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Trademarks
1
SLUU396A – January 2010 – Revised July 2010
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Copyright © 2010, Texas Instruments Incorporated
User's Guide
SLUU396A – January 2010 – Revised July 2010
bq2461x/bq2463x EVM (HPA422) Multi-Cell Synchronous
Switch-Mode Charger
2
3
4
5
6
7
Contents
Introduction ................................................................................................................... 3
2.1
EVM Features ....................................................................................................... 3
2.2
General Description ................................................................................................ 3
2.3
I/O Description ...................................................................................................... 3
2.4
1.4 Controls and Key Parameters Setting ....................................................................... 4
2.5
Recommended Operating Conditions ............................................................................ 4
Test Summary ................................................................................................................ 5
3.1
Definitions ............................................................................................................ 5
3.2
Equipment ........................................................................................................... 5
3.3
Equipment Setup.................................................................................................... 6
3.4
Procedure ............................................................................................................ 7
PCB Layout Guideline ....................................................................................................... 9
Bill of Materials, Board Layout and Schematics ........................................................................ 11
5.1
Bill of Materials .................................................................................................... 11
Board Layout ................................................................................................................ 14
Schematics .................................................................................................................. 22
List of Figures
10
............................................................ 6
Top Layer ................................................................................................................... 14
2nd Layer ..................................................................................................................... 15
3rd Layer ..................................................................................................................... 16
Bottom Layer................................................................................................................ 17
Top Assembly............................................................................................................... 18
Bottom Assembly ........................................................................................................... 19
Top Silkscreen .............................................................................................................. 20
Bottom Silkscreen .......................................................................................................... 21
bq2461x/bq2463x EVM Schematic ...................................................................................... 22
1
I/O Description ............................................................................................................... 3
2
Controls and Key Parameters Setting
3
Recommended Operating Conditions ..................................................................................... 4
4
Bill of Materials
1
2
3
4
5
6
7
8
9
Original Test Setup for HPA422 (bq2461x/bq2463x EVM)
List of Tables
2
....................................................................................
.............................................................................................................
bq2461x/bq2463x EVM (HPA422) Multi-Cell Synchronous Switch-Mode
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Introduction
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2
Introduction
2.1
EVM Features
•
•
•
•
•
•
•
2.2
Evaluation Module For bq2461x/bq2463x
High Efficiency Synchronous Buck Charger
User-programmable up to 26V Battery Voltage
AC Adapter Operating Range 5 V–28 V
LED Indication for Control and Status Signals.
Test Points for Key Signals Available for Testing Purpose. Easy Probe Hook-up.
Jumpers Available. Easy to Change Connections.
General Description
The bq2461x is highly integrated Li-ion or Li-polymer switch-mode battery charge controllers. The
bq2463x is highly integrated switch-mode battery charge controllers designed specifically to charge
Lithium Phosphate battery chemistries.
They offer a constant-frequency synchronous PWM controller with high accuracy charge current and
voltage regulation, adapter current regulation, termination, charge preconditioning, and charge status
monitoring,
The bq2461x/bq2463x charges the battery in three phases: preconditioning, constant current, and
constant voltage. Charge is terminated when the current reches a minimum user-selectable level. A
programmable charge timer provides a safety backup for charge termination. The bq2461x/bq2463x
automatically restarts the charge cycle if the battery voltage falls below an internal threshold, and enters a
low-quiescent current sleep mode when the input voltage falls below the battery voltage.
The dynamic power management (DPM) function modifies the charge current depending on system load
conditions, avoiding ac adapter overload.
High accuracy current sense amplifiers enable accurate measurement of the ac adapter current, allowing
monitoring of overall system power.
For details, see bq24610 and bq24617 (SLUS892), bq24616 (SLUSA49) and bq2463x (SLUS894) data
sheets. Project collateral discussed in this document can be downloaded from the following URL:
http://www.ti.com/lit/zip/SLUU396.
2.3
I/O Description
Table 1. I/O Description
Jack
Description
J1–DCIN
AC adapter, positive output
J1–GND
AC adapter, negative output
J2–VEXT
External power supply, positive output
J2–GND
External power supply, negative output
J2–TTC
Timer capacitor pin
J3–ACSET
Input current program pin
J3–ISET1
Charge Current Program Pin
J3–ISET2
Pre-charge/Termination program pin
J3–GND
Ground
J–PG
Power Good (active low)
J4–CHGEN
Charge enable
J4–VREF
IC reference voltage VREF
J4–TS
Temperature Qualification Voltage Input
J5–VSYS
Connected to system
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Introduction
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Table 1. I/O Description (continued)
2.4
Jack
Description
J5–VBAT
Connected to battery pack
J5–GND
Ground
JP1–LOW
Ground
JP1–TTC
Timer capacitor pin
JP1–HI
Pull-up voltage source
JP2–HI
Pull-up voltage source
JP2–LEDPWR
LED Pull-up power line
JP3–VREF
IC reference voltage VREF
JP3–VPULLUP
Pull-up voltage source
JP3–EXT
External voltage supply from J2
JP4–VCC
Pull-up voltage source of ACDRV and BATDRV LED logic circuit
JP4–VCOM
Q7 and Q11 common source
JP5–HI
Pull-up voltage source
JP5–CHGEN
Charge enable
1.4 Controls and Key Parameters Setting
Table 2. Controls and Key Parameters Setting
2.5
Jack
Description
JP1
TTC setting
1-2 : Connect TTC to GROUND (Disable termination and the safety timer)
2-3 : Connect TTC to VPULLUP (Allow termination, but disable the safety time)
2 floating: Allow termination, CTTC sets the safety timer
Factory Setting
Jumper on 2-3 (TTC and VPULLUP)
JP2
The pull-up power source supplies the LEDs when on.
LED has no power source when off.
Jumper On
JP3
VPULLUP setting
1-2 : Connect VPULLUP to VREF
2-3 : Connect VPULLUP to VEXT
Jumper On 1-2 (VPULLUP and
VREF)
JP4
The pull-up voltage source of ACDRV and BATDRV LED logic circuit.
Jumper on
JP5
CHGEN setting
Jumper on: CHGEN to VPULLUP
Jumper off: CHGEN is set to low by pull down resistor.
Jumper Off
Recommended Operating Conditions
Table 3. Recommended Operating Conditions
Symbol
Description
Min
Typ
Max
Unit
5
24
24(617)
28
(610/616/63x)
V
21 (61x)
18 (63x)
Supply voltage, VIN
Input voltage from ac adapter input
Battery voltage, VBAT
Voltage applied at VBAT terminal of J5
2.1 (61x)
1.8 (63x)
Supply current, IAC
Maximum input current from ac adapter
input
0
Charge current, Ichrg
Battery charge current
2
Operating junction
temperature range, TJ
0
3
V
4.5
A
8
A
125
°C
The bq2461x/bq2463x EVM board requires a regulated supply approximately 0.5 V minimum above the
regulated voltage of the battery pack to a maximum input voltage of 28 VDC.
4
bq2461x/bq2463x EVM (HPA422) Multi-Cell Synchronous Switch-Mode
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R25 and R28 can be changed to regulate output.
VBAT = 2.1V × [1+ R25/R28]; for bq2461x;
VBAT = 1.8V × [1+ R25/R28]; for bq2463x;
Adjust the input voltage as required. Output set to operate at 21V (bq2461x) or 18V (bq2463x) from the
factory.
3
Test Summary
3.1
Definitions
This procedure details how to configure the HPA422 evaluation board. On the test procedure the following
naming conventions are followed. See the HPA422 schematic for details.
VXXX:
LOADW:
V(TPyyy):
V(Jxx):
V(TP(XXX)):
External voltage supply name (VADP, VBT, VSBT)
External load name (LOADR, LOADI)
Voltage at internal test point TPyyy. For example, V(TP12) means the voltage at TP12
Voltage at jack terminal Jxx.
Voltage at test point "XXX". For example, V(ACDET) means the voltage at the test
point which is marked as "ACDET".
V(XXX, YYY):
Voltage across point XXX and YYY.
I(JXX(YYY)):
Current going out from the YYY terminal of jack XX.
Jxx(BBB):
Terminal or pin BBB of jack xx
Jxx ON:
Internal jumper Jxx terminals are shorted
Jxx OFF:
Internal jumper Jxx terminals are open
Jxx (-YY-) ON:
Internal jumper Jxx adjacent terminals marked as "YY" are shorted
Measure:→ A,B Check specified parameters A, B. If measured values are not within specified limits the
unit under test has failed.
Observe → A,B Observe if A, B occur. If they do not occur, the unit under test has failed.
Assembly drawings have location for jumpers, test points and individual components.
3.2
3.2.1
Equipment
Power Supplies
Power Supply #1 (PS#1): a power supply capable of supplying 30-V at 5-A is required.
Power Supply #2 (PS#2): a power supply capable of supplying 5-V at 1-A is required.
Power Supply #3 (PS#3): a power supply capable of supplying 5-V at 1-A is required.
3.2.2
LOAD #1
A 30V (or above), 5A (or above) electronic load that can operate at constant current mode
3.2.3
LOAD #2
A Kepco bipolar operational power supply/amplifier, 0 ±30V (or above), 0 ±6A (or above).
3.2.4
Oscilloscope
Tektronix TDS3054 scope or equivalent, 10X voltage probe.
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Test Summary
3.2.5
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METERS
Seven Fluke 75 multimeters, (equivalent or better)
Or: Four equivalent voltage meters and three equivalent current meters.
The current meters must be capable of measuring 5A+ current
3.3
Equipment Setup
1. Set the power supply #1 for 0V ± 100mVDC, 5.0 ± 0.1A current limit and then turn off supply.
2. Connect the output of power supply #1 in series with a current meter (multimeter) to J1 (VIN, GND).
3. Connect a voltage meter across J1 (VIN, GND).
4. Set the power supply #2 for 0V ± 100mVDC, 1.0 ± 0.1A current limit and then turn off supply.
5. Connect the output of the power supply #2 to J4 and J5 (TS, GND).
6. Connect Load #1 in series with a current meter to J5 (SYS, GND). Turn off Load #1
7. Connect Load #2 in series with a current meter to J5 (BAT, GND). Turn off Load #2.
8. Connect a voltage meter across J5 (BAT, GND).
9. Connect an oscilloscope's probe across J5 (BAT, GND)
10. Connect a voltage meter across J5 (SYS, GND).
11. JP1 (TTC and HI): ON, JP2: ON, JP3 (VPULLUP and VREF): ON, JP4: ON, JP5: OFF.
After the above steps, the test setup for HPA422 is shown in Figure 1.
Power
supply #1
J1
I
Iin
bq24610/616/617/30 EVM
HPA422
PH
ACPWR
V
Isys
TP12
SYS
TP1
ACPWR
PGND
J5
I
Load
#1
I
Load
#2
V
SYS
BAT
TP2
U1
TP9
J3
V
PGND
VCC
ACSET
ISET1
JP4
ISET2
Oscilloscope
I
VBAT
APPLICATION CIRCUIT
GND
VREF
JP3
J2
VEXT
GND
TTC
Ibat
J4
VEXT
HI
L
O
PG
JP1
JP2
JP5
STAT1
VREF
TS
/ACDRV
/BATDRV
CE
PG
/STAT1
Power
sup ply #2
/STAT2
Figure 1. Original Test Setup for HPA422 (bq2461x/bq2463x EVM)
6
bq2461x/bq2463x EVM (HPA422) Multi-Cell Synchronous Switch-Mode
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3.4
Procedure
3.4.1
AC Adapter Detection Threshold
1. Make sure EQUIPMENT SETUP steps are followed. Turn on PS#2.
2. Turn on PS#1
Measure → V(J5(SYS)) = 0 ± 500mV
Measure → V(TP(VREF)) = 0V ± 1000mV
Measure → V(TP(REGN)) = 0V ± 500mV
3. Increase the output voltage on PS#1 until D5 (PG) on but do not exceed 5V. Set the power supply #2
to 1.8V ± 100mVDC
Measure → V(J1(VIN)) = 4.5V ± 0.5V
Measure → V(J5(SYS)) = 4.5V ± 0.5V
Measure → V(TP(VREF)) = 3.3V ± 200mV
Measure → V(TP(REGN)) = 0V ± 500mV
Measure → D4 (/ACDRV) on, D5 (PG) on
3.4.2
Charger Regulation Voltage
1. Increase the voltage of PS#1 until V(J1(VIN)) = 24V ± 0.1V.
Measure → V(J5(BAT, GND)) = 0V ± 1V
2. Put JP5 on (Enable the charging).
Observe → D3 (CE) on.
Measure → Peak V(J5(BAT)) = 21.0V ± 1V (bq2461x)
Measure → Peak V(J5(BAT)) = 18.0V ± 1V (bq2463x)
Measure → V(TP(REGN)) = 6V ± 500mV
3.4.3
Charge Current and AC Current Regultion (DPM)
1. Take off JP5 (Disable the charging).
2. Connect the Load #2 in series with a current meter (multimeter) to J5 (BAT, GND). Make sure a
voltage meter is connected across J5 (BAT, GND). Turn on the Load #2. Set the output voltage to 12V
(bq2461x) or 2V (bq2463x).
3. Connect the output of the Load #1 in series with a current meter (multimeter) to J5 (SYS, GND). Make
sure a voltage meter is connected across J5 (SYS, GND). Turn on the power of the Load #1. Set the
load current to 3.0A ± 50mA but disable the load #1. The setup is now like Figure 1 for HPA422. Make
sure Ibat = 0A ± 10mA and Isys = 0A ± 10mA.
4. Put JP5 on (Enable the charging).
Observe → D3 (CE) on
Measure → Ibat = 300mA ± 200mA (bq2461x)
Measure → Ibat = 125mA ± 60mA (bq2463x)
Observe → D7 (STAT1) on; D8 (STAT2) off.
5. Set the Load #2 output voltage to 16.5V.
Measure → Ibat = 3000mA ± 300mA
Observe → D7 (STAT1) on; D8 (STAT2) off.
6. Enable the output of the Load #1
Measure → Isys = 3000mA ± 200mA, Ibat = 1400mA ± 500mA, Iin = 4000mA ± 500mA
7. Turn off the Load #1.
Measure → Isys = 0 ± 100mA, Ibat = 3000mA ± 300mA.
8. Increase the Load #2 output voltage from 16.5V to 22V (61x) or 19V (63x).
Measure → Isys = 0 ± 100mA, Ibat = 0mA ± 100mA.
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Observe → D7 (STAT1) off; D8 (STAT2) on.
9. Decrease the Load #2 output voltage back to 16.5V.
Observe → D7 (STAT1) on; D8 (STAT2) off.
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PCB Layout Guideline
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3.4.4
Charger Cut-Off by Thermistor
1. Slowly increase the output voltage of PS2 until Ibat = 0 ± 10mA.
Measure → V(J4(TS)) = 2.44V ± 200mV
Observe → D7 (STAT1) off; D8 (STAT2) off.
2. Slowly decrease the output voltage of PS2 to 1.4V ± 0.1V.
Measure → V(J4(TS)) = 1.4V ± 100mV
Measure → Ibat = 3000mA ± 300mA (bq24610/617)
Measure → Ibat = 0mA ± 100mA (bq24616)
Measure → Ibat = 375mA ± 150mA (bq2463x)
Observe → D7 (STAT1) on; D8 (STAT2) off (bq24610/617/630)
Observe → D7 (STAT1) off; D8 (STAT2) off (bq24616)
3. Slowly decrease the output voltage of PS2.
Charge will resume. Continue to decrease the output voltage of PS2 slowly until Ibat = 0 ±10mA.
Measure → V(J4(TS)) = 1.14V ± 200mV
Observe → D7 (STAT1) off; D8 (STAT2) off.
4. Slowly increase the output voltage of PS2 to 1.8V ± 100mV.
Measure → Ibat = 3000mA ± 200mA
Observe → D7 (STAT1) on; D8 (STAT2) off.
3.4.5
Power Path Selection
Take off JP5 (Disable the charging)
Observe → D3 (CE) off; D7 (STAT1) off.
Set JP3 Jumper On 2-3 (VPULLUP and VEXT). Connect the output of the power supply #3 to
J2(VEXT, GND). Set the power supply #3 for 3.3V ± 200mVDC, 1.0 ± 0.1A current limit.
Set the Load #2 output voltage to 16.5V ± 500mV.
Measure → V(J5(SYS)) = 24V ± 1V (adapter connected to system)
Observe → D4 (ACDRV) on, D6 (BATDRV) off, D5 (PG) on, D7 (STAT1) off, D8 (STAT2) off.
Turn off PS#1.
Measure → V(J5(SYS)) = 16.5V ± 0.5V (battery connected to system)
Observe → D4 (ACDRV) off, D6 (BATDRV) on, D5 (PG) off, D7 (STAT1) off, D8 (STAT2) off.
Turn off power supply #2 and #3. Set JP3 on 1-2 (VPULLUP and VREF).
1.
2.
3.
4.
5.
6.
7.
8.
4
PCB Layout Guideline
1. It is critical that the exposed power pad on the backside of the bq2461x/bq2463x package be soldered
to the PCB ground. Make sure there are sufficient thermal vias right underneath the IC, connecting to
the ground plane on the other layers.
2. The control stage and the power stage should be routed separately. At each layer, the signal ground
and the power ground are connected only at the power pad.
3. AC current sense resistor must be connected to ACP and ACN with a Kelvin contact. The area of this
loop must be minimized. The decoupling capacitors for these pins should be placed as close to the IC
as possible.
4. Charge current sense resistor must be connected to SRP, SRN with a Kelvin contact. The area of this
loop must be minimized. The decoupling capacitors for these pins should be placed as close to the IC
as possible.
5. Decoupling capacitors for DCIN, VREF, VCC, REGN should make the interconnections to the IC as
short as possible.
6. Decoupling capacitors for BAT must be placed close to the corresponding IC pins and make the
interconnections to the IC as short as possible.
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PCB Layout Guideline
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7. Decoupling capacitor(s) for the charger input must be placed close to top buck FET's drain and bottom
buck FET’s source.
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5
Bill of Materials, Board Layout and Schematics
5.1
Bill of Materials
Table 4. Bill of Materials
bq24610-001
bq24617-002
Bq24630-003
bq24616-004
Value
RefDes
Description
Size
Part Number
Mfr
1
0
0
0
bq24610RGE
U1
Charger Controller IC
QFN-24 (RGE) bq24610RGE
TI
0
1
0
0
bq24617RGE
U1
Charger Controller IC
QFN-24 (RGE) bq24617RGE
TI
0
0
1
0
bq24630RGE
U1
Charger Controller IC
QFN-24 (RGE) bq24630RGE
TI
0
0
0
1
bq24616RGE
U1
Charger Controller IC
QFN-24 (RGE) bq24616RGE
TI
1
1
1
1
0.1uF
C3
Capacitor, Ceramic, 16V, X7R, 5%,
603
STD
STD
6
6
6
6
0.1uF
C7,C8,C13,C1 Capacitor, Ceramic, 16V, X7R, 10%
8,C19,C33
603
STD
STD
6
6
6
6
0.1uF
C4,C5,C16,C1 Capacitor, Ceramic, 50V, X7R, 10%
7,C24,C26
603
STD
STD
1
1
1
1
22p
C22
0
0
0
0
3
3
3
3
0
0
0
0
2
2
2
2
1
1
1
1
0
0
0
0
6
6
6
6
0
0
0
0
0
0
0
0
0
0
6
Capacitor, Ceramic, 50V, X7R, 10%
603
STD
STD
C9,C21,C30,C Capacitor, Ceramic, 50V, X7R, 10%
31
603
STD
STD
C1,C6,C15
Capacitor, Ceramic, 16V, X7R, 20%
805
STD
STD
C34
Capacitor, Ceramic, 50V, X7R, 10%
805
STD
STD
1.0uF/50V
C12,C14
Capacitor, Ceramic, 50V, X5R, 20%
1206
STD
STD
2.2uF/50V
C2
Capacitor, Ceramic, 50V, X7R, 20%
1206
STD
STD
C32
Capacitor, Ceramic, 50V, X7R, 20%
1206
STD
STD
C10,C11,C20,
C23,C28,C29
Capacitor, Ceramic, 50V, Y5V,
-20/+80%
1812
STD
STD
0
C25,C27
Capacitor, Ceramic, 50V, X5R, 20%
1812
STD
STD
0
D11
Diode, Zener, 7.5V, 350-mW
SOT-23
BZX84C7V5
Diodes
0
0
D10
Diode, Schottky, 200-mA, 30-V
SOT23
BAT54
Vishay-Liteon
0
0
D9
Diode, Zener, 7.5V, 350-mW
SOT-23
BZX84C7V5
Diodes
6
6
6
D3,D4,D5,D6,
D7,D8
Diode, LED, Green, 2.1V, 20mA, 6mcd 603
LTSTC190GKT
Lite On
0
0
0
0
D2
Diode, Schottky, 1A, 40V
DO-214AA
MBRS140
Fairchild
1
1
1
1
ZLLS350
D1
Diode, Schottky, 1.16A, 40-V
SOD-523
ZLLS350
Zetex
1
1
0
1
6.8uH
L1
Inductor, SMT, 9A, 19.8milliohm
0.520 sq inch
IHLP5050CEE Vishay
R6R8M01
0
0
1
0
8.2uH
L1
Inductor, SMT, 9.5A, 18.3milliohm
0.520 sq inch
IHLP5050CEE Vishay
R8R2M01
3
3
3
3
PEC02SAAN
JP2,JP4,JP5
Header, 2 pin, 100mil spacing,
0.100 inch x 2
PEC02SAAN
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1.0uF
10uF/50V
Green
Sullins
bq2461x/bq2463x EVM (HPA422) Multi-Cell Synchronous Switch-Mode Charger
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Bill of Materials, Board Layout and Schematics
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Table 4. Bill of Materials (continued)
bq24610-001
bq24617-002
Bq24630-003
bq24616-004
Value
RefDes
Description
Size
Part Number
Mfr
2
2
2
2
PEC03SAAN
JP1,JP3
Header, 3 pin, 100mil spacing,
0.100 inch x 3
PEC03SAAN
Sullins
4
4
4
4
0
R10,R19,R26,
R13
Resistor, Chip, 1/16W, 1%
402
Std
Std
1
1
1
1
10
R22
Resistor, Chip, 1/4W, 1%
1206
Std
Std
1
1
0
0
9.31k
R4
Resistor, Chip, 1/16W, 1%
402
Std
Std
0
0
1
1
2.2k
R4
Resistor, Chip, 1/16W, 1%
402
Std
Std
3
3
3
3
1k
R21,R24,R27
Resistor, Chip, 1/16W, 1%
402
Std
Std
1
1
1
1
100
R8
Resistor, Chip, 1/16W, 1%
402
Std
Std
1
1
0
0
430k
R5
Resistor, Chip, 1/16W, 1%
402
Std
Std
0
0
1
1
6.8k
R5
Resistor, Chip, 1/16W, 1%
402
Std
Std
1
1
1
1
0
R17
Resistor, Chip, 1/16W, 1%
603
Std
Std
6
6
6
6
2.21k
R31,R34,R35,
R36,R39,R40
Resistor, Chip, 1/16W, 1%
603
Std
Std
1
1
1
1
10
R14
Resistor, Chip, 1/16W, 1%
603
Std
Std
2
2
2
2
10k
R29,R30
Resistor, Chip, 1/16W, 1%
603
Std
Std
6
6
6
6
100k
R3,
R20,R32,R33,
R37,R38
Resistor, Chip, 1/16W, 1%
603
Std
Std
1
1
1
1
10k
R16
Resistor, Chip, 1/10W, 1%
805
Std
Std
1
1
1
1
100k
R15
Resistor, Chip, 1/10W, 1%
805
Std
Std
1
1
1
1
22.1k
R12
Resistor, Chip, 1/10W, 1%
805
Std
Std
1
1
1
1
32.4k
R7
Resistor, Chip, 1/10W, 1%
805
Std
Std
4
4
4
4
100k
R6,R11,R23,R Resistor, Chip, 1/10W, 1%
28
805
Std
Std
1
1
1
1
909k
R25
Resistor, Chip, 1/10W, 1%
805
Std
Std
2
2
2
2
3.9
R1,R2
Resistor, Chip, 1/8W, 5%
1206
Std
Std
2
2
2
2
0.01
R9,R18
Resistor, Chip, 1/2W, 1%
2010
WSL2010R01
00FEA
Vishay
1
1
1
1
ED1515
J2
Terminal Block, 3 pin, 6A, 3.5mm
0.41 x 0.25
inch
ED555\3DS
OST
2
2
2
2
ED1516
J3,J4
Terminal Block, 4 pin, 6A, 3.5mm
0.55 x 0.25
inch
ED555\4DS
OST
1
1
1
1
ED120/2DS
J1
Terminal Block, 2 pin, 15A, 5.1mm
0.40 x 0.35
inch
ED120/2DS
OST
1
1
1
1
ED120/4DS
J5
Terminal Block, 4 pin, 15A, 5.1mm
0.80 x 0.35
inch
ED120/4DS
OST
12
bq2461x/bq2463x EVM (HPA422) Multi-Cell Synchronous Switch-Mode Charger
Copyright © 2010, Texas Instruments Incorporated
SLUU396A – January 2010 – Revised July 2010
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Bill of Materials, Board Layout and Schematics
www.ti.com
Table 4. Bill of Materials (continued)
bq24610-001
bq24617-002
Bq24630-003
bq24616-004
Value
RefDes
Description
Size
Part Number
Mfr
1
1
1
1
5001
GND
Test Point, Black, Thru Hole Color
Keyed
0.100 x 0.100
inch
5001
Keystone
14
14
14
14
5002
/ACDRV,/BAT Test Point, White, Thru Hole Color
DRV,/PG,
Keyed
ACSET,CHGE
N,ISET1,ISET
2, REGN,
STAT1,STAT2
,TS,TTC,
VCC,VREF
0.100 x 0.100
inch
5002
Keystone
5
5
5
5
131-4244-00
TP1,TP2,TP8,
TP9,TP12
Adaptor, 3.5-mm probe clip ( or 1315031-00)
0.200 inch
131-4244-00
Tektronix
3
3
3
3
2N7002DICT
Q6,Q8,Q9
MOSFET, N-ch, 60V, 115mA,
1.2Ohms
SOT23
2N7002DICT
Vishay-Liteon
3
3
3
3
SI4401BDYT1-GE
FDS4141
Q1,Q2,Q5
(Note 5)
MOSFET, PChan, -40V, -18A,
9.2millohm
S0-8
SI4401BDY
FDS4141
VishaySiliconxi
Fairchild
2
2
2
2
FDS8447
Q3,Q4
MOSFET, NChan, 40V, 50A, 4.5
millohm
S0-8
FDS8447
VishaySiliconix
2
2
2
2
TP0610K
Q7,Q10
Mosfet, P-Ch, 60V, Rds 6 ohms, Id
185 mA
SOT-23
TP0610K
VishaySiliconix
1
1
1
1
PCB
4 layer 2oz. PCB
HPA422
5
5
5
5
Shorting jumpers, 2-pin, 100mil
spacing
929950-00
3M/ESD
4
4
4
4
STANDOFF M/F HEX 6-32 NYL .500"
4816
Keystone
4
4
4
4
6-32 NYL Hex nuts
NY HN 632
Building
Fasteners
SLUU396A – January 2010 – Revised July 2010
Submit Documentation Feedback
929950-00
bq2461x/bq2463x EVM (HPA422) Multi-Cell Synchronous Switch-Mode Charger
Copyright © 2010, Texas Instruments Incorporated
13
Board Layout
6
www.ti.com
Board Layout
Figure 2. Top Layer
14
bq2461x/bq2463x EVM (HPA422) Multi-Cell Synchronous Switch-Mode
Charger
Copyright © 2010, Texas Instruments Incorporated
SLUU396A – January 2010 – Revised July 2010
Submit Documentation Feedback
Board Layout
www.ti.com
Figure 3. 2nd Layer
SLUU396A – January 2010 – Revised July 2010
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bq2461x/bq2463x EVM (HPA422) Multi-Cell Synchronous Switch-Mode
Charger
Copyright © 2010, Texas Instruments Incorporated
15
Board Layout
www.ti.com
Figure 4. 3rd Layer
16
bq2461x/bq2463x EVM (HPA422) Multi-Cell Synchronous Switch-Mode
Charger
Copyright © 2010, Texas Instruments Incorporated
SLUU396A – January 2010 – Revised July 2010
Submit Documentation Feedback
Board Layout
www.ti.com
Figure 5. Bottom Layer
SLUU396A – January 2010 – Revised July 2010
Submit Documentation Feedback
bq2461x/bq2463x EVM (HPA422) Multi-Cell Synchronous Switch-Mode
Charger
Copyright © 2010, Texas Instruments Incorporated
17
Board Layout
www.ti.com
Figure 6. Top Assembly
18
bq2461x/bq2463x EVM (HPA422) Multi-Cell Synchronous Switch-Mode
Charger
Copyright © 2010, Texas Instruments Incorporated
SLUU396A – January 2010 – Revised July 2010
Submit Documentation Feedback
Board Layout
www.ti.com
Figure 7. Bottom Assembly
SLUU396A – January 2010 – Revised July 2010
Submit Documentation Feedback
bq2461x/bq2463x EVM (HPA422) Multi-Cell Synchronous Switch-Mode
Charger
Copyright © 2010, Texas Instruments Incorporated
19
Board Layout
www.ti.com
Figure 8. Top Silkscreen
20
bq2461x/bq2463x EVM (HPA422) Multi-Cell Synchronous Switch-Mode
Charger
Copyright © 2010, Texas Instruments Incorporated
SLUU396A – January 2010 – Revised July 2010
Submit Documentation Feedback
Board Layout
www.ti.com
Figure 9. Bottom Silkscreen
SLUU396A – January 2010 – Revised July 2010
Submit Documentation Feedback
bq2461x/bq2463x EVM (HPA422) Multi-Cell Synchronous Switch-Mode
Charger
Copyright © 2010, Texas Instruments Incorporated
21
Schematics
7
www.ti.com
Schematics
Figure 10. bq2461x/bq2463x EVM Schematic
22
bq2461x/bq2463x EVM (HPA422) Multi-Cell Synchronous Switch-Mode
Charger
Copyright © 2010, Texas Instruments Incorporated
SLUU396A – January 2010 – Revised July 2010
Submit Documentation Feedback
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