TI BQ24055DSSR

bq24050
bq24052
bq24055
www.ti.com.................................................................................................................................... SLUS940A – SEPTEMBER 2009 – REVISED SEPTEMBER 2009
800mA, Single Cell Li-Ion Battery Charger With Automatic Adaptor/USB Detection
Check for Samples: bq24050 bq24052 bq24055
FEATURES
•
1
•
•
CHARGING
– 1% Charge Voltage Accuracy
– 10% Charge Current Accuracy
– Pin Selectable USB 100mA and 500mA
Maximum Input Current Limit
– Programmable Termination and Precharge
Threshold
PROTECTION
– 30V Input Rating; with 6.6V Input
Overvoltage Protection
– Input Voltage Dynamic Power Management
– 125°C Thermal Regulation; 150°C Thermal
Shutdown Protection
– OUT Short-Circuit Protection and ISET
short detection
– Operation over JEITA Range via Battery
NTC - ½ Fast-Charge-Current at Cold, 4.06V
at Hot
– Fixed 10 Hour Safety Timer
SYSTEM
– Auto Input Source Detection (D+,D– Pins)
– No Device Transceiver Required
– USB Friendly
– Automatic Termination and Timer Disable
Mode (TTDM) for Absent Battery Pack With
Thermistor
– Status Indication – Charging/Done
– Available in Small 2×2mm2 DFN-10 or
2×3mm2 DFN-12 Packages
APPLICATIONS
•
•
•
•
Smart Phones
PDAs
MP3 Players
Low-Power Handheld Devices
DESCRIPTION
The bq2405x series of devices are highly integrated Li-ion linear chargers devices targeted at space-limited
portable applications. The devices operate from either a USB port or AC adapter. The high input voltage range
with input overvoltage protection supports low-cost unregulated adapters.
The bq2405x has a single power output that charges the battery. A system load can be placed in parallel with the
battery as long as the average system load does not keep the battery from charging fully during the 10 hour
safety timer.
The battery is charged in three phases: conditioning, constant current and constant voltage. In all charge phases,
an internal control loop monitors the IC junction temperature and reduces the charge current if an internal
temperature threshold is exceeded. (Description continued on next page)
bq24050/2
Adaptor
DC+
1
IN
OUT
System Load
10
1.5kW
GND
1mF
2
ISET
TS
9
3
VSS
CHG
8
4
PRETERM ISET2
7
5
D+
6
1kW
OR
D-
Battery Pack
+
1mF
VDD
2kW
TTDM
USB Port
ISET/100/500 mA
VBUS
GND
GND
D+
D+
D-
D-
Host
Disconnect after Detection
1
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.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2009, Texas Instruments Incorporated
bq24050
bq24052
bq24055
SLUS940A – SEPTEMBER 2009 – REVISED SEPTEMBER 2009.................................................................................................................................... www.ti.com
These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
DESCRIPTION
The charger power stage and charge current sense functions are fully integrated. The charger function has high
accuracy current and voltage regulation loops, charge status display, and charge termination. The precharge
current and termination current threshold are programmed via an external resistor. The fast charge current value
is also programmable via an external resistor.
AVAILABLE OPTIONS
VO(REG)
VOVP
RNTC
PG
PACKAGE
2
DEVICES
MARKING
CVC
4.2 V
6.6 V
10 kΩ
No
10 PIN 2 × 2mm DFN
bq24050
4.2 V
6.6 V
100 kΩ
No
10 PIN 2 × 2mm 2 DFN
bq24052
CGT
4.2 V
6.6 V
10 kΩ
Yes
12 PIN 2 × 3mm 2 DFN
bq24055
CGU
ABSOLUTE MAXIMUM RATINGS (1)
over operating free-air temperature range (unless otherwise noted)
Input Voltage
VALUE
UNIT
IN (with respect to VSS)
–0.3 to 30
V
OUT (with respect to VSS)
–0.3 to 7
V
PRE-TERM, ISET, ISET2, TS, CHG, PG, D+, D–,
(with respect to VSS)
–0.3 to 7
V
A
Input Current
IN
1.25
Output Current (Continuous)
OUT
1.25
A
Output Sink Current
CHG
15
mA
8 contact
15 Air
kV
1µF between IN and GND,
1µF between TS and GND,
2µF between OUT and GND,
x5R Ceramic or equivalent
ESD
Electrostatic discharge
(IEC61000-4-2) (2)
TJ
Junction temperature
–40 to 150
°C
TSTG
Storage temperature
–65 to 150
°C
(1)
(2)
IN, OUT, TS
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. All voltage
values are with respect to the network ground terminal unless otherwise noted.
The test was performed on IC pins that may potentially be exposed to the customer at the product level. The bq2405x IC requires a
minimum of the listed capacitance, external to the IC, to pass the ESD test. The D+ D- lines require clamp diodes such as
CM1213A-02SR from CMD to protect the IC for this testing.
PACKAGE DISSIPATION RATINGS (1)
(1)
(2)
2
(2)
PACKAGE
RθJA
RθJC
TA ≤ 25°C
POWER RATING
DERATING FACTOR
TA > 25°C
2 × 2 mm2
60°C/W
8.8°C/W
1.66W
16.6mW/°C
2 × 3 mm2
58°C/W
5.3°C/W
1.72W
17.2mW/°C
For the most current package and ordering information, see the Package Option Addendum at the end of this document, or see the TI
Web site at www.ti.com.
This data is based on using the JEDEC High-K board and the exposed die pad is connected to a copper pad on the board. This is
connected to the ground plane by a 2×3 via matrix
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Copyright © 2009, Texas Instruments Incorporated
Product Folder Link(s): bq24050 bq24052 bq24055
bq24050
bq24052
bq24055
www.ti.com.................................................................................................................................... SLUS940A – SEPTEMBER 2009 – REVISED SEPTEMBER 2009
RECOMMENDED OPERATING CONDITIONS (1)
IN voltage range
VIN
IN operating voltage range, Restricted by VDPM and VOVP
MIN
NOM
3.5
28
UNIT
V
4.45
6.45
V
0.8
A
IIN
Input current, IN pin
IOUT
Current, OUT pin
0.8
A
TJ
Junction temperature
0
125
°C
RPRE-TERM
Programs precharge and termination current thresholds
1
10
kΩ
RISET
Fast-charge current programming resistor
0.675
49.9
kΩ
1.66
258
kΩ
24
885
kΩ
10k NTC thermistor range without entering TTDM, bq24050/55
RTS
(1)
100k NTC thermistor range without entering TTDM, bq24052
Operation with VIN less than 4.5V or in drop-out may result in reduced performance.
ELECTRICAL CHARACTERISTICS
Over junction temperature range 0°C ≤ TJ ≤ 125°C and recommended supply voltage (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
INPUT
Undervoltage lock-out Exit
VIN: 0V → 4V Update based on sim/char
3.15
3.3
3.45
V
VHYS_UVLO
Hysteresis on VUVLO_RISE falling
VIN: 4V→0V,
VUVLO_FALL = VUVLO_RISE –VHYS-UVLO
175
230
280
mV
VIN-DT
Input power good detection threshold
is VOUT + VIN-DT
(Input power good if VIN > VOUT + VIN-DT); VOUT =
3.6V, VIN: 3.5V → 4V
30
80
145
mV
VHYS-INDT
Hysteresis on VIN-DT falling
VOUT = 3.6V, VIN: 4V → 3.5V
31
mV
tDGL(PG_PWR)
Deglitch time on exiting sleep.
Time measured from VIN: 0V → 5V 1μs rise-time to
PG = low, VOUT = 3.6V
45
μs
tDGL(PG_NO-
Deglitch time on VHYS-INDT power
down. Same as entering sleep.
Time measured from VIN: 5V → 3.2V 1μs fall-time
to PG = High Z, VOUT = 3.6V
29
ms
PWR)
VOVP
Input over-voltage protection threshold VIN: 5V → 7V (50/52/55)
tDGL(OVP-SET)
Input over-voltage blanking time
VIN: 5V → 12V
113
μs
VHYS-OVP
Hysteresis on OVP
VIN: 11V → 5V
95
mV
tDGL(OVP-REC)
Deglitch time exiting OVP
Time measured from VIN: 12V → 5V 1μs fall-time
to PG = LO
30
μs
VIN-DPM
USB/Adaptor low input voltage
protection. Restricts lout at VIN-DPM
UVLO
IIN-USB-CL
6.5
6.65
6.8
Feature active in USB mode; Limit Input Source
Current to 50mA; VOUT=3.5V; RISET = 825Ω
4.34
4.4
4.46
Feature active in Adaptor mode; Limit Input Source
Current to 50mA; VOUT=3.5V; RISET = 825Ω
4.24
4.3
4.36
V
V
USB input I-Limit 100mA
ISET2 = Float; RISET = 825Ω
85
92
100
USB input I-Limit 500mA
ISET2 = High; RISET = 825Ω
430
462
500
280
mA
ISET SHORT CIRCUIT TEST
RISET_SHORT
Highest Resistor value considered a
fault (short). Monitored for Iout>90mA
Riset: 600Ω → 250Ω, Iout latches off. Cycle power
to Reset. USB100 mode.
tDGL_SHORT
Deglitch time transition from ISET
short to Iout disable
Clear fault by cycling IN or TS
IOUT_CL
Maximum OUT current limit
Regulation (Clamp)
VIN = 5V, VOUT = 3.6V, VISET2 =Low, Riset: 600Ω →
250Ω, Iout latches off after tDGL-SHORT
1.05
0.75
500
1
Ω
ms
1.4
A
0.85
V
BATTERY SHORT PROTECTION
VOUT(SC)
OUT pin short-circuit detection
threshold/ precharge threshold
VOUT:3V → 0.5V, no deglitch
VOUT(SC-HYS)
OUT pin Short hysteresis
Recovery ≥ VOUT(SC) + VOUT(SC-HYS); Rising, no
Deglitch
IOUT(SC)
Source current to OUT pin during
short-circuit detection
0.8
77
10
15
mV
20
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Copyright © 2009, Texas Instruments Incorporated
Product Folder Link(s): bq24050 bq24052 bq24055
mA
3
bq24050
bq24052
bq24055
SLUS940A – SEPTEMBER 2009 – REVISED SEPTEMBER 2009.................................................................................................................................... www.ti.com
ELECTRICAL CHARACTERISTICS (continued)
Over junction temperature range 0°C ≤ TJ ≤ 125°C and recommended supply voltage (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
QUIESCENT CURRENT
IOUT(PDWN)
Battery current into OUT pin
VIN = 0V
1
IOUT(DONE)
OUT pin current, charging terminated
VIN = 6V, VOUT > VOUT(REG)
6
IIN(STDBY)
Standby current into IN pin
TS = LO, VIN ≤ 6V
Active supply current, IN pin
TS = open, VIN = 6V, TTDM – no load on OUT pin,
VOUT > VOUT(REG), IC enabled
ICC
μA
125
μA
0.8
1
mA
BATTERY CHARGER FAST-CHARGE
VOUT(REG)
Battery regulation voltage
VIN =5.5V, IOUT =25mA, VTS-45°C≤ VTS ≤ VTS-0°C
4.16
4.20
4.23
V
VO_HT(REG)
Battery hot regulation Voltage
VIN =5.5V, IOUT =25mA, VTS-60°C≤ VTS ≤ VTS-45°C
4.02
4.06
4.1
V
IOUT(RANGE)
Programmed Output “fast charge”
current range
VOUT(REG) > VOUT > VLOWV, VIN = 5V, ISET2=Lo,
RISET = 675 to 10.8kΩ
10
800
mA
VDO(IN-OUT)
Drop-Out, VIN – VOUT
Adjust VIN down until IOUT = 0.5A, VOUT = 4.15V,
RISET = 675 , ISET2=Lo (Adaptor Mode); Tj ≤
100°C
500
mV
IOUT
Output “fast charge” formula
VOUT(REG) > VOUT > VLOWV, VIN = 5V, ISET2=Lo
KISET
Fast charge current factor
325
KISET/RISET
A
RISET = KISET /IOUT 50 < IOUT < 800 mA
510
540
570
RISET = KISET /IOUT 25 < IOUT < 50 mA
480
527
600
RISET = KISET /IOUT 10 < IOUT < 25 mA
350
520
680
2.4
2.5
2.6
AΩ
PRECHARGE – SET BY PRETERM PIN
VLOWV
Pre-charge to fast-charge transition
threshold
tDGL1(LOWV)
Deglitch time on pre-charge to
fast-charge transition
70
μs
tDGL2(LOWV)
Deglitch time on fast-charge to
pre-charge transition
32
ms
IPRE-TERM
Refer to the Termination Section
%PRECHG
Pre-Charge Current Level, Default
Setting
VOUT < VLOWV; RPRE-TERM = High Z (≥13kΩ); RISET
= 1k
Pre-charge current formula
RPRE-TERM = KPRE-CHG (Ω/%) × %PRE-CHG (%)
RPRE-TERM/KPRE-CHG
VOUT < VLOWV, VIN = 5V, RPRE-TERM = 2k to 10kΩ;
RISET = 1080Ω , RPRE-TERM = KPRE-CHG ×
%IFAST-CHG, where %IFAST-CHG is 20 to 100%
90
100
110
Ω/%
VOUT < VLOWV, VIN = 5V, RPRE-TERM = 1k to 2kΩ;
RISET = 1080Ω, RPRE-TERM = KPRE-CHG ×
%IFAST-CHG, where %IFAST-CHG is 10% to 20%
84
100
117
Ω/%
KPRE-CHG
% Pre-charge Factor
18
20
22
V
%IOUT-CC
TERMINATION – SET BY PRE-TERM PIN
%TERM
KTERM
Termination Current Threshold,
Default Setting
VOUT > VRCH; RPRE-TERM = High Z (≥13kΩ); RISET =
1k
Termination Current Threshold
Formula
RPRE-TERM = KTERM (Ω/%) × %TERM (%)
% Term Factor
IPRE-TERM
Current for programming the term.
and pre-chg with resistor. ITerm-Start is
the initial PRE-TERM curent.
%TERM
Termination current formula
tDGL(TERM)
Deglitch time, termination detected
ITerm-Start
Elevated PRE-TERM current for,
tTerm-Start, during start of charge to
prevent recharge of full battery,
tTerm-Start
Elevated termination threshold initially
active for tTerm-Start
4
9
10
11
%IOUT-CC
RPRE-TERM/ KTERM
VOUT > VRCH, VIN = 5V, RPRE-TERM = 2k to 10kΩ ;
RISET = 750Ω; KTERM × %IFAST-CHG, where
%IFAST-CHG is 10 to 50%
182
VOUT > VRCH, VIN = 5V, RPRE-TERM = 1k to 2kΩ ;
RISET = 750Ω; KTERM × %IFAST-CHG, where
%IFAST-CHG is 5 to 10%
174
199
224
71
75
81
RPRE-TERM = 2k, VOUT = 4.15V
200
216
Ω/%
RTERM/ KTERM
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%
29
80
85
1.25
μA
ms
92
μA
min
Copyright © 2009, Texas Instruments Incorporated
Product Folder Link(s): bq24050 bq24052 bq24055
bq24050
bq24052
bq24055
www.ti.com.................................................................................................................................... SLUS940A – SEPTEMBER 2009 – REVISED SEPTEMBER 2009
ELECTRICAL CHARACTERISTICS (continued)
Over junction temperature range 0°C ≤ TJ ≤ 125°C and recommended supply voltage (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
RECHARGE OR REFRESH
Recharge detection threshold –
Normal Temp
VIN = 5V, VTS = 0.5V, VOUT: 4.25V → VRCH
VO(REG)0.120
VO(REG
-0.095
VO(REG)0.070
V
Recharge detection threshold – Hot
Temp
VIN = 5V, VTS = 0.2V, VOUT: 4.15V → VRCH
VO_HT(REG)
-0.130
VO_HT(REG)
-0.105
VO_HT(REG)
-0.080
V
tDGL1(RCH)
Deglitch time, recharge threshold
detected
VIN = 5V, VTS = 0.5V, VOUT: 4.25V → 3.5V in 1μs;
tDGL1(RCH) is time to ISET ramp
29
ms
tDGL2(RCH)
Deglitch time, recharge threshold
detected in OUT-Detect Mode
VIN = 5V, VTS = 0.5V, VOUT = 3.5V inserted;
tDGL2(RCH) is time to ISET ramp
3.6
ms
VRCH
BATTERY DETECT ROUTINE (NOTE: In Hot Mode VO(REG) becomes VO_HT(REG))
VREG-BD
VOUT Reduced regulation during
battery detect
IBD-SINK
Sink current during VREG-BD
tDGL(HI/LOW
REG)
VO(REG)0.450
VIN = 5V, VTS = 0.5V, Battery Absent
VO(REG
-0.400
VO(REG)0.350
7
Regulation time at VREG or VREG-BD
10
25
V
mA
ms
VBD-HI
High battery detection threshold
VIN = 5V, VTS = 0.5V, Battery Absent
VO(REG)0.150
VO(REG)0.100
VO(REG)0.050
V
VBD-LO
Low battery detection threshold
VIN = 5V, VTS = 0.5V, Battery Absent
VREG-BD
+0.050
VREG-BD
+0.100
VREG-BD
+0.150
V
1700
1940
2250
s
34000
38800
45000
s
BATTERY CHARGING TIMERS AND FAULT TIMERS
tPRECHG
Pre-charge safety timer value
Restarts when entering Pre-charge; Always
enabled when in pre-charge.
tMAXCH
Charge safety timer value
Clears fault or resets at UVLO, TS ("CE") disable,
OUT Short, exiting LOWV and Refresh
BATTERY-PACK NTC MONITOR (Note 1); TS pin: bq24050/5: 10k NTC; bq24052: 100k NTC; See TS section for thermistor information
INTC-10k
NTC bias current; 10k NTC
thermsistor, bq24050/5
VTS = 0.3V
48
50
52
μA
INTC-100k
NTC bias current; 100k NTC
thermsistor, bq24052
VTS = 0.3V
4.8
5
5.2
μA
INTC-DIS-10k
bq24050/5 bias current when
Charging is disabled.
VTS = 0V
27
30
34
μA
INTC-DIS-100k
bq24052 bias current when Charging
is disabled.
VTS = 0V
4.4
5
5.8
μA
INTC-FLDBK-10k
INTC is reduced prior to entering
TTDM to keep cold thermistor from
entering TTDM, bq24050/5
VTS: Set to 1.525V
4
5
6.5
μA
INTC-FLDBK-100k
INTC is reduced prior to entering
TTDM to keep cold thermistor from
entering TTDM, bq24052
VTS: Set to 1.525V
1.1
1.5
1.9
μA
VTTDM(TS)
Termination and timer disable mode
Threshold – Enter
VTS: 0.5V → 1.7V; Timer Held in Reset
1550
1600
1650
mV
VHYS-TTDM(TS)
Hysteresis exiting TTDM
VTS: 1.7V → 0.5V; Timer Enabled
VCLAMP(TS)
TS maximum voltage clamp
VTS= Open (Float)
1800
1950
tDGL(TTDM)
VTS_I-FLDBK
Deglitch exit TTDM between states
Deglitch enter TTDM between states
TS voltage where INTC is reduce to
keep thermistor from entering TTDM
INTC adjustment (90 to 10%; 45 to 6.6uA) takes
place near this spec threshold.
VTS: 1.425V → 1.525V
100
mV
2000
ms
8
μs
1475
mV
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57
5
bq24050
bq24052
bq24055
SLUS940A – SEPTEMBER 2009 – REVISED SEPTEMBER 2009.................................................................................................................................... www.ti.com
ELECTRICAL CHARACTERISTICS (continued)
Over junction temperature range 0°C ≤ TJ ≤ 125°C and recommended supply voltage (unless otherwise noted)
PARAMETER
TEST CONDITIONS
CTS
Optional Capacitance – ESD
VTS-0°C
bq24050/2/5 Low temperature CHG
Pending
Low Temp Charging to Pending;
VTS: 1V → 1.5V
VHYS-0°C
Hysteresis at 0°C
Charge pending to low temp charging; VTS: 1.5V →
1V
VTS-10°C
Low temperature, half charge
Normal charging to low temp charging; VTS: 0.5V
→ 1V
VHYS-10°C
Hysteresis at 10°C
Low temp charging to normal CHG;
VTS: 1V → 0.5V
VTS-45°C
High temperature at 4.1V
Normal charging to high temp CHG;
VTS: 0.5V → 0.2V
VHYS-45°C
Hysteresis at 45°C
High temp charging to normal CHG;
VTS: 0.2V → 0.5V
VTS-60°C
High temperature Disable
High temp charge to pending;
VTS: 0.2V → 0.1V
VHYS-60°C
Hysteresis at 60°C
Charge pending to high temp CHG;
VTS: 0.1V → 0.2V
tDGL(TS_10C)
Deglitch for TS thresholds: 10C.
tDGL(TS)
Deglitch for TS thresholds: 0/45/60C.
Battery charging
VTS-EN-10k
Charge Enable Threshold, (10k NTC)
VTS: 0V → 0.175V;
VTS-DIS_HYS-10k
HYS below VTS-EN-10k to Disable, (10k
NTC)
VTS: 0.125V → 0V;
VTS-EN-100k
Charge Enable Threshold, (100k
NTC)
VTS: 0V → 0.175V
HYS below VTS-EN-100k to Disable,
(100k NTC)
VTS: 0.125V → 0V;
VTS-DIS_HYS100k
MIN
TYP
MAX
1205
1230
1255
86
765
790
278
815
178
293
50
Cold to Normal Operation: VTS: 1.0V → 0.6V
12
186
88
ms
ms
96
12
140
150
mV
mV
30
80
mV
mV
11.5
Normal to Cold Operation: VTS: 0.6V → 1V
mV
mV
10.7
170
mV
mV
35
263
UNIT
μF
0.22
mV
mV
160
mV
50
mV
THERMAL REGULATION
TJ(REG)
Temperature regulation limit
125
°C
TJ(OFF)
Thermal shutdown temperature
155
°C
TJ(OFF-HYS)
Thermal shutdown hysteresis
20
°C
LOGIC LEVELS ON ISET2
VIL
Logic LOW input voltage
Sink more than 8μA
VIH
Logic HIGH input voltage
Source more than 8μA
IIL
Sink current required for LO
IIH
Source current required for HI
1.1
VFLT
ISET2 Float Voltage
650
6
V
9
μA
V
2
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0.4
1.4
900
8
μA
1200
mV
Copyright © 2009, Texas Instruments Incorporated
Product Folder Link(s): bq24050 bq24052 bq24055
bq24050
bq24052
bq24055
www.ti.com.................................................................................................................................... SLUS940A – SEPTEMBER 2009 – REVISED SEPTEMBER 2009
ELECTRICAL CHARACTERISTICS (continued)
Over junction temperature range 0°C ≤ TJ ≤ 125°C and recommended supply voltage (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
D+/D– DETECTION – bq24050/2/5
tDPDM
DetectionTime from start of D+/Ddetection to latched output
t=0 at D– pulled-up > 0.5V or D+ pulled up
externally, >0.8V
VD+
Bias at D+, during detection routine
Can source at least 200μA
ID+
Current Limit at D+ pin, during
detection routine
VD+ = 0V
ID–
Current Sink at D- pin, during
detection routine
VD- = 0.5V
ID+_LEAK
D+ leakage when not in detection
mode
ID–_LEAK
D– leakage when not in detection
mode
VDPDM_0.4V
D– Comparator Threshold Rising
VDPDM_HYS_0.4
D– Comparator Hysteresis
65
0.475
0.7
V
1.5
mA
150
μA
VD+ = 5V
1
μA
VD- = 5V
1
μA
0.45
V
50
0.6
ms
100
0.35
42
mV
V
VDPDM_0.8V
D+/D– Comparator Threshold Rising
VDPDM_HYS_0.8
D+/D– Comparator Hysteresis
0.75
0.875
42
V
mV
V
LOGIC LEVELS ON CHG AND PG
VOL
Output LOW voltage
ISINK = 5mA
Ilkg
Leakage current into IC
V CHG = 5V, V PG = 5V
0.4
V
1
μA
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PIN CONFIGURATION
bq24055
bq24050/2
1 IN
1 IN
OUT 10
OUT 12
2 ISET
TS 9
2 ISET
TS 11
3 VSS
CHG 8
3 VSS
CHG 10
4 PRETERM
4 PRETERM
ISET 2 7
5 D+
5 D+
D- 6
6
PG
ISET2 9
D- 8
NC 7
PIN FUNCTIONS
NAME
bq24050/2
bq24055
I/O
DESCRIPTION
IN
1
1
I
Input power, connected to external DC supply (AC adapter or USB port). Expected range
of bypass capacitors 1μF to 10μF, connect from IN to VSS.
OUT
10
12
O
Battery Connection. System Load may be connected. Average load should not be
excessive, allowing battery to charge within the 10 hour safety timer window. Expected
range of bypass capacitors 1μF to 10μF.
Programs the Current Termination Threshold (5 to 50% of Iout which is set by ISET) and
Sets the Pre-Charge Current to twice the Termination Current Level.
PRE-TERM
4
4
I
ISET
2
2
I
Programs the Fast-charge current setting. External resistor from ISET to VSS defines fast
charge current value. Range is 10.8k (50mA) to 675 Ω (800mA).
ISET2
7
9
I
Programming the Input/Output Current Limit for the USB or Adaptor source: High =
500mAmax, Low = ISET, FLOAT = 100mA max. D+D– Detection initially sets the charge
threshold and requires ISET2 to change states to take control.
11
I
Temperature sense pin connected to ‘50/55 –10k at 25C NTC thermistor, ’52 – 100k NTC
at 25°C, in the battery pack. Floating TS Pin or pulling High puts part in TTDM and disable
TS monitoring, Timers and Termination. Pulling pin Low disables the IC ( CE function). If
NTC sensing is not needed, connect this pin to VSS through an external ‘50/55-10kΩ
/’52-100kΩ resistor. A ‘50/55-250kΩ/’52-880kΩ from TS to ground will prevent IC entering
TTDM when battery with thermistor is removed.
TS
9
(1)
Expected range of programming resistor is 1k to 10kΩ (2k: IOUT/10 for term; IOUT/5 for
precharge)
VSS
3
3
–
Ground terminal
CHG
8
10
O
Low (FET on) indicates charging and Open Drain (FET off) indicates no Charging or
Charge complete.
PG
–
6
O
Low (FET on) indicates the input voltage is above UVLO and the OUT (battery) voltage
and less than VOVP
D+
5
5
I
USB port D+ input connection
D–
6
8
I
USB port D– input connection
NC
–
7
NA
Pad 2x2mm2
Pad
2x3mm2
–
Thermal
PAD and
Package
(1)
8
Do not make connection to this pin (internal use) – Do not route through this pin
There is an internal electrical connection between the exposed thermal pad and the VSS
pin of the device. The thermal pad must be connected to the same potential as the VSS
pin on the printed circuit board. Do not use the thermal pad as the primary ground input
for the device. VSS pin must be connected to ground at all times.
Spins have different pin definitions
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Typical Application Circuit: bq24050/2
IOUT_FAST_CHG = 540mA; IOUT_PRE_CHG = 108mA; IOUT_TERM = 54mA
bq24050/2
Adaptor
1 IN
DC+
OUT 10
System Load
1.5kW
GND
2 ISET
Battery Pack
TS 9
+
1kW
3
CHG 8
VSS
1mF
1mF
4
OR
PRETERM
ISET 2 7
5 D+
D- 6
VDD
2kW
TTDM
USB Port
ISET/100/500mA
VBUS
GND
GND
D+
D+
D-
Host
DDisconnected after Detection
Typical Application Circuit: bq24055
IOUT_FAST_CHG = 540mA; IOUT_PRE_CHG = 108mA; IOUT_TERM = 54mA
bq 24055
Adaptor
1 IN
DC+
System Load
OUT 12
1.5kW
GND
2 ISET
1kW
Battery Pack
TS 11
+
3
VSS
4
PRETERM
CHG 10
1mF
OR
2kW
USB Port
5 D+
6 PG
1mF
ISET2 9
D- 8
NC 7
VBUS
GND
VDD
TTDM
ISET/100/500 mA
GND
D+
D+
D-
D-
Host
Disconnected after Detection
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FUNCTIONAL BLOCK DIAGRAM
Internal Charge
Current Sense
w/Multiple Outputs
IN
OUT
OUT
IN
OUT
+
_
+
_
80 Input
mV Power
+ Detect
_
+
-
IN-DPMREF
IOUT x 1.5 V
540 AW
Charge
Pump
OUTREGREF
TJ°C
+
_
125°CREF
FAST CHARGE
Thermal Regulation
PRE-CHARGE
ISET
IN
+
_
1.5 V
Pre-CHG Reference
+
_
USB Sense
Resistor
USB100/500REF
TJoC
+
_
Term Reference
+
_
150oCREF
Thermal Shutdown
Charge
Pump
X2 Gain (1:2)
Term:Pre-CHG
75mA+
PRE-TERM
IN
Increased from 75mA to 85mA for
1st minute of charge.
+
_
+
OUT
CHG
OVPREF
+
_
On During
1st Charge Only
+
_
VTERM_EN
ON:
OFF:
ISET2 (LOW = ISET, HI = USB500,
CHARGE
CONTROL
0.9 V Float
FLOAT = USB100)
PG
bq24055 Only
VCOLD-10C
+
_
+
_
VHOT-45C
HI = Half CHG (JEITA)
HI = 4.06Vreg (JEITA)
0.6 V(200 mA)
VCOLD-FLT
+
_
+
_
VHOT-FLT
D+
LO = TTDM MODE
HI = Suspend CHG
TS
VTTDM
VDISABLE
+
_
10
D(100 mA)
HI = CHIP DISABLE
+
_
Cold Temperature
Sink Current
VCLAMP = 1.4 V
= 45mA
+
_
5m A
D+ / DDETECTION
CONTROL
- On Initial
Supply Power
Connection
Disable
Sink Current
= 20mA
+
_
45mA
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TYPICAL OPERATIONAL CHARACTERISTICS
SETUP: bq24055 typical applications schematic; VIN = 5V, VBAT = 3.6V (unless otherwise indicated)
RISET = 1k; IOUT_FAST_CHG = 540mA; RPAC_TERM = 2k; IOUT_PRE_CHG = 108mA; IOUT_TERM = 54mA
Power UP, DOWN, OVP, Disable and Enable Waveforms
Vin
Vin
2V/div
D+
2V/div
D+
1V/div
Vd-
1V/div
Vd-
1V/div
1V/div
Vchg
2V/div
5V/div
Viset
2V/div
Vchg
Viset
2V/div
t - time - 100ms/div
t - time - 10ms/div
Detected D- line pulled to 0.6V and the detection routine is
started.
No signal detected on D+ or D-. After 500ms, the detection
routine is forced to run.
Figure 1. D+ D- Detection for Adaptor Hot Plug
Figure 2. D+ D- Detection for Unknown Source Hot Plug
Vin
Vin
2V/div
2V/div
D+
1V/div
Vd-
1V/div
5V/div
End of
Detection
Routine
D+
1V/div
Detection Routine
Started
Vd1V/div
Vchg
5V/div
Viset
Vchg
2V/div
Viset
t - time - 100ms/div
2V/div
t - time - 50ms/div
(Device transceiver is "dead") After 500ms, the detection
routine is forced to run.
Figure 3. D+ D- Detection for USB Hot Plug no Pullup
Vin
USB Communication
Between Host and
Device Receiver
Figure 4. D+ D- Detection for USB Hot Plug with Pullup
Vin
5V/div
5V/div
Vchg
2V/div
Vchg
Vpg
2V/div
Vpg
Viset
2V/div
2V/div
Viset 2V/div
2V/div
t - time - 20ms/div
t - time - 100ms/div
Figure 5. OVP 8V Adaptor – Hot Plug
Figure 6. OVP from Normal Operation –
VIN = 0V→5V→8V→5V
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TYPICAL OPERATIONAL CHARACTERISTICS (continued)
SETUP: bq24055 typical applications schematic; VIN = 5V, VBAT = 3.6V (unless otherwise indicated)
RISET = 1k; IOUT_FAST_CHG = 540mA; RPAC_TERM = 2k; IOUT_PRE_CHG = 108mA; IOUT_TERM = 54mA
Vpg
Vpg
2V/div
5V/div
Vchg
Vchg
2V/div
2V/div
Vout
500mV/div
Vts
2V/div
Viset
Battery Detect Mode
2V/div
Vin
t - time - 50ms/div
5V/div
10kΩ resistor from TS to GND. 10kΩ is shorted to disable the
IC.
t - time - 20ms/div
Fixed 10kΩ resistor, between TS and GND.
Figure 7. TS Enable and Disable
Figure 8. Hot Plug Source w/No Battery – Battery Detection
1 Battery Detect Cycle
Vout
Vin
2V/div
1V/div
Vchg
Vout
Viset
500mV/div
5V/div
1V/div
Viset
1V/div
Vts
1V/div
Vts
2V/div
Entered TTDM
t - time - 5ms/div
t - time - 10ms/div
Figure 9. Battery Removal – GND Removed 1st,
42-Ω Load
Vout
Figure 10. Battery Removal with OUT and
TS Disconnect 1st, With 100–Ω Load
1V/div
Vchg
Battery Declared Absent
5V/div
Viset
1V/div
V_0.1 W_OUT
100mV/div
t - time - 20ms/div
Continuous battery detection when not in TTDM.
Figure 11. Battery Removal With Fixed TS = 0.5V
12
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TYPICAL OPERATIONAL CHARACTERISTICS (continued)
SETUP: bq24055 typical applications schematic; VIN = 5V, VBAT = 3.6V (unless otherwise indicated)
RISET = 1k; IOUT_FAST_CHG = 540mA; RPAC_TERM = 2k; IOUT_PRE_CHG = 108mA; IOUT_TERM = 54mA
PROTECTION CIRCUITS WAVEFORMS
1V/div
Vout
Vout
1V/div
Vchg
5V/div
Viset
Battery
Threshold
Reached
Vchg 2V/div
500mV/div
1V/div
IOUT Clamped Current
Viset
V_0.1 W_OUT
V_0.1 W_OUT
100mV/div
100mV/div
ISET Short Detected
and Latched Off
t - time - 500ms/div
CH4: Iout (1A/Div)Battery voltage swept from 0V to 4.25V to
3.9V.
Figure 12. Battery Charge Profile
Vchg
t - time - 200ms/div
CH4: Iout (1A/Div)
Figure 13. ISET Shorted During Normal Operation
Vin
2V/div
2V/div
Vchg
Vin
2V/div
2V/div
500mV/div
Short Detected in 100mA
mode and Latched Off
Viset
V_0.1 W_OUT
t - time - 1ms/div
t - time - 5ms/div
CH4: Iout (0.2A/Div)
CH4: Iout (0.2A/Div)
Figure 14. ISET Shorted Prior to USB Power Up
Vin
2V/div
Vchg
V_0.1W_OUT
20mV/div
500mV/div
20mV/div
Viset
Figure 15. DPM – Adaptor Current Limits – VIN Regulated to
4.3V
Vin
Vout
2V/div
1V/div
2V/div
Enters
Thermal
Regulation
Exits
Thermal
Regulation
Viset
1V/div
500mV/div
20mV/div
V_0.1W_OUT
Viset
50mV/div
V_0.1W_OUT
t - time - 500ms/div
t - time - 1s/div
The IC temperature rises to 125°C and enters thermal
regulation. Charge current is reduced to regulate the IC at
125°C. VIN is reduced, the IC temperature drops, the charge
current returns to the programmed value.
Figure 16. DPM – USB Current Limits – VIN Regulated to 4.4V
Figure 17. Thermal Reg. – VIN Increases
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TYPICAL OPERATIONAL CHARACTERISTICS (continued)
SETUP: bq24055 typical applications schematic; VIN = 5V, VBAT = 3.6V (unless otherwise indicated)
RISET = 1k; IOUT_FAST_CHG = 540mA; RPAC_TERM = 2k; IOUT_PRE_CHG = 108mA; IOUT_TERM = 54mA
546
Kiset
544
Vin
1V/div
542
Low to High Currents
(may occur in recharge to fast charge transion)
Kiset - W
540
Viset
1V/div
Vchg
5V/div
Vpg
538
High to Low Currents
(may occur in Voltage Regulation - Taper Current)
536
5V/div
534
t - time - 20ms/div
532
Vin swept from 5V to 3.9V to 5V, Vbat = 4V
530
528
.15
0
Figure 18. Entering and Exiting Sleep Mode
0.2
0.4
IO - Output Current - A
0.6
0.8
Figure 19. Kiset for Low and High Currents
4.212
4.2
VO @ 0°C
ROUT = 100 Ω
4.21
4.199
4.208
4.198
4.206
VOUT - Output Voltage - V
VOUT - Output Voltage DC - V
Vreg @ 25°C
VO @ 25°C
4.204
4.202
VO @ 85°C
4.2
4.196
4.195
Vreg @ 0°C
4.194
4.193
4.198
4.196
4.5
Vreg @ 85°C
4.197
4.192
5
5.5
VI - Input Voltage DC - V
6
6.5
0
Figure 20. Line Regulation
0.2
0.4
0.6
IO - Output current - A
0.8
1
Figure 21. Load Regulation Over Temperature
363.4
363.2
IO - Output Current - mA
IO @ 25°C
363
362.8
IO @ 85°C
362.6
362.4
362.2
IO @ 0°C
362
361.8
2.5
3
3.5
VO - Output Voltage - V
4
4.5
Figure 22. Current Regulation Overtemperature
14
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FUNCTIONAL GENERAL DESCRIPTION
The bq2405x is a highly integrate family of 2×2 or 2×3mm single cell Li-Ion chargers. The charger can be used to
charge a battery, power a system or both. The charger has three phases of charging: Pre-charge to recover a
fully discharged battery, fast-charge constant current to supply the buck charge safely and voltage regulation to
safely reach full capacity. The charger is very flexible, allowing programming of the fast-charge current,
pre-charge current and termination. This charger is designed to work with a USB connection or Adaptor (DC out).
The charger also checks to see if a battery is present.
The charger also comes with a full set of safety features: JEITA Temperature Standard, Over-Voltage Protection,
DPM-IN, Safety Timers, and ISET short protection. All of these features and more are described in detail below.
The charger is designed for a single power path from the input to the output to charge a single cell Li-Ion battery
pack. Upon application of a 5VDC power source the D+/D– detection routine is run to determine if the source is
an Adaptor or a USB port. This feature is useful, when the battery is discharged (USB transceiver dead) or there
is no transceiver, by early detection of an adaptor, thus allowing initial charging at the adaptor level. ISET and
OUT short checks are performed in parallel with the detection routine to assure a proper charge cycle.
If the battery voltage is below the LOWV threshold, the battery is considered discharged and a preconditioning
cycle begins. The amount of precharge current can be programmed using the PRE-TERM pin which programs a
percent of fast charge current (10 to 100%) as the precharge current. This feature is useful when the system load
is connected across the battery “stealing” the battery current. The precharge current can be set higher to account
for the system loading while allowing the battery to be properly conditioned. The PRE-TERM pin is a dual
function pin which sets the precharge current level and the termination threshold level. The termination "current
threshold" is always half of the precharge programmed current level.
Once the battery voltage has charged to the VLOWV threshold, fast charge is initiated and the fast charge
current is applied. The fast charge constant current is programmed using the ISET pin. The constant current
provides the bulk of the charge. Power dissipation in the IC is greatest in fast charge with a lower battery voltage.
If the IC reaches 125°C the IC enters thermal regulation, slow the timer clock by half and reduce the charge
current as needed to keep the temperature from rising any further. Figure 23 shows the charging profile with
thermal regulation. Typically under normal operating conditions, the IC’s junction temperature is less than 125°C
and thermal regulation is not entered.
Once the cell has charged to the regulation voltage the voltage loop takes control and holds the battery at the
regulation voltage until the current tapers to the termination threshold. The charge termination can be disabled if
desired. The CHG pin is low (LED on) during the first charge cycle only and turns off once the charge termination
threshold is reached, regardless if termination is enabled or disabled.
The TS pin monitors the voltage across the pack thermistor and implements the JEITA standard. This allows for
reduced voltage regulation at hot temperatures and reduced charge currents at low temperatures. The TS pin
incorporates a chip disable feature when pulled low and an Termination and Timer Disable Mode (TTDM) feature
when left floating or pulled high.
Further details are mentioned in the Operating Modes section.
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VO(REG)
PreConditioning
Phase
Thermal
Regulation
Phase
Current
Regulation
Phase
Voltage Regulation and
Charge Termination
Phase
DONE
IO(OUT)
FAST-CHARGE
CURRENT
PRE-CHARGE
CURRENT AND
TERMINATION
THRESHOLD
Battery
Voltage,
V(OUT)
Battery Current,
I(OUT)
Charge
Complete
Status,
Charger
Off
VO(LOWV)
I(TERM)
IO(PRECHG)
T(THREG)
0A
Temperature, Tj
T(PRECHG)
T(CHG)
DONE
Figure 23. Charging Profile with Thermal Regulation
DETAILED FUNCTIONAL DESCRIPTION
Power-Down, or Undervoltage Lockout (UVLO):
The bq2405x family is in power down mode if the IN pin voltage is less than UVLO. The part is considered
“dead” and all the pins are high impedance. Once the IN voltage rises above the UVLO threshold the IC will
enter Sleep Mode or Active mode depending on the OUT pin (battery) voltage.
Power-up
The IC is alive after the IN voltage ramps above UVLO (see sleep mode), resets all logic and timers, and starts
to perform the D+D– detection along with many of the continuous monitoring routines. The D+/D– detection
typically take less than 100ms, but can take as long as 600ms if there is no activity on the D+ or D– lines which
indicates the device transceiver nor an adaptor is present. Typically the input voltage quickly rises through the
UVLO and sleep states where the IC declares power good, starts the qualification charge at 100mA, finishes the
USB detection routine, sets the input current limit threshold base on the source detected (ISET=adaptor or
100mA=USB), starts the safety timer and enables the CHG pin. See Figure 25
D+/D– Detection:
This detection is designed to give the charger advance notice that an adaptor or USB port is connect for the
cases where the battery is discharged and device transceiver is not able to communicate with a USB host or
there is not a device transceiver. If an adaptor is detected, then the charger can immediately start charging at the
programmed ISET level. Without this early detection, the charger would have to default to the 100mA input
current level to make sure it was not over-loading a low power USB port. The detection method monitors the
D+/D– communication lines looking for a short between the lines (Adaptor source connected) or pull down
resistors on D+/D– (USB source connected) to determine what source is connected (no USB communication
takes place). If an adaptor source is detected then the charger will transition from the 100mA startup level to the
ISET programmed current level. If a USB port is detected, the input current limit will stay at the100mA level. If a
different charge level is desired, than the one detected, the host has to change the state of the ISET2 pin
(signals the internal logic to start using the ISET2 as the program pin) and then set to the desired state.
The D+ and D– pin connections inside the charger are disconnected within 100ms of the D+ or D– lines being
16
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pulled high (start of detection), to minimize any interaction between the charger detection pins and the USB
normal communications. If the device transceiver is able to communicate with the USB host, communication
typically starts after 100ms after the device has pulled the D+ or D– line high indicating it is “on line”, and by then
the IC detection is complete and has been disconnected. The device host then may change the ISET2 level or
disable the IC by pulling the TS pin low.
Sleep Mode
If the IN pin voltage is between than VOUT+VDT and UVLO, the charge current is disabled, the safety timer
counting stops (not reset) and the PG and CHG pins are high impedance. As the input voltage rises and the
charger exits sleep mode, the PG pin goes low, the safety timer continues to count, charge is enabled and the
CHG pin returns to its previous state. See Figure 18
New Charge Cycle
A new charge cycle is started when a good power source is applied, performing a chip disable/enable (TS pin),
exiting Termination and Timer Disable Mode (TTDM), detecting a battery insertion or the OUT voltage dropping
below the VRCH threshold. The CHG pin is active low only during the first charge cycle, therefore exiting TTDM
or a dropping below VRCH will not turn on the CHG pin FET, if the CHG pin is already high impedance.
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18
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0V
DISHYS
EN
60°C
60°CHYS
45°C
45°CHYS
10°CHYS
10°C
0°CHYS
0°C
LDOHYS
LDO
1.8V
VSS
tDGL(TS)
Disabled
4.06 V
HOT
Operation
tDGL(TS)
Normal
Operation
tDGL(TS)
4.06 V
HOT
Operation
tDGL(TS)
HOT
Fault
tDGL(TS)
Cold
Fault
LDO
Mode
t < tDGL(IS)
Normal
Operation
Cold
Operation
tDGL(TS_IOC)
Falling
tDGL(TS)
tDGL(TTDM)
Exit
Cold
Fault
Drawing Not to Scale
Dots Show Threshold Trip Points
fllowed by a deglitch time before
transitioning into a new mode.
tDGL(TTDM)
Enter
Cold
Operation
tDGL(TS)
Normal
Operation
tDGL(TS_IOC)
Rising
Disabled
Normal
Operation
t
tDGL(TS1_IOC)
Cold to Normal
t < tDGL(TTDM)
Exit
tDGL(TTDM)
Enter
LDO
Mode
bq24050
bq24052
bq24055
SLUS940A – SEPTEMBER 2009 – REVISED SEPTEMBER 2009.................................................................................................................................... www.ti.com
Figure 24. TS Battery Temperature Bias Threshold and Deglitch Timers
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bq24050
bq24052
bq24055
www.ti.com.................................................................................................................................... SLUS940A – SEPTEMBER 2009 – REVISED SEPTEMBER 2009
Apply Input
Power
Is Chip Enabled &Alive?
VTS > VEN
& VIN>VUVLO
No
Start Running USB
Detection Routine
Yes
Is power good?
VBAT +VDT < VIN < VOVP
& VUVLO < VIN
No
Yes
Turn on PG FET – PG pin LOW
Set Input Current Limit to 100mA
and Start Charge
Perform ISET & OUT short tests
Remember ISET2 State
Yes
Has ISET2 changed state since
Detection Routine was run?
No
Yes
Set charge current
based on ISET2 truth
table.
Set charge current
based Detection
Routine..
Return to
Charge
Figure 25. Power-up Flow Diagram
Overvoltage-Protection (OVP) – Continuously Monitored
If the input source applies an overvoltage, the pass FET, if previously on, turns off after a deglitch, tBLK(OVP). The
timer ends and the CHG and PG pin goes to a high impedance state. Once the overvoltage returns to a normal
voltage, the PG pin goes low, timer continues, charge continues and the CHG pin goes low after a 25ms
deglitch.. PG pin is optional on some packages.
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Power Good Indication (PG)
After application of a 5V source, the input voltage rises above the UVLO and sleep thresholds (VIN>VOUT+VDT),
but is less than OVP (VIN<VOVP), then the PG FET turns on and provides a low impedance path to ground. SEE
Figure 5, Figure 6, and Figure 18.
CHG Pin Indication
The charge pin has an internal open drain FET which is on (pulls down to VSS) during the first charge only
(independent of TTDM) and is turned off once the battery reaches voltage regulation and the charge current
tapers to the termination threshold set by the PRE-TERM resistor.
The charge pin will be high impedance in sleep mode and OVP (if PG is high impedance) and return to its
previous state once the condition is removed.
Cycling input power, pulling the TS pin low and releasing or entering pre-charge mode will cause the CHG pin to
reset and is considered the start of a first charge.
CHG and PG LED Pull-up Source
For host monitoring, a pull-up resistor is used between the "STATUS" pin and the VCC of the host and for a visual
indication a resistor in series with an LED is connected between the "STATUS" pin and a power source. If the
CHG or PG source is capable of exceeding 7V, a 6.2V zener should be used to clamp the voltage. If the source
is the OUT pin, note that as the battery changes voltage, the brightness of the LEDs vary.
Charging State
CHG FET/LED
1st Charge
ON
Refresh Charge
OVP
OFF
SLEEP
TEMP FAULT
ON for 1st Charge
VIN Power Good State
PG FET/LED
UVLO
SLEEP Mode
OFF
OVP Mode
Normal Input (VOUT + VDT < VIN <
VOUP)
ON
PG is independent of chip disable (bq24055, VTS = 0V)
Input DPM Mode (VIN-DPM or IN-DPM)
The IN-DPM feature is used to detect an input source voltage that is folding back (voltage dropping), reaching its
current limit due to an excessive load. When the input voltage drops to the VIN-DPM threshold the internal pass
FET starts to reduce the current until there is no further drop in voltage at the input. This would prevent a source
with voltage less than VIN-DPM to power the out pin. This works well with current limited adaptors and USB ports
as long as the nominal voltage is above 4.3V and 4.4V respectively. This is an added safety feature that helps
protect the source from excessive loads.
OUT
The Charger’s OUT pin provides current to the battery and to the system, if present. This IC can be used to
charge the battery plus power the system, charge just the battery or just power the system (TTDM) assuming the
loads do not exceed the available current. The OUT pin is a current limited source and is inherently protected
against shorts. If the system load ever exceeds the output programmed current threshold, the output will be
discharged unless there is sufficient capacitance or a charged battery present to supplement the excessive load.
20
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ISET
An external resistor is used to Program the Output Current (50 to 800mA) and can be used as a current monitor.
RISET = KISET ÷ IOUT
(0)
Where:
IOUT is the desired fast charge current;
KISET is a gain factor found in the electrical specification
For greater accuracy at lower currents, part of the sense FET is disabled to give better resolution. Figure 19
shows the transition from low current to higher current. Going from higher currents to low currents, there is
hysteresis and the transition occurs around 0.15A.
The ISET resistor is short protected and will detect a resistance lower than 340Ω. The detection requires at
least 80mA of output current. If a “short” is detected, then the IC will latch off and can only be reset by cycling the
power. The OUT current is internally clamped to a maximum current between 1.1A and 1.35A and is independent
of the ISET short detection circuitry, as shown in Figure 27. Also, see Figure 13 and Figure 14.
4.5
o
For < 45 C, 4.2V Regulation
No Operation
During Cold
Fault
3.5
3
60oC to 45oC
HOT TEMP
4.06V
Regulation
VOUT
2.5
< 48oC
1.5
1
0.5
0
0
o
10oC
60oC
Termination
Disable
2
0C
100% of Programmed
Current
} IC Disable
} Hot Fault
Normalized OUT Current and VREG - V
4
50%
Cold
Fault
IOUT
0.2
0.4
0.6
0.8
1
1.2
1.4
1.6
1.8
VTS - Voltage - V
Figure 26. OPERATION OVER TS BIAS VOLTAGE
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1.8
1.6
IO - Output Current - A
1.4
IOUT Clamp min - max
IOUT Fault min - max
SLUS940A – SEPTEMBER 2009 – REVISED SEPTEMBER 2009.................................................................................................................................... www.ti.com
1.2
IOUT Internal Clamp Range
1
0.8
IOUT Programmed
max
0.6
ISET Short
Fault
Range
min
0.4
0.2
Non Restricted
Operating Area
0
1000
100
10000
ISET - W
Figure 27. PROGRAMMED / CLAMPED OUT CURRENT
PRE_TERM – Pre-Charge and Termination Programmable Threshold
Pre-Term is used to program both the pre-charge current and the termination current threshold, on the
bq24050/2/5. The pre-charge current level is a factor of two higher than the termination current level. The
termination can be set between 5 and 50% of the programmed output current level set by ISET. If left floating the
termination and pre-charge are set internally at 10/20% respectively. The pre-charge-to-fast-charge, Vlowv
threshold is set to 2.5V.
RPRE-TERM = %Term × KTERM = %Pre-CHG × KPRE-CHG
(0)
Where:
%Term is the percent of fast charge current where termination occurs;
%Pre-CHG is the percent of fast charge current that is desired during precharge;
KTERM and KPRE-CHG are gain factors found in the electrical specifications.
22
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ISET2
Is a 3-state input and programs the Input Current Limit/Regulation Threshold. A low will program a regulated fast
charge current via the ISET resistor and is the maximum allowed input/output current for any ISET2 setting, Float
will program a 100mA Current limit and High will program a 500mA Current limit. Note that initially the D+/D–
detection will latch the charge mode according to the source detected (dedicated charger: ISET; USB Host: at
100mA) until the ISET2 pin has changed states, indicating the processor or transceiver is controlling the pin.
The detection routine registers the input level (Low–High-Z–High) of the ISET2 pin ~532 μs after applying input
power (VIN > 3.4 V – UVLO). After the detection routine is complete, which is ~100 ms after a pull-up on the D+
or D– line or after ~570 ms if no pull-up, the IC monitors the ISET2 pin for a change of state. If the state changes
(Low–High-Z–High) from the one registered, for more than 5 μs, then the "detected" latched charge mode is
released and is then controlled by the ISET2 pin. The completion of the detection routine varies due to the
mechanical-plugging action of the USB cable; therefore, it is best to wait ≥ 600 ms after VIN > 3.4 V to take
control of the ISET2 pin.
The following illustration shows two configurations for driving the 3-state ISET2 pin:
VCC
VCC
To
ISET2
R1
To ISET2
Drive
Logic
Q1
OR
Drive
Logic
R1/R2 Divider
set to 0.9 V
Which is the
Float Voltage
R2
Q2
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TS
The TS pin is designed to follow the new JEITA temperature standard for Li-Ion batteries. There are now four
thresholds, 60°C, 45°C, 10°C, and 0°C. Normal operation occurs between 10°C and 45°C. If between 0°C and
10°C the charge current level is cut in half and if between 45°C and 60°C the regulation voltage is reduced to
4.1Vmax, see Figure 26. The TS feature is implemented using an internal 50μA current source to bias the
thermistor (bq24050/5 designed for use with a 10k NTC β = 3370 (SEMITEC 103AT-2 or Mitsubishi
TH05-3H103F), and bq24052 with a 100k NTC β = 3540 (Mitsubishi TH05-36104F) or equivalent) connected
from the TS pin to VSS. If this feature is not needed, a fixed 10k can be placed between TS and VSS to allow
normal operation. This may be done if the host is monitoring the thermistor and then the host would determine
when to pull the TS pin low to disable charge.
The TS pin has two additional features, when the TS pin is pulled low or floated/driven high. A low disables
charge (similar to a CE feature) and a high puts the charger in TTDM.
Above 60°C or below 0°C the charge is disable. Once the thermistor reaches –10°C the TS current folds back
to keep a cold thermistor (between –10°C and –50°C) from placing the IC in the TTDM mode. If the TS pin is
pulled low into disable mode, the current is reduce to 30μA, see Figure 24. Since the ITS current is fixed along
with the temperature thresholds, it is not possible to use thermistor values other than the 10k and 100k.
Termination and Timer Disable Mode (TTDM) -TS pin high
The battery charger is in TTDM when the TS pin goes high from removing the thermistor (removing battery
pack/floating the TS pin) or by pulling the TS pin up to the TTDM threshold.
When entering TTDM, the 10 hour safety timer is held in reset and termination is disabled. A battery detect
routine is run to see if the battery was removed or not. If the battery was removed then the CHG pin will go to its
high impedance state if not already there. If a battery is detected the CHG pin does not change states until the
current tapers to the termination threshold, where the CHG pin goes to its high impedance state if not already
there (the regulated output will remain on).
The charging profile does not change (still has pre-charge, fast-charge constant current and constant voltage
modes). This implies the battery is still charged safely and the current is allowed to taper to zero.
When coming out of TTDM, the battery detect routine is run and if a battery is detected, then a new charge cycle
begins and the CHG LED turns on.
If TTDM is not desired upon removing the battery with the thermistor, one can add a 237k resistor between TS
and VSS to disable TTDM. This keeps the current source from driving the TS pin into TTDM. This creates 0.1°C
error at hot and a 3°C error at cold.
Timers
The pre-charge timer is set to 30 minutes . The pre-charge current, can be programmed to off-set any system
load, making sure that the 30 minutes is adequate.
The fast charge timer is fixed at 10 hours and can be increased real time by going into thermal regulation,
IN-DPM or if in USB current limit. The timer clock slows by a factor of 2, resulting in a clock than counts half as
fast when in these modes. If either the 30 minute or ten hour timer times out, the charging is terminated and the
CHG pin goes high impedance if not already in that state. The timer is reset by disabling the IC, cycling power or
going into and out of TTDM.
Termination
Once the OUT pin goes above VRCH, (reaches voltage regulation) and the current tapers down to the
termination threshold, the CHG pin goes high impedance and a battery detect route is run to determine if the
battery was removed or the battery is full. If the battery is present the charge current will terminate. If the battery
was removed along with the thermistor, then the TS pin will be driven high and the charge will enter TTDM. If the
battery was removed and the TS pin is held in the active region, then the battery detect routine will continue until
a battery is inserted.
24
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Battery Detect Routine
The battery detect routine should check for a missing battery while keeping the OUT pin at a useable voltage.
Whenever the battery is missing the CHG pin should be high impedance.
The battery detect routine is run when entering and exiting TTDM to verify if battery is present, or run all the time
if battery is missing and not in TTDM. On power-up, if battery voltage is greater than VRCH threshold, a battery
detect routine is run to determine if a battery is present.
The battery detect routine will be disabled while the IC is in TTDM or has a TS fault. See Figure 28 for the
Battery Detect Flow Diagram.
Refresh Threshold
After termination, if the OUT pin voltage drops to VRCH (100mV below regulation) then a new charge is initiated,
but the CHG pin remains at a high impedance (off).
Starting a Charge on a Full Battery
The termination threshold is raised by 14%, for the first minute of a charge cycle so if a full battery is removed
and reinserted or a new charge cycle is initiated, that the new charge terminates (less than 1 minute). Batteries
that have relaxed many hours may take several minutes to taper to the termination threshold and terminate
charge.
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Start
BATT_DETECT
Start 25ms timer
Timer Expired?
No
Yes
Is VOUT<VREG-100mV?
Yes
Battery Present
Turn off Sink Current
Return to flow
No
Set OUT REG
to VREG-400mV
Enable sink current
Reset & Start 25ms timer
Timer Expired?
No
Yes
Yes
Is VOUT>VREG-300mV?
Battery Present
Turn off Sink Current
Return to flow
No
Battery Absent
Don’t Signal Charge
Turn off Sink Current
Return to Flow
Figure 28. Battery Detect Flow Diagram
26
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bq2405x CHARGER APPLICATION DESIGN EXAMPLE
bq24050/2
Adaptor
DC+
1
IN
2
ISET
TS
9
3
VSS
CHG
8
4
PRETERM
5
D+
OUT
System Load
10
1.5kW
GND
Battery Pack
+
1kW
1mF
1mF
OR
ISET 2 7
D- 6
VDD
2kW
TTDM
USB Port
ISET/100/500 mA
VBUS
GND
GND
D+
D+
D-
D-
Host
Disconnect after Detection
Requirements
• Supply voltage = 5 V
• Fast charge current: IOUT-FC = 540 mA; ISET-pin 2
• Termination Current Threshold: %IOUT-FC = 10% of Fast Charge or 54mA
• Pre-Charge Current by default is twice the termination Current or 108mA
• TS – Battery Temperature Sense = 10k NTC (103AT)
Calculations
Program the Fast Charge Current, ISET:
RISET = [K(ISET) / I(OUT)]
from electrical characteristics table. . . K(SET) = 540AΩ
RISET = [540AΩ/0.54A] = 1.0 kΩ
Selecting the closest standard value, use a 1kΩ resistor between ISET (pin 16) and VSS.
Program the Termination Current Threshold, ITERM:
RPRE-TERM = K(TERM) × %IOUT-FC
RPRE-TERM = 200Ω/% × 10% = 2kΩ
Selecting the closest standard value, use a 2kΩ resistor between ITERM (pin 15) and Vss.
One can arrive at the same value by using 20% for a pre-charge value (factor of 2 difference).
RPRE-TERM = K(PRE-CHG) × %IOUT-FC
RPRE-TERM = 100Ω/% × 20%= 2kΩ
TS Function
Use a 10k NTC thermistor in the battery pack (103AT).
To Disable the temp sense function, use a fixed 10k resistor between the TS (Pin 1) and VSS.
CHG and PG
LED Status: connect a 1.5k resistor in series with a LED between the OUT pin and the CHG pin. Connect a 1.5k
resistor in series with a LED between the OUT pin and the and PG pin.
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Processor Monitoring: Connect a pull-up resistor between the processor’s power rail and the CHG pin.
Connect a pull-up resistor between the processor’s power rail and the PG pin.
SELECTING IN AND OUT PIN CAPACITORS
In most applications, all that is needed is a high-frequency decoupling capacitor (ceramic) on the power pin, input
and output pins. Using the values shown on the application diagram, is recommended. After evaluation of these
voltage signals with real system operational conditions, one can determine if capacitance values can be adjusted
toward the minimum recommended values (DC load application) or higher values for fast high amplitude pulsed
load applications. Note if designed for high input voltage sources (bad adaptors or wrong adaptors), the capacitor
needs to be rated appropriately. Ceramic capacitors are tested to 2x their rated values so a 16V capacitor may
be adequate for a 30V transient (verify tested rating with capacitor manufacturer).
THERMAL PACKAGE
The bq2405x family is packaged in a thermally enhanced MLP package. The package includes a thermal pad to
provide an effective thermal contact between the IC and the printed circuit board (PCB). The power pad should
be directly connected to the VSS pin. Full PCB design guidelines for this package are provided in the QFN/SON
PCB Attachment Application Note application note (SLUA271). The most common measure of package thermal
performance is thermal impedance (θJA ) measured (or modeled) from the chip junction to the air surrounding the
package surface (ambient). The mathematical expression for θJA is:
θJA = (TJ – T) / P
(0)
Where:
TJ = chip junction temperature
T = ambient temperature
P = device power dissipation
Factors that can influence the measurement and calculation of θJA include:
1. Whether or not the device is board mounted
2. Trace size, composition, thickness, and geometry
3. Orientation of the device (horizontal or vertical)
4. Volume of the ambient air surrounding the device under test and airflow
5. Whether other surfaces are in close proximity to the device being tested
Due to the charge profile of Li-Ion batteries the maximum power dissipation is typically seen at the beginning of
the charge cycle when the battery voltage is at its lowest. Typically after fast charge begins the pack voltage
increases to 3.4V within the first 2 minutes. The thermal time constant of the assembly typically takes a few
minutes to heat up so when doing maximum power dissipation calculations, 3.4V is a good minimum voltage to
use. This is verified, with the system and a fully discharged battery, by plotting temperature on the bottom of the
PCB under the IC (pad should have multiple vias), the charge current and the battery voltage as a function of
time. The fast charge current will start to taper off if the part goes into thermal regulation.
The device power dissipation, P, is a function of the charge rate and the voltage drop across the internal
PowerFET. It can be calculated from the following equation when a battery pack is being charged :
P = [V(IN) – V(OUT)] × I(OUT) + [V(OUT) – V(OUT)] × I(OUT)
(0)
The thermal loop feature reduces the charge current to limit excessive IC junction temperature. It is
recommended that the design not run in thermal regulation for typical operating conditions (nominal input voltage
and nominal ambient temperatures) and use the feature for non typical situations such as hot environments or
higher than normal input source voltage. With that said, the IC will still perform as described, if the thermal loop
is always active.
Leakage Current Effects on Battery Capacity
To determine how fast a leakage current on the battery discharges, the battery is used for the calculation. The
time from full to discharge can be calculated by dividing the Amp-Hour Capacity of the battery by the leakage
current. For a 0.75AHr battery and a 10μA leakage current (750mAHr/0.010mA = 75000 Hours), it would take
75k hours or 8.8 years to discharge. In reality, the self discharge of the cell is much faster, so the 10μA leakage
would be considered negligible.
28
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Layout Tips
To obtain optimal performance, the decoupling capacitor from IN to GND (thermal pad) and the output filter
capacitors from OUT to GND (thermal pad) should be placed as close as possible to the bq2405x, with short
trace runs to both IN, OUT and GND (thermal pad).
• All low-current GND connections should be kept separate from the high-current charge or discharge paths
from the battery. Use a single-point ground technique incorporating both the small signal ground path and the
power ground path.
• The high current charge paths into IN pin and from the OUT pin must be sized appropriately for the maximum
charge current in order to avoid voltage drops in these traces
• The bq2405x family is packaged in a thermally enhanced MLP package. The package includes a thermal pad
to provide an effective thermal contact between the IC and the printed circuit board (PCB); this thermal pad is
also the main ground connection for the device. Connect the thermal pad to the PCB ground connection. It is
best to use multiple 10-mill vias in the power pad of the IC and in close proximity to conduct the heat to the
bottom ground plane. The bottom ground place should avoid traces that “cut off” the thermal path. The thinner
the PCB the less temperature rise. The EVM PCB has a thickness of 0.031 inches and uses 2 oz. (2.8-mill
thick) copper on top and bottom, and is a good example of optimal thermal performance.
SPACER
REVISION HISTORY
Changes from Original (August 2009) to Revision A ..................................................................................................... Page
•
Changed the status of the devices From: Product Preview To: Prodcution Data ................................................................ 1
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PACKAGE OPTION ADDENDUM
www.ti.com
15-Sep-2009
PACKAGING INFORMATION
Orderable Device
Status (1)
Package
Type
Package
Drawing
Pins Package Eco Plan (2)
Qty
BQ24050DSQR
ACTIVE
SON
DSQ
10
3000 Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-2-260C-1 YEAR
BQ24050DSQT
ACTIVE
SON
DSQ
10
250
Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-2-260C-1 YEAR
BQ24052DSQR
ACTIVE
SON
DSQ
10
3000 Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-2-260C-1 YEAR
BQ24052DSQT
ACTIVE
SON
DSQ
10
250
Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-2-260C-1 YEAR
BQ24055DSSR
ACTIVE
SON
DSS
12
3000 Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-2-260C-1 YEAR
BQ24055DSST
ACTIVE
SON
DSS
12
250
CU NIPDAU
Level-2-260C-1 YEAR
Green (RoHS &
no Sb/Br)
Lead/Ball Finish
MSL Peak Temp (3)
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in
a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check
http://www.ti.com/productcontent for the latest availability information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements
for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered
at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and
package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS
compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame
retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder
temperature.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is
provided. TI bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the
accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and continues to take
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.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI
to Customer on an annual basis.
Addendum-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
12-Sep-2009
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
Package Package Pins
Type Drawing
BQ24050DSQR
SON
DSQ
10
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
B0
(mm)
K0
(mm)
P1
(mm)
W
Pin1
(mm) Quadrant
3000
179.0
8.4
2.2
2.2
1.2
4.0
8.0
Q2
BQ24050DSQT
SON
DSQ
10
250
179.0
8.4
2.2
2.2
1.2
4.0
8.0
Q2
BQ24052DSQR
SON
DSQ
10
3000
179.0
8.4
2.2
2.2
1.2
4.0
8.0
Q2
BQ24052DSQT
SON
DSQ
10
250
179.0
8.4
2.2
2.2
1.2
4.0
8.0
Q2
BQ24055DSSR
SON
DSS
12
3000
179.0
8.4
2.3
3.2
1.0
4.0
8.0
Q1
BQ24055DSST
SON
DSS
12
250
179.0
8.4
2.3
3.2
1.0
4.0
8.0
Q1
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
12-Sep-2009
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
BQ24050DSQR
SON
DSQ
10
3000
195.0
200.0
45.0
BQ24050DSQT
SON
DSQ
10
250
195.0
200.0
45.0
BQ24052DSQR
SON
DSQ
10
3000
195.0
200.0
45.0
BQ24052DSQT
SON
DSQ
10
250
195.0
200.0
45.0
BQ24055DSSR
SON
DSS
12
3000
195.0
200.0
45.0
BQ24055DSST
SON
DSS
12
250
195.0
200.0
45.0
Pack Materials-Page 2
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