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MAX1772EEI 参数 Datasheet PDF下载

MAX1772EEI图片预览
型号: MAX1772EEI
PDF下载: 下载PDF文件 查看货源
内容描述: 低成本,多种化学电池 - 充电积木 [Low-Cost, Multichemistry Battery- Charger Building Block]
分类和应用: 电池光电二极管信息通信管理
文件页数/大小: 20 页 / 340 K
品牌: MAXIM [ MAXIM INTEGRATED PRODUCTS ]
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Low-Cost, Multichemistry Battery-  
Charger Building Block  
cations. Individual compensation of the voltage regula-  
tion and current-regulation loops allow for optimal com-  
pensation.  
Detailed Description  
The MAX1772 includes all of the functions necessary to  
charge Li+, NiMH, and NiCd batteries. A high-efficiency  
synchronous-rectified step-down DC-DC converter con-  
trols charging voltage and current. It also includes input  
source-current limiting and analog inputs for setting the  
charge current and charge voltage. The DC-DC con-  
verter uses external N-channel MOSFETs as the buck  
switch and synchronous rectifier to convert the input  
voltage to the required charging current and voltage.  
The typical application circuit shown in Figure 1a uses  
a microcontroller (µC) to allow control of charging cur-  
rent or voltage, while Figure 1b shows a typical appli-  
cation with charging voltage and current fixed to  
specific values for the application. The voltage at ICTL  
and the value of RS2 set the charging current. The DC-  
DC converter generates the control signals for the  
external MOSFETs to regulate the voltage and the cur-  
rent set by the VCTL, ICTL, and CELLS inputs.  
Setting the Charging-Current Limit  
The ICTL input sets the maximum charging current. The  
current is set by current-sense resistor RS2, connected  
between CSIP and CSIN. The nominal differential volt-  
age between CSIP and CSIN is 204mV; thus, for a  
0.05sense resistor, the maximum charging current is  
4A. Battery-charging current is programmed with ICTL  
using the equation:  
V
RS2  
V
1
20  
REF  
ICTL  
I
=
×
×
2
( )  
CHG  
V
REFIN  
The input range for ICTL is REFIN/32 to REFIN (3.3V).  
The device shuts down if ICTL is forced below  
REFIN/55 (typical). The current at ICHG is a scaled-  
down replica of the battery output current being sensed  
across CSIP and CSIN.  
The MAX1772 features a voltage-regulation loop (CCV)  
and two current-regulation loops (CCI and CCS). The  
CCV voltage-regulation loop monitors BATT to ensure  
that its voltage never exceeds the voltage set by VCTL.  
The CCI battery current-regulation loop monitors cur-  
rent delivered to BATT to ensure that it never exceeds  
the current limit set by ICTL. A third loop (CCS) takes  
control and reduces the battery-charging current when  
the sum of the system load and the battery-charging  
current exceeds the charging source current limit set  
by CLS.  
When choosing the current-sense resistor, note that the  
voltage drop across this resistor causes further power  
loss, reducing efficiency. However, adjusting ICTL to  
reduce the voltage across the current-sense resistor  
may degrade accuracy due to the input offset of the  
current-sense amplifier. The charging current-error  
amplifier (GMI) is compensated at CCI. A 0.01µF  
capacitor at CCI provides suitable performance for  
most applications.  
Setting the Input Current Limit  
The total input current (from a wall cube or other DC  
source) is a function of the system supply current and  
the battery-charging current. The input current regula-  
tor limits the source current by reducing the charging  
current when the input current exceeds the set input  
current limit. System current will normally fluctuate as  
portions of the system are powered up or put to sleep.  
Without input current regulation, the input source must  
be able to supply the maximum system current and the  
maximum charger input current. By using the input cur-  
rent limiter, the current capability of the AC wall adapter  
may be lowered, reducing system cost.  
Setting the Battery Regulation Voltage  
The MAX1772 uses a high-accuracy voltage regulator  
for charging voltage. The VCTL input adjusts the bat-  
tery output voltage. VCTL is allowed to vary from 0 to  
REFIN (3.3V). The per-cell battery termination voltage  
is a function of the battery chemistry and construction;  
thus, consult the battery manufacturer to determine this  
voltage. The battery voltage is calculated by the equa-  
tion:  
V
V
VCTL  
REF  
V
= CELLS × V  
+
×
1
( )  
BATT  
REF  
  
10  
V
REFIN  
The MAX1772 limits the current drawn by the charger  
when the load current becomes high. The device limits  
the charging current, so the AC adapter voltage is not  
loaded down. An internal amplifier compares the volt-  
age between CSSP and CSSN to the voltage at CLS.  
CELLS is the programming input for selecting cell  
count. Table 1 shows how CELLS is connected to  
charge 2, 3, or 4 cells. Use a voltage-divider from LDO  
to set the desired voltage at CELLS.  
The internal error amplifier (GMV) maintains voltage  
regulation (Figure 2). The voltage error amplifier is com-  
pensated at CCV. The component values shown in  
Figure 1 provide suitable performance for most appli-  
V
can be set by a resistor-divider between REF and  
CLS  
GND. Connect CLS to REF for maximum input current  
limiting.  
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