impedance Track algorithm, sets Bit 2 of UpdateStatus, and
causes the [VOK] and [QEN] flags to be set in the CONTROL_STATUS register. [VOK] is cleared if the voltages
are not suitable for a Qmax update. Once set, [QEN] cannot be cleared. This command is only available when
the gas gauge is UNSEALED and is typically enabled at the last step of production after a system test is
completed.
The CFET and DFET are not automatically enabled until the IT Enable bit is sent. Prior to this, to control these
FETs, a command must be sent to set the CHGFET and DSGFET bits in the Flags Bit Definitions Register to
enable the COUT and DOUT, respectively.
CAL_ENABLE: 0x002D
This command toggles the CalEn bit in the PACK Configuration register.
RESET: 0x0041
This command instructs the gas gauge to perform a full reset. This command is only available when the gas
gauge is unsealed.
EXIT_CAL: 0x0080
This command instructs the gas gauge to exit CALIBRATION mode.
ENTER_CAL: 0x0081
This command instructs the gas gauge to enter CALIBRATION mode.
OFFSET_CAL: 0x0082
This command instructs the gas gauge to perform offset calibration.
AtRate(): 0x02/0x03
The AtRate() read-/write-word function is the first half of a two-function command call-set used to set the AtRate
value in calculations made by the AtRateTimeToEmpty() function. The AtRate() units are in mA.
24
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The AtRate() value is a signed integer with negative values interpreted as a discharge current value. The
AtRateTimeToEmpty() function returns the predicted operating time at the AtRate value of discharge. The default
value for AtRate() is zero and will force AtRateTimeToEmpty() to return 65,535. Both the AtRate() and
AtRateTimeToEmpty() commands should only be used in NORMAL mode.
AtRateTimeToEmpty(): 0x04/0x05
This read-only function returns an unsigned integer value of the predicted remaining operating time if the battery
is discharged at the AtRate() value in minutes with a range of 0 to 65,534. A value of 65,535 indicates AtRate() =
0. The gas gauge updates AtRateTimeToEmpty() within 1 s after the system sets the AtRate() value. The gas
gauge automatically updates AtRateTimeToEmpty() based on the AtRate() value every 1 s. The AtRate() and
AtRateTimeToEmpty() commands should only be used in NORMAL mode.
Temperature(): 0x06/0x07
This read-only function returns an unsigned integer value of the battery temperature in units of 0.1K measured by
the gas gauge.
Voltage(): 0x08/0x09
This read-only function returns an unsigned integer value of the measured cell-pack voltage in mV with a range
of 0 to 6000 mV.
Flags(): 0x0a/0x0b
This read-only function returns the contents of the gas-gauge status register, depicting the current operating
status.
Table 7. Flags Bit Definitions
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
High Byte
OT
OC
BATHI
BATLO
CHG_INH
ALRT
FC
CHG
Low Byte
OCVTAKEN
ISD
TDD
CHGFET
DSGFET
SOC1
SOCF
DSG
These fault flags will only clear if the fault condition is removed:
OT = Overtemperature in a Charge or Discharge condition is detected. True when set.
OC = Overcurrent in a Charge or Discharge condition is detected. True when set.
BATHI =
BATLO =
Battery High bit indicating a high battery voltage condition. Refer to the data flash BATTERY HIGH parameters for
threshold settings.
Battery Low bit indicating a low battery voltage condition. Refer to the data flash BATTERY LOW parameters for
threshold settings.
CHG_INH = Charge Inhibit indicates the temperature is outside the range [Charge Inhibit Temp Low, Charge Inhibit Temp
High]. True when set.
ALRT = Indicates there is an Alert in the system. True when set.
Full-charged is detected. FC is set when charge termination is reached and FC Set% = –1 (see CHARGING AND
FC = CHARGE TERMINATION INDICATION for details) or State of Charge is larger than FC Set% and FC Set% is not –1.
True when set.
CHG = (Fast) charging allowed. True when set.
OCVTAKEN = Cleared on entry to RELAX mode and set to 1 when OCV measurement is performed in RELAX.
ISD = Internal Short is detected. True when set.
TDD = Tab Disconnect is detected. True when set.
CHGFET= Indicates the state of the firmware CFET control. True when set to 1.
DSGFET= Indicates the state of the firmware DFET control. True when set to 1.
SOC1 = State-of-Charge-Threshold 1 (SOC1 Set) reached. True when set.
SOCF = State-of-Charge-Threshold Final (SOCF Set %) reached. True when set.
DSG = Discharging detected. True when set.
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NominalAvailableCapacity(): 0x0c/0x0d
This read-only command pair returns the uncompensated (less than C/20 load) battery capacity remaining. Units
are mAh.
FullAvailableCapacity(): 0x0e/0x0f
This read-only command pair returns the uncompensated (less than C/20 load) capacity of the battery when fully
charged. Units are mAh. FullAvailableCapacity() is updated at regular intervals, as specified by the Impedance
Track algorithm.
RemainingCapacity(): 0x10/0x11
This read-only command pair returns the compensated battery capacity remaining. Units are mAh.
FullChargeCapacity(): 0x12/13
This read-only command pair returns the compensated capacity of the battery when fully charged. Units are
mAh. FullChargeCapacity() is updated at regular intervals, as specified by the Impedance Track algorithm.
AverageCurrent(): 0x14/0x15
This read-only command pair returns a signed integer value that is the average current flow through the sense
resistor. It is updated every 1 s. Units are mA.
TimeToEmpty(): 0x16/0x17
This read-only function returns an unsigned integer value of the predicted remaining battery life at the present
rate of discharge, in minutes. A value of 65,535 indicates battery is not being discharged.
TimeToFull(): 0x18/0x19
This read-only function returns an unsigned integer value of predicted remaining time until the battery reaches
full charge, in minutes, based upon AverageCurrent(). The computation accounts for the taper current time
extension from the linear TTF computation based on a fixed AverageCurrent() rate of charge accumulation. A
value of 65,535 indicates the battery is not being charged.
StandbyCurrent(): 0x1a/0x1b
This read-only function returns a signed integer value of the measured standby current through the sense
resistor. The StandbyCurrent() is an adaptive measurement. Initially it reports the standby current programmed in
Initial Standby, and after spending some time in standby, reports the measured standby current.
The register value is updated every 1 s when the measured current is above the Deadband and is less than or
equal to 2 x Initial Standby. The first and last values that meet this criteria are not averaged in, since they may
not be stable values. To approximate a 1-minute time constant, each new StandbyCurrent() value is computed
by taking the approximate 93% weight of the last standby current and the approximate 7% of the current
measured average current.
StandbyTimeToEmpty(): 0x1c/0x1d
This read-only function returns an unsigned integer value of the predicted remaining battery life at the standby
rate of discharge, in minutes. The computation uses Nominal Available Capacity (NAC), the uncompensated
remaining capacity, for this computation. A value of 65,535 indicates the battery is not being discharged.
MaxLoadCurrent(): 0x1e/0x1f
This read-only function returns a signed integer value, in units of mA, of the maximum load conditions. The
MaxLoadCurrent() is an adaptive measurement, which is initially reported as the maximum load current
programmed in Initial Max Load Current. If the measured current is ever greater than Initial Max Load
Current, then MaxLoadCurrent() updates to the new current. MaxLoadCurrent() is reduced to the average of the
previous value and Initial Max Load Current whenever the battery is charged to full after a previous discharge
to an SOC less than 50%. This prevents the reported value from maintaining an unusually high value.
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MaxLoadTimeToEmpty(): 0x20/0x21
This read-only function returns an unsigned integer value of the predicted remaining battery life at the maximum
load current discharge rate, in minutes. A value of 65,535 indicates that the battery is not being discharged.
AvailableEnergy(): 0x22/0x23
This read-only function returns an unsigned integer value of the predicted charge or energy remaining in the
battery. The value is reported in units of mW (Design Energy Scale = 1) or cW (Design Energy Scale = 10).
AveragePower(): 0x24/0x25
This read-word function returns an unsigned integer value of the average power of the current discharge. It is
negative during discharge and positive during charge. A value of 0 indicates that the battery is not being
discharged. The value is reported in units of mW (Design Energy Scale = 1) or cW (Design Energy
Scale = 10).
TimeToEmptyAtConstantPower(): 0x26/0x27
This read-only function returns an unsigned integer value of the predicted remaining operating time if the battery
is discharged at the AveragePower() value in minutes. A value of 65,535 indicates AveragePower() = 0. The gas
gauge automatically updates TimeToEmptyatConstantPower() based on the AveragePower() value every 1 s.
Internal_Temp(): 0x28/0x29
This read-only function returns an unsigned integer value of the measured internal temperature of the device in
units of 0.1K measured by the gas gauge.
CycleCount(): 0x2a/0x2b
This read-only function returns an unsigned integer value of the number of cycles the battery has experienced
with a range of 0 to 65,535. One cycle occurs when accumulated discharge ≥ CC Threshold.
StateOfCharge(): 0x2c/0x2d
This read-only function returns an unsigned integer value of the predicted remaining battery capacity expressed
as a percentage of FullChargeCapacity(), with a range of 0 to 100%.
StateOfHealth(): 0x2e/0x2f
0x2E SOH percentage: This read-only function returns an unsigned integer value, expressed as a percentage of
the ratio of predicted FCC(25°C, SOH current rate) over the DesignCapacity(). The FCC(25°C, SOH current rate)
is the calculated full charge capacity at 25°C and the SOH current rate, which is specified in the data flash (State
of Health Load). The range of the returned SOH percentage is 0x00 to 0x64, indicating 0 to 100%,
correspondingly.
PassedCharge(): 0x34/0x35
This signed integer indicates the amount of charge passed through the sense resistor since the last Impedance
Track simulation in mAh.
DOD0(): 0x36/0x37
This unsigned integer indicates the depth of discharge during the most recent OCV reading.
SelfDischargeCurrent(): 0x38/0x39
This read-only command pair returns the signed integer value that estimates the battery self discharge current.
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EXTENDED DATA COMMANDS
Extended commands offer additional functionality beyond the standard set of commands. They are used in the
same manner; however, unlike standard commands, extended commands are not limited to 2-byte words. The
number of command bytes for a given extended command ranges in size from single to multiple bytes, as
specified in Table 8. For details on the SEALED and UNSEALED states, see ACCESS MODES.
Table 8. Extended Commands
NAME
COMMAND CODE
Reserved
PackConfig()
DesignCapacity()
DataFlashClass()
(2)
DataFlashBlock()
(2)
BlockData() / Authenticate()
(3)
UNITS
SEALED
ACCESS (1) (2)
UNSEALED
ACCESS (1) (2)
RSVD
0x38…0x39
N/A
R
R
PCR
0x3A / 0x3B
HEX#
R
R
DCAP
0x3C / 0x3D
mAh
R
R
DFCLS
0x3E
N/A
N/A
R/W
DFBLK
0x3F
N/A
R/W
R/W
A/DF
0x40…0x53
N/A
R/W
R/W
ACKS/DFD
0x54
N/A
R/W
R/W
DFD
0x55…0x5F
N/A
R
R/W
BlockDataCheckSum()
DFDCKS
0x60
N/A
R/W
R/W
BlockDataControl()
DFDCNTL
0x61
N/A
N/A
R/W
RSVD
0x62...0x69
N/A
R
R
BAC
0x6A/0x6B
N/A
R/W
R/W
BlockData() / AuthenticateCheckSum()
(3)
BlockData()
Reserved
BatAlertConfig()
BatAlertStatus()
Reserved
(1)
(2)
(3)
BAS
0x6C/0x6D
N/A
R/W
R/W
RSVD
0x6E...0x7F
N/A
R
R
SEALED and UNSEALED states are entered via commands to Control() 0x00/0x01.
In SEALED mode, data flash CANNOT be accessed through commands 0x3E and 0x3F.
The BlockData() command area shares functionality for accessing general data flash and for using Authentication. See
AUTHENTICATION for details.
PackConfig(): 0x3A/0x3B
SEALED and UNSEALED Access: This command returns the value stored in Pack Configuration, which is
expressed in hex value.
DesignCapacity(): 0x3C/0x3D
SEALED and UNSEALED Access: This command returns the value stored in Design Capacity, which is
expressed in mAh. This is intended to be the theoretical or nominal capacity of a new pack, but has no bearing
on the operation of the gas gauge functionality.
DataFlashClass(): 0x3E
This command sets the data flash class to be accessed. The class to be accessed should be entered in
hexadecimal.
SEALED Access: This command is not available in SEALED mode.
DataFlashBlock(): 0x3F
UNSEALED Access: This command sets the data flash block to be accessed. When 0x00 is written to
BlockDataControl(), DataFlashBlock() holds the block number of the data flash to be read or written. Example:
writing a 0x00 to DataFlashBlock() specifies access to the first 32-byte block, and a 0x01 specifies access to the
second 32-byte block, and so on.
Reading Device Name in UNSEALED Mode
To read the DeviceName in UNSEALED mode, set the BlockDataControl() (command 0x61) to a 1. This is
similar to how the manufacturer information block works. Since the Device Name is 20 bytes, the device name
will be followed by null bytes.
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SEALED Access: This command directs which data flash block will be accessed by the BlockData() command.
Writing a 0x00 to DataFlashBlock() specifies the BlockData() command will transfer authentication data. Issuing a
0x01, 0x02, or 0x03 instructs the BlockData() command to transfer Manufacturer Info Block A or B,
respectively.
Reading Device Name in SEALED Mode
To read the DeviceName when in SEALED mode, set the DataFlashBlock() (command 0x3F) to 0x05, and read
the device name from the BlockData() commands.
In general, there will be at least 12 null characters because the data flash field is limited to 20 bytes and the
SEALED mode block has 32 bytes of space.
BlockData(): 0x40…0x5F
This command range is used to transfer data for data flash class access. This command range is the 32-byte
data block used to access Manufacturer Info Block A or B. Manufacturer Info Block A is read-only for the
SEALED access. UNSEALED access is read/write.
BlockDataChecksum(): 0x60
The host system should write this value to inform the device that new data is ready for programming into the
specified data flash class and block.
UNSEALED Access: This byte contains the checksum on the 32 bytes of block data read or written to data flash.
The least-significant byte of the sum of the data bytes written must be complemented ([255 – x] for x the 8-bit
summation of the BlockData() (0x40 to 0x5F) on a byte-by-byte basis) before being written to 0x60.
SEALED Access: This byte contains the checksum for the 32 bytes of block data written to Manufacturer Info
Block A or B. The least-significant byte of the sum of the data bytes written must be complemented ([255 – x]
for x the 8-bit summation of the BlockData() (0x40 to 0x5F) on a byte-by-byte basis) before being written to 0x60.
BlockDataControl(): 0x61
UNSEALED Access: This command is used to control data flash ACCESS mode. The value determines the data
flash to be accessed. Writing 0x00 to this command enables BlockData() to access general data flash.
SEALED Access: This command is not available in SEALED mode.
Reserved(): 0x62...0x69
Reserved.
BatAlertConfig(): 0x6A/0x6B
The BatAlertConfig() register can be written to set which faults, once detected, will trigger an Alert. The data flash
value for BatAlertConfig() is used to initialize this value.
Table 9. BatAlertConfig() Definitions
High Byte
Bit 15
Bit 14
Bit 13
Bit 12
Bit 11
Bit 10
Bit 9
Bit 8
BatAlertConfig()
UTC_EN
UTD_EN
RSVD
RSVD
RSVD
RSVD
RSVD
RSVD
Low Byte
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
BatAlertConfig()
OTC_EN
OTD_EN
BATHI_EN
BATLO_EN
RSVD
SOC1_EN
OCC_EN
OCD_EN
UTC_EN = Enables alert for Over Temperature Charge Current when set to 1. Default is 1.
UTD_EN = Enables alert for Over Temperature Discharge Current when set to 1. Default is 1.
RSVD = Reserved. Default = 0.
OTC_EN = Enables alert for Over Temperature Charge Current when set to 1. Default is 1.
OTD_EN = Enables alert for Over Temperature Discharge Current when set to 1. Default is 1.
BATHI_EN= Enables alert for Battery High Condition when set to 1. Default is 0.
BATLO_EN = Enables alert for Battery Low Condition when set to 1. Default is 0.
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RSVD = Reserved. Default = 0.
SOC1_EN = Enables alert for State-of-Charge-Threshold 1 (SOC1 Set) reached. True when set. Default is 1.
OCC_EN = Enables alert for Over Current Charge Condition when set to 1. Default is 0.
OCD_EN= Enables alert for Over Current DISCHARGE Condition when set to 1. Default is 0.
BatAlertStatus(): 0x6C/0x6D
The BatAlertStatus() register allows reading the safety conditions that triggered the alert. If the Pack
Configuration [CLR_READ] is set to 1, BatAlertStatus() will be reset, and the alert assertion removed
immediately. Otherwise, the BatAlertStatus() flags will clear only after the safety flag has reset, and the alert
assertion clears once all flags in BatAlertStatus() have cleared.
Table 10. BatAlertStatus() Definitions
High Byte
Bit 15
Bit 14
Bit 13
Bit 12
Bit 11
Bit 10
Bit 9
Bit 8
BatAlertStatus()
UTC
UTD
RSVD
RSVD
RSVD
RSVD
RSVD
RSVD
Low Byte
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
BatAlertStatus()
OTC
OTD
BATHI
BATLO
RSVD
SOC1
OCC
OCD
The following functions can be detected for fault conditions when set in the BatAlert Configuration register. The
fault can be indicated on Alert pin (if configured) but not differentiated because of the OR logic.
UTC = Detected Under Temperature Charge Current when set to 1.
UTD = Detected Under Temperature Discharge Current when set to 1.
RSVD = Reserved. Default = 0.
OTC = Detected Over Temperature Charge Current when set to 1.
OTD = Detected Over Temperature Discharge Current when set to 1.
BATHI= Detected Battery High Condition when set to 1.
BATLO = Detected Battery Low Condition when set to 1.
RSVD = Reserved. Default = 0.
SOC1 = Detected State-of-Charge-Threshold 1 (SOC1 Set) reached.
OCC = Detected Over Current Charge Condition when set to 1.
OCD= Detected Over Current DISCHARGE Condition when set to 1.
Reserved – 0x6E–0x7F
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DATA FLASH INTERFACE
ACCESSING THE DATA FLASH
The bq28z560-R1 data flash is a non-volatile memory that contains initialization, default, cell status, calibration,
configuration, and user information. The data flash can be accessed in several different ways, depending on in
which mode the bq28z560-R1 is operating and what data is being accessed.
Commonly accessed data flash memory locations frequently read by a system are conveniently accessed
through specific instructions, as described in DATA COMMANDS. These commands are available when the
bq28z560-R1 is either in UNSEALED or SEALED mode.
Most data flash locations, however, are only accessible in UNSEALED mode by use of the bq28z560-R1
evaluation software or by data flash block transfers. These locations should be optimized and/or fixed during the
development and manufacture processes. They become part of a golden image file and can then be written to
multiple battery packs. Once established, the values generally remain unchanged during end-equipment
operation.
To access data flash locations individually, the block containing the desired data flash location(s) must be
transferred to the command register locations where they can be read to the system or changed directly. This is
accomplished by sending the set-up command BlockDataControl() (0x61) with data 0x00. Up to 32 bytes of data
can be read directly from the BlockData() (0x40…0x5F), externally altered, then rewritten to the BlockData()
command space. Alternatively, specific locations can be read, altered, and rewritten if their corresponding offsets
are used to index into the BlockData() command space. Finally, the data residing in the command space is
transferred to data flash once the correct checksum for the whole block is written to BlockDataChecksum()
(0x60).
Occasionally, a data flash CLASS will be larger than the 32-byte block size. In this case, the DataFlashBlock()
command is used to designate which 32-byte block the desired locations reside. The correct command address
is then given by 0x40 + offset modulo 32. For example, to access Terminate Voltage in the Gas Gauging class,
DataFlashClass() is issued 80 (0x50) to set the class. Because the offset is 67, it must reside in the third 32-byte
block. Hence, DataFlashBlock() is issued 0x02 to set the block offset, and the offset used to index into the
BlockData() memory area is 0x40 + 67 modulo 32 = 0x40 + 16 = 0x40 + 0x03 = 0x43.
Reading and writing subclass data are block operations up to 32 bytes in length. If the data length exceeds the
maximum block size during a write, then the data is ignored.
NOTE
None of the data written to memory is bounded by the bq28z560-R1: The values are not
rejected by the gas gauge. Writing an incorrect value may result in hardware failure due to
firmware program interpretation of the invalid data. The written data is persistent, so a
power-on reset does not resolve the fault.
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FUNCTIONAL DESCRIPTION
FUEL GAUGING
The bq28z560-R1 measures the cell voltage, temperature, and current to determine the battery SOC based on
the Impedance Track algorithm (refer to the Theory and Implementation of Impedance Track Battery FuelGauging Algorithm Application Report [SLUA450] for more information). The bq28z560-R1 monitors charge and
discharge activity by sensing the voltage across a small-value resistor (5 mΩ to 20 mΩ typ.) between the SRP
and SRN pins and in series with the cell. By integrating charge passing through the battery, the battery’s SOC is
adjusted during battery charge or discharge.
The total battery capacity is found by comparing states of charge before and after applying the load with the
amount of charge passed. When an application load is applied, the impedance of the cell is measured by
comparing the OCV obtained from a predefined function for present SOC with the measured voltage under load.
Measurements of OCV and charge integration determine chemical state of charge and chemical capacity
(Qmax). The initial Qmax values are taken from a cell manufacturers' data sheet multiplied by the number of
parallel cells. It is also used for the value in Design Capacity. The bq28z560-R1 acquires and updates the
battery-impedance profile during normal battery usage. It uses this profile, along with SOC and the Qmax value,
to determine FullChargeCapacity() and StateOfCharge(), specifically for the present load and temperature.
FullChargeCapacity() is reported as capacity available from a fully charged battery under the present load and
temperature until Voltage() reaches Terminate Voltage. NominalAvailableCapacity() and FullAvailableCapacity()
are the uncompensated (no or light load) versions of RemainingCapacity() and FullChargeCapacity(),
respectively.
The bq28z560-R1 has two flags accessed by the Flags() function that warn when the battery’s SOC has fallen to
critical levels. When RemainingCapacity() falls below the first capacity threshold specified in SOC1 Set
Threshold, the [SOC1] (State of Charge Initial) flag is set. The flag is cleared once RemainingCapacity() rises
above SOC1 Clear Threshold. All units are in mAh.
When RemainingCapacity() falls below the second capacity threshold (SOCF Set Threshold), the [SOCF] (State
of Charge Final) flag is set, serving as a final discharge warning. If SOCF Set Threshold = –1, the flag is
inoperative during discharge. Similarly, when RemainingCapacity() rises above SOCF Clear Threshold and the
[SOCF] flag has already been set, the [SOCF] flag is cleared. All units are in mAh.
The bq28z560-R1 has two additional flags accessed by the Flags() function that warn of internal battery
conditions. The gas gauge monitors the cell voltage during relaxed conditions to determine if an internal short
has been detected. When this condition occurs, [ISD] will be set. The bq28z560-R1 also has the capability to
detect when a tab is disconnected in a 2-cell parallel system by actively monitoring the SOH. When this
conditions occurs, [TDD] will be set.
IMPEDANCE TRACK VARIABLES
The bq28z560-R1 has several data flash variables that permit the user to customize the Impedance Track
algorithm for optimized performance. These variables are dependent upon the power characteristics of the
application as well as the cell itself.
LOAD Mode
LOAD mode is used to select either the CONSTANT CURRENT mode or CONSTANT POWER mode for the
Impedance Track algorithm as used in Load Select (see Load Select). When LOAD mode is 0, the CONSTANT
CURRENT mode is used (default). When LOAD mode is 1, CONSTANT POWER mode is used. The [LDMD] bit
of CONTROL_STATUS reflects the status of LOAD mode.
Load Select
Load Select defines the type of power or current mode to be used to compute load-compensated capacity in the
Impedance Track algorithm. If LOAD mode = 0 (Constant Current), then the options presented in Table 11 are
available.
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Table 11. CONSTANT CURRENT Mode Used when LOAD Mode = 0
LoadSelect Value
Current Mode Used
Average discharge current from previous cycle. There is an internal register that records the average discharge current through each
entire discharge cycle. The previous average is stored in this register.
0
1(default)
Present average discharge current. This is the average discharge current from the beginning of this discharge cycle until present time.
2
Average current: based off the AverageCurrent()
3
Current: based off of a low-pass-filtered version of AverageCurrent() (τ = 14 s)
4
Design capacity / 5: C Rate based off of Design Capacity /5 or a C / 5 rate in mA
5
Use the value specified by AtRate()
6
Use the value in User_Rate-mA. This provides a completely user-configurable method.
If LOAD mode = 1 (Constant Power), then the following options are available:
Table 12. CONSTANT POWER Mode Used When LOAD Mode = 1
LoadSelect Value
Power Mode Used
Average discharge power from the previous cycle. There is an internal register that records the average discharge power through
each entire discharge cycle. The previous average is stored in this register.
0 (default)
1
Present average discharge power. This is the average discharge power from the beginning of this discharge cycle until the present
time.
2
Average current × voltage: based off the AverageCurrent() and Voltage()
3
Current × voltage: based off of a low-pass-filtered version of AverageCurrent() (τ = 14 s) and Voltage()
4
Design energy / 5: C Rate based off of Design Energy /5 or a C / 5 rate in mA
5
Use the value specified by AtRate()
6
Use the value in User_Rate-mW/cW. This provides a completely user- configurable method.
Reserve Cap-mAh
Reserve Cap-mAh determines how much actual remaining capacity exists after reaching 0
RemainingCapacity(), before Terminate Voltage is reached. A loaded rate or no-load rate of compensation can
be selected for Reserve Cap by setting the [RESCAP] bit in the Pack Configuration register.
Reserve Cap-mWh/cWh
Reserve Cap-mWh determines how much actual remaining capacity exists after reaching 0 AvailableEnergy(),
before Terminate Voltage is reached. A loaded rate or no-load rate of compensation can be selected for
Reserve Cap by setting the [RESCAP] bit in the Pack Configuration register.
Design Energy Scale
Design Energy Scale is used to select the scale/unit of a set of data flash parameters. The value of Design
Energy Scale can be either 1 or 10 only.
Table 13. Data Flash Parameter Scale/Unit-Based on Design Energy Scale
Data Flash
Design Energy Scale = 1 (default)
Design Energy Scale = 10
Design Energy
mWh
cWh
Reserve Capacity –mWh/cWh
mWh
cWh
Avg Power Last Run
mW
cW
User Rate-mW/cW
mWh
cWh
T Rise
No Scale
Scaled by x10
Dsg Current Threshold
This register is used as a threshold by many functions in the bq28z560-R1 to determine if actual discharge
current is flowing into or out of the cell. The default for this register should be sufficient for most applications.
This threshold should be set low enough to be below any normal application load current but high enough to
prevent noise or drift from affecting the measurement.
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Chg Current Threshold
This register is used as a threshold by many functions in the bq28z560-R1 to determine if actual charge current
is flowing into or out of the cell. The default for this register should be sufficient for most applications. This
threshold should be set low enough to be below any normal charge current but high enough to prevent noise or
drift from affecting the measurement.
Quit Current, Dsg Relax Time, Chg Relax Time, and Quit Relax Time
The Quit Current is used as part of the Impedance Track algorithm to determine when the bq28z560-R1 enters
RELAX mode from a current flowing mode in either the charge direction or the discharge direction. The value of
Quit Current is set to a default value that should be above the standby current of the system.
Either of the following criteria must be met to enter RELAX mode:
1. | AverageCurrent() | < | Quit Current | for Dsg Relax Time.
2. | AverageCurrent() | < | Quit Current | for Chg Relax Time.
After about 6 minutes in RELAX mode, the bq28z560-R1 attempts to take accurate OCV readings. An additional
requirement of dV/dt < 4 µV/s is required for the bq28z560-R1 to perform Qmax updates. These updates are
used in the Impedance Track algorithms. It is critical that the battery voltage be relaxed during OCV readings and
that the current is not higher than C/20 when attempting to go into RELAX mode.
Quit Relax Time specifies the minimum time required for AverageCurrent() to remain above the QuitCurrent
threshold before exiting RELAX mode.
Qmax
Qmax contains the maximum chemical capacity of the active cell profiles, and is determined by comparing states
of charge before and after applying the load with the amount of charge passed. They also correspond to capacity
at a low rate of discharge, such as C/20 rate. For high accuracy, this value is periodically updated by the
bq28z560-R1 during operation. Based on the battery cell capacity information, the initial value of chemical
capacity should be entered in the Qmax field. The Impedance Track algorithm updates this value and maintains
it in the Pack profile.
Update Status
The Update Status register indicates the status of the Impedance Track algorithm.
Table 14. Update Status Definitions
UPDATE STATUS
STATUS
0x02
Qmax and Ra data are learned, but Impedance Track is not enabled. This should be the standard setting for a
golden image.
0x04
Impedance Track is enabled but Qmax and Ra data are not learned.
0x05
Impedance Track is enabled and only Qmax has been updated during a learning cycle.
0x06
Impedance Track is enabled. Qmax and Ra data are learned after a successful learning cycle. This should be the
operation setting for end equipment.
This register should only be updated by the bq28z560-R1 during a learning cycle or when IT_ENABLE()
subcommand is received. Refer to the application note How to Generate Golden Image for a Single-Cell
Impedance Track™ Device (SLUA544) for learning cycle details.
Avg I Last Run
The bq28z560-R1 logs the current averaged from the beginning to the end of each discharge cycle. It stores this
average current from the previous discharge cycle in this register. This register should never need to be
modified. It is only updated by the bq28z560-R1 when required.
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Avg P Last Run
The bq28z560-R1 logs the power averaged from the beginning to the end of each discharge cycle. It stores this
average power from the previous discharge cycle in this register. To get a correct average power reading, the
bq28z560-R1 continuously multiplies instantaneous current times Voltage() to get power. It then logs this data to
derive the average power. This register should never need to be modified. It is only updated by the bq28z560-R1
when required.
Delta Voltage
The bq28z560-R1 stores the maximum difference of Voltage() during short load spikes and normal load, so the
Impedance Track algorithm can calculate remaining capacity for pulsed loads.
NOTE
It is not recommended to change this value.
Ra Tables and Ra Filtering Related Parameters
These tables contain encoded data and are automatically updated during device operation. The bq28z560-R1
has a filtering process to eliminate unexpected fluctuations in Ra values while the Ra values are being updated.
The DF parameters RaFilter, RaMaxDelta, MaxResfactor, and MinResfactor control the Filtering process of Ra
values. RaMaxDelta Limits the change in Ra values to an absolute magnitude. MinResFactor and MaxResfactor
parameters are cumulative filters that limit the change in Ra values to a scale on a per discharge cycle basis.
These values are data flash configurable. No further user changes should be made to Ra values except for
reading/writing the values from a pre-learned pack (part of the process for creating golden image files).
MaxScaleBackGrid
The MaxScaleBackGrid parameter limits the resistance grid point after which back scaling will not be performed.
This variable ensures that the resistance values in the lower resistance grid points remain accurate while the
battery is at a higher DoD state.
Max DeltaV, Min DeltaV
This is the Maximal/Minimal value allowed for delta V, which will be subtracted from simulated voltage during
remaining capacity simulation.
Qmax Max Delta %
This is the maximal change of Qmax during one update, as a percentage of Design Capacity. If the gauge
attempts to change the Qmax value and this delta change value exceeds the Qmax Max delta % limit, the
change value will be capped to the old value ± DesignCapacity×QmaxMaxDelta/100.
Fast Resistance Scaling
This new algorithm improves convergency of Remaining Capacity and terminates voltage at end of discharge.
The algorithm is enabled when cell voltage goes below (Terminate Voltage + Term V Delta) or StateofCharge()
goes below Fast Scale Start SOC. For most applications, the default value of Term V Delta and Fast Scale Start
SOC are recommended.
DeltaV Max Delta
This is the maximal change of the Delta V value. If an attempted change of the value exceeds this limit, the
change value will be capped to the old value ±DeltaV Max Delta.
Lifetime Data Logging Parameters
NOTE
IT_ENABLE must be enabled (Command 0x0021) for Lifetime Data logging functions to
be active.
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The Lifetime Data logging function helps development and diagnosis with the bq28z560-R1. The bq28z560-R1
device logs the Lifetime Data as specified in the Lifetime Data and Lifetime Temp Samples data flash
subclasses. The data log recordings are controlled by the Lifetime Resolution data flash subclass.
The Lifetime Data Logging can be started by setting the IT_ENABLE bit and setting the Update Time register to a
non-zero value.
Once the Lifetime Data Logging function is enabled, the measured values are compared to what is already
stored in the data flash. If the measured value is higher than the maximum or lower than the minimum value
stored in the data flash by more than the Resolution set for at least one parameter, the entire data flash Lifetime
registers are updated after at least LTUpdateTime.
LTUpdateTime sets the minimum update time between DF writes. When a new max/min is detected, an LT
Update window of 60 seconds is enabled and the DF writes occur at the end of this window. Any additional
max/min value detected within this window will also be updated. The first new max/min value detected after this
window will trigger the next LT Update window.
Internal to bq28z560-R1 is a RAM max/min table in addition to the DF max/min table. The RAM table is updated
independent of the resolution parameters. The DF table is updated only if at least one of the RAM parameters
exceeds the DF value by more than the resolution associated with it. When DF is updated, the entire RAM table
is written to DF. Consequently, it is possible to see a new max/min value for a certain parameter even if the
value of this parameter never exceeds the maximum or minimum value stored in the data flash for this parameter
value by the resolution amount.
The Lifetime Data Logging of one or more parameters can be reset or restarted by writing new default (or
starting) values to the corresponding data flash registers through sealed or unsealed access as described below.
However, when using unsealed access, new values will only take effect after device reset.
The logged data can be accessed as R/W in UNSEALED mode from the Lifetime Data SubClass (SubClass
ID=59) of data flash. Lifetime Data may be accessed (R/W) when sealed using a process identical in
Manufacturer Info Block B and C. The DataFlashBlock command code is 4.
NOTE
Only the first 32 bytes of Lifetime Data (not resolution parameters) can be R/W when
sealed. See MANUFACTURER INFORMATION BLOCKS for sealed access.
The logging settings such as Temperature Resolution, Voltage Resolution, Current Resolution, and Update Time
can be configured only in UNSEALED mode by writing to the Lifetime Resolution subclass (SubClassID=66) of
the data flash.
The Lifetime resolution registers contain the parameters that set the limits related to how much a data parameter
must exceed the previously logged Max/Min value to be updated in the lifetime log. For example, V must exceed
MaxV by more than Voltage Resolution to update MaxV in the data flash.
DETAILED CONFIGURATION REGISTER DESCRIPTIONS
The Pack Configuration Register
Some bq28z560-R1 pins are configured via the Pack Configuration data flash register, as indicated in Table 15.
This register is programmed/read via the methods described in ACCESSING THE DATA FLASH. The register is
located at subclass = 64, offset = 0.
Table 15. Pack Configuration Bit Definition
Bit 7
36
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
High Byte
RESCAP
CalEn
RSVD
RSVD
RSVD
IWAKE
RSNS1
RSNS0
Low Byte
GNDSEL
RESFACTSTEP
SLEEP
RMFCC
CLR_READ
ALRT_POL
RSVD
TEMPS
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RESCAP = No-load rate of compensation is applied to the reserve capacity calculation. True when set. Default is 0.
CalEn = bq28z560-R1 CALIBRATION mode is enabled. Default is 0.
RSVD = Reserved. Default = 0
RSVD = Reserved. Default = 0.
RSVD = Reserved. Default = 0.
GNDSEL = The ADC ground select control. The VSS (Pin 6) is selected as ground reference when the bit is clear. Pin 7 is
selected when the bit is set. Default is 0.
IWAKE/RSNS1/RSNS0 = These bits configure the current wake function. Default is 0/0/1.
GNDSEL = The ADC ground select control. The VSS (Pin 6) is selected as ground reference when the bit is clear. Pin 7 is
selected when the bit is set. Default is 0.
ResFactStep = Enables Ra step up/down to Max/Min Res Factor before disabling Ra updates. Default is 1.
SLEEP = The gas gauge can enter sleep, if operating conditions allow. True when set. Default is 1.
RMFCC = RM is updated with the value from FCC, on valid charge termination. True when set. Default is 1.
CLR_READ = Clear on Read the Fault Flag register. True when set. Default = 0.
ALRT_POL = Set polarity of Alert output. Set to 1 means active high, so any faults detected will change output from low to
high. Default = 0, which means any fault detected will change output from high to low.
RSVD = Reserved. Default = 0.
TEMPS = Selects external thermistor for Temperature() measurements. True when set. Default is 1.
Pack Configuration B Register
Some bq28z560-R1 pins are configured via the Pack Configuration B data flash register, as indicated in
Table 16. This register is programmed/read via the methods described in ACCESSING THE DATA FLASH. The
register is located at subclass = 64, offset = 2.
Table 16. Pack Configuration B Bit Definition
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
ChgDoDEoC
SE_TDD
VconsEN
SE_ISD
JEITA
LFPRelax
DoDWT
FConvEn
ChgDoDEoC = Enable DoD at EoC during charging only. True when set. Default is 1. Default setting is recommended.
SE_TDD = Enable Tab Disconnection Detection. True when set. Default is 1.
VconsEN = Enable voltage consistency check. True when set. Default is 1. Default setting is recommended.
SE_ISD = Enable Internal Short Detection. True when set. Default is 1.
JEITA = Enable JEITA Temperature Charging function. True when set. Default is 1.
LFPRelax = Enable LiFePO4 long RELAX mode when chemical ID 400 series is selected. True when set. Default is 1.
DoDWT = Enable Dod weighting for LiFePO4 support when chemical ID 400 series is selected. True when set. Default is
1.
FConvEn = Enable fast convergence algorithm. Default is 1. Default setting is recommended.
Pack Configuration C Register
Some bq28z560-R1 algorithm settings are configured via the Pack Configuration C data flash register, as
indicated in Table 17. This register is programmed/read via the methods described in ACCESSING THE DATA
FLASH. The register is located at subclass = 64, offset = 3.
Table 17. Pack Configuration C Bit Definition
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
RSVD
RSVDSBS
PIN12F1
PIN12F0
SleepWakeChg
ChgFetTerm
CFET_INIT
DFET_INIT
RSVD = Reserved. Default = 0.
RSVDSBS = Reserved for SBS command set. True when set. Default is 0.
PIN12F1 = In combination with PIN12F0 will set the operation mode of pin 12 (see below).
PIN12F0 = In combination with PIN12F1 will set the operation mode of pin 12 (see below).
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SleepWakeChg = If set to 1 will accumulate the charge as if it was active for 10 s ( instead of 20 s).
ChgFetTerm =
If set, the CHG FET is turned OFF on detecting primary charge termination. The CHG FET is allowed to turn
back ON again when RSOC < TCA Clear %.
CFET_INIT= Sets initial state of CHG FET at reset condition. 0 = CHG FET OFF, 1 = CHG FET ON.
DFET_INIT= Sets initial state of DSG FET at reset condition. 0 = DSG FET OFF, 1 = DSG FET ON.
PIN12F1
PIN12F0
State
0
0
NC or HDQ (default)
0
1
CHG FET
1
0
Bat Alert
1
1
RSVD
Battery Alert Default Configuration Register
When the system is configured as an interrupt indication, the bq28z560-R1 allows settings to be configured
based on which faults are OR'ed for indication on the Alert output Table 18. This register is programmed/read via
the methods described in ACCESSING THE DATA FLASH. The register is located at subclass = 64, offset = 4.
Table 18. Battery Alert Default Configuration Bit Definition
Bit 15
Bit 14
Bit 13
Bit 12
Bit 11
Bit 10
Bit 9
Bit 8
UTC_EN
UTD_EN
RSVD
RSVD
RSVD
RSVD
RSVD
RSVD
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
OTC_EN
OTD_EN
BH_EN
BL_EN
RSVD
SOC1_EN
OCC_EN
OCD_EN
UTC_EN = Allows detection of Under Temperature Charging when set to 1. Default is 0.
UTD_EM = Allows detection of Under Temperature Discharging when set to 1. Default is 0.
RSVD = Reserved. Default = 0.
OTC_EN = Allows detection of Over Temperature Charging when set to 1. Default is 0.
OTD_EN = Allows detection of Over Temperature Discharging when set to 1. Default is 0.
BH_EN = Allows detection of Battery High when set to 1. Default is 0.
BL_EN = Allows detection of Battery Low when set to 1. Default is 0.
RSVD = Reserved. Default = 0.
SOC1_EN Allows detection of SOC low when set to 1. Default is 0.
OCC_EN = Allows detection of Overcurrent in CHARGE mode when set to 1. Default is 0.
OCD_EN = Allows detection of Over Current in Discharge mode when set to 1. Default is 0.
NOTE
Important: The enable flags (Bits 7 to 4) are the reset values. Changing the data flash will
not take effect until the gas gauge is re-started. Read/Write of the BatAlert_Configuration
I2C data controls the runtime alert mask.
MANUFACTURER INFORMATION BLOCKS
The bq28z560-R1 contains 64 bytes of user-programmable data flash storage: Manufacturer Info Block A and
Manufacturer Info Block B. The method for accessing these memory locations is slightly different, depending
on whether the device is in UNSEALED or SEALED modes.
When in UNSEALED mode and when and 0x00 has been written to BlockDataControl(), accessing the
Manufacturer Info Blocks is identical to accessing general data flash locations. First, a DataFlashClass()
command is used to set the subclass, then a DataFlashBlock() command sets the offset for the first data flash
address within the subclass. The BlockData() command codes contain the referenced data flash data. When
writing the data flash, a checksum is expected to be received by BlockDataChecksum(). Only when the
checksum is received and verified is the data actually written to data flash.
38
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As an example, the data flash location for Manufacturer Info Block B is defined as having a Subclass = 58 and
an Offset = 32 through 63 (32 byte block). The specification of Class = System Data is not needed to address
Manufacturer Info Block B, but is used instead for grouping purposes when viewing data flash info in the
bq28z560-R1 evaluation software.
When in SEALED mode or when 0x01 BlockDataControl() does not contain 0x00, data flash is no longer
available in the manner used in UNSEALED mode. Rather than issuing subclass information, a designated
Manufacturer Information Block is selected with the DataFlashBlock() command. Issuing a 0x01, 0x02, or 0x03
with this command causes the corresponding information block (A, B, or C, respectively) to be transferred to the
command space 0x40…0x5F for editing or reading by the system. Upon successful writing of checksum
information to BlockDataChecksum(), the modified block is returned to data flash.
NOTE
Manufacturer Info Block A is read-only when in SEALED mode.
ACCESS MODES
The bq28z560-R1 provides three security modes (FULL ACCESS, UNSEALED, and SEALED) that control data
flash access permissions according to Table 19. Data flash refers to those data flash locations specified in
Table 20, that are accessible to the user. Manufacturer Information refers to the three 32-byte blocks.
Table 19. Data Flash Access
SECURITY MODE
DATA FLASH
MANUFACTURER INFORMATION
FULL ACCESS
R/W
R/W
UNSEALED
R/W
R/W
SEALED
None
R (A); R/W (B,C)
Although FULL ACCESS and UNSEALED modes appear identical, only FULL ACCESS mode allows the
bq28z560-R1 to write access-mode transition keys.
SEALING/UNSEALING DATA FLASH
The bq28z560-R1 implements a key-access scheme to transition between SEALED, UNSEALED, and FULL
ACCESS modes. Each transition requires that a unique set of two keys be sent to the bq28z560-R1 via the
Control() command. The keys must be sent consecutively, with no other data being written to the Control register
in between. Note that to avoid conflict, the keys must be different from the codes presented in the CNTL DATA
column of Table 4 subcommands.
When in SEALED mode, the [SS] bit of CONTROL_STATUS is set; but when the UNSEAL keys are correctly
received by the bq28z560-R1, the [SS] bit is cleared. When the full-access keys are correctly received, the
CONTROL_STATUS [FAS] bit is cleared.
Both Unseal Key and Full-Access Key have two words and are stored in data flash. The first word is Key 0 and
the second word is Key 1. The order of the keys sent to bq28z560-R1 are Key 1 followed by Key 0. The order of
the bytes for each key entered through the Control() command is the reverse of what is read from the part. For
an example, if the Unseal Key is 0x56781234, key 1 is 0x1234 and key 0 is 0x5678. Then Control() should
supply 0x3412 and 0x7856 to unseal the part. The Unseal Key and the Full-Access Key can only be updated
when in FULL ACCESS mode.
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DATA FLASH SUMMARY
Table 20 provides a summary of data flash locations available to the user, including their default, minimum, and
maximum values.
Table 20. Data Flash Summary
Class
Subclass
ID
Subclass
Offset
Configuration
1
Safety Current
0
OC Chg
Configuration
1
Safety Current
2
OC Chg Time
Configuration
1
Safety Current
3
OC Chg Recovery
Name
Min Value
Max Value
Default Value
Units
(EVSW
Units)*
I2
0
20000
6000
mA
U1
0
60
2
s
I2
0
20000
200
mA
mA
Data
Type
Configuration
1
Safety Current
5
OC Dsg
I2
–20000
0
–6000
Configuration
1
Safety Current
7
OC Dsg Time
U1
0
60
2
s
Configuration
1
Safety Current
8
OC Dsg Recovery
I2
–20000
0
–200
mA
Configuration
1
Safety Current
10
Current Recovery Time
U1
0
255
8
s
Configuration
2
Safety Temperature
0
OT Chg
I2
0
1200
550
0.1°C
Configuration
2
Safety Temperature
2
OT Chg Time
U1
0
60
2
s
Configuration
2
Safety Temperature
3
OT Chg Recovery
I2
0
1200
500
0.1°C
Configuration
2
Safety Temperature
5
OT Dsg
I2
0
1200
600
0.1°C
Configuration
2
Safety Temperature
7
OT Dsg Time
U1
0
60
2
s
Configuration
2
Safety Temperature
8
OT Dsg Recovery
I2
0
1200
550
0.1°C
Configuration
2
Safety Temperature
10
UT Chg
I2
-400
1200
0
0.1°C
Configuration
2
Safety Temperature
12
UT Chg Time
U1
0
60
2
s
Configuration
2
Safety Temperature
13
UT Chg Recovery
I2
-400
1200
50
0.1°C
Configuration
2
Safety Temperature
15
UT Dsg
I2
-400
1200
0
0.1°C
Configuration
2
Safety Temperature
17
UT Dsg Time
U1
0
60
2
s
Configuration
2
Safety Temperature
18
UT Dsg Recovery
I2
-400
1200
50
0.1°C
Configuration
32
Charge Inhibit Cfg
0
Chg Inhibit Temp Low
I2
–400
1200
0
0.1°C
Configuration
32
Charge Inhibit Cfg
2
Chg Inhibit Temp High
I2
–400
1200
450
0.1°C
Configuration
32
Charge Inhibit Cfg
4
Temp Hys
I2
0
100
50
0.1°C
Configuration
33
Pre-Charge
0
Pre-Charge Voltage
I2
0
4600
3000
mV
Configuration
33
Pre-Charge
2
Pre-Charge Current
I2
0
32767
150
mA
Configuration
36
Charge Termination
0
Taper Current
I2
0
1000
100
mA
Configuration
36
Charge Termination
2
Min Taper Capacity
I2
0
1000
25
mAh
mV
Configuration
36
Charge Termination
4
Taper Voltage
I2
0
1000
100
Configuration
36
Charge Termination
6
Current Taper Window
U1
0
60
40
s
Configuration
36
Charge Termination
7
TCA Set %
I1
–1
100
99
%
Configuration
36
Charge Termination
8
TCA Clear %
I1
–1
100
95
%
Configuration
36
Charge Termination
9
FC Set %
I1
–1
100
100
%
Configuration
36
Charge Termination
10
FC Clear %
I1
–1
100
98
%
Configuration
36
Charge Termination
11
DODatEOC Delta T
I2
0
1000
100
0.1°C
Configuration
48
Data
0
Rem Cap Alarm
I2
0
700
100
mA
Configuration
48
Data
8
Initial Standby
I1
–256
0
–10
mA
Configuration
48
Data
9
Initial MaxLoad
I2
–32767
0
–500
mA
Configuration
48
Data
17
Cycle Count
U2
0
65535
0
num
mAh
Configuration
48
Data
19
CC Threshold
I2
100
32767
900
Configuration
48
Data
23
Design Capacity
I2
0
32767
1000
mA
Configuration
48
Data
25
Design Energy
I2
0
32767
5400
mWh/cWh
Configuration
48
Data
27
SOH Load I
I2
–32767
0
–400
mA
Configuration
48
Data
29
TDD SOH Percent
I1
0
100
90
%
Configuration
48
Data
30
TA CV T1-T2
U1
0
225
120
10 mV
Configuration
48
Data
31
TA CV T2-T3
U1
0
225
120
10 mV
Configuration
48
Data
32
TA CV T3-T4
U1
0
225
110
10 mV
Configuration
48
Data
33
TA CC T1-T2
U1
0
100
10
%
Configuration
48
Data
34
TA CC T2-T3
U1
0
100
50
%
Configuration
48
Data
35
TA CC T3-T4
U1
0
100
30
%
Configuration
48
Data
36
JEITA T1
I1
–128
127
0
°C
Configuration
48
Data
37
JEITA T2
I1
–128
127
10
°C
40
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Table 20. Data Flash Summary (continued)
Class
Subclass
ID
Subclass
Offset
Name
Data
Type
Min Value
Max Value
Default Value
Units
(EVSW
Units)*
Configuration
48
Data
38
JEITA T3
I1
–128
127
45
°C
Configuration
48
Data
39
JEITA T4
I1
–128
127
55
°C
Configuration
48
Data
40
ISD Current
I2
0
32767
10
HourRate
Configuration
48
Data
42
ISD I Filter
U1
0
255
127
num
Configuration
48
Data
43
Min ISD Time
U1
0
255
7
Hour
Configuration
48
Data
44
Design Energy Scale
U1
0
255
1
num
Configuration
48
Data
45
Device Name
S21
x
x
bq28z560-R1
—
Configuration
49
Discharge
0
SOC1 Set Threshold
U2
0
65535
150
mAh
Configuration
49
Discharge
2
SOC1 Clear Threshold
U2
0
65535
175
mAh
Configuration
49
Discharge
4
SOCF Set Threshold
U2
0
65535
75
mAh
Configuration
49
Discharge
6
SOCF Clear Threshold
U2
0
65535
100
mAh
Configuration
49
Discharge
9
BL Set Volt Threshold
I2
0
16800
0
mV
Configuration
49
Discharge
11
BL Set Volt Time
U1
0
60
0
s
Configuration
49
Discharge
12
BL Clear Volt Threshold
I2
0000
16800
5
mV
Configuration
49
Discharge
14
BH Set Volt Threshold
I2
0
16800
4300
mV
Configuration
49
Discharge
16
BH Volt Time
U1
0
60
2
s
Configuration
49
Discharge
17
BH Clear Volt Threshold
I2
0000
16800
5
mV
Configuration
56
Manufacturer Data
0
Pack Lot Code
H2
0x0
0xffff
0x0
—
Configuration
56
Manufacturer Data
2
PCB Lot Code
H2
0x0
0xffff
0x0
—
Configuration
56
Manufacturer Data
4
Firmware Version
H2
0x0
0xffff
0x0
—
Configuration
56
Manufacturer Data
6
Hardware Revision
H2
0x0
0xffff
0x0
—
Configuration
56
Manufacturer Data
8
Cell Revision
H2
0x0
0xffff
0x0
—
Configuration
56
Manufacturer Data
10
DF Config Version
H2
0x0
0xffff
0x0
—
Configuration
57
Integrity Data
6
Static Chem DF Checksum
H2
0x0
0x7fff
0x0
—
System Data
58
Manufacturer Info
0–31
Block A [0–31]
H1
0x0
ff
0
—
System Data
58
Manufacturer Info
32–63
Block B [0–31]
H1
0x0
ff
0
—
Configuration
59
Lifetime Data
0
Lifetime Max Temp
I2
0
1400
300
0.1°C
Configuration
59
Lifetime Data
2
Lifetime Min Temp
I2
–600
1400
200
0.1°C
Configuration
59
Lifetime Data
4
Lifetime Max Pack Voltage
I2
0
32767
3200
mV
Configuration
59
Lifetime Data
6
Lifetime Min Pack Voltage
I2
0
32767
3500
mV
Configuration
59
Lifetime Data
8
Lifetime Max Chg Current
I2
–32767
32767
0
mA
Configuration
59
Lifetime Data
10
Lifetime Max Dsg Current
I2
–32767
32767
0
mA
Configuration
60
Lifetime Temp Samples
0
LT Flash Cnt
U2
0
65535
0
—
Configuration
64
Registers
0
Pack Configuration
H2
0x0
0xffff
0x0177
—
Configuration
64
Registers
2
Pack Configuration B
H1
0x0
0xff
0x1f
—
Configuration
64
Registers
3
Pack Configuration C
H1
0x0
0xff
0x0
—
Configuration
64
Registers
4
Battery Alert Default Configuration
H2
0x0
0xffff
c0c4
—
Configuration
66
Lifetime Resolution
0
LT Temp Res
U1
0
255
10
Num
Configuration
66
Lifetime Resolution
1
LT V Res
U1
0
255
25
Num
Configuration
66
Lifetime Resolution
2
LT Cur Res
U1
0
255
100
Num
Configuration
66
Lifetime Resolution
3
LT Update Time
U2
0
65535
60
Num
Configuration
68
Power
0
Flash Update OK Voltage
I2
0
4200
2800
mV
Configuration
68
Power
2
Sleep Current
I2
0
100
10
mA
Configuration
68
Power
11
Hibernate I
U2
0
700
8
mA
Configuration
68
Power
13
Hibernate V
U2
2400
3000
2550
mV
Configuration
68
Power
15
FS Wait
U1
0
255
0
s
Gas Gauging
80
IT Cfg
0
Load Select
U1
0
255
1
—
Gas Gauging
80
IT Cfg
1
Load Mode
U1
0
255
0
—
Gas Gauging
80
IT Cfg
21
Max Res Factor
U1
0
255
15
num
Gas Gauging
80
IT Cfg
22
Min Res Factor
U1
0
255
3
num
Gas Gauging
80
IT Cfg
25
Ra Filter
U2
0
1000
500
num
Gas Gauging
80
IT Cfg
67
Terminate Voltage
I2
2800
3700
3000
mV
Gas Gauging
80
IT Cfg
69
Term V Delta
I2
0
4200
200
mV
Gas Gauging
80
IT Cfg
72
ResRelax Time
U2
0
65534
200
s
Gas Gauging
80
IT Cfg
76
User Rate-mA
I2
2000
9000
0
mA
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Table 20. Data Flash Summary (continued)
Name
Data
Type
Min Value
Max Value
Default Value
Units
(EVSW
Units)*
78
User Rate-Pwr
I2
3000
14000
0
mW/cW
80
Reserve Cap-mAh
I2
0
9000
0
mA
IT Cfg
82
Reserve Energy
I2
0
14000
0
mWh/cWh
80
IT Cfg
86
Max Scale Back Grid
U1
0
15
4
—
80
IT Cfg
87
Max DeltaV
U2
0
65535
200
mV
Gas Gauging
80
IT Cfg
89
Min DeltaV
U2
0
65535
0
mV
Gas Gauging
80
IT Cfg
91
Max Sim Rate
U1
0
255
2
C/rate
Gas Gauging
80
IT Cfg
92
Min Sim Rate
U1
0
255
20
C/rate
Gas Gauging
80
IT Cfg
93
Ra Max Delta
U2
0
65535
44
mΩ
Gas Gauging
80
IT Cfg
95
Qmax Max Delta %
U1
0
100
5
mAh
mV
Class
Subclass
ID
Subclass
Offset
Gas Gauging
80
IT Cfg
Gas Gauging
80
IT Cfg
Gas Gauging
80
Gas Gauging
Gas Gauging
Gas Gauging
80
IT Cfg
96
DeltaV Max Delta
U2
0
65535
10
Gas Gauging
80
IT Cfg
102
Fast Scale Start SOC
U1
0
100
10
%
Gas Gauging
80
IT Cfg
103
Charge Hys Voltage Shift
I2
0
2000
40
mV
Gas Gauging
81
Current Thresholds
0
Dsg Current Threshold
I2
0
2000
60
mA
Gas Gauging
81
Current Thresholds
2
Chg Current Threshold
I2
0
2000
75
mA
Gas Gauging
81
Current Thresholds
4
Quit Current
I2
0
1000
40
mA
Gas Gauging
81
Current Thresholds
6
Dsg Relax Time
U2
0
8191
60
s
Gas Gauging
81
Current Thresholds
8
Chg Relax Time
U1
0
255
60
s
Gas Gauging
81
Current Thresholds
9
Quit Relax Time
U1
0
63
1
s
Gas Gauging
81
Current Thresholds
10
Max IR Correct
U2
0
1000
400
mV
Gas Gauging
82
State
0
Qmax Cell 0
I2
0
32767
1000
mAh
Gas Gauging
82
State
2
Cycle Count
U2
0
65535
0
num
Gas Gauging
82
State
4
Update Status
H1
0x0
0x6
0x0
—
Gas Gauging
82
State
5
V at Chg Term
I2
0
5000
4200
mV
Gas Gauging
82
State
7
Avg I Last Run
I2
–32768
32767
–299
mA
Gas Gauging
82
State
9
Avg P Last Run
I2
–32768
32767
–1131
mA
Gas Gauging
82
State
11
Delta Voltage
I2
–32768
32767
2
mV
Gas Gauging
82
State
15
T Rise
I2
0
32767
0
Num
Gas Gauging
82
State
17
T Time Constant
I2
0
32767
32767
Num
OCV Table
83
OCVa Table
0
Chem ID
H2
0x0
0xffff
0x0107
—
Ra Table
88
R_a0
0
Cell0 R_a flag
H2
0x0
0x0
0xff55
—
2–10Ω
42
Ra Table
88
R_a0
2–30
Cell0 R_a 0–14
I2
183
183
105
Ra Table
89
R_a0x
0
xCell0 R_a flag
H2
0xffff
0xffff
0xffff
—
Ra Table
89
R_a0x
2–30
xCell0 R_a 0–14
I2
183
183
105
2–10Ω
Calibration
104
Data
0
CC Gain
F4
1.0e–1
4.0e+1
0.4768
num
Calibration
104
Data
4
CC Delta
F4
2.9826e+4
1.193046e+
6
5677445.6
num
Calibration
104
Data
8
CC Offset
I2
–32768
32767
–1200
num
Calibration
104
Data
10
Board Offset
I1
–128
127
0
num
Calibration
104
Data
11
Int Temp Offset
I1
–128
127
0
num
Calibration
104
Data
12
Ext Temp Offset
I1
–128
127
0
num
Calibration
104
Data
13
Pack V Offset
I1
–128
127
0
mV
Calibration
107
Current
1
Deadband
U1
0
255
5
mA
Security
112
Codes
0
Sealed to Unsealed
H4
0x0
0xffffffff
0x36720414
—
Security
112
Codes
4
Unsealed to Full
H4
0x0
0xffffffff
0xffffffff
—
Security
112
Codes
8
Authen Key3
H4
0x0
0xffffffff
0x01234567
—
Security
112
Codes
12
Authen Key2
H4
0x0
0xffffffff
0x89abcdef
—
Security
112
Codes
16
Authen Key1
H4
0x0
0xffffffff
0xfedcba98
—
Security
112
Codes
20
Authen Key0
H4
0x0
0xffffffff
0x76543210
—
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CHARGING AND CHARGE TERMINATION INDICATION
Detection Charge Termination
For proper bq28z560-R1 operation, the cell charging voltage must be specified by the user. The default value for
this variable is in the data flash Charging Voltage.
The bq28z560-R1 detects charge termination when:
The battery current drops below the Taper Current for two consecutive Current Taper Window time periods
during charging AND battery voltage is equal to or higher than the Charging Voltage – Taper Voltage. Full
Charge is set when the taper condition is met.
Charge Inhibit
The bq28z560-R1 can indicate when battery temperature has fallen below or risen above predefined thresholds
Charge Inhibit Temp Low or Charge Inhibit Temp High. In this mode, the CHG_FET bit is set in the Control
register to indicate this condition, and is returned to its low state once battery temperature returns to the range
[Charge Inhibit Temp Low + Temp Hys, Charge Inhibit Temp High – Temp Hys]. This is implemented to
indicate that an action is required by the battery charger.
The charging should not start when the temperature is below the Charge Inhibit Temp Low or above the
Charge Inhibit Temp High.
The charge FET should not turn off when Temp > Chg Inhibit Temp during charging .
The gas gauge will enter CHARGE INHIBIT mode only if it is in DISCHARGE mode or RELAX mode and Temp >
Chg Inhibit Low. Then it will set the Charging Current and Charging Voltage values to 0.
POWER MODES
The bq28z560-R1 has four power modes: NORMAL, SLEEP, HIBERNATE, and SHUTDOWN. In NORMAL
mode, the bq28z560-R1 is fully powered and can execute any allowable task. In SLEEP mode, the gas gauge
exists in a reduced-power state, periodically taking measurements and performing calculations. In HIBERNATE
mode, the gas gauge is in a low power state, but can be awakened by communication or certain I/O activity. The
device enters SHUTDOWN mode if there is a BATLOW condition detected or power down of the system.
Figure 7 shows the relationship between these modes. The sections that follow describe the details.
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POR
NORMAL
Fuel gauging and data
updated every 1 s
Exit From HIBERNATE
VBAT < POR threshold
Exit From HIBERNATE
Communication Activity
OR
Entry to SLEEP
the gas gauge clears Control Status
Pack Configuration[ SLEEP] = 1
[ HIBERNATE ] = 0
AND
Recommend Host also set Control
| AverageCurrent( ) | =Sleep Current
Status [HIBERNATE] = 0
Exit From SLEEP
Pack Configuration [SLEEP ] =0
OR
| AverageCurrent( ) | > Sleep Current
OR
Exit from SHUTDOWN
Charger Detected
AND
Protection FETs closed
Current is Detected above I WAKE
HIBERNATE
SLEEP
SHUTDOWN
Fuel gauging and data
updated every 20 seconds
Disable all gas gauge
subcircuits except GPIO
Exit from PRE - SHUTDOWN
Wakeup From HIBERNATE
Communication Activity
AND
Comm address is NOT for the gas gauge
Entry to WAITFULLSLEEP
Full Sleep Wait Time > 0
Exit From WAITFULLSLEEP
Any Communication Cmd
Fuel Gauge is OFF
VBAT = 0 V
Communication Activity
OR
Current Detected > I
WAKE
Entry to SHUTDOWN
Exit From WAIT _ HIBERNATE
Cell relaxed
AND
V
BAT < Hibernate Voltage
No Charger Present
WAITFULLSLEEP
Cell relaxed
AND
| AverageCurrent () | < Hibernate
Current
OR
FULLSLEEP Count Down
Exit From WAIT HIBERNATE
_
Host must set Control Status
[ HIBERNATE ] = 0
Entry to FULLSLEEP
AND
Host must set Control Status
V
BAT > Hibernate Voltage
[FULLSLEEP] = 1
WAIT_HIBERNATE
Entry to FULLSLEEP
Count < 1
Exit From FULLSLEEP
Any Communication Cmd
PRE - SHUTDOWN
FULLSLEEP
Fuel gauging and data
updated every 20 s
System HIBERNATION
Entry to PRE-SHUTDOWN
Exit From SLEEP
(Host has set Control Status
[HIBERNATE ] = 1
OR
V
< Hibernate Voltage
In low-power state of SLEEP
mode. Gas gauging and data
are updated every 20 s.
[SHUTDOWN ] = 1
Fuel Gauging stopped
Discharge FET opened
IBAT = Hibernate
System SHUTDOWN
BAT
System SLEEP
Figure 7. Power Mode Diagram
NORMAL MODE
The gas gauge is in NORMAL mode when not in any other power mode. During this mode, AverageCurrent(),
Voltage(), and Temperature() measurements are taken, and the interface data set is updated. Decisions to
change states are also made. This mode is exited by activating a different power mode.
Because the gauge consumes the most power in NORMAL mode, the algorithm minimizes the time the gas
gauge remains in this mode.
NOTE
When the battery is connected for the first time, discharging may not be enabled. For this
case, one of the following procedures is required:
Short the VM pin to the VSS pin or connect the charger such that the IC returns to normal
status.
SLEEP MODE
SLEEP mode is entered automatically if the feature is enabled (Pack Configuration [SLEEP]) = 1) and
AverageCurrent() is below the programmable level Sleep Current. Once entry into SLEEP mode has been
qualified, but prior to entering it, the bq28z560-R1 performs an ADC auto-calibration to minimize offset.
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While in SLEEP mode, the gas gauge can suspend serial communications as much as 4 ms by holding the
comm line(s) low. This delay is necessary to correctly process host communication, since the gas gauge
processor is mostly halted in SLEEP mode.
During the SLEEP mode, bq28z560-R1 periodically takes data measurements and updates its data set.
However, a majority of its time is spent in an idle condition. The bq28z560-R1 exits SLEEP if any entry condition
is broken, specifically when (1) AverageCurrent() rises above Sleep Current, or (2) a current in excess of IWAKE
through RSENSE is detected.
FULLSLEEP MODE
FULLSLEEP mode is entered automatically if the feature is enabled by setting the Configuration [FULLSLEEP]
bit in the Control Status register when the bq28z560-R1 is in SLEEP mode. The gauge exits the FULLSLEEP
mode when there is any communication activity. Therefore, the execution of SET_FULLSLEEP sets the
[FULLSLEEP] bit, but EVSW might still display the bit clear. FULLSLEEP mode can be verified by measuring the
current consumption of the gauge. In this mode, the high frequency oscillator is turned off. The power
consumption is further reduced in this mode compared to SLEEP mode.
FULLSLEEP mode can also be entered by setting the Full Sleep Wait Time to be a number larger than 0.
FULLSLEEP will be entered when the timer counts down to 0. This feature is disabled when the data flash is set
as 0.
During FULLSLEEP mode, the bq28z560-R1 periodically takes data measurements and updates its data set.
However, a majority of its time is spent in an idle condition.
The bq28z560-R1 exits SLEEP if any entry condition is broken, specifically when (1) AverageCurrent() rises
above Sleep Current, or (2) a current in excess of IWAKE through RSENSE is detected.
While in FULLSLEEP mode, the gas gauge can suspend serial communications as much as 4 ms by holding the
comm line(s) low. This delay is necessary to correctly process host communication, since the gas gauge
processor is mostly halted in SLEEP mode.
Clearing FULLSLEEP Mode
FULLSLEEP mode will stay on permanently if Full Sleep Wait Time is not set to 0.
Clearing FULLSLEEP mode:
• If Full Sleep Wait Time is set to 0, the CLEAR condition clears the flag. If it is not set to 0, the CLEAR
condition resets the timer.
• The CLEAR condition determines that there is I2C communication while FULLSLEEP is active. I2C
communication while not in FULLSLEEP will NOT clear the flag. This means if there is current flowing when
the FULLSLEEP command is sent, there is no way to clear it until after the device enters SLEEP mode.
HIBERNATE MODE
HIBERNATE mode should be used when the host system needs to enter a low-power state, and minimal gauge
power consumption is required. This mode is ideal when the host is set to its own HIBERNATE, SHUTDOWN, or
OFF modes. The gas gauge can enter HIBERNATE due to either low cell voltage or low load current.
• HIBERNATE due to the load current—If the gas gauge enters the HIBERNATE mode due to the load current,
the [HIBERNATE] bit of the CONTROL_STATUS register must be set. The gauge waits to enter HIBERNATE
mode until it has taken a valid OCV measurement and the magnitude of the average cell current has fallen
below Hibernate Current.
• HIBERNATE due to the cell voltage—When the cell voltage drops below the Hibernate Voltage and a valid
OCV measurement has been taken, the gas gauge enters HIBERNATE mode. The [HIBERNATE] bit of the
CONTROL register has no impact for the gas gauge to enter the HIBERNATE mode. If the [SHUTDOWN] bit
of CONTROL _STATUS is also set.
The gauge will remain in HIBERNATE mode until communication activity appears on the communication lines.
Upon exiting HIBERNATE mode, the [HIBERNATE] bit of CONTROL_STATUS is cleared.
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Because the gas gauge is dormant in HIBERNATE mode, the battery should not be charged or discharged in this
mode, because any changes in battery charge status will not be measured. If necessary, the host equipment can
draw a small current (generally infrequent and less than 1 mA, for purposes of low-level monitoring and
updating); however, the corresponding charge drawn from the battery will not be logged by the gauge. Once the
gauge exits to NORMAL mode, the algorithm re-establishes the correct battery capacity.
If a charger is attached, the host should immediately take the gas gauge out of HIBERNATE mode before
beginning to charge the battery.
CAUTION
Charging the battery in HIBERNATE mode results in a notable gauging error that will
take several hours to correct. In the HDQ bus communication interface, the bus line,
when in HIBERNATE mode, must always be pulled high with an external resistor, and
not allowed to go low in this mode. If the bus line is pulled low, the system may need
to go through a full reset by the battery pack being removed and re-inserted. This may
be an issue for systems with embedded battery packs. Alternatively, disable
HIBERNATE mode by setting the CLEAR HIBERNATE bit to 0. Another option is to set
Hibernate I,V settings to 0 in DF commands.
SHUTDOWN MODE
The device enters SHUTDOWN mode if there is a BATLOW condition detected or power down of the system.
The device can also disable SHUTDOWN by using the CLEAR_SHUTDOWN (0x0014) option.
•
•
•
NOTE
A SHUTDOWN command should NOT be invoked if charger voltage is present.
Sending a SHUTDOWN command while charger voltage is present causes a 1–2 s
time of DSG FET off, and may or may not cause a watchdog reset. (If current is ≤ 0
after the DSG FET is opened, it will attempt to shutdown and start a watchdog;
otherwise, it will only clear the shutdown flag without a reset.)
The recommendation is to NOT send a SHUTDOWN command if charger voltage is
present.
Figure 8 shows an overview of the hardware controlled SHUTDOWN operation.
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Shutdown
CHG: OFF
DSG: OFF
VREG: OFF
No Charger
Charger attached
Over - Discharge
Voltage
CHG: ON
DSG: OFF
VREG OFF
VBAT < 2.3 V
for a period
of t > 24 ms
VBAT > 2.3 V
for a period
of t > 4.0 ms
Normal
CHG: ON
DSG: ON
VREG: ON
VBAT< 2.3 V
for a period
of t > 24 ms
FG shutdown
FG turn
on DSG
FG turn
off DSG
DSG "OFF”
CHG: ON
DSG: OFF
VREG: ON
Figure 8. Shutdown Operation
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OPERATIONAL MODES
POWER CONTROL
Reset Functions
When the bq28z560-R1 detects a software reset ([RESET] bit of Control() initiated), it determines the type of
reset and increments the corresponding counter. This information is accessible by issuing the command Control()
function with the RESET_DATA subcommand.
Wake-Up Comparator
The wake up comparator is used to indicate a change in cell current while the bq28z560-R1 is in SLEEP mode.
Pack Configuration uses bits [RSNS1–RSNS0] to set the sense resistor selection. Pack Configuration also uses
the [IWAKE] bit to select one of two possible voltage threshold ranges for the given sense resistor selection. An
internal interrupt is generated when the threshold is breached in either charge or discharge directions. Setting
both [RSNS1] and [RSN0] to 0 disables this feature.
Table 21. IWAKE Threshold Settings (1)
(1)
RSNS1
RSNS0
IWAKE
Vth (SRP–SRN)
0
0
0
Disabled
0
0
1
Disabled
0
1
0
+1.0 mV or –1.0 mV
0
1
1
+2.2 mV or –2.2 mV
1
0
0
+2.2 mV or –2.2 mV
1
0
1
+4.6 mV or –4.6 mV
1
1
0
+4.6 mV or –4.6 mV
1
1
1
+9.8 mV or –9.8 mV
The actual resistance value vs. the setting of the sense resistor is not important, only the actual voltage threshold when calculating the
Configuration. The voltage thresholds are typical values under room temperature.
Flash Updates
Data flash can only be updated if Voltage() > Flash Update OK Voltage. Flash programming current can cause
an increase in the LDO dropout.
The mode of going from one state to another is as follows: NORMAL → SLEEP → FULLSLEEP, then from
FULLSLEEP to either HIBERNATE or SHUTDOWN.
Mode
Exit Mode
Comment
NORMAL
If ALL conditions are satisfied like
Average Current, Cell Voltage, and
Temperature.
Go into other modes like SLEEP,
FULLSLEEP, HIBERNATE, or
SHUTDOWN if conditions are
satisfied.
SLEEP
SLEEP bit set = 1 in the Control
register AND AverageCurrent
measured is equal to Sleep current
value.
Change SLEEP bit = 0 OR
AverageCurrent measurement > Sleep The data is measured every 20 s to
current value OR Current detected is
reduce current consumption.
above the IWAKE setting.
From SLEEP mode if the
WAIT_FULLSLEEP wait is
programmed, this is the time the
system must be in SLEEP mode
before it can go to FULLSLEEP
mode.
The system exits the FULLSLEEP
mode if there are any communication
commands set on the bus to the
device.
FULLSLEEP
48
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In this mode, power consumption is
the highest. Measurements are taken
and updated every 1 s.
The wait time to enter FULLSLEEP
from SLEEP is 1 s to 240 s with the
default at 15 s.
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Mode
Enter Mode
Exit Mode
Comment
HIBERNATE
From FULLSLEEP mode, the
system will go into HIBERNATE
mode if the load current decreases
to programmed value,
OR if the cell voltage falls below the
programmed value,
OR if the host sets the command in
MAC.
The system exits this mode if the VBAT
> programmed threshold,
OR load current is > programmed
threshold,
OR communication activity is on the
bus line,
OR the host sets the command in
MAC.
Enters hibernation if VBAT range is
2.4 V to 3 V with a default at 2.55 V.
The load current threshold range is 0
to 0.7 A with a default value of 8 mA.
SHUTDOWN
From SLEEP mode, the system will
enter this mode if the VBAT < 2.4 V
for a period longer than 24 ms and
the charger is not attached. The
system can also be put in
SHUTDOWN mode through MAC.
Exit from this mode if there is bus
activity,
OR the load current detected is >
IWAKE,
OR the charger is connected to the
system.
In this mode, the VREG and DSG
FET are turned OFF and the system
will only wake up if the charger is
attached on the Pack+, Pack–
terminals.
AUTOCALIBRATION
The bq28z560-R1 provides an auto calibration feature that measures the voltage offset error across SRP and
SRN from time-to-time as operating conditions change. It subtracts the resulting offset error from the normal
sense resistor voltage, VSR, for maximum measurement accuracy.
Auto calibration of the ADC begins on entry to SLEEP mode, except if Temperature() is ≤ 5°C or Temperature() ≥
45°C.
The gas gauge also performs a single offset when (1) the condition of AverageCurrent() ≤ 100 mA and (2) {cell
voltage change since last offset calibration ≥ 256 mV} or {temperature change since last offset calibration is
greater than 80°C for ≥ 60 s}.
Capacity and current measurements continue at the last measured rate during the offset calibration when these
measurements cannot be performed. If the battery voltage drops more than 32 mV during the offset calibration,
the load current has likely increased considerably and the offset calibration will be aborted.
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COMMUNICATIONS
AUTHENTICATION
The bq28z560-R1 can act as a SHA-1/HMAC authentication slave by using its internal engine. Refer to the Using
SHA-1 in bq20zxx Family of Gas Gauges Application Note (SLUA359) for SHA-1/HMAC information.
By sending a 160-bit SHA-1 challenge message to the bq28z560-R1, it causes the gauge to return a 160-bit
digest, based upon the challenge message and a hidden, 128-bit plain-text authentication key. If this digest
matches an identical one generated by a host or dedicated authentication master, and when operating on the
same challenge message and using the same plain text keys, the authentication process is successful.
KEY PROGRAMMING (DATA FLASH KEY)
By
default,
the
bq28z560-R1
contains
a
plain-text
authentication
key
of 0x0123456789ABCDEFFEDCBA9876543210. This default key is intended for development purposes. It
should be changed to a secret key and the part immediately sealed before putting a pack into operation. Once
written, a new plain-text key cannot be read again from the gas gauge while in SEALED mode.
Once the bq28z560-R1 is UNSEALED, the authentication key can be changed from its default value by writing to
the Authenticate() Extended Data Command locations. A 0x00 is written to BlockDataControl() to enable the
authentication data commands. The DataFlashClass() is issued 112 (0x70) to set the Security class. Up to 32
bytes of data can be read directly from the BlockData() (0x40...0x5F) and the authentication key is located at
0x48 (0x40 + 0x08 offset) to 0x57 (0x40 + 0x17 offset). The new authentication key can be written to the
corresponding locations (0x48 to 0x57) using the BlockData() command. The data is transferred to the data flash
when the correct checksum for the whole block (0x40 to 0x5F) is written to BlockDataChecksum() (0x60). The
checksum is (255 – x) where x is the 8-bit summation of the BlockData() (0x40 to 0x5F) on a byte-by-byte basis.
Once the authentication key is written, the gauge can then be SEALED again.
KEY PROGRAMMING (THE SECURE MEMORY KEY)
As the name suggests, the bq28z560-R1 secure-memory authentication key is stored in the secure memory of
the bq28z560-R1. If a secure-memory key has been established and the Data Flash Key is
0x00000000000000000000000000000000, only this key can be used for authentication challenges (the
programmable data flash key is not available). The selected key can only be established/programmed by special
arrangements with TI, using TI’s Secure B-to-B Protocol. The secure-memory key can never be changed or read
from the bq28z560-R1.
EXECUTING AN AUTHENTICATION QUERY
To execute an authentication query in UNSEALED mode, a host must first write 0x01 to the BlockDataControl()
command to enable the authentication data commands. If in SEALED mode, 0x00 must be written to
DataFlashBlock(), instead.
Next, the host writes a 20-byte authentication challenge to the Authenticate() address locations (0x40 through
0x53). After a valid checksum for the challenge is written to AuthenticateChecksum(), the bq28z560-R1 uses the
challenge to perform the SHA-1/HMAC computation in conjunction with the programmed key. The resulting
digest is written to AuthenticateData(), overwriting the pre-existing challenge. The host may then read this
response and compare it against the result created by its own parallel computation.
HDQ SINGLE-PIN SERIAL INTERFACE
The HDQ interface is an asynchronous return-to-one protocol where a processor sends the command code to
the bq28z560-R1. With HDQ, the least significant bit (LSB) of a data byte (command) or word (data) is
transmitted first. Note that the DATA signal on pin 12 is open-drain and requires an external pull-up resistor. The
8-bit command code consists of two fields: the 7-bit HDQ command code (bits 0–6) and the 1-bit R/W field (MSB
bit 7). The R/W field directs the bq28z560-R1 to do either of the following two actions:
• Store the next 8 or 16 bits of data to a specified register or,
• Output 8 bits of data from the specified register.
The HDQ peripheral can transmit and receive data as either an HDQ master or slave.
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HDQ serial communication is normally initiated by the host processor sending a break command to the
bq28z560-R1. A break is detected when the DATA pin is driven to a logic-low state for a time t(B) or greater. The
DATA pin should then be returned to its normal ready high logic state for a time t(BR). The bq28z560-R1 is now
ready to receive information from the host processor.
The bq28z560-R1 is shipped in the I2C mode. TI provides tools to enable the HDQ peripheral.
HDQ HOST INTERRUPTION FEATURE
The default bq28z560-R1 behaves as an HDQ slave only device. If the HDQ interrupt function is enabled, the
bq28z560-R1 is capable of mastering and also communicating to a HDQ device. There is no mechanism for
negotiating who is to function as the HDQ master and care must be taken to avoid message collisions. The
interrupt is signaled to the host processor with the bq28z560-R1 mastering an HDQ "message." This message is
a fixed message that will be used to signal the interrupt condition. The message itself is 0x80 (slave write to
register 0x00) with no data byte being sent as the command is not intended to convey any status of the interrupt
condition. The HDQ interrupt function is not public and needs to be enabled by command.
When the SET_HDQINTEN subcommand is received, the bq28z560-R1 will detect any of the interrupt conditions
and assert the interrupt at 1-s intervals until the CLEAR_HDQINTEN command is received or the count of
HDQHostIntrTries has lapsed.
The number of tries for interrupting the host will be determined by the data flash parameter named
Configuration.Register.HDQHostIntrTries.
The HDQ host interrupt is triggered by the settings in the bat alert feature. The HDQ host interrupt signal will be
asserted when the Flags()[ALRT] bit is triggered, based on the settings in the BatAlertConfig() register.
I2C INTERFACE
The gas gauge supports the standard I2C read, incremental read, 1-byte write quick read, and functions. The 7bit device address (ADDR) is the most significant 7 bits of the hex address and is fixed as 1010101. The 8-bit
device address is therefore 0xAA or 0xAB for write or read, respectively.
Host Generated
S
0 A
ADDR[6:0]
Fuel Gauge Generated
A
CMD[7:0]
A P
DATA[7:0]
S
A
1
ADDR[6:0]
(a)
S
ADDR[6:0]
0 A
DATA[7:0]
N P
(b)
CMD[7:0]
A Sr
1
ADDR[6:0]
A
DATA[7:0]
N P
...
DATA[7:0]
(c)
S
ADDR[6:0]
0 A
CMD[7:0]
A Sr
ADDR[6:0]
1
A
DATA[7:0]
A
N P
(d)
Figure 9. Supported I2C formats: (a) 1-byte write, (b) quick read, ©) 1 byte-read, and (d) incremental read
(S = Start, Sr = Repeated Start, A = Acknowledge, N = No Acknowledge, and P = Stop).
The "quick read" returns data at the address indicated by the address pointer. The address pointer, a register
internal to the I2C communication engine, increments whenever data is acknowledged by the bq28z560-R1 or
the I2C master. "Quick writes" function in the same manner and are a convenient means of sending multiple
bytes to consecutive command locations (such as 2-byte commands that require two bytes of data).
Attempt to write a read-only address (NACK after data sent by master):
S
ADDR[6:0]
0
A
A
CMD[7:0]
A
DATA[7:0]
P
Attempt to read an address above 0x7F (NACK command):
S
0
ADDR[6:0]
A
CMD[7:0]
N P
Attempt at incremental writes (NACK all extra data bytes sent):
S
ADDR[6:0]
0 A
CMD[7:0]
A
DATA[7:0]
A
DATA[7:0]
N
...
N P
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Incremental read at the maximum allowed read address:
S
ADDR[6:0]
0 A
A Sr
CMD[7:0]
1
ADDR[6:0]
A
A
DATA[7:0]
Address
0x7F
...
N P
DATA[7:0]
Data From
addr 0x7F
Data From
addr 0x00
The I2C engine releases both SDA and SCL if the I2C bus is held low for t(BUSERR). If the gas gauge was holding
the lines, releasing them frees the master to drive the lines. If an external condition is holding either of the lines
low, the I2C engine enters the low-power SLEEP mode.
I2C Timeout
The I2C engine will release both SDA and SCL if the I2C bus is held low for about 2 s. If the bq28z560-R1 was
holding the lines, releasing them will free the master to drive the lines.
I2C Command Waiting Time
To ensure getting the correct results of a command with the 400 KHz I2C operation, a proper waiting time should
be added between issuing the command and reading results. For subcommands, the following diagram shows
the waiting time required between issuing the control command and reading the status with the exception of the
checksum command. A 100-ms waiting time is required between the checksum command and reading result. For
read-write standard commands, a minimum of 2 s is required to get the result updated. For read-only standard
commands, there is no waiting time required, but the host should not issue all standard commands more than
two times per second. Otherwise, the gauge could result in a reset issue due to the expiration of the watchdog
timer.
S
ADDR[6:0]
0 A
CMD[7:0]
A
DATA [7:0]
S
ADDR[6:0]
0 A
CMD[7:0]
A Sr
ADDR[6:0]
A
1 A
DATA [7:0]
A P
DATA [7:0]
66ms
A
DATA [7:0]
N P
A
DATA [7:0]
A
66ms
Waiting time between control subcommand and reading results
S
ADDR[6:0]
DATA [7:0]
0 A
A
CMD[7:0]
DATA [7:0]
A Sr
N P
ADDR[6:0]
1 A
DATA [7:0]
66ms
Waiting time between continuous reading results
The I2C clock stretch could happen in a typical application. A maximum 80-ms clock stretch could be observed
during the flash updates. There can be up to a 270-ms clock stretch after the OCV command is issued.
52
Submit Documentation Feedback
Copyright © 2013, Texas Instruments Incorporated
Product Folder Links: bq28z560-R1
TP2
TB1
3
2
1
R1
0.005
R2
R3
100
100
0.1uF
C2
0.1uF
C1
R4
5M
CSD16340Q3
Q1
Copyright © 2013, Texas Instruments Incorporated
Product Folder Links: bq28z560-R1
R13
1K
WAKE
0.1uF
S1
C4
CSD16340Q3
C3
0.1uF
R5
5M
0.1uF
C5
TP5 COUT
TP7 DOUT
R6
510
TP6
VM
1uF
C6
U1
0.47uF
6 VSS
5 VREG
4 BAT
3 VM
2 COUT
1 DOUT
10
11
SRP
TR-BC847BPDXV6T1
Q3-B
7
SRN 8
TS 9
SDA
SCL
HDQ 12
BQ28z560-R1DRZ
PWPD
TP1
CELL–
CELL–
CELL+
CELL+
C7
RT1
10K
J6
J5
J2
TR-BC847BPDXV6T1
Q3-A
R16
5.1k
R15
12k
VREG
0.1uF
C8
2
1
2
R17
100k
2
1
1
R7
3.3K
2
R8
3.3K
2
J4
1
J3
1
R9 100
R14
3.3K
EARTH_GND
HDQ
D2
GND SIDE
GND SIDE
J1
GND
SCL
SDA
J7
GND SIDE
GND
HDQ
HDQ
J8
VBUS
D–
7
USB mini-AB
ID
5
GND
D+
4
3
2
1
6
EARTH_GND
1
2
3
4
1
2
3
4
EARTH_GND
EARTH_GND
100 R12 100
MM3Z5V6C
D1
R11
D3
R18 100
MM3Z5V6C
R10 100
R19 100
GND SIDE
CASE
CASE
VREG
TP8
PACK–/LOAD–
PACK+/LOAD+
TP3
PACK–
3
2
1
TP4
PACK+
TB2
Not Recommended For New Designs
bq28z560-R1
www.ti.com
SLUSBD3 – APRIL 2013
REFERENCE SCHEMATIC
13
Q2
Note: R4 and R5 must be greater than 3 MΩ.
Q3A, Q3B, R15 to R17 are required if configured
for CFET control.
Submit Documentation Feedback
53
PACKAGE OPTION ADDENDUM
www.ti.com
29-Aug-2014
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
Lead/Ball Finish
MSL Peak Temp
(2)
(6)
(3)
Op Temp (°C)
Device Marking
(4/5)
BQ28Z560DRZR-R1
NRND
SON
DRZ
12
3000
Green (RoHS
& no Sb/Br)
CU NIPDAU
Level-2-260C-1 YEAR
-40 to 85
BQ28
Z560
BQ28Z560DRZT-R1
NRND
SON
DRZ
12
250
Green (RoHS
& no Sb/Br)
CU NIPDAU
Level-2-260C-1 YEAR
-40 to 85
BQ28
Z560
(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.
(4)
There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5)
Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
(6)
Lead/Ball Finish - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead/Ball Finish values may wrap to two lines if the finish
value exceeds the maximum column width.
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 reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on 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.
Addendum-Page 1
Samples
PACKAGE OPTION ADDENDUM
www.ti.com
29-Aug-2014
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 2
PACKAGE MATERIALS INFORMATION
www.ti.com
12-Aug-2013
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
Package Package Pins
Type Drawing
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
B0
(mm)
K0
(mm)
P1
(mm)
W
Pin1
(mm) Quadrant
BQ28Z560DRZR-R1
SON
DRZ
12
3000
330.0
12.4
2.8
4.3
1.2
4.0
12.0
Q2
BQ28Z560DRZT-R1
SON
DRZ
12
250
330.0
12.4
2.8
4.3
1.2
4.0
12.0
Q2
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
12-Aug-2013
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
BQ28Z560DRZR-R1
SON
DRZ
12
3000
338.1
338.1
20.6
BQ28Z560DRZT-R1
SON
DRZ
12
250
338.1
338.1
20.6
Pack Materials-Page 2
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