FOSLINK FSP3301QAD

FIXED FREQUENCY WHITE LED DRIVER
FSP3301
„
FEATURES
„
z
z
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z
z
z
On Board Power Transistor
Drives up to 6 Series White LEDs
Up to 87% Efficiency
Over 1 MHz Fixed Switching Frequency
Open Load protection
Low 104mV Feedback Voltage
PWM Dimming
UVLO
Internal Current Limit
Available in TSOT23-6L and QFN8L Packages
The FSP3301 is a step-up converter designed for
„
APPLICATIONS
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z
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Cell Phones
Handheld Computers and PDAs
Digital Still Cameras
Small LCD Displays
„
PIN CONFIGURATION
(1) TSOT23-6L
driving up to 6 series white LEDs from a single cell
Lithium Ion battery. The FSP3301 uses current mode,
fixed frequency architecture to regulate the LED
current, which is measured through an external
current sense resistor. Its low 104mV feedback
voltage reduces power loss and improves efficiency.
The OV pin monitors the output voltage and hold the
output voltage equal Vov if an over-voltage condition
is present due to an open circuit condition.
The FSP3301 includes under-voltage lockout, current
limiting and thermal overload protection preventing
damage in the event of an output overload.
The FSP3301 is available in small 6-pin TSOT23 or
8-pin QFN (2mm x 2mm) packages.
(2) QFN8L
(Top View)
Symbol
TSOT23-6L
QFN8L
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GENERAL DESCRIPTION
(Top View)
Name
1
8
SW
2
1,5
GND
3
6
FB
4
4
EN
5
3
OV
6
2
IN
Descriptions
Power Switch Output. SW is the drain of the internal MOSFET switch. Connect
the power inductor and output rectifier to SW. SW can swing between GND and
29V.
Ground.
Feedback Input. The FSP3301 regulates the voltage across the current sense
resistor between FB and GND. Connect a current sense resistor from the
bottom of the LED string to GND. Connect the bottom of the LED string to FB.
The regulation voltage is 104mV.
Regulator On/Off Control Input. A high input at EN turns on the converter, and a
low input turns it off. When not used, connect EN to the input source for
automatic startup. The EN pin cannot be left floating.
Over Voltage Input. OV measures the output voltage for open circuit protection.
Connect OV to the output at the top of the LED string.
Input Supply Pin. Must be locally bypassed.
2007-4-16
FIXED FREQUENCY WHITE LED DRIVER
„
FSP3301
ABSOLUTE MAXIMUM RATINGS (NOTE 1)
Symbol
Parameter
SW, OV Pins
All Other Pins
Tstg
Storage Temperature Range
TSOT23-6L
θJC
Thermal Resistance
QFN8L
(Note 2)
TSOT23-6L
θJA
QFN8L
Note 1: Exceeding these ratings may damage the device.
Note 2: Measured on approximately 1” square of 1 oz copper.
„
Rating
-0.5 to +29
-0.3 to +10
-65 to +150
110
16
220
80
Unit
V
V
℃
℃/W
℃/W
RECOMMENDED OPERATING CONDITIONS (NOTE 3)
Symbol
Parameter
Rating
Input Supply Voltage
+2.5 to +10
Output Voltage
VIN to +29
TOP
Operating Temperature Range
-40 to +85
Note 3: The device is not guaranteed to function outside of its operating conditions.
„
Unit
V
V
℃
ELECTRICAL CHARACTERISTICS
(VIN = VEN = 5V, TA = +25°C, unless otherwise noted.)
Parameters
Symbol
Operating Input Voltage
Supply Current (Shutdown)
Supply Current (Quiescent)
Switching Frequency
Maximum Duty Cycle
Under Voltage Lockout
IN Under Voltage Lockout
Under Voltage Lockout
Hysteresis
Open Lamp Shutdown
Threshold
Condition
VIN
Min
fSW
VFB = 0V
VOV
Max
Units
10
V
0.1
2.0
1.2
90
1
2.6
1.5
µA
mA
MHz
%
2.10
2.18
V
2.5
VEN = 0V
VFB = 0.15V
UVLO
Typ
VIN Rising
0.9
85
80
mV
VOV Rising
29
V
VE N Rising
0.77
0.76
30
V
V
mV
Enable
EN Threshold
EN Threshold
EN Hysteresis
VE N Rising, VI N = 2.5V
VE N = 0V, 5V
EN Input Bias Current
Feedback
FB Voltage
FB Input Bias Current
Output Switch
SW Current Limit (Note 4)
Switch VCEAST
Switch Leakage Current
Note 4: Guaranteed by design.
2/9
VF B = 0.1V
BVCES
94
104
-0.01 -0.045
65
µA
114
-1
mV
µA
Duty Cycle =60%
320
mA
ISW=250mA
350
mV
VSW=5V
0.01
2007-4-16
5
uA
FIXED FREQUENCY WHITE LED DRIVER
„
FUNCTIONAL BLOCK DIAGRAM
„
FUNCTION DESCRIPTION
FSP3301
The FSP3301 uses a constant frequency, current mode control scheme to provide excellent line and load regulation.
operation can be best understood by referring to the block diagram. At the start of each oscillator cycle, the SR latch
is set, which turns on the power switch Q1. A voltage proportional to the switch current is added to a stabilizing ramp
and the resulting sum is fed into the positive terminal of the PWM comparator A2. When this voltage exceeds the level
at the negative input of A2, the SR latch is reset turning off the power switch. The level at the negative input of A2 is
set by the error amplifier A1, and is simply an amplified version of the difference between the negative input of A3 is
set by the difference between the feedback voltage and the reference voltage of 100mV. In this manner, the error
amplifier sets the correct peak current level to keep the output in regulation. If the error amplifier’s output increases,
more current is delivered to the output; if it decreases, less current is delivered.
„
3/9
TYPICAL APPLICATIONS CIRCUIT
2007-4-16
FIXED FREQUENCY WHITE LED DRIVER
„
FSP3301
APPLICATION INFORMATION
Figure 1 Circuit For Driving 3W LEDS
A typical application circuit can be seen in Figure 1. The 3 white LEDs can be driven from a voltage supply range of
2.5V to 10V at an output current of 20mA. A 0.22µF output capacitor is sufficient for most applications but an output
capacitor up to 1 µF may be used. A 22µH inductor with low DCR (Inductor resistance) is recommended to improve
efficiency. A 1µF ceramic capacitor is recommended for the input capacitance in the real system. Schottky diodes
have fast recovery and a low forward voltage and are recommended. Schottky diodes rated with 100mA to 200mA are
sufficient for the FSP3301. The switching characteristics during normal operation can be seen in Figure 2.
Figure 2 Steady State Operation
Figure 3 shows the startup behavior of the FSP3301. The ramped voltage that is added to the current sense amplifier
reduces the current output as the duty cycle increases. As more LEDs are added, the output voltage rises but the
current that can be delivered to the load is reduced as well.
Figure 3 Startup Waveforms
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2007-4-16
FIXED FREQUENCY WHITE LED DRIVER
Figure 4 shows the dependence on current limit versus duty cycle.
FSP3301
Figure 4 Current Limit vs Duty Cycle
Setting the LED Current
The LED current is controlled by the feedback resistor, R1, in Figure 5. The current through the LEDs is given by the
equation 104mV/R1. Table 2 shows the selection of resistors for a given LED current.
IL E D (mA)
1
5
10
15
20
R1 (Ω)
104
20.8
10.4
6.93
5.2
Figure 5 Dimming Control Using a DC Voltage
Table 1 LED vs R
Analog and Digital Dimming
There are three different ways to control dimming for the FSP3301 during normal operation. The first way uses a DC
voltage to control the feedback voltage. This can be seen in Figure 5. As the DC voltage increases, current starts
flowing down R1, R2 and R3. The loop will continue to regulate the feedback voltage to 104mV. Thus the current has
to decrease through the LEDs by the same amount of current as is being injected from the DC voltage source. With a
VDC from 0V to 2V, the resistor values shown for R2 and R3 can control the LED current from 0mA to 20mA.
Other applications need to use a logic signal to do the dimming. This can be seen in Figure 6. The PWM signal is
applied to the EN pin of the FSP3301. The LEDs will switch between full load to completely shut off. The average
current through the LEDs will increase proportionally to the duty cycle of the PWM signal.
Figure 6 PWM Dimming Control Using a Logic Signal
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2007-4-16
FIXED FREQUENCY WHITE LED DRIVER
FSP3301
If the PWM signal is above 1 KHz, dimming can be achieved by using the circuit shown in Figure 7
Figure 7 Dimming Control Using a Filtered PWM Signal
Open Load Protection
Open Load protection will hold the output voltage equal Vov if an over-voltage condition is present due to an open
circuit condition when the OV pin is tied to the output. In some cases an LED may fail, this will result in the feedback
voltage always being zero.
Figure 8 shows the behavior of the FSP3301 into an open load.
Figure 8 Startup Waveforms into an Open Load
Layout Considerations
Careful attention must be paid to the PCB board layout and component placement. Proper layout of the high
frequency switching path is critical to prevent noise and electromagnetic interference problems. Due to the high
frequency switching the length and area of all the traces connected to the switch node should be minimized.
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2007-4-16
FIXED FREQUENCY WHITE LED DRIVER
FSP3301
„
ORDERING INFORMATION
„
Marking Information
(1) TSOT23-6L
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(2) QFN8L
2007-4-16
FIXED FREQUENCY WHITE LED DRIVER
FSP3301
„
PACKAGE INFORMATION
(1) TSOT23-6L
D
e
2
3
A1
1
A
4
A2
5
E1
6
E
e1
b
C
θ
L
Symbol
A
A1
A2
b
C
D
E
E1
L
e
e1
θ
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Dimensions In Millimeters
Min.
Max.
0.900
1.100
0.000
0.100
0.900
1.000
0.300
0.500
0.100
0.200
2.800
3.100
2.50
3.100
1.500
1.700
0.200
0.550
0.95 Bsc.
1.90 Bsc.
0ο
10ο
Dimensions In Inches
Min.
Max.
0.036
0.044
0.000
0.004
0.036
0.040
0.012
0.020
0.004
0.008
0.112
0.124
0.100
0.124
0.060
0.068
0.002
0.022
0.038 Bsc.
0.076 Bsc.
0ο
10ο
2007-4-16
FIXED FREQUENCY WHITE LED DRIVER
FSP3301
(2) QFN8L
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2007-4-16