ACT6311 Просмотр технического описания (PDF) - Active-Semi, Inc
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ACT6311 Datasheet PDF : 11 Pages
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ACT6311
Rev 4, 15-Nov-12
APPLICATION INFORMATION
and determine R2 from the output voltage:
Inductor Selection
Table 1:
Recommended Inductors
CURRENT
PART NUMBER RATING
(MA)
DCR
(Ω)
SUPPLIER
CDRH3D16-220
350
0.5 Sumida
ELJPC220KF
160
4.0 Panasonic
LQH3C220
250
0.7 Murata
LEM2520-220
125
5.5 Taiyo Yuden
A 22µH inductor is typically used for the ACT6311.
The inductor should have low DC resistance (DCR)
and losses at 1MHz. See Table 1 for examples of
small size inductors.
Capacitor Selection
The ACT6311 only requires a 1µF input capcitor
and a 1µF output capacitor for most applications.
Ceramic capacitors are ideal for these applications.
For best performance, use X5R and X7R type
ceramic capacitors, which possess less degradation
in capacitance over voltage and temperature
ranges.
Diode Selection
The ACT6311 requires a fast recovery Schottky
diode as the rectifier. Select a low forward voltage
drop Schottky diode with a forward current (IF)
rating of 100mA to 200mA and a sufficient peak
repetitive reverse voltage (VRRM). Some suitable
Schottkky diodes are listed in Table 2.
Table 2:
Recommended Schottky Diodes
PART
NUMBER
CMDSH-3
CMDSH2-3
BAT54
IF(MA)
100
200
200
VRRM (V) SUPPLIER
30
Central
30
Central
30
Zetex
OLED Application
Figure 1 shows the feedback network necessary to
set the output voltage. Select the proper ratio of the
two feedback resistors R1 and R2 based on the
desired output voltage. Typically choose R1 = 20kΩ
R 2 = R1⎜⎛ VOUT − 1 ⎟⎞
(1)
⎝ 1 .24 V ⎠
White LED Application
The LED current is determined by the value of the
feedback resistor R1. Because the FB input of the
IC is regulated to 1.24V, the LED current is
determined by ILED = 1.24V/R1. The value of R1 for
different LED currents is shown in Table 3.
Table 3:
R1 Resistor Value Selection
ILED (MA)
5
10
12
15
20
R1 (Ω)
246
124
103.3
82.7
62
To improve efficiency, resistors R2 and R3 can be
connected as shown in Figure 4 to lower the
effective feedback voltage.
The following are dimming control methods for the
ACT6311 series white LED application.
1) PWM Signal Driving SHDN
When a PWM signal is connected to the SHDN pin,
the ACT6311 is turned on and off alternately under
the control of the PWM signal. The current through
the LEDs is either zero or full scale. By changing
the duty cycle of the PWM signal (typically 1kHz to
10kHz), a controlled average current is obtained.
2) DC Voltage Control
Figure 5 shows an application in which a DC
voltage is used to adjust the LED current. The LED
current increases when VDC is lower than VFB and
decreases when VDC is higher than VFB. In Figure 5,
the LED current range of 15mA to 0mA is controlled
by VDC = 0V to 2V.
3) Filtered PWM Control
Figure 6 shows an application using a filtered PWM
signal to control dimming.
4) Logic Control
A logic signal can be used to adjust the LED current
in a discrete step, as shown in Figure 7.
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