TOREX XC9213_2

XC9213 Series
ETR0505_001
Synchronous Step-Down
DC/DC Controller IC - Input Voltage : 25V
☆GreenOperation Compatible
■GENERAL DESCRIPTION
The XC9213 series is N-ch & N-ch drive, synchronous, step-down DC/DC controller IC with a built-in bootstrap driver circuit.
Output will be stable no matter which load capacitors, including low ESR capacitors, are used.
Resistance (RSENSE) of about several 10mΩ will be required as a current sense. The phase compensation is also run when
a low ESR capacitor is used. In addition, the circuit is double protected by the ways of limiting the current while detecting
overshoot current and making output shutdown at any given timing by a protection time setting capacitor (CPRO).
The output voltage can be set freely within a range of 1.5V~15.0V with 1.0V (accuracy±2%) of internal reference voltage by
using externally connected resistors (RFB1, 2). Synchronous rectification PWM control can be switched to non-synchronous
current limit PFM/PWM automatic switchable control (=voltage between RSENSE pins) by using the MODE pin.
The series has a built-in voltage detector for monitoring a selected voltage by external resistors.
During stand-by (CE pin = low) all circuits are shutdown to reduce current consumption to as low as 4.0μA or less.
■APPLICATIONS
■FEATURES
: 4.0V ~ 25.0V
: 1.5V ~ 15.0V externally set
Reference voltage: 1.0V (±2%)
Oscillation Frequency : 300kHz (±15%)
Output Current
: More than 5A
(VIN=5.0V, VOUT=3.3V)
Control
: PWM/PFM
manual-switching control
Current Limiter
: Current limit operates at voltage
Protection
sense 170mV (TYP.). Shutdown
time can be adjusted by CPRO.
High Efficiency
: 93%
[TYP. PWM Mode@VIN=5.0V,
VOUT=3.3V, IOUT=1A]
Detect Voltage Function : Detects 0.9V/Open-drain output
Stand-by Current
: ISTB = 4.0μA (MAX.)
Load Capacitor
: Low ESR capacitor compatible
Synchronous Bootstrap N-ch & N-ch Driver
Package
: TSSOP-16
Input Voltage Range
Output Voltage Range
●PDAs
●Mobile phones
●Note book computers
●Portable audio systems
●Various multi-function power supplies
■TYPICAL APPLICATION CIRCUIT
■TYPICAL PERFORMANCE
CHARACTERISTICS
SD2
RSENSE
VIN
VDIN
VIN
VL
CVL
CSS
CPRO
Tr1
L
LX
VDOUT
CSS
CBST
BST
EXT1
VDIN
VDOUT
CIN
VSENSE
SD1
XC9213
VOUT
RFB1
CFB
CL
FB
EXT2
RFB2
Tr2
AGND MODE CE PGND
CPRO
1/34
XC9213 Series
■PIN CONFIGURATION
TSSOP-16 (TOP VIEW)
■PIN ASSIGNMENT
PIN NUMBER
PIN NAME
1
2
VIN
VSENSE
3
VL
FUNCTION
Input Voltage
Current Detection
Local Power Supply
4
CE
5
AGND
Analog Ground
6
MODE
PWM / Current Limit PFM Switch
7
CPRO
Protection Time Setting Capacitor Connection
<Set shutdown time of VOUT when detecting overcurrent>
8
CSS
Soft-start Capacitor Connection
Voltage Detector Input (0.9V)
9
VDIN
10
FB
11
Chip Enable
<Set soft-start time>
Output Voltage Setting Resistor Connection
VDOUT
Voltage Detector Output (Open-Drain)
12
PGND
Power Ground
13
EXT2
Low Side N-ch Driver Transistor
14
LX
15
EXT1
High Side N-ch Driver Transistor
16
BST
Bootstrap
< Set output voltage freely by split resistors >
<Connect to Gate of Low Side N-ch MOSFET >
Coil Connection
<Connect to Gate of High Side N-ch MOSFET >
■CE PIN & MODE PIN FUNCTION
CE PIN
OPERATIONAL STATE
H
Operation
L
Shut down
MODE PIN
H
L
OPERATIONAL STATE
Synchronous
PWM Control
Non-Synchronous
PWM / Current Limit PFM Automatic Switching Control
■PRODUCT CLASSIFICATION
●Ordering Information
XC9213B①②③④⑤
DESIGNATOR
DESCRIPTION
SYMBOL
① ②
Reference Voltage
10
③
Oscillation Frequency
3
: 300kHz
④
Package
V
: TSSOP-16
⑤
Device Orientation
R
: Embossed tape, standard feed
L
: Embossed tape, reverse feed
2/34
DESCRIPTION
: 1.0V (Fixed)
XC9213
Series
■ABSOLUTE MAXIMUM RATINGS
PARAMETER
SYMBOL
RATINGS
Ta = 25OC
UNITS
VIN Pin Voltage
VSENSE Pin Voltage
VL Pin Voltage
CE Pin Voltage (*)
MODE Pin Voltage (*)
CPRO Pin Voltage
CSS Pin Voltage
VDIN Pin Voltage
FB Pin Voltage
VDOUT Pin Voltage
EXT2 Pin Voltage
Lx Pin Voltage
EXT1 Pin Voltage
BST Pin Voltage
EXT1 Pin Current
EXT2 Pin Current
Lx Pin Current
Power Dissipation
Operational Temperature Range
Storage Temperature Range
VIN
VSENSE
VL
CE
MODE
CPRO
CSS
VDIN
FB
VDOUT
EXT2
Lx
EXT1
BST
IEXT1
IEXT2
ILx
Pd
Topr
Tstg
- 0.3 ~ 30.0
- 0.3 ~ 30.0
- 0.3 ~ 6.0
- 0.3 ~ 30.0
- 0.3 ~ 30.0
- 0.3 ~ 6.0
- 0.3 ~ 6.0
- 0.3 ~ 6.0
- 0.3 ~ 6.0
- 0.3 ~ 30.0
- 0.3 ~ 6.0
- 0.3 ~ 30.0
- 0.3 ~ 30.0
- 0.3 ~ 30.0
±100
±100
100
350
- 40 ~ + 85
- 55 ~ + 125
V
V
V
V
V
V
V
V
V
V
V
V
V
V
mA
mA
mA
mW
O
C
O
C
(*) CE, MODE pin voltage
1) 1.4V≦High Level≦6V
The CE pin and the MODE pin can be connected directly
to the high level power supply.
2) 6V < High Level < 30V
The CE pin and the MODE pin should be connected to
over 1kΩ resistor when connecting
1.4V<High Level<6V
6V<High Level<30V
R>1kΩ
IC Inside
IC Inside
CE or
MODE
CE or
MODE
3/34
XC9213 Series
■ELECTRICAL CHARACTERISTICS
XC9213B103 (FOSC = 300kHz)
PARAMETER
SYMBOL
Input Voltage (*2)
Output Voltage
Setting Range
FB Control Voltage
U.V.L.O. Voltage
Supply Current 1
Supply Current 2
Stand-by Current
Oscillation Frequency
Maximum Duty Ratio 1
Maximum Duty Ratio 2
VFB
UVLO
IDD1
IDD2
ISTB
FOSC
MAXDTY1
MAXDTY2
PFM Duty Ratio
PFMDTY
Sense Voltage
VSENSE
CPRO time
TPRO
Soft-Start Time
TSS
Short Protection Circuit
Operating Voltage
VSHORT
Efficiency
EFFI
CE "H" Voltage
VCEH
CE "L" Voltage
VCEL
MODE "H" Voltage
VMODEH
MODE "L" Voltage
VMODEL
EXT1 "H"
ON Resistance
EXT1 "L"
ON Resistance
EXT2 "H"
ON Resistance
EXT2 "L"
ON Resistance
MIN.
TYP.
MAX.
UNITS
CIRCUIT
VIN
4.0
-
25.0
V
-
VOUTSET
1.5
-
15.0
V
-
0.980
1.0
255
91
-
1.000
1.5
550
450
300
95
98
1.020
2.0
800
600
4.0
345
-
V
V
μA
μA
μA
kHz
%
%
1
2
3
3
4
5
5
5
2.5
3.0
3.9
μs
6
145
170
200
mV
7
2.3
4.7
9.4
ms
8
4
8
21
ms
9
0.15
0.40
0.72
V
25
-
93
-
%
10
1.4
-
-
V
11
-
-
0.4
V
11
1.4
-
-
V
12
-
-
0.4
V
12
CONDITIONS
Voltage which EXT1 pin starts oscillation
CE=VIN, FB=0.9V
CE=VIN, FB=1.1V
CE=FB=0V
CE=VIN, FB=0.9V
CE=VIN, FB=0.9V
CE=VIN, FB=1.1V
With external components,
VOUT=3V, MODE=0V, IOUT=1mA,
No RSENSE
Voltage which EXT1 pin stops oscillation
CPRO=4700pF, VSENSE=0V 0.5V,
Time until VDOUT inverts H to L
With external components,
CSS=4700pF, CE=0V 3V,
Time until voltage becomes VOUT x 0.95
VIN-VSENSE: 0.3V fixed, FB: SWEEP.
Voltage which VDOUT inverts H to L
With external components, IOUT=1A,
VOUT=3.0V
Voltage which EXT1 pin starts oscillation
Voltage which EXT1 pin voltage holding
"L" level
Voltage which EXT2 pin starts oscillation
Voltage which EXT2 pin voltage holding
"L" level
REXT1H
FB=0.9V, EXT1=3.6V
-
18
23
Ω
13
REXT1L
FB=1.1V, EXT1=0.4V
-
11
18
Ω
14
REXT2H
FB=1.1V, EXT1=3.6V
-
18
23
Ω
15
REXT2L
FB=0.9V, EXT2=0.4V
-
4
8
Ω
16
-
100
-
ns
10
-
60
-
ns
10
-0.1
-0.1
-4.0
-0.1
-2.0
-
0.1
0.1
0.1
-
μA
μA
μA
μA
μA
μA
μA
17
17
18
18
19
20
20
Dead Time 1
TDT1
Dead Time 2
TDT2
CE "H" Current
CE "L" Current
MODE "H" Current
MODE "L" Current
CSS Current
FB "H" Current
FB "L" Current
ICEH
ICEL
4/34
Ta=25OC
IMODEH
IMODEL
ICSS
IFBH
IFBL
With external components,
EXT1: H L, EXT2: L H
With external components,
EXT2: H L, EXT1: L H
CE=5.0V
CE=0V
MODE=5.0V
MODE=0V
CSS=0V
FB=5.0V
FB=0V
XC9213
Series
■ELECTRICAL CHARACTERISTICS (Continued)
XC9213B103 (Continued)
●Voltage Regulator (*3)
PARAMETER
Output Voltage
Load Regulation
Input Regulation
SYMBOL
VLOUT
VLOUT
VLOUT
VIN・VLOUT
CONDITIONS
MIN.
TYP.
MAX.
UNITS
CIRCUIT
FB=1.1V, ILOUT=10mA
FB=1.1V, 1mA≦ILOUT≦30mA
FB=1.1V, ILOUT=10mA,
VLOUT+1V≦VIN≦25V
3.86
-
4.00
45
4.14
90
V
mV
21
21
-
0.05
0.1
%/V
21
CONDITIONS
MIN.
TYP.
MAX.
UNITS
CIRCUIT
0.855
0.900
0.925
V
22
0.915
0.954
0.980
V
22
2.9
5
-
6.0
15
-
7.5
20
10
0.1
%
mA
μs
μA
22
23
22
24
●Voltage Detector
PARAMETER
SYMBOL
Detect Voltage
VDF
Release Voltage (*4)
VDR
Hysteresis Range
Output Current
Delay Time
VDIN Current
HYS
VDIOUT
TDLY
IVDIN
FB=1.1V,
Voltage which VDOUT inverters H to L
FB=1.1V,
Voltage which VDOUT inverters L to H
FB=1.1V
FB=1.1V, VDIN=VDF-0.4V, VDOUT=0.5V
VDR→VDOUT inversion
VDIN=5.0V
NOTE:
*1: Unless otherwise stated, VIN=5.0V, CE=5.0V, MODE=5.0V, FB=0.9V
*2: The operation may not be stable at no load, if the step-down ratio (VOUT/VIN x 100) becomes lower than 12%.
*3: The regulator block is used only for bootstrap.
*4: Release voltage: (VDR) = VDF + HYS x VDF
Please do not use as a local power supply.
5/34
XC9213 Series
■TEST CIRCUITS
Circuit 1
Circuit 2
OCS
OCS
Circuit 3
Circuit 4
Circuit 5
Circuit 6
SBD1
VIN
VSE NSE
VL
+
-
10u F 1uF
+
-
+
-
VIN
OCS
OCS
EXT1
LX
EXT2
AGND
PGND
MODE
VDOUT
CSS
VSENSE
100 kΩ
+
-
1uF
EXT1
1uF
Tr1
VL
LX
CE
EXT2
AGND
PGND
MODE
VDOUT
Tr2
CFB
+
-
FB
BST
L
100 kΩ
OCS
OCS
CE
CPRO
OSC
OSC
CIN
BST
+
-
CPRO
CSS
VDIN
FB
RFB1
RFB2
VDIN
100pF
100p F
+
-
Circuit 7
+
-
+
-
10uF 1uF
+
-
+
-
VIN
VSENSE
6/34
EXT1
VL
LX
CE
EXT2
AGND
PGND
MODE
VDOUT
CPRO
CSS
100pF100pF
BST
OSC
OSC
100kΩ
FB
VDIN
+
-
100kΩ
Tr1:
Tr2:
SBD1:
L:
22μH
CL:
100μF
CIN1:
22μF
RFB1: 220kΩ
RFB2: 110kΩ
CFB:
68pF
2SK2857 (NEC)
2SK2857 (NEC)
CRS02 (TOSHIBA)
CDRH6D28 (SUMIDA)
(OS-CON, NIPPON CHEMI-CON)
(OS-CON, SANYO)
CL
XC9213
Series
■TEST CIRCUITS (Continued)
Circuit 8
Circuit 9
VIN
RSENSE: 33 mΩ
10uF 1uF
+
-
+
-
4700pF
XB01SB04A2BR(TOREX)
EXT1
VSE NSE
VL
LX
CE
EXT2
AGND
PG ND
M O DE
VDO UT
CPR
FB
CSS
VDIN
OSC
OSC
VIN
100kΩ 100kΩ
VSENSE
ceramic
1uF
+
-
100pF
ceramic
10uF+10uF
BST
ceramic
1uF
EXT1
VL
LX
CE
EXT2
AGND
PGND
MODE
VDOUT
CPRO
FB
7.4uH(SUMIDA)
VOUT
CMS02
(TOSHIBA)
VIN
100kΩ
ceramic
47pF
200kΩ
VL
VDIN
CSS
IRF7313
(IR)
100kΩ
100kΩ
ceramic
4700pF
25PS100JM12 100uF
(NIPPON CHEMI-CON)
+
-
BST
VIN
+
-
GND
Circuit 10
Circuit 11
VIN
RSENSE: 33 mΩ
VIN
XB01SB04A2BR(TOREX)
VL
ceramic
1uF
ceramic
4700pF
CE
EXT1
ceramic
1uF
VSENSE
IRF7313
(IR)
7.4uH(SUMIDA)
LX
EXT2
AGND
PGND
MODE
VDOUT
CPRO
FB
CSS
ceramic
10uF+10uF
VDIN
CMS02
(TOSHIBA)
+
-
ceramic
47pF
VIN
100kΩ
200kΩ
VL
100kΩ
100kΩ
ceramic
4700pF
25 PS 100 JM12 100u F
VSENSE
BST
10uF 1uF
+
-
(NIPP ON CH EMI-CON)
VIN
BST
EXT1
VL
LX
CE
EXT2
AGND
PGND
MODE
VDOUT
CPRO
CSS
OSC
OSC
100kΩ
100kΩ
FB
VDIN
100pF
+
-
GND
Circuit 12
Circuit 13
VIN
VSENSE
+
-
10uF 1uF
+
-
VL
LX
CE
EXT2
AGND
PGND
MODE
VDOUT
CPRO
CSS
100pF
VIN
BST
EXT1
VSENSE
100kΩ
100kΩ
OSC
O SC
+
-
FB
10uF 1uF
+
-
VDIN
VL
LX
CE
EXT2
AGND
PGND
MODE
VDOUT
CPRO
CSS
+
-
100pF
BST
OSC
OSC
EXT1
FB
50kΩ
VDIN
+
-
+
-
10uF
7/34
XC9213 Series
■TEST CIRCUITS (Continued)
Circuit 14
Circuit 15
VSENSE
+
-
10uF 1uF
+
-
VSENSE
EXT1
VL
LX
VL
LX
EXT2
CE
EXT2
AGND
PGND
MODE
VDOUT
CPRO
V
FB
+
-
AGND
PGND
MODE
VDOUT
CPRO
FB
CSS
+
-
OSC
OSC
50Ω
VDIN
100pF
Circuit 16
+
-
+
-
10uF
Circuit 17
VIN
VSENSE
10uF 1uF
+
-
BST
VIN
BST
EXT1
VSENSE
EXT1
VL
LX
VL
LX
CE
EXT2
CE
EXT2
AGND
PGND
MODE
VDOUT
CPRO
CSS
+
-
V
10uF 1uF
A
FB
+
-
VDIN
AGND
PGND
MODE
VDOUT
CPRO
100kΩ
100kΩ
FB
CSS
VDIN
+
-
100pF
100pF
Circuit 18
Circuit 19
VIN
VSENSE
10uF 1uF
VSENSE
EXT1
LX
CE
EXT2
AGND
PGND
MODE
VDOUT
CSS
+
-
VIN
FB
100kΩ
100kΩ
+
-
10uF 1uF
+
-
+
-
EXT1
VL
LX
CE
EXT2
AGND
PGND
MODE
VDOUT
CPRO
CSS
VDIN
A
100pF
BST
BST
VL
CPRO
A
8/34
10uF 1uF
+
-
VDIN
100pF
+
-
EXT1
CE
CSS
+
-
BST
VIN
BST
VIN
FB
VDIN
100kΩ
100kΩ
XC9213
Series
■TEST CIRCUITS (Continued)
Circuit 20
Circuit 21
+
-
10uF 1uF
EXT1
VL
LX
CE
EXT2
AGND
PGND
VDOUT
CPRO
CSS
EXT1
VSE NSE
100kΩ
MODE
BST
VIN
BST
VIN
VSENSE
100kΩ
10u F
+
-
IL
↓
1uF
V
+
-
FB
VDIN
+
-
LX
CE
EXT2
AGND
PGND
MODE
VDOUT
CSS
+
-
100 kΩ
VDIN
+
-
100p F
Circuit 22
100 kΩ
FB
CPRO
A
100p F
VL
Circuit 23
VIN
VSENSE
+
-
10uF 1uF
+
-
VL
LX
CE
EXT2
AGND
PGND
MODE
VDOUT
CPRO
CSS
VIN
BST
100kΩ
+
-
10u F 1uF
+
-
V
FB
+
-
+
-
Circuit 24
EXT1
VL
LX
CE
EXT2
AGND
PGND
MODE
VDOUT
CPRO
A
FB
VDIN
CSS
VDIN
100p F
BST
VSE NSE
EXT1
+
-
100p F
+
-
+
-
Circuit 25
VIN
VSENSE
+ 10uF 1uF
-
+
-
100kΩ
VIN
VSENSE
BST
EXT1
VL
LX
VL
LX
CE
EXT2
CE
EXT2
AGND
PGND
MODE
VDOUT
CPRO
CSS
100pF
BST
EXT1
+
-
+
-
FB
VDIN
10uF 1uF
A
+
-
+
-
AGND
PGND
MODE
VDOUT
CPRO
CSS
100pF
OSC
OSC
100kΩ 100kΩ
FB
VDIN
+
-
9/34
XC9213 Series
■BLOCK DIAGRAM
■OPERATIONAL EXPLANATION
< Error Amplifier >
The error amplifier is designed to monitor output voltage. The amplifier compares the reference voltage with the feedback
voltage. When a voltage lower than the reference voltage is fed back, the output voltage of the error amplifier increases.
<Ramp Wave Generator>
The Ramp Wave Generator is organized by the circuits generates a saw-tooth waveform based on the oscillator circuit which
sets an oscillation frequency and a signal from the oscillator circuit.
< PWM Comparator >
The PWM Comparator compares outputs from the error amp. and saw-tooth waveform. When the voltage from the error
amp's output voltage is low, the external switch will be set to OFF.
< U.V.L.O. Comparator >
When the VIN pin voltage is lower than 1.5V (TYP.), the circuit sets EXT/2 to "L" and the external transistor is forced OFF.
< Voltage Regulator >
The voltage regulator block generates 4.0V voltage for the bootstrap circuit. The regulator block is also the power supply for
the internal circuit. Please do not use the regulator block as a local power supply.
<Vref with Soft Start>
The reference voltage, Vref (FB pin voltage)=0.9V, is adjusted and fixed by laser trimming. The soft-start circuit protects
against inrush current, when the power is switched on, and also to protect against voltage overshoot. It should be noted,
however, that this circuit does not protect the load capacitor (CL) from inrush current. With the Vref voltage limited and
depending upon the input to the error amps, the operation maintains a balance between the two inputs of the error amps and
controls the EXT1 pin's ON time so that it doesn't increase more than is necessary.
<CE Control Logic >
This function controls the operation and shutdown of the IC. When the voltage of the CE pin is 0.4V or less, the mode will
be chip disable, the channel's operations will stop. The EXT1/2 pins will be kept at a low level (the external N-ch MOSFET
will be OFF). When the CE pin is in a state of chip disable, current consumption will be no more than 4.0μA. When the
CE pin's voltage is 1.4V or more, the mode will be chip enable and operations will recommence. With soft-start, 95% of the
set output voltage will be reached within 8mS (CSS: 4700pF (TYP.)) from the moment of chip enable.
< Voltage Detector >
The voltage detector of the XC9213 series is FB type. The reference voltage is 0.9V (TYP.) and the detect voltage can be
set by external resistors. The output is N-ch Open Drain type. The detector is switched on / off with DC/DC by the CE pin.
10/34
XC9213
Series
■OPERATIONAL EXPLANATION (Continued)
< Protection Circuit Operation (Current Limit, Latch Protection Circuit, and Short Protection Circuit) >
Shown above is a timing chart for protection circuit operations. When the output current changes from normal to an
overcurrent condition, the current-limiting circuit detects the overcurrent condition as a voltage drop occurring, by virtue of the
current-sensing resistor, at the VSENSE pin. Upon detection, the current-limiting circuit limits the peak current passed
through the high-side N-ch MOSFET at every clock pulse (state ①). It is possible to regulate the value of limited current by
varying the resistance value of the current-sensing resistor. A protection circuit (protective latch circuit), which is designed
to stop the clock, functions if the overcurrent condition continues for a predetermined time (state ②). Time delay before the
protective latch circuit functions is adjustable by the capacitance connected to the CPRO pin (typically 4.7 ms if CPRO has
4,700 pF). The protective latch circuit is reset by turning off and on, or by a disable action followed by an enable action
using the CE pin. If, furthermore, the output is short-circuited (state ③) and VOUT decreases to a value close to 0 V, the
short-circuit protection circuit detects the condition by means of the FB pin and stops the clock with no time delay. The
short-circuit protection circuit is reset by turning off and on or by a disable action followed by an enable action using the CE
pin, as with the protective latch circuit.
< Mode Control Logic >
A timing chart for automatic switching of current-limiting PFM/PWM is shown above. High-level of the MODE pin allows
PWM operations to occur for synchronous rectification (state ①). When the MODE pin shifts to low-level, current-limiting
PFM/PWM automatic switching occurs with synchronous rectification stopped. Consequently, the low-side N-ch MOSFET
is constantly off under this condition. In addition, a comparison is made for the purposes of automatic switching, between
the ON time of the high-side N-ch MOSFET determined by the internal error amp. and the time required for the current
passed at every clock pulse through the high-side N-ch MOSFET to reach a preset amount of current. The longer one is
selected and becomes on duty (state ② or ③). If the time determined by the error amp. is longer than the other, PWM
operation occurs. Current-limiting PFM operation occurs if the time taken by the current passing at every clock pulse to
reach a preset amount of current is longer. Thus the automatic switching mechanism achieves high efficiency under light to
heavy load conditions.
11/34
XC9213 Series
■TYPICAL APPLICATION CIRCUIT
*Please place CIN close to RSENSE as much as possible, so that an impedance does not occur between the elements.
*Please place CIN, RSENSE, Tr1, Tr2, L, CL, and SD1 as close as possible to each other.
■EXTERNAL COMPONENTS
* Please refer to the DC/DC simulation section of the Torex web site (http//:www.torex.co.jp) for more details.
●Recommended N-ch MOSFETs for Tr1 and Tr2
●IOUT: Less than 3A
PART NUMBER
MANUFACTURER
TYPE
Ciss (pF)
Crss (pF)
Crss / (Ciss + Crss)
uPA2751GR
NEC
Dual
1040
130
0.111
IRF7313
International Rectifier
Dual
650
130
0.167
●IOUT: More than 3A
PART NUMBER
MANUFACTURER
TYPE
Ciss (pF)
Crss (pF)
Crss / (Ciss + Crss)
SUD30N03
Vishay
Single
1170
30
0.049
SUD70N03
Vishay
Single
2700
360
0.118
* It is recommended to use MOSFETs with Ciss less than 3000pF.
* For Tr2, MOSFETs with smaller Crss / (Ciss + Crss) are recommended.
●Recommended Coil (L)
PART NUMBER
MANUFACTURER
CDRH127/LD-7R4
SUMIDA
CDRH127-6R1
SUMIDA
* For stable operation, please use a coil with L less than 22μH.
●Recommended Capacitor (CIN, CVL, CBST, CL)
COMPONENTS
CIN (*1)
PART NUMBER
MANUFACTURER
TYPE
VALUE
PCS
-
-
Ceramic
10μF
2
25SC22M
SANYO
OS
22μF
1
CVL
-
-
Ceramic
1μF
1
CBST
-
-
Ceramic
1μF ~ 4.7μF
1
20SS150M
SANYO
OS
150μF
25PS100JM12
NIPPON CHEMI-CON
-
100μF
CL (*2)
(*1)Please place CIN close to RSENSE as much as possible, so that an impedance does not occur between the elements.
A 1μF ceramic capacitor is recommended for CVL.
(*2)Operation may become unstable if a ceramic capacitor is used for CL.
12/34
1
XC9213
Series
■EXTERNAL COMPONENTS (Continued)
●Output Voltage Setting (RFB1, RFB2, CFB)
Output voltage can be set by adding external split resistors. Output voltage is determined by the following equation,
based on the values of RFB1 and RFB2. The sum of RFB1 and RFB2 should normally be 2 MΩ or less
(RFB1 + RFB2≦2MΩ).
VOUT = RFB1 / RFB2 + 1
The value of CFB, speed-up capacitor for phase compensation, should be adjusted by the following equation.
fzfb= 1 / (2 x π x CFB x RFB1)≒10kHz
Adjustments are required from 1kHz to 50kHz depending on the application, value of inductance (L), and value of load
capacity (CL).
VOUT (V)
RFB1 (Ω)
RFB2 (Ω)
CFB (pF)
1.5
150
300
100
1.8
160
200
100
2.5
360
240
47
3.0
220
110
47
3.3
620
270
27
5.0
300
75
47
●Recommended Schottky Diode (SD1, SD2)
SYMBOL
SD1
SD2
PART NUMBER
MANUFACTURER
CMS02
DE5PC3
XB01SB04A2BR
CRS02
TOSHIBA
SHINDENGEN
TOREX
TOSHIBA
* SD1 and SD2 should be of favorable reverse-current characteristics.
If, in particular, SD2 has poor reverse-current characteristics,
CBST cannot be fully charged at high temperatures, resulting, in some cases, in failure to drive Tr1.
●Setting Latch Protection Circuit Delay Time (CPRO)
Time delay is 4.7 ms (TYP.) under the current conditions if CPRO has 4,700 pF. This time delay is roughly proportional to
the value of CPRO.
ex.)
When CPRO is 2200pF,
4.7ms (TYP.) x 2200pF / 4700pF
=2.2ms (TYP.)
When CPRO is 0.01μF (10,000pF),
4.7ms (TYP.) x 10000pF / 4700pF
=10ms (TYP.)
* For stable operation, please use a capacitor with more than 2200pF as CPRO.
●Setting Soft-Start Time (CSS)
Relationships between the value of
CSS and the soft-start time (25OC
TYP.) are shown at left.
For stable
operation, please use a capacitor
with more than 2200pF as CSS.
13/34
XC9213 Series
■EXTERNAL COMPONENTS (Continued)
●Sense Resistance (RSENSE)
The below values can be adjusted by using sense resistance (RSENSE).
It is recommended using the RSENSE value in the range of 20mΩ to 100mΩ.
1) Detect current value of the overcurrent detect circuit
Maximum output current (IOUTMAX) can be adjusted as the equation below.
IOUTMAX (A) ≒ 200mV (MAX.) / RSENSE (mΩ)
When 4V≦VIN＜5V, the maximum output current becomes larger than the calculated value.
Please also refer to the characteristics performance below.
2) Peak current value of the current limit PFM control
Peak current value of the current limit PFM control (I_PFM) varies depending on the dropout voltage (VDIF), the coil (L)
value and the sense resistance value (RSENSE). For the XC9213 series' sample with voltage sense (VSENSE) 170mV,
the characteristic performance below shows the changes in the peak current (I_PFM) when the sense resistance values
(RSENSE) are 20mΩ, 33 mΩ, and 50 mΩ. The peak current varies according to the dropout voltage and the coil value.
PFM Peak Current
RSENSE:20mΩ
3.0
2.5
2.0
1.5
1.0
0.5
0.0
RSENSE:33mΩ
3.0
I_PFM(TYP. 25℃) (A)
I_PFM(TYP. 25℃) (A)
PFM Peak Current
2.5
2.0
1.5
1.0
0.5
0.0
0
1
2
3
Vdif/L (V/μ H)
4
5
0
1
2
3
4
5
Vdif/L (V/μ H)
PFM Peak Current
RSENSE:50mΩ
I_PFM(TYP. 25℃) (A)
3.0
The peak current as shown in three graphs fluctuates
2.5
according to the sample's sense voltage.
2.0
1.5
1.0
0.5
0.0
0
1
2
3
Vdif/L (V/μ H)
14/34
The sense voltage varies within the range of 145 mV≦VSENSE≦200mV.
4
5
XC9213
Series
■EXTERNAL COMPONENTS (Continued)
●Divided Resistors For VD Input Voltages (RVDIN1, RVDIN2)
Detect voltage of the detector block can be adjusted by the external divided resistors for VD input voltages
(RVDIN1, RVDIN2) as the equation below.
When 0.855V < VDF < 0.925V (0.9V TYP.)
Detect voltage = VDF x (RVDIN1 + RVDIN2) / RVDIN2 [V]
Please select RVDIN1 and RVDIN2 as the sum of RVDIN1 and RVDIN2 becomes less than 2MΩ.
●Divided Resistor For VD Output Voltage (RVDOUT)
Output type of the detector block is N-channel open drain. Please use a 1kΩ resistor or more as RVDOUT.
■APPLICATION CIRCUIT EXAMPLE
The application circuit shown below is the example for using the detector block as power good.
Please connect the VDIN pin with the FB pin as below.
15/34
XC9213 Series
■NOTES ON USE
1. Overcurrent Limit Function
The internal current detection circuit is designed to monitor voltage occurs between RSENSE resistors in the overcurrent
condition. In case that the overcurrent limit function operates when the output is shorted, etc., the current detection circuit
detects that the voltage between RSENSE resistors reaches the SENSE voltage (170mV TYP.), and, thereby, the overcurrent
limit circuit outputs the signal, which makes High side’s N-ch MOSFET turn off. Therefore, delay time will occur (300ns TYP.)
after the current detection circuit detects the SENSE voltage before High side’s N-ch MOSFET turns off. When the
overcurrent limit function operates because of rapid load fluctuation etc., the SENSE voltage will spread during the delay
time without being limited at the voltage value, which is supposed to be limited. Therefore, please be noted to the absolute
maximum ratings of external MOSFET, a coil, and an Schottky diode.
2. Short Protection Circuit
In case that a power supply is applied to the IC while the output is shorted, or the IC is switched to enable state from disable
state via the CE pin, when High side’s N-ch MOSFET is ON and Low side’s N-ch MOSFET is OFF, the potential difference
for input voltage will occur to the both ends of a coil. Therefore, the time rate of coil current becomes large. By contrast, when
High side’s N-ch MOSFET is OFF and Low side’s N-ch MOSFET is ON, there is almost no potential difference at both ends
of the coil since the output voltage is shorted to the Ground. For this, the time rate of coil current becomes quite small. This
operation is repeated within soft-start time; therefore, coil current will increase for every clock. Also with the delay time of the
circuit, coil current will be converged on a certain current value without being limited at the current amount, which is
supposed to be limited. However, step-down operation will stop and the circuit can be latched if FB voltage is decreasing to
the voltage level, which enables to operate a short protection circuit when the soft-start time completes. Even if the FB
voltage is not decreasing to the voltage level, which a short protection circuit cannot be operated, the step-down operation
stops when CPRO time completes, and the circuit will be latched.
Please be noted to the absolute maximum ratings of external MOSFET, a coil, and an Schottky diode.
3. Current Limit PFM Control
With a built-in bootstrap buffer driver circuit, the XC9213 series generates voltage for Tr1 to be turned on by charging CBST
with VL (4V). When Tr1 is off, Tr2 is on, and the Lx signal is low, it will be suitable timing for charging CBST. (Please refer to
the above figure.) For that reason, at PFM control (MODE: Low), the clock pulses will decrease extremely according to the
decrease of the load current. As a result, it will cause a decrease of charging frequency and an electric discharge of CBST
so that sufficient voltage for the Tr1 to be turned on will not be supplied.
Therefore,
1) Please use a Schottky Barrier Diode with few reverse current values for SD2.
2) Please avoid extreme light loads (e.g. less than a few mA)
Moreover, the above-mentioned operation may occur, influenced by external components including SD2 and ambient
temperature. It’s recommended to use the IC after evaluation with an actual device.
VL(4V)
SD2
BST
VIN
Tr1
EXT1
XC9213
CBST
CL
Tr2
EXT2
SD1
PGND
16/34
GND
L
LX
CBST Charge
CBST Charge
LX W aveform (MODE:Low, PFM)
XC9213
Series
■NOTES ON USE (Continued)
4. Switching on and off the IC by the input voltage pin
When the IC is switched on and off by the input voltage pin (VIN) instead of the chip enable pin (CE), the IC may stop
operation because a protection circuit built inside the short-protection circuit, etc. begins to work in order to block ON
signal which is sent before the soft-start capacitor connection pin (CSS) resets. The following methods can be used for
avoiding this situation;
a) Turn on the power source again after input voltage becomes below U.V.L.O. detect voltage (1.0V MIN.), furthermore,
after the lapse of the time constant of τ=CSS x 50k.
b) Before turning the power source on again, start-up the IC after resetting the CSS forcibly and keeping soft-start time.
Please make sure the CSS pin is discharged once and the soft-start time is secured when starting up the IC.
17/34
XC9213 Series
■REFERENCE PCB LAYOUT
●Layout For Using a Dual MOSFET
TOREX
TR
CL
CL
RVD1
VDIN
CSS
+
L
VOUT
VL
RFB2
RFB1
FB
Ceramic Capacitor
Test pin
XC9213
RVD2
CPRO
Resistance
VER.2.0B
Tr
GND
CVL
IC
SD
CDD
RVD3
SD1
CBST
CE
0306
RSENSE
RSENSE
SD
SD2
VDOUT
MODE
VIN
+
CIN
CFB
L
●Layout For Using a Single MOSFET
RSENSE
VIN
0308
VER.2.1A
G
TR1
SD2
SD
G
Tr
Resistance
TR2
VDOUT
CIN
RSENSE
TOREX
XC9213
CIN
+
<TOP VIEW>
RVD3
CBST
Ceramic Capacitor
IC
CVL
CE
MODE
Test pin
SD
CDD
GND
CSS
L
SD1
CPRO
RVD1
RVD2
CL
VL
+
CL
L
+
RFB1
FB
VDIN
RFB2
CL
VOUT
CFB
<BOTTOM VIEW>
Tr
* Please use tinned wires etc. for the VIN, the VOUT, and the
GND.
** Please attach test pins etc. to the CE, the MODE, the
EXT, and the EXT2.
*** Please solder mount the RSENSE and the CE as close as
possible.
18/34
XC9213
Series
■TYPICAL PERFORMANCE CHARACTERISTICS
(Unless otherwise stated, Topr:25℃)
(1) Output Voltage vs. Output Current <MODE: High>
VOUT vs. IOUT
1.9
1.8
VIN:5V, 8V, 15V, 20V
1.7
1.6
1.5
100
1000
Output Current IOUT (mA)
VOUT vs. IOUT
3.5
1.8
VIN:5V, 8V, 15V, 20V
1.7
1.6
10000
10
100
1000
Output Current IOUT (mA)
FET:SUD30N03
3.5
3.4
3.3
VIN:5V, 8V, 15V, 20V
3.2
3.1
10000
VOUT vs. IOUT
FET:IRF7313
Output Voltage VOUT (mA)
Output Voltage VOUT (mA)
1.9
1.5
10
3.0
3.4
3.3
VIN:5V, 8V, 15V, 20V
3.2
3.1
3.0
10
100
1000
Output Current IOUT (mA)
VOUT vs. IOUT
5.2
10000
5.0
VIN:8V, 15V, 20V
4.8
100
1000
Output Current IOUT (mA)
VOUT vs. IOUT
FET:IRF7313
5.1
4.9
10
5.2
Output Voltage VOUT (mA)
Output Voltage VOUT (mA)
FET:SUD30N03
2.0
Output Voltage VOUT (mA)
Output Voltage VOUT (mA)
2.0
VOUT vs. IOUT
FET:IRF7313
10000
FET:SUD30N03
5.1
5.0
VIN:8V, 15V, 20V
4.9
4.8
4.7
4.7
10
100
1000
Output Current IOUT (mA)
10000
10
100
1000
Output Current IOUT (mA)
10000
19/34
XC9213 Series
■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)
(2) Output Voltage vs. Output Current <MODE: Low>
VOUT vs. IOUT
FET:IRF7313
2.0
2.0
1.9
1.9
Output Voltage VOUT (mA)
Output Voltage VOUT (mA)
VOUT vs. IOUT
1.8
VIN:5V, 8V, 15V, 20V
1.7
1.6
1.5
100
1000
Output Current IOUT (mA)
VOUT vs. IOUT
VIN:5V, 8V, 15V, 20V
1.7
1.6
10000
3.3
VIN:5V, 8V, 15V, 20V
3.1
100
1000
Output Current IOUT (mA)
VOUT vs. IOUT
FET:IRF7313
3.4
3.2
10
10000
FET:SUD30N03
3.5
Output Voltage VOUT (mA)
Output Voltage VOUT (mA)
3.5
3.4
3.3
VIN:5V, 8V, 15V, 20V
3.2
3.1
3.0
3.0
10
100
1000
Output Current IOUT (mA)
VOUT vs. IOUT
10
10000
5.2
5.2
5.1
5.1
5.0
VIN:8V, 15V, 20V
4.9
4.8
4.7
100
1000
Output Current IOUT (mA)
VOUT vs. IOUT
FET:IRF7313
Output Voltage VOUT (mA)
Output Voltage VOUT (mA)
1.8
1.5
10
10000
FET:SUD30N03
5.0
VIN:8V, 15V, 20V
4.9
4.8
4.7
10
20/34
FET:SUD30N03
100
1000
Output Current IOUT (mA)
10000
10
100
1000
Output Current IOUT (mA)
10000
XC9213
Series
■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)
(3) Efficiency vs. Output Current <MODE: High>
EFFI. vs. IOUT
VOUT:1.8V, FET:IRF7313
100
100
80
Efficiency EFFI. (%)
Efficiency EFFI. (%)
80
60
40
VIN:5V, 8V, 15V, 20V
40
VIN:5V, 8V, 15V, 20V
0
0
10
100
1000
Output Current IOUT (mA)
10
10000
EFFI vs. IOUT
VOUT:3.3V, FET:IRF7313
100
100
1000
Output Current IOUT (mA)
10000
EFFI. vs. IOUT
VOUT:3.3V, FET:SUD30N03
100
80
Efficiency EFFI. (%)
80
Efficiency EFFI. (%)
60
20
20
60
40
VIN:5V, 8V, 15V, 20V
60
40
VIN:5V, 8V, 15V, 20V
20
20
0
0
10
100
1000
Output Current IOUT (mA)
10
10000
EFFI. vs. IOUT
VOUT:5.0V, FET:IRF7313
100
100
1000
Output Current IOUT (mA)
10000
EFFI. vs. IOUT
VOUT:5.0V, FET:SUD30N03
100
80
Efficiency EFFI. (%)
80
Efficiency EFFI. (%)
EFFI. vs. IOUT
VOUT:1.8V, FET:SUD30N03
60
40
VIN:8V, 15V, 20V
20
60
40
VIN:8V, 15V, 20V
20
0
0
10
100
1000
Output Current IOUT (mA)
10000
10
100
1000
Output Current IOUT (mA)
10000
21/34
XC9213 Series
■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)
(4) Efficiency vs. Output Current <MODE: Low>
EFFI. vs. IOUT
EFFI. vs. IOUT
VOUT:1.8V, FET:IRF7313
100
80
Efficiency EFFI. (%)
Efficiency EFFI. (%)
80
60
VIN:5V, 8V, 15V, 20V
40
60
VIN:5V, 8V, 15V, 20V
40
20
20
0
0
10
100
1000
Output Current IOUT (mA)
10
10000
EFFI. vs. IOUT
VOUT:3.3V, FET:IRF7313
100
VOUT:3.3V, FET:SUD30N03
100
Efficiency EFFI. (%)
40
VIN:5V, 8V, 15V, 20V
20
60
40
VIN:5V, 8V, 15V, 20V
20
0
0
10
100
1000
Output Current IOUT (mA)
10
10000
EFFI. vs. IOUT
100
1000
Output Current IOUT (mA)
10000
EFFI. vs. IOUT
VOUT:5.0V, FET:IRF7313
100
VOUT:5.0V, FET:SUD30N03
100
80
80
Efficiency EFFI. (%)
Efficiency EFFI. (%)
10000
80
60
60
40
VIN:8V, 15V, 20V
20
60
40
VIN:8V, 15V, 20V
20
0
0
10
22/34
100
1000
Output Current IOUT (mA)
EFFI. vs. IOUT
80
Efficiency EFFI. (%)
VOUT:1.8V, FET:SUD30N03
100
100
1000
Output Current IOUT (mA)
10000
10
100
1000
Output Current IOUT (mA)
10000
XC9213
Series
■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)
(5) Ripple Voltage vs. Output Current <MODE: High, Coil: CDRH127/LD-7R4>
Vripple vs. IOUT
FET:IRF7313, VIN=5V, VOUT=3.3V
80
Ripple Voltage Vripple (mV)
Ripple Voltage Vripple (mV)
80
60
CL:150μ F (OS-CON SANYO)
40
CL:300μ F (OS-CON SANYO)
20
Vripple vs. IOUT
FET:SUD30N03, VIN=5V, VOUT=3.3V
60
CL:150μ F (OS-CON SANYO)
40
CL:300μ F (OS-CON SANYO)
20
0
0
10
100
1000
Output Current IOUT (mA)
10
10000
FET:IRF7313, VIN=15V, VOUT=5.0V
CL:150μ F (OS-CON SANYO)
40
20
FET:SUD30N03, VIN=15V, VOUT=5.0V
80
Ripple Voltage Vripple (mV)
Ripple Voltage Vripple (mV)
60
10000
Vripple vs. IOUT
Vripple vs. IOUT
80
100
1000
Output Current IOUT (mA)
CL:150μ F (OS-CON SANYO)
60
40
20
CL:300μ F (OS-CON SANYO)
CL:300μ F (OS-CON SANYO)
0
0
10
100
1000
Output Current IOUT (mA)
10
10000
100
1000
Output Current IOUT (mA)
10000
(6) FB Voltage Temperature Characteristics
1.04
FB Voltage
VFB (V)
VFB (V)
1.02
1.00
0.98
0.96
0.94
-50
0
Topr ( ℃ )
50
Temperature Topr(℃)
100
VFB Temperature coefficient (ppm/℃,25℃-based)
VFB vs. Topr
VFB Temperature coefficient vs. Topr
(25℃ -based)
100
50
0
-50
-100
-50
0
Topr ( ℃ )
50
100
Temperature Topr(℃)
23/34
XC9213 Series
■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)
(7) Oscillation Frequency Temperature Characteristics
400
FOSC( kHz)
350
300
250
200
-50
0
50
)
Topr ( ℃Topr(℃)
Temperature
100
FOSC Temperature coefficient (ppm/℃ ,25℃ -based)
FOSC vs. Topr
FOSC Temperature Coefficient vs. Topr
(25℃ -based)
3000
2000
1000
0
-1000
-2000
-3000
-50
0
50
100
Topr ( ℃
)
Temperature
Topr(℃)
(8) Supply Current 1 & 2 Temperature Characteristics
IDD2 vs. Topr
800
800
700
700
Supply Current 2 IDD2 (A)
Supply Current 1 IDD1 (μ A)
IDD1 vs. Topr
600
500
400
300
200
-50
0
50
100
Topr ( ℃
)
Temperature
Topr(℃)
(9) Stand-by Current Temperature Characteristics
ISTB vs. Topr
Standby Current ISTB (μ A)
10
8
6
4
2
0
-50
0
50
Topr (Topr(℃)
Temperature
℃)
24/34
100
600
500
400
300
200
-50
0
50
Temperature
Topr ( ℃Topr(℃)
)
100
XC9213
Series
■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)
VLOUT vs. Topr
VD Output Volage VLOUT (V)
4.2
4.1
4.0
3.9
3.8
-50
0
50
100
Temperature
Topr(℃)
)
Topr ( ℃
VLOUT Temperature coefficient (ppm/℃ ,25℃ -based)
(10) VR Output Voltage Temperature Characteristics
VLOUT Temperature coefficient vs. Topr (25℃ -based)
100
50
0
-50
-100
(11) VD Detect Voltage Temperature Characteristics
-50
0
50
(12) VD Release Voltage Temperature Characteristics
VDR vs. Topr
1.00
0.95
0.95
Release Voltage VDR (V)
Detect Voltage VDF (V)
VDF vs. Topr
1.00
0.90
0.85
0.80
-50
0
100
Temperature
Topr ( ℃Topr(℃)
)
50
0.90
0.85
0.80
100
-50
Temperature Topr(℃)
0
50
100
)
Topr ( ℃Topr(℃)
Temperature
Topr ( ℃ )
(13) CE "H", "L" Voltage Temperature Characteristics
VCEL vs. Topr
1.4
1.2
1.2
CE "L" Voltage VCEL (V)
CE "H" Voltage VCEH (V)
VCEH vs. Topr
1.4
1.0
0.8
0.6
0.4
1.0
0.8
0.6
0.4
0.2
0.2
-50
0
50
Temperature
)
Topr ( Topr(℃)
℃
100
-50
0
50
100
Temperature
Topr(℃)
)
Topr ( ℃
25/34
XC9213 Series
■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)
(14) MODE "H", "L" Voltage Temperature Characteristics
VMODEL vs. Topr
1.4
1.2
1.2
MODE "L" Voltage VMODEL(V)
MODE "H" Voltage VMODEH(V)
VMODEH vs. Topr
1.4
1.0
0.8
0.6
0.4
0.2
1.0
0.8
0.6
0.4
0.2
-50
0
50
-50
100
Temperature
Topr ( ℃Topr(℃)
)
VSHORT vs. Topr
Sense Voltage VSENSE (V)
0.18
0.16
0.14
0.12
0.10
50
100
Temperature
Topr ( ℃Topr(℃)
)
UVLO vs. Topr
U.V.L.O. Voltage UVLO (V)
2.5
2.0
1.5
1.0
0.5
26/34
0
50
Topr ( ℃ )Topr(℃)
Temperature
0.7
0.6
0.5
0.4
0.3
0.2
0.1
-50
0
50
Topr ( ℃Topr(℃)
)
Temperature
(17) U.V.L.O. Voltage Temperature Characteristics
-50
Short Protection Circuit Operating Voltage VSHORT (V)
VSENSE vs. Topr
0
100
(16) Short Protection Circuit Operation Voltage
Temperature Characteristics
VIN:5V, VOUT:1.8V, RSENSE:33mΩ , L:6.1μ H
-50
50
℃
(15) Sense Voltage Temperature Characteristics
0.20
0
Temperature
Topr ( Topr(℃)
)
100
100
XC9213
Series
■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)
(18) Load Transient Response Characteristics <MODE: High>
<Condition>
VIN: 5V
VOUT: 1.8V
1A
IOUT:0A
<Condition>
VIN: 15V
VOUT: 1.8V
1A
IOUT:0A
<Condition>
VIN: 5V
VOUT: 3.3V
1A
IOUT:0A
MODE: High
FET:IRF7313 (International Rectifier)
RSENSE:33mΩ
MODE: High
FET:IRF7313 (International Rectifier)
RSENSE:33mΩ
MODE: High
FET:IRF7313 (International Rectifier)
RSENSE:33mΩ
CL:150μF (OS-CON, SANYO)
L: CDRH127/LD-7R4 (SUMIDA)
CL:150μF (OS-CON, SANYO)
L: CDRH127/LD-7R4 (SUMIDA)
CL:150μF (OS-CON, SANYO)
L: CDRH127/LD-7R4 (SUMIDA)
27/34
XC9213 Series
■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)
(18) Load Transient Response Characteristics <MODE: High> (Continued)
<Condition>
VIN: 15V
VOUT: 3.3V
1A
IOUT:0A
<Condition>
VIN: 5V
VOUT: 1.8V
1A
IOUT:0A
<Condition>
VIN: 15V
VOUT: 1.8V
IOUT:0A ⇔1A
28/34
MODE: High
FET:IRF7313 (International Rectifier)
RSENSE:33mΩ
MODE: High
FET: SUD30N03 (Vishay)
RSENSE:33mΩ
MODE: High
FET: SUD30N03 (Vishay)
RSENSE:33mΩ
CL:150μF (OS-CON, SANYO)
L: CDRH127/LD-7R4 (SUMIDA)
CL:150μF (OS-CON, SANYO)
L: CDRH127/LD-7R4 (SUMIDA)
CL:150μF (OS-CON, SANYO)
L: CDRH127/LD-7R4 (SUMIDA)
XC9213
Series
■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)
(18) Load Transient Response Characteristics <MODE: High> (Continued)
<Condition>
VIN: 5V
VOUT: 3.3V
IOUT:0A ⇔1A
<Condition>
VIN: 15V
VOUT: 3.3V
IOUT:0A ⇔1A
MODE: High
FET:SUD30N03 (Vishay)
RSENSE:33mΩ
MODE: High
FET: SUD30N03 (Vishay)
RSENSE:33mΩ
CL:150μF (OS-CON, SANYO)
L:CDRH127/LD-7R4 (SUMIDA)
CL:150μF (OS-CON, SANYO)
L: CDRH127/LD-7R4 (SUMIDA)
29/34
XC9213 Series
■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)
(19) Load Transient Response Characteristics <MODE: Low>
<Condition>
VIN: 5V
VOUT: 1.8V
IOUT:0A ⇔1A
<Condition>
VIN: 5V
VOUT: 1.8V
IOUT:0A ⇔1A
30/34
MODE: Low
FET:IRF7313 (International Rectifier)
RSENSE:33mΩ
MODE: Low
FET: SUD30N03 (Vishay)
RSENSE:33mΩ
CL:150μF (OS-CON, SANYO)
L: CDRH127/LD-7R4 (SUMIDA)
CL:150μF (OS-CON, SANYO)
L: CDRH127/LD-7R4 (SUMIDA)
XC9213
Series
■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)
(20) Latch Protection Circuit Operating Waveform <MODE: High>
<Condition>
VIN: 5V
VOUT: 3.3V
MODE: High
Topr : - 40℃
FET: SUD30N03 (Vishay)
RSENSE:33mΩ
CPRO: ceramic 4700pF
CL:150μF (OS-CON, SANYO)
L: CDRH127/LD-7R4 (SUMIDA)
Topr : 25℃
Topr : 85℃
31/34
XC9213 Series
■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)
(21) Short-circuit Protection Circuit Operation Waveform
<Condition>
VIN: 5V
VOUT: 3.3V
MODE: High
FET: SUD30N03 (Vishay)
RSENSE:33mΩ
CPRO: ceramic 4700pF
CL:150μF (OS-CON, SANYO)
L: CDRH127/LD-7R4 (SUMIDA)
Topr : 25℃
Topr : - 40℃
Topr : 85℃
(22) Soft-start Circuit Operation Waveform
<Condition>
VIN: 5V
VOUT: 3.3V
IOUT:100mA
32/34
MODE: High
Css: 4700pF
<Condition>
VIN: 20V
VOUT: 15V
IOUT:100mA
MODE: High
Css: 4700pF
XC9213
Series
■PACKAGING INFORMATION
●TSSOP-16
+0. 1
- 0. 05
6. 4± 0. 2
4. 4± 0. 2
0. 5± 0. 2
0. 22
1. 15± 0. 1
0. 22
+0. 1
- 0. 05
0. 1± 0. 05
5. 1± 0. 2
（
0. 65）
■MARKING RULE
●TSSOP-16
16 15
14
13
12
11
a b c
①
②
10
9
①②③④Represents product series
MARK
①
②
③
④
2
1
3
B
1
2
3
⑤
4
⑥
5
6
TSSOP-16
(TOP VIEW)
XC9213B103Vx
d
⑤⑥Represents standard voltage
③
MARK
④
PRODUCT SERIES
⑦
7
8
⑤
⑥
1
0
VOLTAGE (V)
PRODUCT SERIES
1.0
XC9213B103Vx
⑦Represents oscillation frequency
MARK
OSCILLATION FREQUENCY
PRODUCT SERIES
3
300kHz
XC9213B103Vx
33/34
XC9213 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 catalog 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 catalog.
3. Please ensure suitable shipping controls (including fail-safe designs and aging
protection) are in force for equipment employing products listed in this catalog.
4. The products in this catalog 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 catalog 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 catalog may be copied or reproduced without the
prior permission of Torex Semiconductor Ltd.
34/34