SEAWARD SE3362

Description
Features
The SE3362 is a charge pump operating in either
¾
Drives individually up to 4 LEDs
1x mode or 2x fractional mode regulating current
¾
Output current up to 30mA per LED
through each of the 4 LED pins. Operation at a fixed
¾
Digital control On/Off of each LED
high frequency of 1MHz typical allows the use of
¾
Compatible with supply voltage of 2.85V to 5.5V
very small value ceramic capacitors.
¾
Power efficiency up to 90%
The SE3362 drives white light-emitting diodes
¾
2 modes of operation 1x and 2x
(LED’s) connected in parallel and provides tightly
¾
Automatic short circuit detect/disable
matched regulated current to achieve uniformity of
¾
High-frequency Operation at 1MHz
brightness in LCD backlighting applications. An
¾
Low value ceramic capacitors
external resistor RSET controls the output current
¾
Automatically switch to power save mode if no
level. LED currents of up to 30mA are supported
LED is deteted to be connected to the IC
over a range of input supply voltages from 2.85V to
¾
Thin QFN 16-lead package, 3×3mm
5.5V, making the device ideal for battery-powered
¾
100% Lead (Pb)-Free
applications.
LED dimming can be accomplished by several
methods including using a resistor Rset (the exact
Application
formula will
be provided in the Application
¾
Color LCD and keypad Backlighting
Section) to set the RSET pin current, applying a
¾
Cellular Phones
PWM signal on the Control signals, or adding a
¾
Handheld Devices
switched resistor in parallel with Rset. The Enable
¾
Digital Cameras
input pin allows the device to be placed in
¾
PDAs
power-down mode with close to "zero” quiescent
¾
Portable MP3 players
current. The SE3362 features short circuit and Over
Temperature Protection (OTP). The device is
available in a 16- lead thin QFN package with a max
height of 0.8mm.
Application Diagram
Revision 12/4/2008
Preliminary and all contents are subject to change without prior notice
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Pin Configuration
Note: The package exposed pad is electrically connected inside the package to AGND.
Functional Pin Description
Pin Number
Name
Function
1
EN
Chip Enable (Active High). Note that this pin is high impedance. There should be a
pull low 100kΩ resistor connected to GND when the control signal is floating.
2
CTR0
Output Control Bit 0. (See Table 1)
3
CTR1
Output Control Bit 1. (See Table 1)
4
AGND
Analog Ground
5
RSET
LED current is set by the value of the resistor RSET connected from the RSET pin to
ground. Do not short the RSET pin. VISET is typically 1.1V. All external capacitance at
this pin, including board parasitic capacitance, must be less than or equal to 30pF.
6
VOUT
Output Voltage Source for connection to the LED anodes.
7
VIN
Input Voltage
8
C1+
Positive Terminal of Bucket Capacitor 1
9
C1-
Negative Terminal of Bucket Capacitor 1
10
NC
No Connection
11
NC
No Connection
12
PGND
Power Ground. This ground should be connected to Power GND on PCB.
13 to16
LED 4 to 1
Current Sink for LED. (If not in use, pin should be connected to VOUT)
Exposed Pad
GND
Exposed pad should be soldered to PCB board and connected to GND.
Revision 12/4/2008
Preliminary and all contents are subject to change without prior notice
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Absolute Maximum Rating (1)
Parameter
Value
Units
VIN, VOUT, LEDx voltage
-0.3～7V
V
EN, CTRx,RSET voltage
-0.3 to VIN
V
RSET current
±1
mA
Lead Temperature (Soldering, 5 sec.)
260
°C
Junction Temperature
0 to +150
°C
Storage Temperature
-40 to +150
°C
Operating Rating (2)
Parameter
Symbol
Value
Units
Supply Input Voltage Range
VIN
5.5
V
Junction Temperature Range
TJ
0 to +125
°C
0to 30
mA
I LED per LED pin
Electrical Characteristics
VIN = 3.5V; C1＝1.0μF; TJ = 25°C; unless otherwise noted
Parameter
Symbol
Input Supply Voltage
Min
Typ
Max
Unit
VIN
2.85
--
5.5
V
RSET Regulated Voltage
VRSET
1.22
1.25
1.28
V
Current into LEDs
ILED
RSET=100K
--
5
--
mA
RSET=25.0 K
--
20
--
mA
RSET=16.7 K
--
30
--
mA
EN=Low, Shutdown Mode
--
1
--
uA
1x Mode , No Load
--
170
--
uA
2x Mode, No Load
--
2.5
--
mA
Quiescent Current
IQ
Conditions
ILED Accuracy
ILED-ERR
2mA<ILED<30mA
--
2
7.5
%
Current Matching(3)
ILED-LED-ERR
2mA<ILED<30mA
--
1
5
%
VTRANS
VLED=3.5V,IOUT=80mA,ILED=20mA
--
3.8
--
V
Oscillator Frenquency
FOSC
VLED=3.5V,IOUT=80mA,ILED=20mA
--
1.0
--
MHz
Input High Threshold
VIH
Input high logic threshold
1.5
--
--
V
Input Low Threshold
VIL
Input low logic threshold
--
--
0.4
V
Input Leakage Current
IIN
--
--
1
μA
x1 mode to x2 mode Transition
Voltage(VIN falling)
TPROTECTION
Thermal
Thermal Protection Temperature
--
150
--
Protection
Protection Hysterisys
--
20
--
Revision 12/4/2008
Preliminary and all contents are subject to change without prior notice
© Seaward Electronics, Inc., 2007. • www.seawardinc.com.cn • Page 3
°C
Control Inputs
Output Status
CTRL1
CTRL0
LED4
LED3
LED2
LED1
0
0
OFF
OFF
ON
ON
0
1
OFF
ON
ON
ON
1
0
ON
ON
ON
ON
1
1
OFF
OFF
OFF
OFF
Table1
Note 1: Exceeding the absolute maximum rating may damage the device.
Note 2: The device is not guaranteed to function outside its operating rating.
Note 3: Current Matching refers to the difference in current from on LED to the next.
ILED Current Matching = ±
I LED ( MAX ) − I LED ( MIN )
I LED ( MAX ) + I LED ( MIN )
× 100%
Operations
Thermal Shutdown
The SE3362 is a high efficiency charge pump white
The SE3362 provides a high current capability to drive 4
LED driver. It provides 4 channels low drop-out voltage
white LEDs. A thermal shutdown circuit is needed to
current source to regulated 4 white LED’s current. For
protect the chip from thermal damage. When the chip
high efficiency, the SE3362 implements x1/x2 mode
reaches the shutdown temperature 150°C, the thermal
charge pump. An external RSET is used to set the
shutdown circuit turns off the chip to prevent the thermal
current of white LED.
accumulation in the chip.
Dimming Control
Short Circuit Protection
CTRL0 and CTRL1 are used to control the on/off of
The SE3362 provides short circuit protection function.
White LED. When an external PWM signal is connected
When output Voltage is shorted to GND, short circuit
to the control pin, brightness of white LED is adjusted by
protection cell shutdown ChargePump and current
the duty cycle. The SE3362 supports the dimming
source, and consequently the IC and the related LED’s
control frequency up to 1KHz.
are protected.
LED Current Setting
The current of white LED connected to SE3362 can be
set by RSET. The channel current that flows through the
white LED is 400 times greater than the current of RSET.
The white LED can be estimated by following equation:
⎛ V RSET
⎝ RSET
ILED = 400× ⎜⎜
⎞
⎟⎟
⎠
where VRSET = 1.25V, and RSET is the resistance
connected from RSET to GND.
Revision 12/4/2008
Preliminary and all contents are subject to change without prior notice
© Seaward Electronics, Inc., 2007. • www.seawardinc.com.cn • Page 4
Applications Information
Selecting Capacitors
ILED(A) =
To get the better performance of SE3362, the selecting of
500(V )
RSET (Ω)
peripherally appropriate capacitor and value is very
LED current and Table 2 shows the values of RSET for a
important. These capacitors determine some parameters
fixed LED current.
such as input and output ripple, power efficiency, maximum
ILED(mA)
RSET (KΩ)
supply current by charge pump, and start-up time. To
5
100
reduce the input and output ripple effectively, the low ESR
10
50
15
33.3
reduce the output ripple, increasing the output capacitance
20
25.0
COUT is necessary. However, this will increase the start-up
25
20
time of output voltage.
30
16.7
ceramic capacitors are recommended. Generally, to
Table 2
For LED driving applications, the input voltage ripple is
more important than output ripple. Input ripple is controlled
by input capacitor CIN, increasing the value of input
LED current setting with NMOS
capacitance can further reduce the ripple. Practically, the
LED current setting control can also be achieved by using
input voltage ripple depends on the power supply’s
the external NMOS to change equivalent resister of RSET
impedance. If a single input capacitor CIN cannot satisfy the
pin. Figure 2 shows this application circuit of method. For
requirement of application, it is necessary to add a
this example, a 3 bit signals can set 8 kinds of different
low-pass filter as shows in Figure 1.
equivalent resister of RSET pin, i.e. produce 8 kinds of LED
current level. Table 3 shows the relation between
equivalent resister of RSET pin and control signal.
Figure1. C-R-C filter used to reduce input ripple
The flying capacitor C1 determines the supply current
capability of the charge pump and to influence the overall
efficiency of system. The lower value will improve
efficiency, but it will limit the LED’ s current at low input
voltage.
Setting the LED Current
The SE3362 can be set a fixed LED’s current by a resister
RSET connected from RSET to GND. RSET establishes the
reference current and mirrors the current into LED1, LED2,
Figure 2. The application circuit of setting LED current
LED3, and LED4. The current into LED is about 400 times
which using a NMOS to set RSET.
of the current flows through the RSET, the approximate
setting formula is given as follows:
Revision 12/4/2008
Preliminary and all contents are subject to change without prior notice
© Seaward Electronics, Inc., 2007. • www.seawardinc.com.cn • Page 5
Table 3. The relation between control signal and
equivalent resister of RSET pin
S1
S2
S3
Equivalent Resister of RSET pin
( RSET )
0
0
0
RSET = R4
0
0
1
RSET = R3//R4
0
1
0
RSET = R2//R4
0
1
1
RSET = R2//R3//R4
Figure 3. The PWM dimming application circuit
1
0
0
RSET = R1//R4
for 4WLEDs
1
0
1
RSET = R1//R3//R4
1
1
0
RSET = R1//R2//R4
1
1
1
RSET = R1//R2//R3//R4
LED Dimming Control Methods
The SE3362 can use two methods to achieve the LED
dimming control. These methods are detailed described
Figure 4. The PWM dimming application circuit
as following:
for 3WLEDs
(1) Dimming using PWM signal into CTRL0 and CTRL1
LED current can be controlled by applying a PWM signal
to CTRL0 or CTRL1. Table 1 shows the relationship
between CTRLx and 4 LED's current states. For an
example, as the CTRL1 is pulled logical high and CTRL0
receives a PWM signal, then, four LED’s will be dimmed
synchronously. Here, the PWM signal setting the LED's
current ON/OFF can achieve the average LED's current
which in design. The application circuit is shown in Figure
Figure 5. The PWM dimming application circuit
for 2WLEDs
3. Figure 4, and Figure 5 show 3WLEDs and 2WLEDs
PWM dimming application circuit, respectively. During
the time of PWM signal logical low, the current is a fixed
value and setting by RSET resistor. So the average LEDs
current can be approximated as Equation.
ILED(AVG) =
Additionally, SE3362 has 100us delay time
between mode transfer. This delay time makes
different
dimming
frequency
corresponds
to
TOFF × I LED ( ON )
different maximum duty of CTRLX pin. Please note
TPWM
that the maximum dimming frequency can not
exceed the maximum dimming frequency which is
Where:
TPWM is the period of PWM dimming signal TOFF is the
internally set at 1KHz.
time of PWM signal at low. ILED(ON) is LED on state
current.
Revision 12/4/2008
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The following equation shows the relation between
4. The PWM frequency should be in the range of
maximum duty of CTRLX pin and PWM dimming
500Hz~1.5kHz or 20kHz~30kHz for audio noise
frequency. Table 4 is shown the common dimming
consideration.
frequency and its corresponding maximum duty. For
5. The PWM duty cycle shall be in the range of 30% to
better performance consideration, the maximum PWM
95%.
dimming frequency is recommended below 1kHz.
6. The driving capability of the GPIO should be greater
D(MAX) = (1-100×10-6×FD)
than 2mA @ 2.8V.
Table 4. The common dimming frequency and its
corresponding maximum duty.
Dimming
CTRLX
RLED
Frequency (Hz)
Maximum Duty
Minimum Duty
1000
0.90
0.10
900
0.91
0.09
800
0.92
0.08
700
0.93
0.07
600
0.94
0.06
500
0.95
0.05
400
0.96
0.04
300
0.97
0.03
200
0.98
0.02
7. The LED current can be obtained by the equation,
ILED = 400×
V RSET
× (1 − DPWM )
RSET
(The typical value of VRSET is 1.25V)
(2). The PWM dimming by GPIO
The PWM dimming by GPIO is shown as Figure 6. DZ
shall be a Schottky diode with forward voltage less
Figure 6. The GPIO PWM dimming application
circuit
than 0.3V at IF = 1mA. C3 is a capacitor to keep the
enable pin voltage is higher than the threshold voltage.
R1 is discharge resister and it should be not too high to
prevent the off time too long while turned-off. The
recommended conditions are shown as following.
1. The recommended value for R1 and C3 are
200kΩ (±5%) and 0.22μF (X7R, ±10%).
2. The forward voltage of the Schottky diode shall be
less than 0.3V at 1mA.
3. The output voltage of GPIO should be greater than
2.8V and keep the voltage on EN pin is higher than
1.5V.
Revision 12/4/2008
Preliminary and all contents are subject to change without prior notice
© Seaward Electronics, Inc., 2007. • www.seawardinc.com.cn • Page 7
Outline Drawing for QFN16 3X3
Customer Support
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Section B, 2nd Floor, ShangDi Scientific Office Complex, #22 XinXi Road
Haidian District, Beijing 100085, China
Tel: 86-10-8289-5700/01/05
Fax: 86-10-8289-5706
Seaward Electronics Corporation – Taiwan
2F, #181, Sec. 3, Minquan East Rd,
Taipei, Taiwan R.O.C
Tel: 886-2-2712-0307
Fax: 886-2-2712-0191
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Milpitas, CA95035, USA
Tel: 1-408-821-6600
Last Updated - 12/4/2008
Revision 12/4/2008
Preliminary and all contents are subject to change without prior notice
© Seaward Electronics, Inc., 2007. • www.seawardinc.com.cn • Page 8