XC6213B37ANR-G [TOREX]

Fixed Positive LDO Regulator, 3.75V, 0.45V Dropout, CMOS, PDSO4, ANTIMONY AND HALOGEN FREE, ROHS COMPLIANT, SSOT-24, 4 PIN;
XC6213B37ANR-G
型号: XC6213B37ANR-G
厂家: Torex Semiconductor    Torex Semiconductor
描述:

Fixed Positive LDO Regulator, 3.75V, 0.45V Dropout, CMOS, PDSO4, ANTIMONY AND HALOGEN FREE, ROHS COMPLIANT, SSOT-24, 4 PIN

光电二极管 输出元件 调节器
文件: 总33页 (文件大小:1122K)
中文:  中文翻译
下载:  下载PDF数据表文档文件
XC6213Series  
ETR0308_008  
High Speed LDO Regulators, Low ESR Cap. Compatible, Ultra Small Package  
GENERAL DESCRIPTION  
The XC6213 series is a highly precise positive voltage LDO regulator with low noise manufactured using CMOS process. The  
series achieves high ripple rejection and low dropout and consists of a voltage reference, an error amplifier, a current limiter  
and a phase compensation circuit plus a driver transistor. Output voltage is selectable in 0.05V increments within a range of  
1.2V to 5.0V. The series is also compatible with low ESR ceramic capacitors, which give output stability. The current limiter's  
foldback circuit also operates as a short circuit protection for the output pin. The CE function enables the output to be turned  
off, resulting in greatly reduced power consumption. Ultra small package SSOT-24, SOT-25, USPN-4 and USP-4 are  
available.  
APPLICATIONS  
Smart phones / Mobile phones  
Portable game consoles  
DSC / Camcorders  
FEATURES  
Maximum Output Current  
: 150mA @ VOUT=3.0V, VIN=4.0V  
Dropout Voltage  
: 400mV @ IOUT = 100mA  
: 2.0 ~ 6.0V  
Input Voltage Range  
Output Voltage Range  
Highly Accurate  
: 1.2 ~ 5.0V (0.05V Increments)  
: ±2%  
Digital audio equipments  
Mobile devices / terminals  
Low Power Consumption : 35μA (TYP.)  
Stand-by Current  
: Less than 0.1μA  
High Ripple Rejection  
: 60dB @ 10kHz  
Operating Ambient Temperature: - 40~ 85℃  
Low ESR Capacitor Compatible : Ceramic capacitor  
Packages  
: SSOT-24  
SOT-25  
USP-4  
USPN-4  
Environmentally Friendly : EU RoHS Compliant, Pb Free  
TYPICAL APPLICATION CIRCUIT TYPICAL PERFORMANCE  
CHARACTERI STICS  
Ripple Rejection Rate vs. Ripple Frequency  
SSOT-24 package  
XC6213B302  
VIN=VCE=4.0VDC+0.5p-pAC  
IOUT=50mA , CL=1.0μF(ceramic)  
VIN  
VOUT  
90  
80  
70  
60  
50  
40  
30  
20  
10  
0
CE VSS  
CL  
1μF  
CIN  
1μF  
0.01  
0.1  
1
10  
100  
Ripple Frequency : f (KHz)  
1/33  
XC6213 Series  
PIN CONFIGURATION  
*The dissipation pad for the USP-4 pae should be  
solder-plated in recommended mount pattern and metal  
masking so as to enhance mounting strength and heat  
release. If the pad needs to be connected to other pins, it  
should be connected to the VSS (No. 2) pin  
PIN ASSIGNMENT  
PIN NUMBER  
PIN NAME  
FUNCTION  
SOT-25 SSOT-24  
USP-4  
USPN-4  
1
2
3
4
5
4
2
1
-
4
2
3
-
4
2
3
-
VIN  
VSS  
CE  
Power Supply  
Ground  
On / Off Switch  
No Connection  
Output  
NC  
3
1
1
VOUT  
PRODUCT CLASSIFICATION  
Ordering Information  
*1  
(
)
XC6213①②③④⑤⑥-⑦  
DESIGNATOR  
ITEM  
SYMBOL  
B
DESCRIPTION  
Type of Regulator  
High Active with no pull-down resistor (standard)  
Output Voltage:  
②③  
Output Voltage  
12~50  
ex.) 3.0V→ ② =3, = 0  
Output Voltage  
Accuracy  
2
0.1V increments, ±2% accuracy ex.) 2.80V → ②=2, = 8, = 2  
0.05V increments, ±2% accuracy ex.) 2.85V → ②=2, = 8, = A  
SOT-25 (3,000/Reel)  
A
MR  
MR-G  
NR  
SOT-25 (3,000/Reel)  
SSOT-24 (3,000/Reel)  
Package  
⑤⑥-⑦  
NR-G  
GR  
SSOT-24 (3,000/Reel)  
(Oder Unit)  
USP-4 (3,000/Reel)  
GR-G  
R-G  
USP-4 (3,000/Reel)  
USPN-4 (5,000/Reel)  
(*1)  
The “-G” suffix indicates that the products are Halogen and Antimony free as well as being fully EU RoHS compliant.  
2/33  
XC6213  
Series  
BLOCK DIAGRAM  
VIN  
ON/OFF  
Control  
CE  
each circuit  
Current  
Limit  
VOUT  
VSS  
R2  
R1  
Voltage  
Reference  
*Diode inside the circuit is a protection diode.  
ABSOLUTE MAXIMUM RATINGS  
Ta = 25℃  
PARAMETER  
Input Voltage  
SYMBOL  
VIN  
RATINGS  
VSS – 0.3 ~ 7.0  
500 (*1)  
UNITS  
V
mA  
V
Output Current  
Output Voltage  
CE Input Voltage  
IOUT  
VOUT  
VCE  
VSS – 0.3 ~ VIN + 0.3  
VSS – 0.3 ~ 7.0  
250  
V
SOT-25  
600(PCB mounted)(*2)  
150  
SSOT-24  
USP-4  
500(PCB mounted)(*2)  
120  
Power Dissipation  
Pd  
mW  
1000(PCB mounted)(*2)  
100  
USPN-4  
600(PCB mounted)(*2)  
- 40 ~ + 85  
Operating Ambient Temperature  
Storage Temperature Range  
Topr  
Tstg  
- 55 ~ + 125  
*1: IOUT=Pd/(VIN-VOUT)  
*2: The power dissipation figure shown is PCB mounted. Please refer to pages 29 to 32 for details.  
3/33  
XC6213 Series  
ELECTRICAL CHARACTERISTICS  
XC6213B series  
Ta=25℃  
CIRCUITS  
PARAMETER  
Output Voltage  
SYMBOL  
CONDITIONS  
MIN.  
TYP.  
MAX. UNITS  
VOUT(T)  
VOUT(T)  
V
VOUT(E)  
IOUT=30mA, CE=VIN  
VOUT(T)  
x 0.98  
x 1.02  
VIN=VOUT(T)+1.0V,  
VOUT(T)=1.20~1.45V, CE=VIN  
VIN=VOUT(T)+1.0V,  
100  
120  
150  
200  
-
-
-
-
-
VOUT(T)=1.50~2.95V, CE=VIN  
VIN=VOUT(T)+1.0V,  
Maximum Output Current  
IOUTMAX  
mA  
-
-
VOUT(T)=3.00~4.05V, CE=VIN  
VIN=VOUT(T)+1.0V,  
-
-
VOUT(T)=4.10~5.00V, CE=VIN  
VIN=VOUT(T)+1.0V,  
Load Regulation  
Dropout Voltage  
VOUT  
15  
50  
mV  
1mAIOUT100mA, CE=VIN  
E-1  
E-2  
35  
Vdif1  
Vdif2  
ISS  
IOUT = 30mA, CE=VIN  
IOUT=100mA, CE=VIN  
mV  
mV  
μA  
μA  
25  
-
50  
Supply Current  
VIN=VOUT(T)+1.0V, CE=VIN  
0.01  
0.10  
Stand-by Current  
Istby  
VIN=VOUT(T)+1.0V6.0V, CE=VSS  
VOUT  
VOUT(T)+1.0VVIN6V  
-
Line Regulation  
-
0.01  
-
0.20  
6.0  
%/V  
V
VIN VOUT  
IOUT=30mA, CE=VIN  
2.0  
Input Voltage  
VIN  
-
Output Voltage  
VOUT  
IOUT=30mA, CE=VIN  
-
-
±100  
-
-
ppm/℃  
Temperature CharacteristicsTopr VOUT  
- 40℃≦Topr85℃  
VIN=[VOUT(T)+1.0 V] +0.5Vp-pAC  
IOUT=50mA, f=10kHz, CE=VIN  
Ripple Rejection Rate  
PSRR  
60  
dB  
-
50  
-
-
Short Circuit Current  
CE ‘H’ Level Voltage  
CE ‘L’ Level Voltage  
CE ‘H’ Level Current  
CE ‘L’ Level Current  
Ishort  
VCEH  
VCEL  
ICEH  
VIN=VOUT(T) + 1.0V, CE=VIN  
mA  
V
1.3  
-
6.0  
0.25  
0.1  
0.1  
-
-
-
V
- 0.1  
- 0.1  
-
μA  
μA  
VCE = VIN=VOUT(T) + 1.0V  
VIN=VOUT(T) +1.0V, VCE =VSS  
-
ICEL  
NOTE:  
*1:  
*2:  
VOUT(T): Setting output voltage  
VOUT(E) = Effective output voltage  
(i.e. the output voltage when “VOUT (T) + 1.0V” is provided at the VIN pin while maintaining a certain IOUT value).  
(*4)  
*3:  
*4:  
*5:  
*6:  
*7:  
Vdif = { VIN1 (*5) – VOUT1  
}
VOUT1 = A voltage equal to 98% of the output voltage whenever an amply stabilized IOUT { VOUT(T) + 1.0V } is input.  
VIN1 = The input voltage when VOUT1 appears as input voltage is gradually decreased.  
Unless otherwise stated, (VIN = VOUT(T) + 1.0V).  
VOUT(T)<1.45V = Minimum: VOUT(T)-30mV, Maximum: VOUT(T)+30mV  
4/33  
XC6213  
Series  
ELECTRICAL CHARACTERISTICS (Continued)  
Dropout Voltage Chart  
Ta=25OC  
SYMBOL  
SETTING  
VOLTAGE  
E-0  
E-1  
E-2  
OUTPUT VOLTAGE  
DROPOUT VOLTAGE 1  
IOUT=30mA (mV)  
DROPTOUT VOLTAGE 2  
IOUT=100mA (mV)  
(V)  
VOUT  
Vdif1  
TYP.  
760  
760  
660  
660  
560  
560  
460  
460  
360  
360  
260  
260  
200  
200  
200  
200  
190  
190  
190  
190  
190  
190  
190  
190  
190  
190  
180  
180  
180  
180  
180  
180  
180  
180  
180  
180  
150  
150  
150  
150  
150  
150  
150  
150  
150  
150  
Vdif1  
MAX.  
800  
800  
700  
700  
600  
600  
500  
500  
400  
400  
300  
300  
240  
240  
240  
240  
230  
230  
230  
230  
230  
230  
230  
230  
230  
230  
210  
210  
210  
210  
210  
210  
210  
210  
210  
210  
180  
180  
180  
180  
180  
180  
180  
180  
180  
180  
Vdif2  
TYP.  
850  
850  
810  
810  
770  
770  
730  
730  
690  
690  
650  
650  
600  
600  
600  
600  
530  
530  
530  
530  
530  
530  
530  
530  
530  
530  
470  
470  
470  
470  
470  
470  
470  
470  
470  
470  
400  
400  
400  
400  
400  
400  
400  
400  
400  
400  
Vdif2  
MAX.  
1000  
1000  
960  
960  
920  
920  
880  
880  
840  
840  
800  
800  
750  
750  
750  
750  
670  
670  
670  
670  
670  
670  
670  
670  
670  
670  
580  
580  
580  
580  
580  
580  
580  
580  
580  
580  
500  
500  
500  
500  
500  
500  
500  
500  
500  
500  
VOUT(T)  
MIN.  
1.170  
1.220  
1.270  
1.320  
1.370  
1.420  
1.470  
1.519  
1.568  
1.617  
1.666  
1.715  
1.764  
1.813  
1.862  
1.911  
1.960  
2.009  
2.058  
2.107  
2.156  
2.205  
2.254  
2.303  
2.352  
2.401  
2.450  
2.499  
2.548  
2.597  
2.646  
2.695  
2.744  
2.793  
2.842  
2.891  
2.940  
2.989  
3.038  
3.087  
3.136  
3.185  
3.234  
2.283  
2.332  
3.381  
MAX.  
1.230  
1.280  
1.330  
1.380  
1.430  
1.480  
1.530  
1.581  
1.632  
1.683  
1.734  
1.785  
1.836  
1.887  
1.938  
1.989  
2.040  
2.091  
2.142  
2.193  
2.244  
2.295  
2.346  
2.397  
2.448  
2.499  
2.550  
2.601  
2.652  
2.703  
2.754  
2.805  
2.856  
2.907  
2.958  
3.009  
3.060  
3.111  
3.162  
3.213  
3.264  
3.315  
3.366  
3.417  
3.468  
3.519  
1.20  
1.25  
1.30  
1.35  
1.40  
1.45  
1.50  
1.55  
1.60  
1.65  
1.70  
1.75  
1.80  
1.85  
1.90  
1.95  
2.00  
2.05  
2.10  
2.15  
2.20  
2.25  
2.30  
2.35  
2.40  
2.45  
2.50  
2.55  
2.60  
2.65  
2.70  
2.75  
2.80  
2.85  
2.90  
2.95  
3.00  
3.05  
3.10  
3.15  
3.20  
3.25  
3.30  
3.35  
3.40  
3.45  
5/33  
XC6213 Series  
ELECTRICAL CHARACTERISTICS (Continued)  
Dropout Voltage Chart (Continued)  
Ta=25OC  
SYMBOL  
SETTING  
VOLTAGE  
E-0  
E-1  
E-2  
OUTPUT VOLTAGE  
DROPOUT VOLTAGE 1  
IOUT=30mA (mV)  
DROPTOUT VOLTAGE 2  
IOUT=100mA (mV)  
(V)  
VOUT  
Vdif1  
TYP.  
140  
140  
140  
140  
140  
140  
140  
140  
140  
140  
130  
130  
130  
130  
130  
130  
130  
130  
130  
130  
120  
120  
120  
120  
120  
120  
120  
120  
120  
120  
120  
Vdif1  
MAX.  
170  
170  
170  
170  
170  
170  
170  
170  
170  
170  
160  
160  
160  
160  
160  
160  
160  
160  
160  
160  
150  
150  
150  
150  
150  
150  
150  
150  
150  
150  
150  
Vdif2  
TYP.  
350  
350  
350  
350  
350  
350  
350  
350  
350  
350  
320  
320  
320  
320  
320  
320  
320  
320  
320  
320  
300  
300  
300  
300  
300  
300  
300  
300  
300  
300  
300  
Vdif2  
MAX.  
450  
450  
450  
450  
450  
450  
450  
450  
450  
450  
420  
420  
420  
420  
420  
420  
420  
420  
420  
420  
400  
400  
400  
400  
400  
400  
400  
400  
400  
400  
400  
VOUT(T)  
MIN.  
3.430  
3.479  
3.528  
3.577  
3.626  
3.675  
3.724  
3.773  
3.822  
3.871  
3.920  
3.969  
4.018  
4.067  
4.116  
4.165  
4.214  
4.263  
4.312  
4.361  
4.410  
4.459  
4.508  
4.557  
4.606  
4.655  
4.704  
4.753  
4.802  
4.851  
4.900  
MAX.  
3.570  
3.621  
3.672  
3.723  
3.774  
3.825  
3.876  
3.927  
3.978  
4.029  
4.080  
4.131  
4.182  
4.233  
4.284  
4.335  
4.386  
4.437  
4.488  
4.539  
4.590  
4.641  
4.692  
4.743  
4.794  
4.845  
7.896  
4.947  
4.998  
5.049  
5.100  
3.50  
3.55  
3.60  
3.65  
3.70  
3.75  
3.80  
3.85  
3.90  
3.95  
4.00  
4.05  
4.10  
4.15  
4.20  
4.25  
4.30  
4.35  
4.40  
4.45  
4.50  
4.55  
4.60  
4.65  
4.70  
4.75  
4.80  
4.85  
4.90  
4.95  
5.00  
6/33  
XC6213  
Series  
TEST CIRCUITS  
Circuit ①  
VIN  
CE  
VOUT  
A
CIN=1.0μF  
(Ceramic)  
RL  
VSS  
V
V
(Ceramic)  
CIN=1.0μF  
V
Circuit ②  
VIN  
CE  
VOUT  
A
OPEN  
A
VSS  
CIN=1.0 μF  
(ceramic)  
Circuit ③  
IOUT=50mA  
VIN  
VOUT  
VIN={VOUT+1}V DC  
+0.25Vp-pAC  
CL=1.0uF  
(ceramic  
)
CE  
VSS  
V
V
7/33  
XC6213 Series  
OPERATIONAL EXPLANATION  
<Output Voltage Regulator Control>  
IN  
V
ON/OFF  
Control  
The voltage, divided by resistors R1 & R2, which are connected  
to the VOUT pin is compared with the internal reference voltage  
by the error amplifier. The P-channel MOSFET which is  
connected to the VOUT pin is then driven by the subsequent  
output signal. The output voltage at the VOUT pin is controlled &  
stabilized by negative feedback. The current limit circuit and  
short circuit protection operate in relation to the level of output  
current. Further, the voltage regulator's internal circuitry can be  
shutdown via the CE pin's signal.  
each circuit  
CE  
-
Current  
Limiter  
+
VOUT  
R2  
R1  
Voltage  
SS  
V
Reference  
<Low ESR Capacitor>  
With the XC6213 series regulator, a stable output voltage is achievable even if low ESR capacitors are used, as a phase  
compensation circuit is built-in to the regulator. In order to ensure the effectiveness of the phase compensation, please  
connect an output capacitor (CL) with a capacitance, based on the chart below. The equivalent serial resistor (ESR) of the  
output capacitor (CL) should be within the range as the graph below shown. We also suggest an input capacitor (CIN) of  
1.0μF: this should be connected between VIN and VSS in order to stabilize input power source.  
Output Capacitor Corresponding Chart  
SETTING VOLTAGE  
CL  
1.2 ~ 1.75V  
1.8 ~ 5.0V  
More than 3.3μF  
More than 1.0μF  
Ta=-40~85℃  
VIN=2.0~6.0V, VOUT=1.2~5.0V, CIN=1.0μF(ceramic)  
100  
10  
STABLE REGION  
1
0.1  
0.01  
0.01  
0.1  
1
10  
100  
Output Current : IOUT (mA)  
<Short-Circuit Protection>  
The XC6213 series regulator offers circuit protection by means of a built-in foldback circuit. When the load current reaches  
the current limit level, the fixed current limiter circuit operates and output voltage drops. As a result of this drop in output  
voltage, the foldback circuit operates, the output voltage drops further and output current decreases. When the output pin  
is shorted, a current of about 50mA flows.  
<CE Pin>  
The IC's internal regulator circuitry can be shut down via the signal from the CE pin with the XC6213 series. In shutdown  
mode, output at the VOUT pin will be pulled down to the VSS level. Note that as the XC6213B types are 'High Active / No  
Pull-Down', operations will become unstable with the CE pin open. We suggest that you use this IC with either a VIN  
voltage or a VSS voltage input at the CE pin. If this IC is used with the correct specifications for the CE pin, the IC will  
operate normally. However, supply current may increase as a result of through current in the IC's internal circuitry if a  
voltage other than VIN or VSS is applied.  
<Minimum Operating Voltage>  
Please apply input voltage more than 2.0V or more in order to stabilize the operation of the IC’s. Normal output voltage  
may not be obtained when the input voltage is lower than 2.0V.  
NOTES ON USE  
1. Please use this IC within the stated absolute maximum ratings. The IC is liable to malfunction should the ratings be  
exceeded.  
2. Where wiring impedance is high, operations may become unstable due to noise and/or phase lag depending on output  
current. Please strengthen VIN and VSS wiring in particular.  
3. Please wire the input capacitor (CIN) and the output capacitor (CL) as close to the IC as possible. Should rapid input  
fluctuation or load fluctuation occur, please increase the capacitor value such as CIN or CL to stabilize the operation.  
4. Make sure not to use the IC with large current at high temperature. When exceeding power dissipation of a package,  
heat occurs before short protection operates, and the IC may break.  
8/33  
XC6213  
Series  
TYPICAL PERFORMANCE CHARACTERISTICS  
(1) Output Voltage vs. Output Current  
XC6213B122  
XC6213B122  
VIN=VCE=2.2V, CIN=1.0μF, CL=3.3μF (ceramic)  
VIN=VCE, Ta=25, CIN=1.0μF, CL=3.3μF (ceramic)  
Output Current: IOUT (mA)  
Output Current: IOUT (mA)  
XC6213B152  
XC6213B152  
VIN=VCE=2.5V, CIN=1.0μF, CL=3.3μF (ceramic)  
VIN=VCE, Ta=25, CIN=1.0,μF CL=3.3μF (ceramic)  
Output Current: IOUT (mA)  
Output Current: IOUT (mA)  
XC6213B182  
XC6213B182  
VIN=VCE, Ta=25, CIN=CL=1.0μF (ceramic)  
VIN=VCE=2.8V, CIN=CL=1.0μF (ceramic)  
VIN=6.0V  
VIN=2.1V  
Output Current: IOUT (mA)  
Output Current: IOUT (mA)  
9/33  
XC6213 Series  
TYPICAL PERFORMANCE CHARACTERISTICS (Continued)  
(1) Output Voltage vs. Output Current (Continued)  
VIN=VCE=4.0V, CIN=CL=1.0μF (ceramic)  
VIN=VCE, Ta=25, CIN=CL=1.0μF (ceramic)  
Output Current: IOUT (mA)  
Output Current: IOUT (mA)  
VIN=VCE, Ta=25, CIN=CL=1.0μF (ceramic)  
VIN=VCE=6.0V, CIN=CL=1.0μF (ceramic)  
VIN=5.3V  
Output Current: IOUT (mA)  
Output Current: IOUT (mA)  
10/33  
XC6213  
Series  
TYPICAL PERFORMANCE CHARACTERISTICS (Continued)  
(2) Output Voltage vs. Input Voltage  
VIN=VCE, Ta=25, CIN=1.0μF, CL=3.3μF (ceramic)  
VIN=VCE, Ta=25, CIN=1.0μF, CL=3.3μF (ceramic)  
Input Voltage: VIN (V)  
Input Voltage: VIN (V)  
VIN=VCE, Ta=25, CIN=CL=1.0μF (ceramic)  
VIN=VCE, Ta=25, CIN=CL=1.0μF (ceramic)  
Input Voltage: VIN (V)  
Input Voltage: VIN (V)  
VIN=VCE, Ta=25, CIN=CL=1.0μF (ceramic)  
Input Voltage: VIN (V)  
11/33  
XC6213 Series  
TYPICAL PERFORMANCE CHARACTERISTICS (Continued)  
(3) Dropout Voltage vs. Output Current  
VIN=VCE, CIN=1.0μF, CL=3.3μF (ceramic)  
VIN=VCE, CIN=1.0μF, CL=3.3μF (ceramic)  
Output Current: IOUT (mA)  
Output Current: IOUT (mA)  
VIN=VCE, CIN=CL=1.0μF (ceramic)  
VIN=VCE, CIN=CL=1.0μF (ceramic)  
Output Current: IOUT (mA)  
Output Current: IOUT (mA)  
VIN=VCE, CIN=CL=1.0μF (ceramic)  
Output Current: IOUT (mA)  
12/33  
XC6213  
Series  
TYPICAL PERFORMANCE CHARACTERISTICS (Continued)  
(4) Supply Current vs. Input Voltage  
VIN=VCE, CL=3.3μF (ceramic)  
VIN=VCE, CL=3.3μF (ceramic)  
Input Voltage: VIN (V)  
Input Voltage: VIN (V)  
XC6213B182  
VIN=VCE, CIN=CL=1.0μF (ceramic)  
VIN=VCE, CIN=CL=1.0μF (ceramic)  
Input Voltage: VIN (V)  
Input Voltage: VIN (V)  
VIN=VCE, CIN=CL=1.0μF (ceramic)  
Input Voltage: VIN (V)  
13/33  
XC6213 Series  
TYPICAL PERFORMANCE CHARACTERISTICS (Continued)  
(5) Output Voltage vs. Ambient Temperature  
VIN=VCE=2.5V,CIN=1.0μF,CL=3.3μF (ceramic)  
VIN=VCE=2.2V, CIN=1.0μF, CL=3.3μF (ceramic)  
Ambient Temperature: Ta ()  
Ambient Temperature: Ta ()  
VIN=VCE=4.0V, CIN=CL=1.0μF (ceramic)  
VIN=VCE=2.8V, CIN=CL=1.0μF (ceramic)  
Ambient Temperature: Ta ()  
Ambient Temperature: Ta ()  
VIN=VCE=6.0 V, CIN=CL=1.0μF (ceramic)  
Ambient Temperature: Ta ()  
14/33  
XC6213  
Series  
TYPICAL PERFORMANCE CHARACTERISTICS (Continued)  
(6) Supply Current vs. Ambient Temperature  
VIN=VCE=2.5V, CIN=1.0μF, CL=3.3μF(ceramic)  
VIN=VCE=2.2V, CIN=1.0μF, CL=3.3μF(ceramic)  
Ambient Temperature: Ta ()  
Ambient Temperature: Ta ()  
VIN=VCE=2.8V, CIN=CL=1.0μF(ceramic)  
VIN=VCE=4.0V, CIN=CL=1.0μF(ceramic)  
Ambient Temperature: Ta ()  
Ambient Temperature: Ta ()  
(7) CE Threshold Voltage vs. Ambient Temperature  
VIN=VCE=6.0V, CIN=CL=1.0μF(ceramic)  
VIN=VCE=6.0V, CIN=CL=1.0μF(ceramic)  
Ambient Temperature: Ta ()  
Ambient Temperature: Ta ()  
15/33  
XC6213 Series  
TYPICAL PERFORMANCE CHARACTERISTICS (Continued)  
(8) Input Transient Response  
XC6213 B122  
XC6213 B122  
VIN=VCE , Ta=25℃  
μ  
IOUT=1mA, tr=tf=5μs, CL=3.3 F (ceramic)  
VIN=VCE , Ta=25℃  
IOUT=30mA,tr=tf=5F (  
μ
s, CL=3.3  
μ
ceramic)  
4
3
1.40  
1.35  
1.30  
1.25  
1.20  
1.15  
4
3
1.40  
1.35  
1.30  
1.25  
1.20  
1.15  
Input Voltage  
Input Voltage  
2
2
Output Voltage  
1
1
Output Voltage  
0
0
-1  
-1  
Time (40μs/div)  
Time (40μs/div)  
XC6213 B152  
XC6213 B152  
VIN=VCE , Ta=25℃  
VIN=VCE , Ta=25℃  
IOUT=1mA,tr=tf=5F (  
μ  
IOUT=30mA, tr=tf=5μs, CL=3.3 F (ceramic)  
μ
s, CL=3.3  
μ
ceramic)  
4
3
1.70  
1.65  
1.60  
1.55  
1.50  
1.45  
4
3
1.70  
1.65  
1.60  
1.55  
1.50  
1.45  
Input Voltage  
Input Voltage  
2
2
1
1
Output Voltage  
Output Voltage  
0
0
-1  
-1  
Time (40μs/div)  
Time (40μs/div)  
XC6213 B182  
XC6213 B182  
VIN=VCE , Ta=25℃  
VIN=VCE , Ta=25℃  
μμ
μμF (  
IOUT=30mA, tr=tf=5 s, CL=1.0 F (ceramic  
)
IOUT=1mA, tr=tf=5 s, CL=1.0  
ceramic)  
5
2.05  
5
4
2.05  
Input Voltage  
Input Voltage  
4
3
2.00  
1.95  
1.90  
1.85  
1.80  
1.75  
2.00  
1.95  
1.90  
1.85  
1.80  
1.75  
3
2
2
1
1
Output Voltage  
Output Voltage  
0
0
-1  
-1  
(40μsec/div)  
Time (40μs/div)  
Time (40μs/div)  
16/33  
XC6213  
Series  
TYPICAL PERFORMANCE CHARACTERISTICS (Continued)  
(8) Input Transient Response (continued)  
XC6213 B302  
XC6213 B302  
VIN=VCE , Ta=25℃  
VIN=VCE , Ta=25℃  
s, CL=1.0 F (ceramic)  
IOUT=30mA, tr=tf=5  
μ
s, CL=1.0 F (ceramic)  
μ
IOUT=1mA, tr=tf=5  
μ
μ
Input Voltage  
Input Voltage  
Output Voltage  
Output Voltage  
Time (40μs/div)  
Time (40μs/div)  
XC6213 B502  
XC6213 B502  
VIN=VCE , Ta=25℃  
s, CL=1.0 F (ceramic)  
VIN=VCE , Ta=25℃  
s, CL=1.0 F (ceramic)  
IOUT=1mA, tr=tf=5  
μ
μ
IOUT=30mA, tr=tf=5  
μ
μ
Input Voltage  
Input Voltage  
Output Voltage  
Output Voltage  
Time (40μs/div)  
Time (40μs/div)  
17/33  
XC6213 Series  
TYPICAL PERFORMANCE CHARACTERISTICS (Continued)  
(9) Load Transient Response  
XC6213B122  
XC6213 B122  
XC6213 B122  
Ta=25, VIN=VCE=2.2V, tr=tf=5μs,  
Ta=25, VIN=VCE=2.2V, tr=tf=5μs,  
CIN=CL=3.3μF (ceramic)  
CIN=CL=3.3μF (ceramic)  
1.3  
1.25  
1.2  
50  
40  
30  
20  
10  
0
1.3  
1.25  
1.2  
250  
200  
150  
100  
50  
Output Voltage  
Output Voltage  
1.15  
1.1  
1.15  
1.1  
Output Current  
50mA  
Output Current  
10mA  
10mA  
1mA  
1.05  
0
1.05  
Time (100μs/div)  
Time (100μs/div)  
XC6213 B152  
XC6213 B152  
Ta=25, VIN=VCE=2.5V, tr=tf=5μs,  
Ta=25, VIN=VCE=2.5V, tr=tf=5μs,  
CIN=CL=3.3μF (ceramic)  
CIN=CL=3.3μF (ceramic)  
1.6  
1.55  
1.5  
250  
200  
150  
100  
50  
1.6  
1.55  
1.5  
50  
40  
30  
20  
10  
0
Output Voltage  
Output Voltage  
1.45  
1.4  
1.45  
1.4  
Output Current  
50mA  
Output Current  
10mA  
10mA  
1mA  
1.35  
0
1.35  
Time (100μs/div)  
Time (100μs/div)  
XC6213 B182  
XC6213 B182  
Ta=25, VIN=VCE=2.8V, tr=tf=5μs,  
Ta=25, VIN=VCE=2.8V, tr=tf=5μs,  
CIN=CL=3.3μF (ceramic)  
CIN=CL=3.3μF (ceramic)  
1.85  
1.80  
1.75  
1.70  
1.65  
1.60  
50  
1.85  
250  
200  
150  
100  
50  
Output Voltage  
Output Voltage  
40  
30  
20  
10  
0
1.80  
1.75  
1.70  
1.65  
1.60  
10mA  
Output Current  
Output Current  
50mA  
1mA  
10mA  
0
Time (100μs/div)  
Time (100μs/div)  
18/33  
XC6213  
Series  
TYPICAL PERFORMANCE CHARACTERISTICS (Continued)  
(9) Load Transient Response (Continued)  
XC6213 B302  
XC6213 B302  
Ta=25, VIN=VCE=4.0V, tr=tf=5μs,  
CIN=CL=1.0μF (ceramic)  
Ta=25, VIN=VCE=4.0V, tr=tf=5μs,  
CIN=CL=1.0μF (ceramic)  
250  
Time (100μs/div)  
Time (100μs/div)  
XC6213 B502  
XC6213 B502  
Ta=25, VIN=VCE=6.0V, tr=tf=5μs,  
CIN=CL=1.0μF (ceramic)  
Ta=25, VIN=VCE=6.0V, tr=tf=5μs,  
CIN=CL=1.0μF (ceramic)  
5.05  
5.00  
4.95  
4.90  
Time (100μs/div)  
Time (100μs/div)  
19/33  
XC6213 Series  
TYPICAL PERFORMANCE CHARACTERISTICS (Continued)  
(10) Turn-On Response  
XC6213 B122  
XC6213 B122  
Ta=25, IOUT=30mA, tr=tf=5μs,  
Ta=25, IOUT=100μA, tr=tf=5μs,  
VIN=VCE=02.2V, CL=3.3μF (ceramic)  
VIN=VCE=02.2V, CL=3.3μF (ceramic)  
3
2
4
3
2
1
0
3
2
4
3
2
1
0
Input Voltage  
Input Voltage  
1
1
Output Voltage  
Output Voltage  
0
0
-1  
-1  
Time (40μs/div)  
Time (40μs/div)  
XC6213 B152  
XC6213B152  
Ta=25, IOUT=100μA, tr=tf=5μs,  
Ta=25, IOUT=30mA, tr=tf=5μs,  
VIN=VCE=02.5V, CL=3.3μF (ceramic)  
VIN=VCE=02.5V, CL=3.3μF (ceramic)  
3
2
4
3
2
1
0
3
2
4
3
2
1
0
Input Voltage  
Input Voltage  
Output Voltage  
1
Output Voltage  
1
0
0
-1  
-1  
Time (40μs/div)  
Time (40μs/div)  
XC6213 B182  
XC6213 B182  
Ta=25, IOUT=100μA, tr=tf=5μs,  
Ta=25, IOUT=30mA, tr=tf=5μs,  
VIN=VCE=02.8V, CL=1.0μF (ceramic)  
VIN=VCE=02.8V, CL=1.0μF (ceramic)  
4
5
4
2
5
2
0
4
3
2
1
0
Input Voltage  
Input Voltage  
4
3
2
1
0
0
-2  
-4  
-6  
-2  
-4  
-6  
Output Voltage  
Time (40μs/div)  
Time (40μs/div)  
20/33  
XC6213  
Series  
TYPICAL PERFORMANCE CHARACTERISTICS (Continued)  
(10) Turn-On Response (Continued)  
XC6213 B302  
XC6213 B302  
Ta=25, IOUT=30mA, tr=tf=5μs,  
Ta=25, IOUT=100μA, tr=tf=5μs,  
VIN=VCE=04.0V, CL=1.0μF (ceramic)  
VIN=VCE=04.0V, CL=1.0μF (ceramic)  
Time (40μs/div)  
Time (40μs/div)  
XC6213 B302  
XC6213 B502  
Ta=25, IOUT=30mA, tr=tf=5μs,  
Ta=25, IOUT=100μA, tr=tf=5μs,  
VIN=VCE=06.0V, CL=1.0μF (ceramic)  
VIN=VCE=06.0V, CL=1.0μF (ceramic)  
Time (80μs/div)  
Time (80μs/div)  
21/33  
XC6213 Series  
TYPICAL PERFORMANCE CHARACTERISTICS (Continued)  
(11) Enable Response  
XC6213 B122  
XC6213 B122  
Ta=25, VIN=2.2V, IOUT=100μA, tr=tf=5μs,  
Ta=25, VIN=2.2V, IOUT=30mA, tr=tf=5μs,  
VCE=0.251.5V, CL=3.3μF (ceramic)  
VCE=0.251.5V, CL=3.3μF (ceramic)  
2
1
5
4
3
2
1
0
2
1
5
4
3
2
1
0
CE Input Voltage  
Output Voltage  
CE Input Voltage  
0
0
-1  
-2  
-3  
-1  
-2  
-3  
Output Voltage  
Time (40μs/div)  
Time (40μs/div)  
XC6213 B152  
XC6213 B152  
Ta=25, VIN=2.5V, IOUT=30mA, tr=tf=5μs,  
Ta=25, VIN=2.5V, IOUT=100μA, tr=tf=5μs,  
VCE=0.251.5V, CL=3.3μF (ceramic)  
VCE=0.251.5V, CL=3.3μF (ceramic)  
2
1
0
5
4
3
2
1
0
2
5
4
3
2
1
0
CE Input Voltage  
Output Voltage  
CE Input Voltage  
Output Voltage  
1
0
-1  
-2  
-3  
-1  
-2  
-3  
Time (40μs/div)  
Time (40μs/div)  
XC6213 B182  
XC6213 B182  
Ta=25, VIN=2.8V, IOUT=30mA, tr=tf=5μs,  
Ta=25, VIN=2.8V, IOUT=100μA, tr=tf=5μs,  
VCE=0.251.5V, CL=1.0μF (ceramic)  
VCE=0.251.5V, CL=1.0μF (ceramic)  
4
5
4
3
2
1
0
4
2
5
2
0
4
3
2
1
0
CE Input Voltage  
Output Voltage  
CE Input Voltage  
Output Voltage  
0
-2  
-4  
-6  
-2  
-4  
-6  
Time (40μs/div)  
Time (40μs/div)  
22/33  
XC6213  
Series  
TYPICAL PERFORMANCE CHARACTERISTICS (Continued)  
(11) Enable Response (Continued)  
XC6213 B302  
XC6213 B302  
Ta=25, VIN=4.0V, IOUT=30mA, tr=tf=5μs,  
VCE=0.251.5V, CL=1.0μF (ceramic)  
Ta=25, VIN=4.0V, IOUT=30mA, tr=tf=5μs,  
VCE=0.251.5V, CL=1.0μF (ceramic)  
Time (40μs/div)  
Time (40μs/div)  
XC6213 B502  
XC6213 B502  
Ta=25, VIN=6.0V, IOUT=30mA, tr=tf=5μs,  
VCE=0.251.5V, CL=1.0μF (ceramic)  
Ta=25, VIN=6.0V, IOUT=30mA, tr=tf=5μs,  
VCE=0.251.5V, CL=1.0μF (ceramic)  
Time (80μs/div)  
Time (80μs/div)  
23/33  
XC6213 Series  
TYPICAL PERFORMANCE CHARACTERISTICS (Continued)  
(12) Ripple Rejection Rate  
XC6213B152  
XC6213 B152  
XC6213 B122  
VIN=VCE=2.2VDC+0.5p-pAC, IOUT=50mA,  
VIN=VCE=2.5VDC+0.5p-pAC,IOUT=50mA,  
CIN=0.01μF, CL=3.3μF (ceramic)  
CIN=0.01μF, CL=3.3μF (ceramic)  
90  
80  
70  
60  
50  
40  
30  
20  
10  
0
90  
80  
70  
60  
50  
40  
30  
20  
10  
0
0.01  
0.1  
1
10  
100  
0.01  
0.1  
1
10  
100  
Ripple Frequency : f (KHz)  
Ripple Frequency: f (kHz)  
Ripple Frequency: f (kHz)  
XC6213 B182  
XC6213 B302  
VIN=VCE=4.0VDC+0.5p-pAC,  
IOUT=50mA, CL=1.0μF (ceramic)  
VIN=VCE=2.8VDC+0.5p-pAC,  
IOUT=50mA, CL=1.0μF (ceramic)  
90  
90  
80  
70  
60  
50  
40  
30  
20  
10  
0
80  
70  
60  
50  
40  
30  
20  
10  
0
0.01  
0.1  
1
10  
100  
0.01  
0.1  
1
10  
100  
Ripple Frequency: f (kHz)  
Ripple Frequency: f (kHz)  
XC6213 B502  
VIN=VCE=5.5VDC+0.5p-pAC,  
IOUT=50mA, CL=1.0μF (ceramic)  
90  
80  
70  
60  
50  
40  
30  
20  
10  
0
0.01  
0.1  
1
10  
100  
Ripple Frequency: f (kHz)  
24/33  
XC6213  
Series  
PACKAGING INFORMATION  
SOT-25  
SSOT-24  
2.9±0.2  
+0.1  
-0.05  
0.4  
5
4
0~0.1  
1
2
3
+0.1  
-0.05  
0.15  
(0.95)  
1.9±0.2  
(Unit : mm)  
(Unit : mm)  
USP-4  
Reference Pattern Layout  
Reference Metal Mask Design  
(Unit : mm)  
25/33  
XC6213 Series  
PACKAGING INFORMATION (Continued)  
USPN-4  
Reference pattern Layout  
Reference metal mask design  
26/33  
XC6213  
Series  
MARKING RULE  
represents product series  
SOT-25 & USP-4  
MARK  
C
PRODUCT SERIES  
XC6213xxxxxx  
5
4
②③ represents type of regulator  
MARK  
VOLTAGE  
=0.1~3.0V  
VOLTAGE  
VOLTAGE  
VOLTAGE  
PRODUCT SERIES  
=3.1~6.0V =0.15~3.05V =3.15~6.05V  
1
2
3
X
B
F
M
XC6213xxxxxx  
SOT-25  
(TOP VIEW)  
represents output voltage  
MARK  
OUTPUT VOLTAGE (V)  
MARK  
OUTPUT VOLTAGE (V)  
0
1
2
3
4
5
6
7
8
9
A
B
C
D
E
-
3.1  
3.2  
3.3  
3.4  
3.5  
3.6  
3.7  
3.8  
3.9  
4.0  
4.1  
4.2  
4.3  
4.4  
4.5  
-
-
-
-
-
-
-
-
-
-
-
3.15  
3.25  
3.35  
3.45  
3.55  
3.65  
3.75  
3.85  
3.95  
4.05  
4.15  
F
H
K
L
1.6  
1.7  
1.8  
1.9  
2.0  
2.1  
2.2  
2.3  
2.4  
2.5  
2.6  
2.7  
2.8  
2.9  
3.0  
4.6  
1.65  
1.75  
1.85  
1.95  
2.05  
2.15  
2.25  
2.35  
2.45  
2.55  
2.65  
2.75  
2.85  
2.95  
3.05  
4.65  
-
4.7  
4.75  
-
4.8  
4.85  
-
4.9  
4.95  
-
-
M
N
P
R
S
T
5.0  
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
USP-4  
(TOP VIEW)  
-
-
-
-
-
U
V
X
Y
Z
1.2  
1.3  
1.4  
1.5  
1.25 4.25  
1.35 4.35  
1.45 4.45  
1.55 4.55  
represents production lot number  
0 to 9, to Z reverse character 0 to 9, A to Z repeated (G, I, J, O, Q, W excluded)  
represents integer of output voltage  
SSOT-24  
MARK  
VOLTAGE (V)  
PRODUCT SERIES  
XC6213B3xxNx  
XC6213B5xxNx  
4
3
3
5
3.X  
5.X  
represents decimal point of output voltage  
VOLTAGE  
VOLTAGE  
(V)  
PRODUCT  
1
2
MARK  
PRODUCT SERIES  
MARK  
(V)  
X.0  
X.1  
X.2  
X.3  
X.4  
X.5  
X.6  
X.7  
X.8  
X.9  
SERIES  
SSOT-24 (SC-82)  
(TOP VIEW)  
0
1
2
3
4
5
6
7
8
9
XC6213Bx0xNx  
XC6213Bx1xNx  
XC6213Bx2xNx  
XC6213Bx3xNx  
XC6213Bx4xNx  
XC6213Bx5xNx  
XC6213Bx6xNx  
XC6213Bx7xNx  
XC6213Bx8xNx  
XC6213Bx9xNx  
A
B
C
D
E
F
X.05  
X.15  
X.25  
X.35  
X.45  
X.55  
X.65  
X.75  
X.85  
X.95  
XC6213Bx0ANx  
XC6213Bx1ANx  
XC6213Bx2ANx  
XC6213Bx3ANx  
XC6213Bx4ANx  
XC6213Bx5ANx  
XC6213Bx6ANx  
XC6213Bx7ANx  
XC6213Bx8ANx  
XC6213Bx9ANx  
H
K
L
M
represents production lot number  
0 to 9, A to Z repeated (G, I, J, O, Q, W excluded). Note: No character inversion used.  
27/33  
XC6213 Series  
MARKING RULE (Continued)  
represents product series  
USPN-4  
MARK  
C
PRODUCT SERIES  
XC6213xxxxxx  
represents type of regulator  
MARK  
VOLTAGE  
=0.1~3.0V  
VOLTAGE  
VOLTAGE  
VOLTAGE  
PRODUCT SERIES  
XC6213Bxxxxx  
=3.1~6.0V =0.15~3.05V =3.15~6.05V  
X
B
F
M
represents output voltage  
MARK  
OUTPUT VOLTAGE (V)  
MARK  
OUTPUT VOLTAGE (V)  
0
1
2
3
4
5
6
7
8
9
A
B
C
D
E
-
3.1  
3.2  
3.3  
3.4  
3.5  
3.6  
3.7  
3.8  
3.9  
4.0  
4.1  
4.2  
4.3  
4.4  
4.5  
-
-
-
-
-
-
-
-
-
-
-
3.15  
3.25  
3.35  
3.45  
3.55  
3.65  
3.75  
3.85  
3.95  
4.05  
4.15  
F
H
K
L
1.6  
1.7  
1.8  
1.9  
2.0  
2.1  
2.2  
2.3  
2.4  
2.5  
2.6  
2.7  
2.8  
2.9  
3.0  
4.6  
1.65  
1.75  
1.85  
1.95  
2.05  
2.15  
2.25  
2.35  
2.45  
2.55  
2.65  
2.75  
2.85  
2.95  
3.05  
4.65  
-
4.7  
4.75  
-
4.8  
4.85  
-
4.9  
4.95  
-
-
M
N
P
R
S
T
5.0  
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
U
V
X
Y
Z
1.2  
1.3  
1.4  
1.5  
1.25 4.25  
1.35 4.35  
1.45 4.45  
1.55 4.55  
④⑤ represents production lot number  
01 to 09, 0A to 0Z 11 to 9Z, A1 to A9, AA to Z9,ZA to ZZ repeated  
(G, I, J, O, Q, W excluded). Note: No character inversion used.  
28/33  
XC6213  
Series  
SOT-25 Power Dissipation  
Power dissipation data for the SOT-25 is shown in this page.  
The value of power dissipation varies with the mount board conditions.  
Please use this data as one of reference data taken in the described  
condition.  
1. Measurement Condition (Reference data)  
Condition:  
Ambient:  
Soldering:  
Board:  
Mount on a board  
Natural convection  
Lead (Pb) free  
Dimensions 40 x 40 mm (1600 mm2 in one side)  
Copper (Cu) traces occupy 50% of the board area  
In top and back faces  
Package heat-sink is tied to the copper traces  
(Board of SOT-26 is used.)  
Glass Epoxy (FR-4)  
Material:  
Thickness:  
1.6 mm  
Through-hole: 4 x 0.8 Diameter  
2. Power Dissipation vs. Ambient temperature  
Evaluation Board (Unit: mm)  
Board Mount (Tj max = 125)  
Ambient Temperature(℃)  
Power Dissipation PdmW)  
Thermal Resistance (/W)  
166.67  
25  
85  
600  
240  
Pd vs. Ta  
700  
600  
500  
400  
300  
200  
100  
0
25  
45  
65  
85  
105  
125  
Ambient Temperature Ta ()  
29/33  
XC6213 Series  
SSOT-24 Power Dissipation  
Power dissipation data for the SSOT-24 is shown in this page.  
The value of power dissipation varies with the mount board conditions.  
Please use this data as one of reference data taken in the described  
condition.  
1. Measurement Condition (Reference data)  
Condition:  
Ambient:  
Soldering:  
Board:  
Mount on a board  
Natural convection  
Lead (Pb) free  
Dimensions 40 x 40 mm (1600 mm2 in one side)  
Copper (Cu) traces occupy 50% of the board area  
In top and back faces  
Package heat-sink is tied to the copper traces  
Glass Epoxy (FR-4)  
Material:  
Thickness:  
Through-hole:  
1.6 mm  
Evaluation Board (Unit: mm)  
4 x 0.8 Diameter  
2. Power Dissipation vs. Ambient temperature  
Board Mount (Tj max = 125)  
Ambient Temperature(℃)  
Power Dissipation PdmW)  
Thermal Resistance (/W)  
200.00  
25  
85  
500  
200  
30/33  
XC6213  
Series  
USP-4 Power Dissipation  
Power dissipation data for the USP-4 is shown in this page.  
The value of power dissipation varies with the mount board conditions.  
Please use this data as one of reference data taken in the described  
condition.  
40.0  
28.9  
1. Measurement Condition (Reference data)  
Condition:  
Ambient:  
Soldering:  
Board:  
Mount on a board  
Natural convection  
Lead (Pb) free  
Dimensions 40 x 40 mm (1600 mm2 in one side)  
Copper (Cu) traces occupy 50% of the board area  
In top and back faces  
Package heat-sink is tied to the copper traces  
Glass Epoxy (FR-4)  
Material:  
Thickness:  
Through-hole:  
1.6 mm  
1.4  
2.54  
4 x 0.8 Diameter  
Evaluation Board (Unit: mm)  
2. Power Dissipation vs. Ambient temperature  
Board Mount (Tj max = 125)  
Ambient Temperature(℃)  
Power Dissipation PdmW)  
Thermal Resistance (/W)  
100.00  
25  
85  
1000  
400  
31/33  
XC6213 Series  
USPN-4 Power Dissipation  
Power dissipation data for the USPN-4 is shown in this page.  
The value of power dissipation varies with the mount board conditions.  
Please use this data as one of reference data taken in the described  
condition.  
1.Measurement Condition (Reference data)  
Condition:  
Ambient:  
Soldering:  
Board:  
Mount on a board  
Natural convection  
Lead (Pb) free  
Dimensions 40 x 40 mm (1600 mm2 in one side)  
Copper (Cu) traces occupy 50% of the front and 50%  
of the back.  
The copper area is divided into four block,  
one block is 12.5% of total.  
The USPN-4 package has for terminals.  
Each terminal connects one copper block in the front and  
one in the back.  
Material:  
Glass Epoxy (FR-4)  
Thickness:  
Through-hole:  
1.6 mm  
Evaluation Board (Unit: mm)  
4 x 0.8 Diameter  
2. Power Dissipation vs. Ambient temperature  
Board Mount (Tj max = 125)  
Ambient Temperature(℃)  
Power Dissipation PdmW)  
Thermal Resistance (/W)  
166.67  
25  
85  
600  
240  
32/33  
XC6213  
Series  
1. The products and product specifications contained herein are subject to change without  
notice to improve performance characteristics. Consult us, or our representatives  
before use, to confirm that the information in this datasheet is up to date.  
2. We assume no responsibility for any infringement of patents, patent rights, or other  
rights arising from the use of any information and circuitry in this datasheet.  
3. Please ensure suitable shipping controls (including fail-safe designs and aging  
protection) are in force for equipment employing products listed in this datasheet.  
4. The products in this datasheet are not developed, designed, or approved for use with  
such equipment whose failure of malfunction can be reasonably expected to directly  
endanger the life of, or cause significant injury to, the user.  
(e.g. Atomic energy; aerospace; transport; combustion and associated safety  
equipment thereof.)  
5. Please use the products listed in this datasheet within the specified ranges.  
Should you wish to use the products under conditions exceeding the specifications,  
please consult us or our representatives.  
6. We assume no responsibility for damage or loss due to abnormal use.  
7. All rights reserved. No part of this datasheet may be copied or reproduced without the  
prior permission of TOREX SEMICONDUCTOR LTD.  
33/33  

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