Texas Instruments System-Side Impedance Track(TM) Fuel Gauge bq27500 Manual De Usuario
www.ti.com
5
FUNCTIONAL DESCRIPTION
5.1 FUEL GAUGING
bq27500
bq27501
System-Side Impedance Track™ Fuel Gauge
bq27501
System-Side Impedance Track™ Fuel Gauge
SLUS785 – SEPTEMBER 2007
Table 4-7. Data Flash Summary (continued)
Subclass
Data
Min
Max
Default
Class
Subclass
Offset
Name
Units
ID
Type
Value
Value
Value
Ra Tables
91
Pack0 Ra
0-18
Ra Tables
92
Pack1 Ra
0-18
See Note
(2)
Ra Tables
93
Pack0 Rax
0-18
Ra Tables
94
Pack1 Rax
0-18
Calibration
104
Data
0
CC Gain
F4
0.1
4
0.47095
m
Ω
Calibration
104
Data
4
CC Delta
F4
29826
1193046
280932.6
m
Ω
Calibration
104
Data
8
CC Offset
I2
-32768
32767
–1667
mV
Calibration
104
Data
10
Board Offset
I1
–128
127
0
mV
Calibration
104
Data
11
Int Temp Offset
I1
–128
127
0
0.1
°
C
Calibration
104
Data
12
Ext Temp Offset
I1
–128
127
0
0.1
°
C
Calibration
104
Data
13
Pack V Offset
I1
–128
127
0
0.1
°
C
Calibration
107
Current
1
Deadband
U1
0
255
3
mA
Security
112
Codes
0
Usealed Key0
H2
0x0000
0xffff
–
–
Security
112
Codes
2
Usealed Key1
H2
0x0000
0xffff
–
–
Security
112
Codes
4
Full-Access Key0
H2
0x0000
0xffff
–
–
Security
112
Codes
6
Full-Access Key1
H2
0x0000
0xffff
–
–
The bq27500/1 measures the cell voltage, temperature, and current to determine battery SOC. The
bq27500/1 monitors charge and discharge activity by sensing the voltage across a small-value resistor
(5m
bq27500/1 monitors charge and discharge activity by sensing the voltage across a small-value resistor
(5m
Ω
to 20 m
Ω
typ.) between the SRP and SRN pins and in series with the cell. By integrating charge
passing through the battery, the cell’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 bq27500/1
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 the Term Voltage.
NominalAvailableCapacity( ) and FullAvailableCapacity( ) are the uncompensated (no or light load)
versions of RemainingCapacity( ) and FullChargeCapacity( ) respectively.
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 bq27500/1
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 the Term Voltage.
NominalAvailableCapacity( ) and FullAvailableCapacity( ) are the uncompensated (no or light load)
versions of RemainingCapacity( ) and FullChargeCapacity( ) respectively.
The bq27500/1 has two flags accessed by the Flags( ) function that warns when the cell’s SOC has fallen
to critical levels. When RemainingCapacity( ) falls below the first capacity threshold, specified in SOC1
Set, the [SOC1] (“State of Charge Initial””) flag is set. The flag is cleared, once RemainingCapacity( ) rises
above SOC1 Set. All units are in mAh.
to critical levels. When RemainingCapacity( ) falls below the first capacity threshold, specified in SOC1
Set, the [SOC1] (“State of Charge Initial””) flag is set. The flag is cleared, once RemainingCapacity( ) rises
above SOC1 Set. All units are in mAh.
When RemainingCapacity( ) falls below the second capacity threshold, SOCF Set, the [SOCF] (“State of
Charge Final”) flag is set, serving as a final discharge warning. If SOCF Set = –1, the flag is inoperative
during discharge.
Charge Final”) flag is set, serving as a final discharge warning. If SOCF Set = –1, the flag is inoperative
during discharge.
Similarly, when RemainingCapacity( ) rises above SOCF Clear and the [SOCF] flag has already been set,
the [SOCF] flag will be cleared, provided SOCF Set
the [SOCF] flag will be cleared, provided SOCF Set
≠
–1. All units are in mAh.
FUNCTIONAL DESCRIPTION
20