Texas Instruments BQ24071 Evaluation Module BQ24064EVM-005 BQ24064EVM-005 Scheda Tecnica
Codici prodotto
BQ24064EVM-005
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2.1.1
EQUIPMENT
+
2.1.2
EQUIPMENT SETUP
2.1.3
PROCEDURE
Test Summary
Note:
Because of the battery detection circuit, it is difficult to test the different charge phases
without a battery (using just resistors); the algorithm sinks and sources current and
applies precharge and fast-charge current depending on the mode it is in. Applying a load
that would keep the voltage at 3.5 V (3.5 V/0.7 A) would pull the output into precharge
mode and keep it there during the battery detection algorithm, which always occurs when
the output is discharged to the refresh threshold. Once in precharge mode, a load
sufficient to allow the capacitor to charge to V
without a battery (using just resistors); the algorithm sinks and sources current and
applies precharge and fast-charge current depending on the mode it is in. Applying a load
that would keep the voltage at 3.5 V (3.5 V/0.7 A) would pull the output into precharge
mode and keep it there during the battery detection algorithm, which always occurs when
the output is discharged to the refresh threshold. Once in precharge mode, a load
sufficient to allow the capacitor to charge to V
(lowV)
would allow the output to jump to
voltage regulation once the 0.7-A fast charge function activated.
In place of a battery, a source meter that can sink current can easily be adjusted to test
each mode.
each mode.
To briefly see each mode on a scope, connect a 1-mF capacitor in parallel with a 20-k
Ω
resistor on the output in place of a battery to observe the power up and cycling between
voltage regulation and fast charge via the refresh threshold.
voltage regulation and fast charge via the refresh threshold.
This is an alternative way of testing the EVM using a dynamic load board in place of a battery. The circuit
is adjusted to work with the displayed parts and their inherent thresholds. The sequence of the test
procedure is important due to the active battery detection circuit, refresh feature, precharge, and
fast-charge current levels (switching the load in and out in different modes has different results). No
damage should occur, but one might get different results than anticipated if the procedure is altered.
is adjusted to work with the displayed parts and their inherent thresholds. The sequence of the test
procedure is important due to the active battery detection circuit, refresh feature, precharge, and
fast-charge current levels (switching the load in and out in different modes has different results). No
damage should occur, but one might get different results than anticipated if the procedure is altered.
1. Power Source: Current-limited 5-V laboratory power supply with its current limit set to 1 A
±
0.1 A
2. Two Fluke 75 digital multimeters, equivalent or better
3. Oscilloscope – TDS220 or better
4. Load test board:
3. Oscilloscope – TDS220 or better
4. Load test board:
1. Connect the load board to the BAT+ and BAT–. Set SW1 through SW4 in the closed position.
2. Connect a voltage meter to the BAT+/BAT– output to monitor the output voltage. (The range is 0 V to
2. Connect a voltage meter to the BAT+/BAT– output to monitor the output voltage. (The range is 0 V to
5 V.)
3. Set the laboratory power supply for 5.1 V
±
0.1 VDC, 1-A
±
0.1-A current limit and then turn off this
supply. Connect the source supply to a current meter and to J1, noting polarity (an internal source
current meter can be used if it has 5% or better accuracy).
current meter can be used if it has 5% or better accuracy).
4. Install shunt jumpers on the LED pins 1 and 2 of each header J4, J5, and J6 and also on J7-1/2 TMR.
1. Ensure that the preceding Equipment Setup steps are followed (switches should be in the closed
position, shunts installed, and the power source set to 5.1 V
±
0.1 VDC). Turn on the power source.
2. Verify that the output voltage, BAT+, charges to between 2.5 V to 2.9 V and the red LED (D1) is lit (all
SLUU235 – February 2006
bq2406x Evaluation Module
3