SLUSAB0D October 2010 – April 2016 BQ24153A , BQ24156A , BQ24158 , BQ24159
UNLESS OTHERWISE NOTED, this document contains PRODUCTION DATA.
NOTE
Information in the following applications sections is not part of the TI component specification, and TI does not warrant its accuracy or completeness. TI’s customers are responsible for determining suitability of components for their purposes. Customers should validate and test their design implementation to confirm system functionality.
The bq24153A/6A/8/9 is a compact, flexible, high-efficiency, USB-friendly, switch-mode charge management solution for single-cell Li-ion and Li-polymer batteries used in a wide range of portable applications. The devices integrate a synchronous PWM controller, power MOSFETs, input current sensing, high-accuracy current and voltage regulation, and charge termination, into a small DSBGA package. The charge parameters can be programmed through an I2C interface.
VBUS = 5 V, ICHARGE = 1250 mA, VBAT = 3.5 V to 4.44 V (Adjustable).
Use the following typical application design procedure to select external components values for the bq24153A/6A/8/9 device.
SPECIFICATIONS | TEST CONDITIONS | MIN | TYP | MAX | UNIT |
---|---|---|---|---|---|
Input DC voltage, VIN | Input voltage from AC adapter input | 4 | 5 | 6 | V |
Input current | Maximum input current from AC adapter input | 0.1 | 0.1 to 0.5 | 1.5 | A |
Charge current | Battery charge current | 0.325 | 0.7 | 1.55 | A |
Output regulation voltage | Voltage applied to VBAT | 0 | 0.3 to 4.2 | 4.44 | V |
Operating junction temperature range, TJ | 0 | 125 | °C |
, the worst case is when battery voltage is as close as to half of the input voltage.
LOUT = 1.11 μH
Select the output inductor to standard 1 μH. Calculate the total ripple current with using the 1-μH inductor:
ΔIL = 0.42 A
Calculate the maximum output current:
ILPK = 1.46 A
Select 2.5mm by 2mm 1-μH 1.5-A surface mount multi-layer inductor. The suggested inductor part numbers are shown as following.
PART NUMBER | INDUCTANCE | SIZE | MANUFACTURER |
---|---|---|---|
LQM2HPN1R0MJ0 | 1 μH | 2.5 x 2.0 mm | Murata |
MIPS2520D1R0 | 1 μH | 2.5 x 2.0 mm | FDK |
MDT2520-CN1R0M | 1 μH | 2.5 x 2.0 mm | TOKO |
CP1008 | 1 μH | 2.5 x 2.0 mm | Inter-Technical |
COUT = 15.8 μF
Select two 0603 X5R 6.3V 10-μF ceramic capacitors in parallel i.e., Murata GRM188R60J106M.
The maximum sense voltage across the sense resistor is 85 mV. In order to get a better current regulation accuracy, V(RSNS) should equal 85mV, and calculate the value for the sense resistor.
R(SNS) = 68 mΩ
This is a standard value. If it is not a standard value, then choose the next close value and calculate the real charge current. Calculate the power dissipation on the sense resistor:
P(RSNS) = I(CHARGE) 2 × R(SNS)
P(RSNS) = 1.252 × 0.068
P(RSNS) = 0.106 W
Select 0402 0.125-W 68-mΩ 2% sense resistor, i.e. Panasonic ERJ2BWGR068.
TA = 25°C | VBUS = 5 V | VBAT = 3 V |
TA = 25°C | VBUS = 5 V | VBAT = 3 V |
Both the termination current range and charge current range depend on the sensing resistor (RSNS). The termination current step (IOTERM_STEP) can be calculated using Equation 11:
Table 12 shows the termination current settings for three sensing resistors.
BIT | VI(TERM) (mV) | I(TERM) (mA) R(SNS) = 55mΩ |
I(TERM) (mA) R(SNS) = 68mΩ |
I(TERM) (mA) R(SNS) = 100mΩ |
---|---|---|---|---|
VI(TERM2) | 13.6 | 247 | 200 | 136 |
VI(TERM1) | 6.8 | 124 | 100 | 68 |
VI(TERM0) | 3.4 | 62 | 50 | 34 |
Offset | 3.4 | 62 | 50 | 34 |
For example, with a 68-mΩ sense resistor, V(ITERM2)=1, V(ITERM1)=0, and V(ITERM0)=1, ITERM = [ (13.6mV x 1) + (6.8mV x 0) + (3.4mV x 1) + 3.4mV ] / 68mΩ = 200mA + 0 + 50mA + 50mA = 300mA.
The charge current step (IO(CHARGE_STEP)) is calculated using Equation 12:
Table 13 shows the charge current settings for three sensing resistors.
BIT | VI(REG) (mV) | IO(CHARGE) (mA) R(SNS) = 55mΩ |
IO(CHARGE) (mA) R(SNS) = 68mΩ |
IO(CHARGE) (mA) R(SNS) = 100mΩ |
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bq24156A bq24159 |
bq24153A bq24158 |
bq24156A bq24159 |
bq24153A bq24158 |
bq24156A bq24159 |
bq24153A bq24158 |
bq24156A bq24159 |
bq24153A bq24158 |
|
VI(CHRG3) | 54.4 | 27.2 | 989 | 495 | 800 | 400 | 544 | 272 |
VI(CHRG2) | 27.2 | 13.6 | 495 | 247 | 400 | 200 | 272 | 136 |
VI(CHRG1) | 13.6 | 6.8 | 247 | 124 | 200 | 100 | 136 | 68 |
VI(CHRG0) | 6.8 | n/a | 124 | n/a | 100 | n/a | 68 | n/a |
Offset | 37.4 | 37.4 | 680 | 680 | 550 | 550 | 374 | 374 |
Using bq24156A as an example, with a 68-mΩ sense resistor, V(CHRG3)=1, V(CHRG2)=0, V(ICHRG1)=0, and V(ICHRG0)=1, ITERM = [ (54.4mV x 1) + (27.2mV x 0) + (13.6mV x 0) + (6.8mV x 1) + 37.4mV ] / 68mΩ = 800mA + 0 + 0 + 100mA = 900mA.
The IC provides internal loop compensation. With the internal loop compensation, the highest stability occurs when the LC resonant frequency, fo, is approximately 40 kHz (20 kHz to 80 kHz). Equation 13 can be used to calculate the value of the output inductor, LOUT, and output capacitor, COUT.
To reduce the output voltage ripple, a ceramic capacitor with the capacitance between 4.7 μF and 47 μF is recommended for COUT, see the application section for components selection.
Using circuit shown in Figure 25, TA = 25°C, unless otherwise specified.
VBUS = 0-5V, | Iin_limit = 500mA, | Voreg = 4.2V |
VBAT = 3.5V, | ICHG = 550mA, | 32S mode |
VBUS = 5V, | No Battery Connected | |
VBUS = 5.05 V, | VBAT = 3.5V, | IBUS = 217 mA |
VBUS = 5.05 V, | VBAT = 3.5V, | IBUS = 0-217 mA |
VBUS = 5 V, | VBAT = 3.4V, | Iin_limit = 500 mA |
(32s Mode) |
VBUS = 5V, | No Battery Connected | |
VBUS = 5.05 V, | VBAT = 3.5V, | IBUS = 42 mA |
VBUS = 5.05 V, | VBAT = 3.5V, | IBUS = 217 mA |
VBUS = 5 V, ICHARGE = 1550 mA, Vbat = 3.5 V to 4.44 V (adjustable).