KEC KIB3402F

SEMICONDUCTOR
KIB3402F
TECHNICAL DATA
BICD LINEAR INTEGRATED CIRCUIT
White LED Step-Up Converter
The KIB3402F is a monolithic step-up DC/DC converter specifically
designed to drive white LEDs with a constant current from Li-ion cell.
Relative large 320mV feedback voltage & it’s high accuracy help you
setting LED current with a external resistor.
KIB3402F is available in a extremely low profile & small TS-6 package.
A 4.7 H inductor is sufficient for most application.
E
K
6
2
5
3
4
DIM
A
B
C
D
E
F
1
G
B
G
A
K
F
G
D
FEATURES
Inherently Matched LED Current.
MILLIMETERS
_ 0.05
2.9 +
_ 0.05
1.6 +
_ 0.05
0.7 +
_ 0.05
0.4 +
_ 0.07
2.8 +
_ 0.05
1.9 +
0.95
_ 0.05
0.16 +
_ 0.05
0.05 +
MIN 0.21
_ 0.07
0.6 +
H
I
K
L
L
J
Built in a open circuits protection for the LEDs fail.
C
High Efficiency : 85% (max.)
Drives Up to four LEDs without external zener diode.
I
J
J
Drives Up to six LEDs with external zener diode.
0.4
H
Built in a N-channel MOSFET Switch.
Fast 1.1MHz(typ.) Switching Frequency.
Uses Tiny 1mm Tall Inductors.
Bulit in Thermal protection.
TS6
Wide Dimming control range : 25%~100%.
Extremely low height & small Packaging.
Marking
APPLICATIONS
6
Celluars Phones
5
4
Lot No.
PDAs
Type Name
Digital Cameras
402
MP3 Players, Color Displays
1
2
3
TYPICAL APPLICATION
L1
4.7 µH~10 µH
CONVERSION EFFICIENCY
D1
VIN
87.00
6
VCC
SW
LED1
85.00
OVD 2
LED3
KIB3402F
ON
OFF
LED2
C2
1µF
LED4
1 CTL
FB 4
Shutdown and
Dimming control
GND
5
R1
21.5Ω
EFFICIENCY (%)
C1
1µF
3
83.00
81.00
79.00
Vin
3.0V
3.6V
4.3V
77.00
75.00
0
0
C1, C2 : X5R OR X7R DIELECTRIC
D1 : KEC KDR730E/KDR720E (Low VF )
5
10
15
20
25
LOAD CURRENT (mA)
L1 : MURATA LQH32CN100K53L OR EQUIVALENT
Figure1. 4Series White LED Driver in Thin TS6
2006. 4. 20
Revision No : 0
1/6
KIB3402F
BLOCK DIAGRAM
VCC
SW
3
6
2 OVD
+
One Shot
-
+
+
OUT
-
+
-
VRef _
OUT
One Shot
+
+
Vth
+
-
-
OUT
+
_
-
+
320mV
CTL 1
ADC
5
GND
4
FB(Rsense)
figure 2. KIB3402F Block Diagram
MAXIMUM RATINGS (Ta=25
)
CHARATERISTICS
SYMBOL
RATING
UNIT
Input Voltage
VCC
-0.3 ~ 6.0
V
Switching pin Voltage
VSW
-0.3 ~ 22
V
OVD pin Voltage
VOVD
-0.3 ~ 22
V
Operating temperature range
Topr
-40 ~ 85
Storage temperature range
Tstg
-40 ~ 150
Tj
150
Maximum Junction temperature
RECOMMENDED OPERATING CONDITIONS (Topr=-40~85
CHARATERISTICS
Input Voltage
CTL pin voltage for full LED current
)
SYMBOL
CONDITION
MIN.
TYP.
MAX.
UNIT
VCC
-
2.8
-
5.5
V
2.7
-
-
V
-
-
0.5
V
33
-
-
-
20
-
2
-
-
VCTL H
VCC=3.0V
CTL pin voltage to shutdown chip
VCTL L
CTL pin input pulse width
tPW(CTL)
LED Current
CTL Response Delay
(When Power ON.)
2006. 4. 20
IF
Tpd CTL
Revision No : 0
Both Positive and Negative pulse
VCC=3.6V, RSENSE=16
Topr =25 , Four LED
-
,
2/6
KIB3402F
ELECTRICAL CHARACTERISTIC
(Topr=-40~85 , VCC=2.8~5.5V, RSENSE=16
CHARATERISTICS
, unless otherwise noted.)
SYMBOL
CONDITION
MIN.
TYP.
MAX.
UNIT
Input Voltage
VCC
-
2.8
-
5.5
V
ICC
VCC = 3.6V, VCTL=3.6V
-
0.9
1.5
Supply Current
VCTL = 0V
-
0.5
1
294
320
346
-
20
-
0.77
1.1
1.43
-
400
-
-
0.7
1.5
Feedback Voltage
VFB
VCC=VCTL=3.0V, Topr = 25 , L =10 H
CTL Pin Bias Current
ICTL
VCC = 3.0V, VCTL = 3.0V
Switching Frequency
fOSC
VCTL = 3.0V
Switching Pin Current
IO(SW)
RON
Switch RDS(ON)
IO(SW)
400
Switch Leak Current
IOZ(SW)
-
-
0.5
1
OVD Pin Voltage
VOVD
-
16
20
22
IOZ(OVD)
-
-
0.5
1
Thermal Shutdown
TSD
-
-
150
180
Switching Pin OVP
VO(SW)
-
25
-
-
V
CTL pin voltage for Full LED Current
VCTL H
2.7
-
-
V
CTL pin voltage to shutdown Chip
VCTL L
-
-
0.5
V
OVD Pin Leak Current
VCC = 3.0V
Feedback Bias Current
IFB
-
-
0.5
1
Maximum Duty Cycle
Dmax
-
85
90
-
V
%
PIN FUNCTIONS
NO.
SYMBOL
FUNCTION AND CONNECTION.
Control pin : Shutdown or dimming control. Connect external enable or dimming circuits.
Shutdown mode (IF = 0) : VCTL<1.0V
1
CTL
Dimming control mode : (IF = 20% ~ 100%, depend on VCTL)
1.0V < VCTL < 2.5V, when VCTL is above 2.5V IF keep its maximum value(100%).
Filtered PWM signal, above 33us of pulse width, can be used for dimming control.
2
OVD
3
SW
Switch pin. Connect inductor/diode here. Minimize trace area at this pin to reduce EMI.
4
FB
Feedback pin. Reference voltage is 320mV. Connect cathode of lowest LED and resistor here.
5
GND
Ground pin. Connect directly to local ground plane,
6
VCC
Input supply pin. Must be locally bypassed.
2006. 4. 20
Over output voltage detect pin. Connect cathode of schottky diode and anode of highest LED.
Revision No : 0
3/6
KIB3402F
APPLICATION INFORMATION
Inductor Selection
A 4.7 H inductor is sufficient for most application. The efficiency
comprison of different value inductors help you design your
application circuits.
90.00
Vin=3.6V, 4LED
Inductor=Murata
88.00
The KIB3402F will then switch at a high duty cycle resulting in a
high output voltage, but Internal Over Voltage Protection Circuits
prevent output voltage ascending over OVD pin voltage( 16V ~ 22V
see Fig.4 ). This circuits is valid when driving up to 4 LEDs in
series. But, when driving more than 4 LEDs in series, Normal
output voltage could be over OVD pin voltage.
In this case, zener diode can be used to limit output voltage, but
check connection of OVD pin to VCC.(see Fig.5)
EFFICIENCY (%)
86.00
L1
4.7 µH~10 µH
84.00
D1
VIN
82.00
80.00
6
78.00
VCC
3
SW
76.00
LED1
OVD 2
74.00
KIB3402F
10uH
70.00
5
10
15
20
LED4
1 CTL
25
FB 4
C1
1µF
LOAD CURRENT (mA)
GND
5
RSENSE
21.5Ω
0
C2
1µF
LED3
4.7uH
72.00
LED2
Figure3. Efficiency Comaprison of different value inductors
Capacitor Selection
input capacitor and output capacitor above 1
A 1
sufficient for most KIB3402F application.
Figure4. 4LEDs driver with Open-circuit protection.
KDR412
20
500 mA
0.5V(max)
at 500 mA
0.30
0.5V(max)
at 200 mA
2
200 mA
0.30
30
1.60
1.20
2
KDR720E
6
3
SW
VCC
LED2
LED3
2 OVD
KIB3402F
LED4
C2
1µF
LED5
LED6
FB 4
C1
1µF
GND
5
R1
16Ω
1.60
1.20
0
2.50
1.70
0.30
0.6V (max)
at 200 mA
LED1
1 CTL
0.80
1
200 mA
D1
VIN
Package
0.80
1
30
Voltage
Drop (V)
1.25
KDR730E
Reverse
Forward
Voltage (V) Current (mA)
L1
4.7 µH~10 µH
DZ
Diode Selection
For Diode Selection, both forward voltage drop and diode
capacitance need to be considered. Shottky diodes with higher
current ratings usually have lower forward voltage and larger diode
capacitance, which can cause significant switching losses. A
schottky diode rated at 100 to 200 is sufficient for most
KIB3402F applications.
Part No.
0
are
Figure5. 6LEDs driver with Open-circuit protection.
Table 1. Recommended Schottky Diodes
Dimming Control
There are 4 different type of dimming control circuits:
LED Current Control
The LED current is controlled by the feedback resistor(RSENSE in
1. Using a DC Voltage to CTL pin.
Figure 1). The feedback reference is 320 .
VCTL
The LED current is 320 /RSENSE. The tolerance of LED Current is
Description
UNIT
depends on tolerance of RSENSE and feedback reference.
0V~0.5V 1V~2.5V VCTL>2.5V
Open-Circuits Protection
In the case of output open circuit, when LEDs are disconnected
from the circuit or the LEDs fail, the feedback voltage will be zero.
2006. 4. 20
Revision No : 0
Rate Of the LED Current
0
25 ~ 100
100
%
Example : RSENSE = 16
0
5 ~ 20
20
mA
Table 2 CTL pin Voltage vs ILED
4/6
KIB3402F
L1
4.7 µH~10 µH
VIN
C1
1µF
D1
6
3
VCC
SW
Vsw
5V/Div
LED1
LED2
OVD 2
DC
C2
1µF
LED3
KIB3402F
VCTL
2V/Div
LED4
1 CTL
FB 4
RSENSE
21.5Ω
GND
5
(A) 1kHz (2ms/Div)
Figure 7. Using a PWM Signal to CTL pin.
0
3. Using a DC Voltage to FB pin.
Figure6. Using a DC Signal to CTL pin.
The dimming control using a DC control voltage to FB pin of the
2. Using a PWM Signal to CTL pin.
KIB3402F is shown in Figure. The LED current can be varied
With the PWM signal applied to the CTL pin, the KIB3402F is turned
applying a DC voltage to the FB pin. The voltage can come from a
on or off by the signal. Typical frequency range of the PWM signal is
filtered PWM signal. It can be used to replace the variable DC
15kHz to 30kHz.
Voltage source in dimming control.
The switching waveforms of the CTL pin PWM
control are shown in Figure 7(A) and 7(B)
D1
L1
VIN
D1
VIN
C1
1µF
6
3
VCC
SW
3
SW
LED1
KIB3402F
LED4
R1
1 CTL
C2
1µF
FB 4
GND
C1
1µF
LED4
5
R2
5
RSENSE
21.5Ω
FB 4
GND
0
C2
1µF
LED3
KIB3402F
LED2
LED3
1 CTL
LED2
OVD 2
LED1
OVD 2
PWM
6
VCC
0
RSENSE
L1
4.7 µH~10 µH
0
DC
0
Figure8. Using DC Voltage to FB pin.
0
4. Using a Logic Signal to FB pin.
For applications that need to adjust the LED current in discret steps,
a logic signal can be used as shown in Figure 9.
Vsw
5V/Div
D1
L1
VIN
VCTL
6
3
VCC
SW
LED1
LED2
2V/Div
OVD 2
KIB3402F
LED4
1 CTL
(A) 1kHz (2ms/Div)
C2
1uF
LED3
FB 4
C1
1uF
Rdim
GND
5
KTK5132V
LOGIC
RSENSE
0
Figure9. Using a Logic Signal to FB pin.
2006. 4. 20
Revision No : 0
5/6
KIB3402F
Efficicncy vs Temperature
VFB vs VCTL
95
350
VFB
90
EFFICICNCY (%)
300
V FB (mV)
250
200
150
100
Vin=4.3V
85
Vin=3.6V
80
Vin=3.0V
75
70
65
60
50
55
0
50
0
1
2
3
4
5
-60
-10
40
V CTL (V)
Temperature ( C)
Switching Frequency vs Temperature
Frequency vs Vcc
SWITCHING FREQUENCY (MHz)
1.01
FREQUENCY (MHz)
1.00
0.99
0.98
0.97
0.96
0.95
0.94
0.93
0.92
0.91
1.5
1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
0
2.5
3.5
4.5
5.5
-50
6.5
0
Vcc (V)
Thermal Shut Down
500
400
350
Vin=4.3V
300
Vin=3.6V
Vin=2.7V
V FB (mV)
Icc (µA)
300
100
50
Temperature ( C)
Quiescent Current vs Temperature
400
140
90
200
250
200
150
100
100
50
0
-50
0
-10
30
TEMP ( C)
2006. 4. 20
Revision No : 0
70
110
105
115
125
135
145
155
165
175
185
TEMP ( C)
6/6