Texas Instruments BQ24083 Evaluation Module BQ24083EVM BQ24083EVM 데이터 시트
제품 코드
BQ24083EVM
2.2
Test Procedures
P
MAX
= V
- V
x I
(DC+)
(BAT+)
(CHG)
(
)
(1)
I
O(CHG)
0.7 A
10
10
= 70 mA
=
(2)
2.3
Alternative Test Procedure
Test Summary
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Table 2. I/O and Jumper Connections
JACK
CONNECTION
J1-DC+
Power supply positive connection, preset to 5 Vdc, 1-A current limit.
J1-DC-
Power supply return connection, ground
J2-BAT+
Positive battery pack terminal
J2-BAT–
Negative battery pack terminal, BAT- is common with DC-
JMP1-STAT1
JMP1-2 STAT1 signal. Place shunt on JMP1 for LED, indication.
JMP2-STAT2
JMP2-2 STAT2 signal. Place shunt on JMP2 for LED indication.
JMP3-PG
JMP3-2 PG signal. Place shunt on JMP3 for LED indiction.
JMP4-CE
Charge Enable-active low. Place shunt on JMP4 to pull CE Hi. Remove shunt for CE = Low
JMP5-VBSEL
JMP5-2 VBSEL signal. Place shunt on JMP5 to change output regulation from 4.2 V to 4.1 V.
Set up the evaluation board as previously described by making the necessary I/O connections and jumper
selections. Prior to test and evaluation, it is important to verify that the maximum power dissipation on the
device is not exceeded: P
selections. Prior to test and evaluation, it is important to verify that the maximum power dissipation on the
device is not exceeded: P
MAX
= 1.5 W.
1. Turn on the power supply, which is preset to 5 Vdc, and 1 A for the current limit setting.
2. The bq24083 enters preconditioning mode if the battery is below the V
2. The bq24083 enters preconditioning mode if the battery is below the V
(LOWV)
threshold. In this mode,
the bq24083 precharges the battery with a low current, typically
until the battery voltage reaches the V(LOWV) threshold or until the precharge timer expires. If the
timer expires, then the charge current is terminated and the bq24083 enters fault mode. Both LEDs
turn off when in fault mode. Toggling input power or battery replacement resets fault mode. Note that
the several fault conditions that can occur are described in the data sheet (
timer expires, then the charge current is terminated and the bq24083 enters fault mode. Both LEDs
turn off when in fault mode. Toggling input power or battery replacement resets fault mode. Note that
the several fault conditions that can occur are described in the data sheet (
).
3. Once the battery voltage is above the V
(LOWV)
threshold, the battery enters fast-charge mode. This
EVM is programmed for 0.7 A of fast-charging current.
4. Once the battery reaches voltage regulation (4.2 V or 4.1 V with JMP5 shunt applied), the current
tapers down as the battery reaches its full capacity.
5. When the current reaches the taper termination threshold, the charge current terminates.
6. After termination, if the battery discharges down to the recharge threshold, the charger starts fast
6. After termination, if the battery discharges down to the recharge threshold, the charger starts fast
charging.
7. The procedure can be repeated with the JMP5 shunt applied for a regulation of 4.1 V.
The alternative methods of testing the EVM without a battery include:
•
Four Quadrant Power Supply (Sinks or Source Current)
•
Large Capacitor
•
Dynamic Load Board
The output of the battery charger delivers varying amounts of power depending on the output voltage and
load impedance. For this reason, it is difficult to test the different charge phases without a battery (using
just resistors). A load resistor is required to keep the output in precharge after power up. If increased in
resistance to allow the output to enter constant current fast-charge, the output voltage would quickly
transition through the constant current phase into voltage regulation and then terminate. Applying a load to
pull the output into fast charge would discharge the output to precharge before the refresh deglitch allows
a recharge, Therefore, it is necessary to use an active load or a small battery as a load (i.e., large
capacitor) that can be charged and discharged fairly quickly for timely evaluations.
load impedance. For this reason, it is difficult to test the different charge phases without a battery (using
just resistors). A load resistor is required to keep the output in precharge after power up. If increased in
resistance to allow the output to enter constant current fast-charge, the output voltage would quickly
transition through the constant current phase into voltage regulation and then terminate. Applying a load to
pull the output into fast charge would discharge the output to precharge before the refresh deglitch allows
a recharge, Therefore, it is necessary to use an active load or a small battery as a load (i.e., large
capacitor) that can be charged and discharged fairly quickly for timely evaluations.
2
bq24083 1-A, Single-Cell Li-Ion and Li-Polymer Charge Management IC EVM
SLUU315 – June 2008