TI bq24278YFFR

bq24278
www.ti.com
SLUSB04 – JUNE 2012
2.5A, Single Input, Single Cell Switchmode Li-Ion BATTERY CHARGER with Power Path
Management
Check for Samples: bq24278
FEATURES
•
1
•
•
•
•
•
•
High-Efficiency Switch Mode Charger with
Separate Power Path Control
– Instantly Startup System from a Deeply
Discharged Battery or No Battery
20V input rating, with 10.5V Over-Voltage
Protection (OVP)
Integrated FETs for Up to 2.5A Charge Rate
Highly Integrated Battery N-Channel MOSFET
Controller for Power Path Management
Safe and accurate Battery Management
Functions
– 0.5% Battery Regulation Accuracy
– 10% Charge Current Accuracy
Voltage-based, NTC Monitoring Input (TS)
– Standard Temp Range
•
•
•
•
Thermal Regulation Protection for Output
Current Control
Low Battery Leakage Current, BAT ShortCircuit Protection
Soft-Start feature to reduce inrush current
Thermal Shutdown and Protection
Available in small 49-ball WCSP or QFN-24
packages
APPLICATIONS
•
•
•
•
Handheld Products
Portable Media Players
Portable Equipment
Netbook and Portable Internet Devices
APPLICATION SCHEMATIC
IN
VBUS
D+
SW
D–
GND
System
Load
VDPM
PMID
BOOT
CD
HOST
SYS
/CE
ILIM
BAT
ISET
BYP
TS
PGND /CHG /PG DRV_S DRV_S DRV
PACK+
TEMP
–
+
PACK–
DESCRIPTION
The bq24278 highly integrated single cell Li-Ion battery charger and system power path management device
targeted for space-limited, portable applications with high capacity batteries. The single cell charger operates
from a dedicated charging source such as an AC adapter or Wireless Power.
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 © 2012, Texas Instruments Incorporated
bq24278
SLUSB04 – JUNE 2012
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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.
DESCRIPTION (CONTINUED)
The power path management feature allows the bq24278 to power the system from a high efficiency DC to DC
converter while simultaneously and independently charging the battery. The charger monitors the battery current
at all times and reduces the charge current when the system load requires current above the input current limit.
This allows for proper charge termination and timer operation. The system voltage is regulated to the battery
voltage but will not drop below 3.5V. This minimum system voltage support enables the system to run with a
defective or absent battery pack and enables instant system turn-on even with a totally discharged battery or no
battery. The power-path management architecture also permits the battery to supplement the system current
requirements when the adapter cannot deliver the peak system currents. This enables the use of a smaller
adapter.
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 the internal
temperature threshold is exceeded. Additionally, the bq24278 offers a voltage-based battery pack thermistor
monitoring input (TS) that monitors battery temperature for safe charging .
ORDERING INFORMATION
PART NUMBER
IN OVP
NTC MONITORING
(TS)
JEITA
COMPATIBLE
MINIMUM SYSTEM
VOLTAGE
PACKAGE
bq24278YFFR
10.5 V
Yes
No
3.5 V
WCSP
bq24278YFFT
10.5 V
Yes
No
3.5 V
WCSP
bq24278RGER
10.5 V
Yes
No
3.5 V
QFN
bq24278RGET
10.5 V
Yes
No
3.5 V
QFN
ABSOLUTE MAXIMUM RATINGS
over operating free-air temperature range (unless otherwise noted) (1)
MIN
MAX
–2
20
V
PMID, BYP, BOOT
–0.3
20
V
SW
–0.7
12
V
SYS, BAT, BGATE, DRV, PG, CHG, CE, CD, TS, DRV_S, ILIM, ISET,
VDPM
–0.3
7
V
IN
Pin voltage range (with respect to
VSS)
BOOT to SW
Output current (continuous)
–0.3
UNIT
7
V
SW
4.5
A
SYS
3.5
A
2.75
A
Input current (continuous)
IN
Output sink current
PG, CHG
10
mA
Operating free-air temperature range
-40
85
°C
Junction temperature, TJ
-40
125
°C
Storage temperature, TSTG
–65
150
°C
300
°C
Lead temperature (soldering, 10 s)
(1)
2
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.
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SLUSB04 – JUNE 2012
THERMAL INFORMATION
bq24278
THERMAL METRIC (1)
YFF (48 PINS)
QFN (24 PINS)
θJA
Junction-to-ambient thermal resistance
49.8
32.6
θJCtop
Junction-to-case (top) thermal resistance
0.2
30.5
θJB
Junction-to-board thermal resistance
1.1
3.3
ψJT
Junction-to-top characterization parameter
1.1
0.4
ψJB
Junction-to-board characterization parameter
6.6
9.3
θJCbot
Junction-to-case (bottom) thermal resistance
N/A
2.6
UNITS
°C/W
spacer
(1)
For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953.
RECOMMENDED OPERATING CONDITIONS
MIN MAX
VIN
IN voltage range
4.2
18 (1)
IN operating range
4.2
10
IIN
Input current IN input
ISYS
Ouput Current from SW, DC
IBAT
TJ
(1)
A
3
A
2.5
Discharging, using internal battery FET
2.5
0
V
2.5
Charging
Operating junction temperature range
UNITS
125
A
ºC
The inherent switching noise voltage spikes should not exceed the absolute maximum rating on either the BOOT or SW pins. A tight
layout minimizes switching noise.
ELECTRICAL CHARACTERISTICS
Circuit of Figure 2, VUVLO < VIN < VOVP AND VIN>VBAT+VSLP, TJ = 0°C–125°C and TJ = 25°C for typical values (unless
otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
VUVLO < VIN < VOVP AND VIN > VBAT+VSLP PWM
switching
IIN
Input quiescent current
TYP
VUVLO < VIN < VOVP AND VIN > VBAT+VSLP PWM NOT
switching
Leakage current from BAT to the supply
0°C< TJ < 85°C, VBAT = 4.2V, VIN = 0 V
IBAT_HIZ
Battery discharge current in High Impedance mode (BAT,
SW, SYS)
0°C< TJ < 85°C, VBAT = 4.2 V, VIN = 0 V or 5 V,
High-Z Mode
UNIT
mA
5
0°C < TJ < 85°C, High-Z Mode
IBATLEAK
MAX
15
175
μA
5
μA
55
μA
POWER PATH MANAGEMENT
VSYS(REG)
VBAT < VMINSYS
System regulation voltage
VSYSREGFETOFF
VMINSYS
Minimum system regulation voltage
3.6
3.7
3.82
4.26
4.33
4.37
3.5
3.62
V
Battery FET turned off, Charge disable or termination
VBAT < VMINSYS, Input current limit or VINDPM active
3.4
V
VBSUP1
Enter supplement mode threshold
VBAT > 2.5 V
VBAT –
40mV
VBSUP2
Exit supplement mode threshold
VBAT > 2.5 V
VBAT –
10mV
V
ILIM(Discharge)
Current limit, discharge or supplement mode
Current monitored in internal FET only
7
A
tDGL(SC1)
Deglitch time, OUT short circuit during discharge or
supplement mode
Measured from (VBAT – VSYS) = 300 mV to
VBGATE = (VBAT – 600 mV)
250
μs
tREC(SC1)
Recovery time, OUT short circuit during discharge or
supplement mode
Battery range for BGATE operation
60
2.5
ms
4.5
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ELECTRICAL CHARACTERISTICS (continued)
Circuit of Figure 2, VUVLO < VIN < VOVP AND VIN>VBAT+VSLP, TJ = 0°C–125°C and TJ = 25°C for typical values (unless
otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
YFF pkg
37
57
RGE pkg
50
70
UNIT
BATTERY CHARGER
RON(BAT-SYS)
VBATREG
Measured from BAT to SYS,
VBAT = 4.2 V
Internal battery charger MOSFET on-resistance
Battery regulation voltage
mΩ
TA = 25°C
4.179
4.2
4.221
VWARM < VTS < VCOOL
4.160
4.2
4.24
4.04
4.06
4.08
4.02
4.06
4.1
V
TA = 25°C
VHOT < VTS < VWARM
K
ICHARGE
Charge current programmable range
KISET
Programmable fast charge current factor
VBATSHRT
VBATSHRThys
ISET
I
=
CHARGE R
ISET
550
2500
mA
TA = 0°C to 125°C, VWARM < VTS < VCOOL
400
490
560
TA = 0°C to 125°C, VCOLD < VTS < VCOOL
225
245
270
Battery short threshold
VBAT Rising
2.9
3.0
3.1
Battery short threshold hysteresis
VBAT Falling
100
mV
IBATSHRT
Battery short current
VBAT < VBATSHRT
50.0
mA
tDGL(BATSHRT)
Deglitch time for battery short to fast charge transition
AΩ
32
ms
ICHARGE ≤ 1A
7
10
11.5
ICHARGE >1A
8
10
11
ITERM
Termination charge current
tDGL(TERM)
Deglitch time for charge termination
Both rising and falling, 2-mV over-drive,
tRISE, tFALL = 100 ns
VRCH
Recharge threshold voltage
Below VBATREG
tDGL(RCH)
Deglitch time
VBAT falling below VRCH, tFALL = 100 ns
IDETECT
tDETECT
V
%ICHARGE
32
ms
120
mV
32
ms
Battery detection current before charge done (sink current)
2.5
mA
Battery detection time
250
ms
INPUT PROTECTION
K
ILIM
I
=
INLIM R
ILIM
IINLIM
Maximum input current limit programmable range for IN
input
KILIM
Maximum input current factor for IN input
238
VIN_DPM_IN
VIN_DPM threshold programmable range for IN Input
4.2
1000
VDPM threshold
VDRV
Internal bias regulator voltage
IDRV
DRV Output current
VDO_DRV
DRV Dropout voltage (VIN – VDRV)
IIN = 1A, VIN = 5 V, IDRV = 10 mA
VUVLO
IC active threshold voltage
VIN rising
VUVLO_HYS
IC active hysteresis
VIN falling from above VUVLO
VSLP
Sleep-mode entry threshold, VIN-VBAT
2.0 V ≤ VBAT ≤ VOREG, VIN falling
VSLP_EXIT
Sleep-mode exit hysteresis
2.0 V ≤ VBAT ≤ VOREG
Deglitch time for supply rising above VSLP+VSLP_EXIT
Rising voltage, 2-mV over drive, tRISE = 100 ns
VOVP
Input supply OVP threshold voltage
IN, VIN Rising
VOVP(HYS)
VOVP hysteresis
Supply falling from VOVP
VBOVP
Battery OVP threshold voltage
VBAT threshold over VOREG to turn off charger during
charge
VBOVP hysteresis
Lower limit for VBAT falling from above VBOVP
VBATUVLO
Battery UVLO threshold voltage
ILIMIT
Cycle by Cycle current limit
TSHUTDWN
Thermal shutdown
TREG
Thermal regulation threshold
251
2500
mA
264
AΩ
10
V
V
1.18
1.2
1.22
5
5.2
5.45
10
450
3.6
V
mA
3.8
4.0
150
mV
V
mV
0
40
100
mV
40
100
160
mV
30
10.3
10.5
ms
10.7
100
1.025 ×
VBATREG
1.05 ×
VBATREG
1.075 ×
VBATREG
2.5
10C Hysteresis
4.9
V
5.6
165
324
VIH
Input high threshold
1.3
VIL
Input low threshold
IIH
High-level leakage current
VCHG = VPG = 5 V
VOL
Low-level output saturation voltage
IO = 10 mA, sink current
360
A
C
120
Safety Timer
V
% of
VBATREG
1
4.1
V
mV
C
396
min
CE, CD, PG, CHG
4
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V
0.4
V
1
µA
0.4
V
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SLUSB04 – JUNE 2012
ELECTRICAL CHARACTERISTICS (continued)
Circuit of Figure 2, VUVLO < VIN < VOVP AND VIN>VBAT+VSLP, TJ = 0°C–125°C and TJ = 25°C for typical values (unless
otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
PWM CONVERTER
Internal top reverse blocking MOSFET on-resistance
IIN_LIMIT = 500 mA, Measured from VIN to PMIDU
95
175
mΩ
Internal top N-channel Switching MOSFET on-resistance
Measured from PMIDU to SW
100
175
mΩ
Internal bottom N-channel MOSFET on-resistance
Measured from SW to PGND
65
115
mΩ
1.50
1.65
MHz
fOSC
Oscillator frequency
DMAX
Maximum duty cycle
DMIN
Minimum duty cycle
1.35
95%
0
BATTERY-PACK NTC MONITOR
VHOT
High temperature threshold
VTS falling
VHYS(HOT)
Hysteresis on high threshold
VTS rising
29.7
30
30.5
VCOLD
Low temperature threshold
VTS rising
59.5
60
60.4
VWARM
Warm temperature threshold
VTS falling
37.9
38.3
39.6
VHYS(WARM)
Hysteresis on warm threshold
VTS rising
VCOOL
Cool temperature threshold
VTS rising
VHYS(COOL)
Hysteresis on cool threshold
VTS falling
VHYS(COLD)
Hysteresis on low threshold
VTS falling
TSOFF
TS Disable threshold
VTS rising, 2% VDRV Hysteresis
tDGL(TS)
Deglitch time on TS change
1
1
56.0
56.5
%VDRV
56.9
1
1
70
73
50
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BLOCK DIAGRAM
PMID
BYP
5.2V
Reference
DRV
IN
5A
+
BOOT
CbC Current
Limit
IN IINLIM
ILIM
Q1
IN VINDPM
DC-DC CONVERTER PWM LOGIC,
COMPENSATION AND BATTERY
FET CONTROL
VSYS(REG)
IBAT (REG)
VBAT (REG)
SW
DIE Temp
Regulation
Q2
PGND
SYS
VSUPPLY
DRV_S
References
ISET
V INOVP
10% of
ICHARGE
+
OVP
Comparator
+
V IN
Termination
Comparator
Q3
IBAT
BAT
Recharge Comparator
V IN
V BAT +V SLP
Start Recharge
Cycle
+
+
V BATREG – 0.12V
VBAT
Hi-Impedance Mode
Sleep
Comparator
VSYSREG Comparator
Enable Linear
Charge
+
BGATE
VSYS
VMINSYS
VBATSC Comparator
/CE
Enable
IBATSHRT
CD
+
VBAT
V BATSHRT
TS
Supplement COMPARATOR
VSYS
+
VBAT
VBSUP
VDRV
V BOVP Comparator
+
VBAT
VBATOVP
+
DISABLE
TS COLD
1C/
0.5C
+
TS COOL
+
4.2V/ 4.06V
/CHG
TS WARM
+
DISABLE
/PG
CHARGE
CONTROLLER
TS HOT
w/ Timer
6
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SLUSB04 – JUNE 2012
PIN CONFIGURATION
SPACER
49-BALL WCSP
(TOP VIEW)
1
2
3
4
5
7
6
A
IN
IN
IN
IN
AGND
AGND
AGND
B
PMID
PMID
PMID
PMID
BYP
BYP
BYP
C
SW
SW
SW
SW
SW
SW
SW
D
PGND
PGND
PGND
PGND
PGND
PGND
PGND
E
ILIM
CD
VDPM
/CE
DRV_S
DRV_S
BOOT
SYS
SYS
SYS
SYS
BGATE
/PG
DRV
BAT
BAT
BAT
BAT
TS
/CHG
ISET
F
G
/CE
BYP
AGND
IN
PMID
BOOT
24
23
22
21
20
19
24-PIN QFN
(TOP VIEW)
VDPM
1
18
SW
CD
2
17
PGND
DRV_S
3
16
PGND
15
ILIM
SYS
SYS
DRV_S
bq24278
4
ISET
5
14
DRV
6
13
7
8
9
10
11
12
/PG
/CHG
TS
BGATE
BAT
BAT
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PIN FUNCTIONS
PIN
NAME
NUMBER
I/O
DESCRIPTION
YFF
RGE
IN
A1-A4
21
I
Input power supply. IN is connected to the external DC supply (AC adapter or alternate power
source). Bypass IN to PGND with at least a 1μF ceramic capacitor.
AGND
A5-A7
22
I
Ground terminal. Connect to the thermal pad (for QFN only) and the ground plane of the circuit.
PMID
B1-B4
20
O
Reverse Blocking MOSFET and High Side MOSFET Connection Point for High Power Input.
Bypass PMID to PGND with at least a 4.7μF ceramic capacitor. Use caution when connecting
an external load to PMID. The PMID output is not current limited. Any short on PMID will result
in damage to the IC.
BYP
B5-B7
23
O
Bypass for internal supply. Bypass BYP to GND with at least a 0.1µF ceramic capacitor.
SW
C1–C7
18
O
Inductor Connection. Connect to the switched side of the external inductor.
PGND
D1–D7
16, 17
—
Ground terminal for Switching FET. Connect to the thermal pad (for QFN only) and the ground
plane of the circuit.
ILIM
E1
15
I
IN Input Current Limit Programming Input. Connect a resistor from ILIM to GND to program the
input current limit for IN. The current limit is programmable from 1A to 2.5A.
CD
E2
2
I
IC Hardware Disable Input. Drive CD high to place the bq24278 in high-z mode. Drive CD low
for normal operation.
I
Input DPM Programming Input. Connect a resistor divider from IN to PGND with VDPM
connected to the center tap to program the Input Voltage based Dynamic Power Management
(VIN_DPM) threshold. The input current is reduced to maintain the supply voltage at VIN_DPM.
See the Input Voltage based Dynamic Power Management section for a detailed explanation.
VDPM
E3
1
E4
24
I
Charge Enable Input. CE is used to disable or enable the charge process. A low logic level (0)
enables charging and a high logic level (1) disables charging. When charging is disabled, the
SYS output remains in regulation, but BAT is disconnected from SYS. Supplement mode is still
available if the system load demands cannot be met by the supply.
DRV_S
E5, E6
3, 4
I
Supply for Internal Circuits. Connect DRV_S to DRV directly.
BOOT
E7
19
I
High Side MOSFET Gate Driver Supply. Connect a 0.01μF ceramic capacitor (voltage rating >
10V) from BOOT to SW to supply the gate drive for the high side MOSFETs.
F1–F4
13,14
I/O
System Voltage Sense and Charger FET Connection. Connect SYS to the system output at the
output bulk capacitors. Bypass SYS locally with 1μF.
BGATE
F5
10
O
External Discharge MOSFET Gate Connection. BGATE drives an external P-Channel MOSFET
to provide a very low resistance discharge path. Connect BGATE to the gate of the external
MOSFET. BGATE is low during supplement mode and when no input is connected.
PG
F6
7
I
Power Good Open Drain Output. /PG is pulled low when a valid supply is connected to IN. A
valid supply is between VBAT+VSLP and VOVP. If no supply is connected or the supply is out of
this range, PG is high impedance.
CE
SYS
DRV
F7
6
O
Gate Drive Supply. DRV is the bias supply for the gate drive of the internal MOSFETs. bypass
DRV to PGND with a 1μF ceramic capacitor. DRV may be used to drive external loads up to
10mA. DRV is active whenever the input is connected and VSUPPLY > VUVLO and VSUPPLY >
(VBAT + VSLP)
BAT
G1–G4
11, 12
I/O
Battery Connection. Connect to the positive terminal of the battery. Additionally, bypass BAT to
GND with a 1μF capacitor.
TS
G5
9
I
Battery Pack NTC Monitor. Connect TS to the center tap of a resistor divider from DRV to
GND. The NTC is connected from TS to GND. The TS function in the bq24278 provides 2
thresholds for Hot/ Cold shutoff, with 2 additional thresholds for JEITA compliance. See the
NTC Monitor section for more details on operation and selecting the resistor values.
CHG
G6
8
O
Charge Status Open Drain Output. CHG is pulled low when a charge cycle starts and remains
low while charging. CHG is high impedance when the charging terminates and when no supply
exists. CHG does not indicate recharge cycles.
ISET
G7
5
I
Charge Current Programming Input. Connect a resistor from ISET to GND to program the fast
charge current. The charge current is programmable from 550mA to 2.5A.
—
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.
Thermal
Pad
8
—
Pad
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TYPICAL APPLICATION CIRCUIT
SW
VBUS
IN
PMID
D–
System
Load
0.01 μF
D+
BOOT
GND
1 μF
4.7 μF
SYS
PGND
VDPM
10 μF
ILIM
BGATE
BAT
BYP
V DRV
0.1 μF
1 μF
GND
TS
DRV
PACK+
TEMP
HOST
DRV_S
1 μF
+
–
DRV_S
ISET
PACK–
/PG
/CHG
bq24278
CD
GPIO
CE
GPIO
Figure 1. bq24278 Application Circuit, External Discharge FET Connected
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DETAILED DESCRIPTION
The bq24278 is a highly integrated single cell Li-Ion battery charger and system power path management
devices targeted for space-limited, portable applications with high capacity batteries. The power path
management feature allows the bq24278 to power the system from a high efficiency DC to DC converter while
simultaneously and independently charging the battery. The charger monitors the battery current at all times and
reduces the charge current when the system load requires current above the input current limit. This allows for
proper charge termination and enables the system to run with a defective or absent battery pack. Additionally,
this enables instant system turn-on even with a totally discharged battery or no battery. The power-path
management architecture also permits the battery to supplement the system current requirements when the
adapter cannot deliver the peak system currents. This enables the use of a smaller adapter. 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 the internal temperature
threshold is exceeded.
Charge Mode Operation
Charge Profile
Charging is done through the internal battery MOSFET. When the battery voltage is above 3.5V, the system
output (SYS) is connected to the battery to maximize the charging efficiency. There are 5 loops that influence the
charge current; constant current loop (CC), constant voltage loop (CV), thermal regulation loop, minimum system
voltage loop (MINSYS) and input voltage dynamic power management loop (VIN-DPM). During the charging
process, all five loops are enabled and the dominant one takes control. The bq24278 supports a precision Li-Ion
or Li-Polymer charging system for single-cell applications. The minimum system output feature regulates the
system voltage to a minimum of VSYS(REG), so that startup is enabled even for a missing or deeply discharged
battery. Figure 2 shows a typical charge profile including the minimum system output voltage feature.
Precharge
Phase
Current Regulation
Phase
Voltage Regulation
Phase
Regulation
voltage
Regulation
Current
System Voltage
VSYS
VBATSHORT
Battery
Voltage
Charge Current
Termination
IBATSHORT
50mA Linear Charge
to Close Pack
Protector
Linear Charge
to Maintain
Minimum
System
Voltage
Battery
FET
is OFF
Battery FET is ON
Figure 2. Typical Charging Profile of bq24278
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PWM Controller in Charge Mode
The bq24278 provides an integrated, fixed 1.5 MHz frequency voltage-mode controller with to power the system
and supply the charge current. The converter is internally compensated and provides enough phase margin for
stable operation, allowing the use of small ceramic capacitors with very low ESR.
The bq24278 input scheme prevents battery discharge when the supply voltage is lower than VBAT. The high-side
N-MOSFET (Q1) switches to control the power delivered to SYS. The DRV LDO supplies the gate drive for the
internal MOSFETs. The high-side MOSFET is supplied by a boot strap circuit with external boot-strap capacitor
(BST).
The input is protected from short circuit by a cycle-by-cycle current limit that is sensed through the high-side
MOSFET. The threshold is set to a nominal 5-A peak current. The input also utilizes an input current limit that
limits the current from the power source.
Battery Charging Process
When the battery is deeply discharged or shorted, the bq24278 applies a 50mA current to charge the battery
voltage up to acceptable charging levels. During this time, the battery FET is linearly regulated to maintain the
system output regulation at VSYS(REG). Once the battery rises above VSHORT, the charge current increases to the
fastcharge current setting. The SYS voltage is regulated to VSYS(REG) while the battery is linearly charged through
the battery FET. Additionally, the thermal regulation loop reduces the charge current to maintain the die
temperature at safe levels. Under normal conditions, the time spent in this region is a very short percentage of
the total charging time, so if the charge current is reduced, the reduced charge rate does not have a major
negative effect on total charge time. If the current limit for the SYS output is reached (limited by the input current
limit, or VIN_DPM), the charge current is reduced to provide the system with all the current that is needed. If the
charge current is reduced to 0mA, pulling further current from SYS causes the output to fall to the battery voltage
and enter supplement mode (see the “Dynamic Power Path Management" section for more details).
Once the battery is charged enough to where the system voltage begins to rise above VSYSREG (depends on the
charge current setting), the battery FET is turned on fully and the battery is charged with the programmed charge
current programmed using the ISET input, ICHARGE. The slew rate for fast charge current is controlled to minimize
the current and voltage over-shoot during transient. The charge current is programmed by connecting a resistor
from ISET to GND. The value for RISET is calculated using Equation 1.
KISET
RISET =
ICHARGE
(1)
Where ICHARGE is the programmed fast charge current and KISET is the programming factor found in the Electrical
Characteristics table.
The charge current is regulated to ICHARGE until the battery is charged to the regulation voltage. Once the battery
voltage is close to the regulation voltage, VBATREG, the charge current is tapered down as shown in Figure 2 while
the SYS output remains connected to the battery. The voltage regulation feedback occurs by monitoring the
battery-pack voltage between the BAT and PGND pins.
The bq24278 monitors the charging current during the voltage regulation phase. Once the termination threshold,
ITERM, is detected and the battery voltage is above the recharge threshold, the bq24278 terminates charge and
turns off the battery charging FET and begins battery detection. The system output is regulated to the VBAT(REG)
voltage and supports the full current available from the input and the battery supplement mode (see the
“Dynamic Power Path Management” section for more details) is still available.
A charge cycle is initiated when one of the following conditions is detected:
1. The battery voltage falls below the VBAT(REG)-VRCH threshold.
2. VIN Power-on reset (POR)
3. CE toggle
4. Toggle Hi-Impedance mode (using CD)
If the battery voltage is ever greater than VBAT(REG), the PWM converter is turned off and the battery is discharged
to VBAT(REG). This prevents further overcharging the battery and allows the battery to discharge to safe operating
levels.
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Battery Detection
When termination conditions are met, a battery detection cycle is started. During battery detection, IDETECT is
pulled from VBAT for tDETECT to verify there is a battery. If the battery voltage remains above VDETECT for the full
duration of tDETECT, a battery is determined to be present and the IC enters “Charge Done”. If VBAT falls below
VDETECT, a “Battery Not Present” fault is signaled and battery detection continues. During the next cycle of battery
detection, the bq24278 turns on IBATSHORT for tDETECT. If VBAT rises to VDETECT, the current source is turned off and
after tDETECT, the battery detection continues through another current sink cycle. Battery detection continues until
charge is disabled or a battery is detected. Once a battery is detected, the fault status clears and a new charge
cycle begins. Battery detection is disabled when termination is disabled.
Dynamic Power Path Management
The bq24278 features a SYS output that powers the external system load connected to the battery. This output
is active whenever a source is connected to IN or BAT. The following sections discuss the behavior of SYS with
a source connected to the supply or a battery source only.
Input Source Connected
When a source is connected to IN, and the bq24278 is enabled, the buck converter starts up. If charging is
enabled using CE, the charge cycle is initiated. When VBAT > 3.5V, the SYS output is connected to VBAT. If the
SYS voltage falls to VSYS(REG), it is regulated to that point to maintain the system output even with a deeply
discharged or absent battery. In this mode, the SYS output voltage is regulated by the buck converter and the
battery FET is linearly regulated to regulate the charge current into the battery. The current from the supply is
shared between charging the battery and powering the system load at SYS. The dynamic power path
management (DPPM) circuitry of the bq24278 monitors the SYS voltage continuously and if VSYS falls to VMINSYS,
adjusts charge current to maintain the load on SYS while preventing the system voltage from crashing. If the
charge current is reduced to zero and the load increases further, the bq24278 enters battery supplement mode.
During supplement mode, the battery FET is turned on and the battery supplements the system load. When the
charge current is reduced by the DPPM regulation loop, the safety timer runs at half speed, so that it is twice a
long. This prevents false safety timer faults. See the Safety Timer section for more details.
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2000mA
1800mA
IOUT
800mA
0mA
1500mA
IIN
~850mA
0mA
1A
IBAT
0mA
-200mA
3.7V
3.5V
DPPM loop active
VOUT
~3.1V
Supplement
Mode
Figure 3. Example DPPM Response (VSupply=5V, VBAT = 3.1V, 1.5A Input current limit)
If the VBAT(REG) threshold is ever less than the battery voltage, the battery FET is turned off to allow the battery to
relax down to VBAT(REG) and the SYS output is regulated to VSYSREG(FETOFF). If the battery is ever above VBOVP, the
battery OVP circuit shuts the PWM converter off and the battery FET is turned on to discharge the battery to safe
operating levels.
The input current limit for IN is programmable using the ILIM input. Connect a resistor from ILIM to GND to set
the maximum input current limit. The programmable range for the IN input current limit is 1000mA to 2.5A. RILIM
is calculated using Equation 2:
K
RILIM = ILIM
IIN _ LIM
(2)
Where IIN_LIM is the programmed input current limit and KILIM is the programming factor found in the Electrical
Characteristics table.
Battery Only Connected
When the battery is connected with no input source, the battery FET is turned on similar to supplement mode. In
this mode, the current is not regulated; however, there is a short circuit current limit. If the short circuit limit is
reached, the battery FET is turned off for the deglitch time. After the deglitch time, the battery FET is turned on to
test and see if the short has been removed. If it has not, the FET turns off and the process repeats until the short
is removed.
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Battery Discharge FET (BGATE)
The bq24278 contains a MOSFET driver to drive an external P-Channel MOSFET between the battery and the
system output. This external FET provides a low impedance path for supply the system from the battery. Connect
BGATE to the gate of the external discharge MOSFET. BGATE is on under the following conditions:
1. No valid input supply connected.
2. CD=high (High-Impedance Mode)
This FET is optional and runs in parallel with the internal charge FET during discharge. Note that this FET is not
protected by the short circuit current limit.
Safety Timer
At the beginning of charging process, the bq24278 starts the 6 hour safety timer. This timer is active during the
entire charging process. If charging has not terminated before the safety timer expires, the charge cycle is
terminated and the battery FET is turned off. A new charge cycle must be entered using CE or High Impedance
mode or input power must be toggled in order to clear the safety timer fault.
During the fast charge phase, several events increase the timer durations.
1. The system load current reduces the available charging current
2. The input current is reduced because the VINDPM loop is preventing the supply from crashing.
3. The device has entered thermal regulation because the IC junction temperature has exceed TJ(REG)
During these events, the timer is slowed by half to extend the timer and prevent any false timer faults. Starting a
new charge cycle by toggling the input, toggling the CE pin to disable/enable charge, resets the safety timer.
Additionally, thermal shutdown events cause the safety timer to reset.
LDO Output (DRV)
The bq24278 contains a linear regulator (DRV) that is used to supply the internal MOSFET drivers and other
circuitry. Additionally, DRV supplies up to 10mA external loads to power the STAT LED or other external circuitry.
The LDO is on whenever a supply is connected to the input of the. The DRV is disabled under the following
conditions:
1. VIN < UVLO
2. VIN < VBAT + VSLP
3. Thermal Shutdown
External NTC Monitoring (TS)
The I2C interface allows the user to easily implement the JEITA standard for systems where the battery pack
thermistor is monitored by the host. Additionally, the bq24278 provides a flexible, voltage-based TS input for
monitoring the battery pack NTC thermistor, Figure 4. The voltage at TS is monitored to determine that the
battery is at a safe temperature during charging. The bq24278 enables the user to easily implement the JEITA
standard for charging temperature. The JEITA specification is shown in Figure 5.
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VDRV
DISABLE
TS COLD
+
VDRV
TS HOT
RHI
+
TS
PACK +
TEMP
bq24278
RLO
PACK -
Figure 4. TS Circuit
1.0 °C
0.5 °C
Portion of spec not covered by TS
Implementation on bq 24278
4.25 V
4.15 V
4.1 V
T1
(0°C)
T2
(10°C)
T3
T4
(45°C) (50°C)
T5
(60°C)
Figure 5. Charge Current During TS Conditions
To satisfy the JEITA requirements, four temperature thresholds are monitored; the cold battery threshold; the
cold battery threshold (TNTC < 0°C), the cool battery threshold (0°C < TNTC < 10°C), the warm battery threshold
(45°C < TNTC < 60°C) and the hot battery threshold (TNTC > 60°C). These temperatures correspond to the VCOLD,
VCOOL, VWARM, and VHOT thresholds. Charging is suspended and timers are suspended when VTS < VHOT or VTS >
VCOLD. When VHOT < VTS < VWARM, the battery regulation voltage is reduced by 140 mV from the programmed
regulation threshold. When VCOOL < VTS < VCOLD, the charging current is reduced to half of the programmed
charge current.
The TS function is voltage based for maximum flexibility. Connect a resistor divider from DRV to GND with TS
connected to the center tap to set the threshold. The connections are shown in Figure 10. The resistor values are
calculated using the following equations:
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é 1
1 ù
VDRV ´ RCOLD ´ RHOT ´ ê
ú
V
V
ë COLD
HOT û
RLO =
éV
ù
é V
ù
RHOT ´ ê DRV - 1ú - RCOLD ´ ê DRV - 1ú
ë VHOT
û
ë VCOLD
û
(3)
VDRV
-1
VCOLD
RHI =
1
1
+
RLO RCOLD
(4)
Where:
VCOLD = 0.60 × VDRV
VHOT = 0.30 × VDRV
Where RHOT is the NTC resistance at the hot temperature and RCOLD is the NTC resistance at cold
temperature.
The WARM and COOL thresholds are not independently programmable. The COOL and WARM NTC
resistances for a selected resistor divider are calculated using the following equations:
RLO ´ 0.564 ´ RHI
RCOOL =
RLO - RLO ´ 0.564 - RHI´ 0.564
(5)
RLO ´ 0.383 ´ RHI
RWARM =
RLO - RLO ´ 0.383 - RHI ´ 0.383
(6)
Thermal Regulation and Protection
During the charging process, to prevent the IC from overheating, bq24278 monitor the junction temperature, TJ,
of the die and begins to taper down the charge current once TJ reaches the thermal regulation threshold, TCF.
The charge current is reduced to zero when the junction temperature increases about 10°C above TCF. Once
the charge current is reduced, the system current is reduced while the battery supplements the load to supply the
system. This may cause a thermal shutdown of the bq24278 if the die temperature rises too high. At any state, if
TJ exceeds TSHTDWN, bq24278 suspends charging and disables the buck converter. During thermal shutdown
mode, PWM is turned off, and the timer is reset. The charging cycle resets when TJ falls below TSHTDWN by
approximately 10°C.
Input Voltage Protection in Charge Mode
Sleep Mode
The bq24278 enters the low-power sleep mode if the voltage on VIN falls below sleep-mode entry threshold,
VBAT+VSLP, and VVBUS is higher than the undervoltage lockout threshold, VUVLO. This feature prevents draining
the battery during the absence of VIN. When VIN < VBAT+ VSLP, the bq24278 turns off the PWM converter, and
turns the battery FET and BGATE on. Once VIN > VBAT+ VSLP, the device initiates a new charge cycle.
Input Voltage Based DPM
During normal charging process, if the input power source is not able to support the programmed or default
charging current, the supply voltage decreases. Once the supply drops to VIN_DPM (set by VDPM), the input
current limit is reduced down to prevent the further drop of the supply. This feature ensures IC compatibility with
adapters with different current capabilities without a hardware change. Figure 6 shows the VIN-DPM behavior to a
current limited source. In this figure the input source has a 750mA current limit and the charging is set to 750mA.
The SYS load is then increased to 1.2A.
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Figure 6. bq24278 VIN-DPM
The VINDPM threshold for the IN input is set using a resistor divider with VDPM connected to the center tap.
Select 10kΩ for the bottom resistor. The top resistor is selected using Equation 7:
RTOP =
10kW ´ ( VINDPM - VDPM )
VDPM
(7)
Where VINDPM is the desired VINDPM threshold and VDPM is the regulation threshold specified in the Electrical
Characteristics table.
Bad Source Detection
When a source is connected to IN, the bq24278 runs a Bad Source Detection procedure to determine if the
source is strong enough to provide some current to charge the battery. A current sink is turned on (70mA) for
32ms. If the source is valid after the 32ms (VBADSOURCE < VIN < VOVP), the buck converter starts up and normal
operation continues. If the supply voltage falls below VBAD_SOURCE during the detection, the current sink shuts off
for 2s and then retries. The detection circuits retries continuously until a valid source is detected after the
detection time. If during normal operation the source falls to VBAD_SOURCE, the bq24278 turns off the PWM
converter, turns the battery FET on and runs the bad source detection. Once a good source is detected, the
device returns to normal operation.
Input Over-Voltage Protection
The bq24278 provides over-voltage protection on the input that protects downstream circuitry. The built-in input
over-voltage protection to protect the device and other components against damage from overvoltage on the
input supply (Voltage from VIN to PGND). When VIN > VOVP, the bq24278 turns off the PWM converter, suspends
the charging cycle and turns the battery FET on. Once the OVP fault is removed, the device returns to the
operation it was in prior to the OVP fault.
Status Indicators (CHG, PG)
The bq24278 contains two open-drain outputs that signal its status. The PG output indicates that a valid input
source is connected to IN. PG is low when (VBAT+VSLP) < VIN < VOVP. When there is no supply connected to the
input within this range, PG is high impedance. Table 1 illustrates the PG behavior under different conditions.
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The CHG output indicates new charge cycles. When a new charge cycle is initiated by CE, toggling High
Impedance mode or toggling the input power, CHG goes low and remains low until termination. After termination,
CHG remains high impedance until a new charge cycle is initiated. CHG does not go low during recharge cycles.
Table 2 illustrates the CHG behavior under different conditions.
Connect PG and CHG to the DRV output through an LED for visual indication, or connect through a 100kΩ
pullup to the required logic rail for host indication.
Table 1. PG Status Indicator
CHARGE STATE
PG BEHAVIOR
VIN < VUVLO
High-Impedance
VIN < (VBAT+VSLP)
High-Impedance
(VBAT+VSLP) < VIN < VOVP
VIN > VOVP
Low
High-Impedance
Table 2. CHG Status Indicator
CHARGE STATE
CHG BEHAVIOR
Charge in progress
Low (first charge cycle)
High-Impedance (recharge cycles)
Charging suspended by thermal loop
Charge Done
Recharge Cycle after Termination
Timer Fault
High-Impedance
No Valid Supply, VIN>VOVP or VIN < VSLEEP
No Battery Present
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APPLICATION INFORMATION
Output Inductor and Capacitor Selection Guidelines
When selecting an inductor, several attributes must be examined to find the right part for the application. First,
the inductance value should be selected. The bq24278 is designed to work with 1.5µH to 2.2µH inductors. The
chosen value will have an effect on efficiency and package size. Due to the smaller current ripple, some
efficiency gain is reached using the 2.2µH inductor, however, due to the physical size of the inductor, this may
not be a viable option. The 1.5µH inductor provides a good tradeoff between size and efficiency.
Once the inductance has been selected, the peak current must be calculated in order to choose the current
rating of the inductor. Use Equation 8 to calculate the peak current.
æ %
ö
IPEAK = ILOAD(MAX) ´ ç 1 + RIPPPLE ÷
2
è
ø
(8)
The inductor selected must have a saturation current rating less than or equal to the calculated IPEAK. Due to the
high currents possible with the bq24278, a thermal analysis must also be done for the inductor. Many inductors
have 40°C temperature rise rating. This is the DC current that will cause a 40°C temperature rise above the
ambient temperature in the inductor. For this analysis, the typical load current may be used adjusted for the duty
cycle of the load transients. For example, if the application requires a 1.5A DC load with peaks at 2.5A 20% of
the time, a Δ40°C temperature rise current must be greater than 1.7A:
ITEMPRISE = ILOAD + D ×)IPEAK – ILOAD) = 1.5 A + 0.2 × (2.5 A – 1.5 A) = 1.7 A
(9)
The bq24278 provides internal loop compensation. Using this scheme, the bq24278 is stable with 10µF to 200µF
of local capacitance. The capacitance on the SYS rail can be higher if distributed amongst the rail. To reduce the
output voltage ripple, a ceramic capacitor with the capacitance between 10µF and 47µF is recommended for
local bypass to SYS.
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PCB Layout Guidelines
It is important to pay special attention to the PCB layout. Figure 7 provides a sample layout for the high current
paths of the bq24278.
GND
PMID
BYP
BOOT
SW
PGND
ILIM
ISET
SYS
SYS
BAT
(RGE Package)
Figure 7. Recommended bq24278 PCB Layout for RGE Device
IN
PMID
GND
SW
SW
PGND
BOOT
ILIM
SYS
BAT
ISET
PGND
SW
SYS
(YFF Package)
Figure 8. Recommended bq24278 PCB Layout for YFF Device
The following provides some guidelines:
• To obtain optimal performance, the power input capacitors, connected from the PMID input to PGND, must be
placed as close as possible to the bq24278
• Place 4.7µF input capacitor as close to PMID pin and PGND pin as possible to make high frequency current
loop area as small as possible. Place 1µF input capacitor GNDs as close to the respective PMID cap GND
and PGND pins as possible to minimize the ground difference between the input and PMID.
• The local bypass capacitor from SYS to GND should be connected between the SYS pin and PGND of the
IC. The intent is to minimize the current path loop area from the SW pin through the LC filter and back to the
PGND pin.
• Place ISET resistor very close to the ISET pin.
• Place ILIM resistor very close to the ILIIM pin.
• Place all decoupling capacitor close to their respective IC pin and as close as to PGND (do not place
components such that routing interrupts power stage currents). All small control signals should be routed
away from the high current paths.
• The PCB should have a ground plane (return) connected directly to the return of all components through vias
(two vias per capacitor for power-stage capacitors, one via per capacitor for small-signal components). It is
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•
SLUSB04 – JUNE 2012
also recommended to put vias inside the PGND pads for the IC, if possible. A star ground design approach is
typically used to keep circuit block currents isolated (high-power/low-power small-signal) which reduces noisecoupling and ground-bounce issues. A single ground plane for this design gives good results. With this small
layout and a single ground plane, there is no ground-bounce issue, and having the components segregated
minimizes coupling between signals.
The high-current charge paths into IN, BAT, SYS and from the SW pins must be sized appropriately for the
maximum charge current in order to avoid voltage drops in these traces. The PGND pins should be
connected to the ground plane to return current through the internal low-side FET.
For high-current applications, the balls for the power paths should be connected to as much copper in the
board as possible. This allows better thermal performance as the board pulls heat away from the IC.
PACKAGE SUMMARY
1
2
3
4
5
6
7
A
IN
IN
IN
IN
GND
GND
GND
B
PMID
PMID
PMID
PMID
BYP
BYP
BYP
C
SW
SW
SW
SW
SW
SW
SW
D
PGN
D
PGN
D
PGN
D
PGN
D
PGN
D
PGN
D
PGN
D
E
ILIM
CD
VDP
M
/CE
DRV_
S
DRV_
S
BOO
T
SYS
SYS
SYS
SYS
BGATE
/PG
DRV
BAT
BAT
BAT
BAT
TS
/CHG
ISET
TI YMLLLLS
bq24278
D
F
G
E
0-Pin A 1 Marker, TI-TI Letters, YM- Year Month Date Code ,
LLLL-Lot Trace Code , S-Assembly Site Code
CHIP SCALE PACKAGING DIMENSIONS
The bq 2427x devices are available in a 49-bump chip scale package (YFF, NanoFree TM). The package dimensions are :
D – 2.78mm ± 0.05mm
E – 2.78mm ± 0.05mm
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PACKAGE OPTION ADDENDUM
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17-Jul-2012
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package
Drawing
Pins
Package Qty
Eco Plan
(2)
Lead/
Ball Finish
MSL Peak Temp
(3)
Samples
(Requires Login)
BQ24278RGER
ACTIVE
VQFN
RGE
24
3000
Green (RoHS
& no Sb/Br)
CU NIPDAU Level-2-260C-1 YEAR
BQ24278RGET
ACTIVE
VQFN
RGE
24
250
Green (RoHS
& no Sb/Br)
CU NIPDAU Level-2-260C-1 YEAR
BQ24278YFFR
ACTIVE
DSBGA
YFF
49
3000
Green (RoHS
& no Sb/Br)
SNAGCU
Level-1-260C-UNLIM
BQ24278YFFT
ACTIVE
DSBGA
YFF
49
250
Green (RoHS
& no Sb/Br)
SNAGCU
Level-1-260C-UNLIM
(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.
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Addendum-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
17-Jul-2012
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
BQ24278RGER
Package Package Pins
Type Drawing
VQFN
RGE
24
BQ24278RGET
VQFN
RGE
BQ24278YFFR
DSBGA
YFF
BQ24278YFFT
DSBGA
YFF
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
B0
(mm)
K0
(mm)
P1
(mm)
W
Pin1
(mm) Quadrant
3000
330.0
12.4
4.25
4.25
1.15
8.0
12.0
Q2
24
250
180.0
12.4
4.25
4.25
1.15
8.0
12.0
Q2
49
3000
180.0
8.4
2.93
2.93
0.81
4.0
8.0
Q1
49
250
180.0
8.4
2.93
2.93
0.81
4.0
8.0
Q1
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
17-Jul-2012
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
BQ24278RGER
VQFN
RGE
24
3000
367.0
367.0
35.0
BQ24278RGET
VQFN
RGE
24
250
210.0
185.0
35.0
BQ24278YFFR
DSBGA
YFF
49
3000
210.0
185.0
35.0
BQ24278YFFT
DSBGA
YFF
49
250
210.0
185.0
35.0
Pack Materials-Page 2
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