PAM PAM2846KR

PAM2846
Integrated 6 String LED Boost Type Driver
Features
Description
n Six Constant-Current Output Channels
n Parallel Channels Allow Higher Current
per LED String
n Maximum 40V Continuous Voltage Output
Limit for Each Channel
n Self-adaptive Vout to Fit Different LED Number
n Adjustable Constant LED Current
n Drives 10 or more LEDs Each String as Long
as the String Voltage Less Than 40V
n Internal 2.5A Power MOSFET
n Low 400mV Feedback Voltage at Full
Current Improves Efficiency
n Allows Digital PWM and Analog Dimming
n Wide (100:1) PWM Dimming Range without
Color Shift
n Independent Dimming and Shutdown
Control of the LED Driver
n ±1% Typical Current Matching between Strings
n Open LED Protection: Adjustable Clamp
Voltage
n Short LED Protection
n 3 Frequencies Selection: 1.6MHz/1MHz/500kHz
n Wide Input Voltage Range: 4.8V to 28V
n Over Temperature Protection
n Available in 24-pin 4mmx4mm QFN Package
n Pb-free Package
The PAM2846 is a high-efficiency boost type LED
driver. It is designed for large LCD panel that
employs an array of LEDs as back light source.
The PAM2846 employs a current-mode step-up
converter that drives six parallel strings of LEDs
connected in multiple series. This built-in stringcurrent-control circuit achieves ±1% typical
current matching between strings, which ensures
even brightness for all LEDs. The device is able to
adapt to different numbers of LEDs in each string
or different forward voltage for different types of
LEDs and keep the string current constant.
Separate feedback loops limit the output voltage if
one or more LEDs open or short. The limit voltage
of over voltage protection is adjustable by
changing the feedback resistor ratio. The
PAM2846 has features cycle-by-cycle current
limit to provide consistent operation and soft-start
capability. A thermal-shutdown circuit provides
another level of protection.
The PAM2846 has a wide +4.8V to +28V inputvoltage range and provides adjustable full-scale
LED current. The switching frequency of this
device can be selected among 500kHz, 1MHz and
1.6MHz according to the application
requirements.
Applications
n White or RGB Backlighting for LCD
TV, LCD Monitor, Notebook, Handy
Terminals, and Avionics Displays Panels
n LED Lighting Devices
Typical Application
22 μ H
VIN: 4.8V to 28V
3A/40V
L
SW
SW
SW
VIN
ENA
PWMD
PWMD
Fsel
R1
300k
OVP
Fsel
R2
PAM2846
Total 10
LEDs
per
string
9.2k
VC
Vcc-5V
Vcc-driver
0-10k
1μ
LED1
LED2
LED3
LED4
LED5
LED6
Iset
1μ
10K
100nF
GND
PGND PGND PGND
Power Analog Microelectronics , Inc
07/2008 Rev 1.2
www.poweranalog.com
1
PAM2846
Integrated 6 String LED Boost Type Driver
Block Diagram
VIN
Vcc-5V
LDO1
Vcc-driver
LDO2
ENA
OVP
SOFT START
Fsel
OVP
UVLO
ENABLE
1.6MHz
1MHz
500KHz
1.2V
SLOPE
COMPENSATION
OTP
PWM
COMPATATOR
1.2V
Bandgap
MAIN
CONTROL
Level Shift Driver
+
SW
EA
POR
CURRENT
LIMIT
VC
LED Feedback
PWMD
CS AMP
LED1-6
PGND
PWM DIMMING
LED1
LED2
LED3
LED4
LED5
LED6
led short protect
led short protect
led short protect
led short protect
led short protect
led short protect
I_set AMP
Iset
GND
Power Analog Microelectronics , Inc
07/2008 Rev 1.2
www.poweranalog.com
2
PAM2846
Integrated 6 String LED Boost Type Driver
Pin Configuration
QFN 4mmX4mm
24
23
22
21 20 19
1
18
2
17
P2846
XXXYW
3
16
4
15
5
14
6
13
7
8
9
XXX: Internal Code
Y: Year
W: Weekly
10 11 12
Pin Descriptions
Pin Number
Name
Description
1
VIN
Supply input
2
Vcc-driver
3
GND
Ground
4
ENA
Enable input
5
PWMD
PWM dimming control
6
LED1
LED1 cathode terminal
7
LED2
LED2 cathode terminal
8
LED3
LED3 cathode terminal
9
GND
Ground
10
GND
Ground
11
LED4
LED4 cathode terminal
12
LED5
LED5 cathode terminal
13
LED6
LED6 cathode terminal
14
Iset
15
Vcc-5V
16
VC
Boost stage compensation pin
17
Fsel
Oscillator frequency selection pin
18
OVP
Over voltage protection
19
PGND
Power ground
20
PGND
Power ground
21
PGND
Power ground
22
SW
Power MOS drain
23
SW
Power MOS drain
24
SW
Power MOS drain
5V linear regulator output for power MOS driver
LED current adjustment pin
5V linear regulator output
Power Analog Microelectronics , Inc
07/2008 Rev 1.2
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3
PAM2846
Integrated 6 String LED Boost Type Driver
Absolute Maximum Ratings
These are stress ratings only and functional operation is not implied . Exposure to absolute
maximum ratings for prolonged time periods may affect device reliability . All voltages are with
respect to ground .
O
O
VIN,ENA.....................................-0.3V To +30V
Junction Temperature Range.......-40 C to 125 C
O
O
SW ,LED.....................................-0.3V To +40V
Storage Temperature..................-40 C to 150 C
O
Vcc-5V,Vcc-driver,VC....................-0.3V To +6V
Maximum Junction Temperature...............150 C
O
PWMD,Fsel,OVP,Iset.....................-0.3V To +6V
Soldering Temperature....................300 C,5sec
Recommended Operating Conditions
Operating Temperature.................-20 OC to 85 OC
Supply Voltage Range.......................4.8V to 28V
Thermal Information
Parameter
Thermal Resistance
(Junction to Case)
Thermal Resistance
(Junction to Environment)
Package
Symbol
Maximum
Unit
4x4mm QFN
θjC
2
°C/W
4x4mm QFN
θjA
37
°C/W
Power Analog Microelectronics , Inc
07/2008 Rev 1.2
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4
PAM2846
Integrated 6 String LED Boost Type Driver
Electrical Characteristic
T A=25°C, V IN=ENA=12V, L=22 μ H, Rset=10k Ω, unless otherwise noted
PARAMETER
Conditions
Min
Input Voltage Range
Quiescent Current
Typ
4.8
Max
Units
28
V
ENA=high (no switching)
1
2
Fsel=high (1.6M switching frequency)
10
Fsel =high (1M switching frequency)
6
Fsel =high (500k switching frequency)
3
ENA=low
5
20
μA
mA
LDO Stage
Vcc_5V
No switching
4.7
5
5.5
V
Vcc_5V current_limit
No switching
14
74
90
mA
Vcc_5V UVLO Threshold
No switching
3.9
4.2
4.5
V
Vcc_5V UVLO Hysteresis
Vcc_driver
No switching
No switching
4.7
5
5.5
V
Vcc_driver current_limit
No switching
14
74
90
mA
Vcc_driver UVLO Threshold
No switching
No switching
3.9
4.2
4.5
V
Vcc_driver UVLO Hysteresis
70
mV
70
mV
0.2
Ω
2.5
A
1
μA
Fsel =Vcc_5V
1.6
MHz
Fsel =Open
1.0
MHz
Fsel =Gnd
500
kHz
Fsel =Vcc_5V
20
%
Fsel =Open
10
%
Fsel =Gnd
5
%
Maximums Duty Cycle
90
%
VC Source Current
60
μA
VC Sink Current
60
μA
Boost Stage
Switch Rdson
Vcc_5V=5V
Switch Current Limit
Switch Leakage Current
Switching Frequency
Minimums Duty Cycle
Power Analog Microelectronics , Inc
07/2008 Rev 1.2
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5
PAM2846
Integrated 6 String LED Boost Type Driver
Electrical Characteristic
T A=25°C, V IN=ENA=12V, L=22 μ H, Rset=10k Ω, unless otherwise noted .
PARAMETER
Conditions
Min
Typ
Max
Units
LED Controller Stage
Full-Scale LED_Output Current
I=190*1.2V/Riset, Riset=7.68k
30
mA
I=190*1.2V/Riset, Riset=11.3k
20
mA
I=190*1.2V/Riset, Riset=22.6k
10
mA
LED current matching
-3
1
+3
%
Iset Voltage
1.2
V
Minimums LED voltage
400
mV
Analog Dimming Range
I=190*1.2V /Riset
PWM Dimming Frequency
I/32
I
mA
100
1k
Hz
5.1
V
Fault Protection
LED_ Overvoltage Threshold
4.6
LED_ Overvoltage Hysteresis
4.9
1
V
Overvoltage Threshold
1.2
V
Overvoltage Hysteresis
80
mV
Thermal-Shutdown
150
°C
Thermal-Shutdown Hysteresis
30
°C
Controll Interface
EN High
1.5
V
EN Low
0.4
PWMD High
1.5
V
PWMD Low
0.4
Fsel High
1
Fsel Low
EN Min pulse width
single wire dimming low level
EN Max pulse width
single wire dimming low level
EN off delay
single wire dimming low level
V
V
Vcc_5V- 0.5
Fsel Midlevel
V
2
V
0.5
V
0.5
μs
10
200
μs
μs
Power Analog Microelectronics , Inc
07/2008 Rev 1.2
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PAM2846
Integrated 6 String LED Boost Type Driver
Typical Performance Characteristic
T A=25°C, V IN=ENA=12V, Rset=10k Ω , L=22 μ H, Fsw=500kHz, 10x6 LEDs, unless otherwise noted
LED Current VS PWMD Duty cycle@100Hz
Input Voltage VS Efficiency
100%
25
90%
20
LED current (mA)
80%
Efficiency
70%
60%
50%
40%
30%
Fsw =500KHz
20%
Fsw =1MHz
10%
Fsw =1.6MHz
15
10
5
0
0%
5
9
13
17
21
25
20%
40%
60%
Input Voltage (V)
100%
Duty cycle
Quiescent current VS Input Voltage
Shutdown current VS Input Voltage
6
10
5
8
Supply Current (mA)
Shutdown current (uA)
80%
4
3
2
PWMD=0
Fsw=500KHz
Fsw=1MHz
Fsw=1.6MHz
6
4
2
1
0
0
0
10
20
6
30
10
14
18
22
26
Input Voltage
Input voltage (V)
Power Analog Microelectronics , Inc
07/2008 Rev 1.2
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PAM2846
Integrated 6 String LED Boost Type Driver
Typical Performance Characteristic
T A=25°C, V IN=ENA=12V, Rset=10k Ω , L=22 μ H, Fsw=500kHz, 10x6 LED, unless otherwise noted
Total LED Current Line regulation
Efficiency VS Input Voltage
100%
137.5
137
95%
136
Efficiency
LED Current (mA)
136.5
135.5
135
90%
85%
10x6 LED
134.5
8x6 LED
80%
134
6x6 LED
133.5
75%
4
8
12
16
20
24
28
4
8
12
16
20
24
28
Input Voltage (V)
Input Voltage (V)
Analog Dimming Signal Step
Max Output Current Vs Output Voltage
(Per Channel)
100
Max Output Current (mA)
LED Current (mA)
25
20
15
10
5
80
60
40
20
Vin=12V
0
Vin=6V
0
0
5
10 15 20 25 30 35 40 45 50 55 60 65
16
ENA Dimming Step
20
24
28
32
36
40
Output Voltage (V)
Power Analog Microelectronics , Inc
07/2008 Rev 1.2
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PAM2846
Integrated 6 String LED Boost Type Driver
Typical Performance Characteristic
T A=25°C, V IN=ENA=12V, Rset=10k Ω , L=22 μ H, Fsw=500kHz, 10x6 LEDs, unless otherwise noted.
LED Current Waveforms (PWMD=50%)
PWM Dimming (Duty Cycle=20%)
PWMD
DC
coupling
PWMD
DC
coupling
V LED1
DC
coupling
V LED1
DC
coupling
I LED
DC
coupling
I LED
DC
coupling
Startup Waveforms
LED Current Waveforms ( PWMD =80%)
PWMD
DC
coupling
V LED1
DC
coupling
Vout
DC
coupling
IL
DC
coupling
I LED
DC
coupling
ENA
DC
coupling
Stable Operation
Start up and Shutdown Waveforms
Vout
DC
coupling
Vsw
DC
coupling
IL
DC
coupling
IL
DC
coupling
ENA
DC
coupling
Power Analog Microelectronics , Inc
07/2008 Rev 1.2
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PAM2846
Integrated 6 String LED Boost Type Driver
Application Information
Inductor Selection
(equivalent series resistance) capacitors should
be used at the input. At least 2.2 μ F input
capacitor is recommended for most applications.
A minimum output capacitor value of 10 μ F is
recommended under normal operating
conditions, while a 22 μ F or higher capacitor may
be required for higher power LED current. A
reasonable value of the output capacitor
depends on the LED current. The total output
voltage ripple has two components: the
capacitive ripple caused by the charging and
discharging on the output capacitor, and the
ohmic ripple due to the capacitor's equivalent
series resistance. The ESR of the output
capacitor is the important parameter to
determine the output voltage ripple of the
converter, so low ESR capacitors should be used
at the output to reduce the output voltage ripple.
The voltage rating and temperature
characteristics of the output capacitor must also
be considered. So a value of 10 μ F, voltage rating
(50V) capacitor is chosen.
The inductance, peak current rating, series
resistance, and physical size should all be
considered when selecting an inductor. These
factors affect the conver ter's operating mode,
efficiency, maximum output load capability,
transient response time, output voltage ripple,
and cost.
The maximum output current, input voltage,
output voltage, and switching frequency
d e t e r m i n e t h e i n d u c t o r v a l u e . Ve r y h i g h
inductance minimizes the current rip ple, and
therefore reduces the peak current, which
2
decreases core losses in the inductor and I R
losses in the entire power path. However, large
inductor values also require more energy storage
and more turns of wire, which increases physical
2
size and I R copper losses in the inductor. Low
inductor values decrease the physical size, but
increase the current ripple and peak current.
Finding the best inductor involves the
compromises among circuit efficiency, inductor
size, and cost.
Diode Selection
PAM2846 is high switching frequency convertor,
w h i c h d e m a n d s h i g h s p e e d r e c t i f i e r. I t ' s
indispensable to use a Schottky diode rated at
2A, 60V with the PAM2846. Using a Schottky
diode with a lower forward voltage drop can
improve efficiency of the convertor. The voltage
rating of the diode should be greater than the
output voltage.
When choosing an inductor, the first step is to
determine the operating mode: continuous
conduction mode (CCM) or discontinuous
conduction mode (DCM). When CCM mode is
chosen, the ripple current and the peak current of
the inductor can be minimized. If a small-size
inductor is required, DCM mode can be chosen.
In DCM mode, the inductor value and size can be
mini mized but the inductor ripple current and
peak current are higher than those in CCM.
Methods for Setting LED Current
There are three methods for setting and
adjusting the LED current outlined here. The
methods are:
1) RSET only
2) PWM Input at PWMD
3) Single wire logic signal at ENA
Capacitor Selection
An input capacitor is required to reduce the input
ripple and noise for proper operation of the
PAM2846. For good input decoupling, low ESR
>10ms
0
ENA
1
2
3
4
31/32
500ns<t LO <10 μ s
30/32 29/32
28/32
27
5
28
29
30
31
32
t SOFT-START
32/32
32/32
t HI>500ns
5/32
I LED_
4/32
3/32
2/32
1/32
t
200μs(typ)
shutdown
shutdown
shutdown
Figure 1. Timing diagram for EN
Power Analog Microelectronics , Inc
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PAM2846
Integrated 6 String LED Boost Type Driver
Method 1: LED Current Setting with External
Resistor R ISET
V out_limit=V ov(1+R 2/R 1)
The recommend procedure is to choose
R 2=300k Ω and R 1=9.2k Ω to set V out_limit=40V. This
OVP pin is used for over voltage protect, not for
output voltage regulate.
The most basic means of setting the LED current
is connecting a resistor between R ISET and GND.
The LED current is decided by I SET Resistor.
I LED=228/ R ISET
LED Short Protection
Method 2: LED Current Setting Using PWM
Signal to PWMD Pin
The PAM2846 uses LED_OVP function to protect
devices when one or more LED(s) is/are shorted.
V LED = V OUT – V f * N
This circuit uses resistor R ISET to set the on state
current and the average LED current, then
proportional to the percentage of on-time when
the PWMD pin is logic low. Average LED current
is approximately equal to:
I= ( t on*I)/ (t on+ t off)
Also, the recommended PWM frequency is
between 100Hz and 1kHz. Frequency <100Hz
can cause the LEDs to blink visibly.
Normally V LED is around 0.4V and V OUT is decided
by LED numbers. When one or more LED(s)
is/are shorted, the PAM2846 will clamp V OUT to
make sure all LED pins’ voltage is less then 5V.
With this function V OUT will be clamped at
(5V+ V f*N MIN).
Note:
V LED: LED pin voltage
V OUT: Output voltage
Vf : LED forward voltage
N MIN: The minimum LED numbers among all
strings.
Method 3: LED Current Setting with single
wire logic to ENA Pin
When the LEDs are enabled by high level, the
LED current initially goes to I LED. Dimming is done
by pulsing ENA low (500ns to 10 μ s pulse width).
Each pulse reduces the LED current by 1/32, so
after one pulse the LED current is 31/32*I LED. The
32th pulse sets the LED current back to I LED.
Figure 1 shows a timing diagram for EN.
LED Open Protection
The control loop is related to all six LED sinks.
When one or more LED(s) is/are opened, the
sink will have no current and the device will work
in unstable open loop state. The V OUT voltage will
be limited by external resistor divider or
5V+V f*N MIN, whichever is lower.
Setting the Over Voltage Protection
The OVP pin is connected to the center tap of a
resistive voltage divider (R 1 and R 2 in Typical
Application diagram) from the high-voltage
output.
Power Analog Microelectronics , Inc
07/2008 Rev 1.2
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11
PAM2846
Integrated 6 String LED Boost Type Driver
PCB Layout Guidelines
noise spikes. Create an analog ground island
(GND) consisting of the output voltage
detection-divider ground connection, the I SET
resistor connections, VCC-5V and VCC-driver
capacitor connections, and the device's exposed
backside pad. Connect the GND and PGND
islands by connecting the GND pins directly to
the exposed backside pad. Make sure no other
connections between these separate ground
planes.
Careful PCB layout is important for proper
operation. Use the following guidelines for good
PCB layout:
1) Minimize the area of the high current
switching loop of the rectifier diode and output
capacitor to avoid excessive switching noise.
2) Connect high-current input and output
components with short and wide connections.
The high-current input loop goes from the
positive terminal of the input capacitor to the
inductor, to the SW pin. The high-current output
loop is from the positive terminal of the input
capacitor through the inductor, rectifier diode,
and positive terminal of the output capacitors,
reconnecting between the output capacitor and
input capacitor ground terminals. Avoid using
vias in the high-current paths. If vias are
unavoidable, use multiple vias in parallel to
reduce resistance and inductance.
4) Place the output voltage setting-divider
resistors as close to the OVP pin as possible.
The divider's center trace should be kept short.
Avoid running the sensing traces near SW Pin.
5) Place the VIN pin bypass capacitor as close to
the device as possible. The ground connection of
the VIN bypass capacitor should be connected
directly to GND pins with a wide trace.
6) Minimize the size of the SW node while
keeping it wide and short. Keep the SW node
away from the feedback node and ground. If
possible, avoid running the SW node from one
side of the PCB to the other.
3) Create a ground island (PGND) consisting of
the input and output capacitor ground and PGND
pin. Connect all these together with short, wide
traces or a small ground plane. Maximizing the
width of the power ground traces improves
efficiency and reduces output-voltage ripple and
7) Refer to the PAM2846 Evaluation board for an
example of proper board layout.
PAM2846 Evaluation Board
Power Analog Microelectronics , Inc
07/2008 Rev 1.2
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12
PAM2846
Integrated 6 String LED Boost Type Driver
Ordering Information
PAM2846 X X
Shipping
Package Type
Part Number
PAM2846KR
Marking
P2846
XXXYW
Package Type
Standard Package
QFN 4mmx4mm
3,000 Unites /Tape &Reel
Power Analog Microelectronics , Inc
07/2008 Rev 1.2
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13
PAM2846
Integrated 6 String LED Boost Type Driver
Outline Dimensions
QFN 4mmx4mm
QFN
Note:all dimensions are in millimeters.
Power Analog Microelectronics , Inc
07/2008 Rev 1.2
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14