Selecting Optimum Drivers For Maximizing Solid-State LED Lighting Performance

by Keith Szolusha
Linear Technology Corporation
SELECTING OPTIMUM
DRIVERS FOR MAXIMIZING
SOLID-STATE LED
LIGHTING PERFORMANCE
Automobile manufacturers are increasingly taking advantage of the latest
technologies in solid-state LED lighting to enhance the aesthetics and
performance of their 2007–2008 model vehicles by using these lighter,
smaller and more reliable devices for interior and exterior illumination.
However, to maximize the benefits of LED lighting, the drivers must be optimal.
In this article, the author discusses various automotive LED applications and their
optimum driver requirements.
H
igh-power LEDs promise a
growing number of advantages, including lower longterm cost and longer life, over both
incandescent light bulbs for interior
lighting, and halogen or HID lamps
used in headlights and brake lights.
The nature of driving an LED or
string of LEDs directly from a typical car battery requires a dc-dc converter to accurately regulate a constant LED current for uniform light
Figure 1. High voltage step-down 1A LED driver LT3474 with 250:1 PWM dimming.
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AUTO ELECTRONICS | MARCH/APRIL 2006
intensity and color integrity. The
converter must also protect the LEDs
from the vagaries of the car battery
bus. The dc-dc converter should be
optimized for the number and type
of LEDs in a string and for the
functionality of each application
such as headlights, taillights, signal
lights, interior reading lights, instrument-panel backlights or LCD GPS
monitor display lighting.
Deciding which dc-dc converter
IC and topology to use for each automotive LED application depends on
the following factors:
Topology: The relation of LED
voltage to battery voltage range dictates a buck, boost or buck-boost
topology that must be able to maintain control of the constant LED
current over the full battery voltage
range.
Dimming:
Large-ratio
LED
dimming must preserve chromatic
characteristics across brightness
levels and avoid visible-to-the-eye
ripple or oscillations.
Efficiency: Highly efficient operation of the dc-dc
converter and low power
consumption are crucial
requirements in driving
high brightness (HB) LEDs
since power losses drain
the battery during nonoperation and are dissipated as heat during operation in a thermally stressed
automotive environment.
DRIVING A SINGLE LED
In-cabin white dome
and reading lights may use
just a single 3 W LED that
produces 75 lumens to 100
lumens. This LED, such as a Luxeon
III star from Lumileds (www.
lumileds.com) has a typical forward
voltage in the range of 3 V to 4.5 V
with 1 A to 1.5 A of maximum
Figure 2. LT3474 buck drives single or
multiple LEDs with high efficiency.
current. The simplest LED driver
design uses a step-down (buck) regulator to drive this LED from the
full voltage range of the car battery.
Figure 1 shows an example of a
single-LED interior lighting
circuit with dimming. The
typical operating voltage
range of the car battery is
between 9 V to 16 V. A
drained battery may drop
down to 9 V before the car
is started and the alternator
charges it back up to 14.4 V
while the motor is running.
With some spikes and some
overshoot, this typical dc
battery voltage can be as
high as 16 V. A normal,
charged car battery rests at
12 V when the motor is not
operating.
During cold-crank conditions, a car battery may drop down
as low as 4 V. Critical electronics
must work at these low voltages, but
not necessarily the interior lighting.
High voltage transients are also
very common in car batteries. The long cables from
the battery to different
locations around the chassis and the electronically
noisy automobile environment ensure that highvoltage spikes are everpresent. Typical transients
of 36 V are necessary to
consider when choosing a
switching regulator for
automotive design. Higher
voltage spikes may be fi ltered with simple transient voltage suppressors
or RC fi lters, in most cases.
The converter IC used in
Figure 1 is a high-voltage,
high-current buck LED
converter with a wide
PWM dimming ratio that
can drive one or more
LEDs up to 1 A. It has
several features that make
it suitable for driving
LEDs in an automobile
environment. It is a dedicated LED driver with an
on-board high-voltage npn
power switch and an
Figure 3. PWM dimming LED current waveform of circuit in Fig. 1.
Figure 4. LED current vs. VADJ pin voltage.
Figure 5. LT3486 drives 20 white LEDs at 100 mA in a GPS LCD monitor.
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AUTO ELECTRONICS | MARCH/APRIL 2006
internal current sense
resistor to minimize board
space, reduce component
count and simplify design
while maintaining high
efficiency.
The wide 4 V to 36 V
operating input voltage
range allows the LED
driver converter to operate
directly from the battery
under all conditions while
maintaining constant LED
current regulation.
A low-voltage internal
current sense resistor
eliminates the need for a
costly external op-amp to
provide a low-voltage reference in the current sense
resistor path. The buck
regulator design and the
adjustable high-frequency
range of the LT3474 allow
extremely low-ripple output current even with very
small, low-cost ceramic
output capacitors. X5R,
X7R or equivalent ceramic
capacitors are recommended for all of the converters discussed in this
article.
Efficiency for the single LT3474
LED buck regulator is greater than
80% at 12V IN for LED currents
above 200 mA, as shown in Figure 2.
As the LED current and brightness
of the LED is reduced using analog
control of the VADJ pin, efficiency
appears to drop off, but power
consumption remains very low.
Tailored for automotive and battery-powered applications, this
LED driver consumes less than 2 µA
(typically 10 nA) when placed in
shutdown. Shutdown can also be
used as an LED on/off button function from a physical pushbutton or
microcontroller IC.
PWM DIMMING AND
BRIGHTNESS CONTROL
LCD MONITOR
DISPLAYS WITH
LED STRINGS
LED brightness can be
controlled on the LT3474 in
GPS navigation and
in-cabin
entertainment
Figure 1 with an analog
voltage input to the VADJ pin
displays are increasingly
or a digital PWM signal to
popular in luxury vehicles
and mainstream conthe gate of the PWM dimming MOSFET and the
sumer models. These LCD
PWM pin. Analog brightdisplays require constant
and bright strings of LEDs
ness control reduces the
constant LED current from
for use in daylight condi1A to a lower value by
tions and wide dimming
ratios for nighttime operareducing the internal sense
resistor voltage. Although
tion. Strings of LEDs pose
this is a simple way to
a different challenge than
the single LED dome light.
decrease the brightness of
the LED, the accuracy of
The multiple strings of
the LED current is reduced
6-10 LEDs in these displays
Figure 6. Efficiency for the LT3486 driver with 2 x 10 white
are usually lower current
at lower currents and the
LED strings is 90% over the operating range of the battery.
chromaticity of the LED
changes. The graph in Figure 4
displays typical LED current as a
function of VADJ pin voltage. The
accuracy is typically 2% at 1 A, but
only 3.5% at 200 mA. The dimming
ratio has a practical limitation
around 10:1.
Another method of reducing
the brightness of the LED is digital
PWM dimming. The PWM MOSFET
in series with the LED creates the
waveform shown in Figure 3 when
a single white LED is dimmed at
1 A constant current. When the LED
and PWM MOSFET are on during
PWM on-time, the current is a
well-regulated 1 A. During PWM
off-time, the current is zero. This
maintains the chromaticity and
true color characteristics of any
LED while reducing its brightness.
Because the PWM function is inside
the IC, the response to PWM is
very fast in returning the LED to
its programmed LED current. It has
a 40 µs minimum dimming ontime, which gives a 250:1 digital
PWM dimming ratio, more than
Figure 7. Buck-boost drives brake and signal 1A LED strings with 80% efficiency.
sufficient for interior lighting.
For nighttime viewing of the extremely bright
displays that are also used during daylight
hours, a 1000:1 dimming ratio is useful.
MARCH/APRIL 2006 | AUTO ELECTRONICS
33
The LT3486 has a PWM dimming
ratio of 1000:1 with its unique internal PWM dimming architecture . An
ultrafast PWM response time returns
the LED current to 100 mA from
0 mA in less than 10 µs for true-color
PWM dimming. Using two such drivers for four strings of R-G-G-B in
top-end displays provides 1000:1
dimming and maintains the truecolor of the display during dim
nighttime operation.
SIGNAL, TAIL AND HEADLIGHTING
Figure 8. Brake light LED driver for 8 x 1.5 A red LEDs.
(<150 mA) for smaller LEDs, but stack
up to a higher voltage than the car
battery (>20 V). A high-power boost
dc-dc LED driver with high efficiency
and high PWM dimming capability
is necessary for these monitors.
The LT3486 dual output boost
LED driver application in Figure 5
drives two strings of LEDs with a
constant current of 100 mA for up
to 36 V of LED forward voltage. The
boost converter LED driver provides
high efficiency with a low voltage
sense resistor in series with the LEDs
and PWM dimming MOSFET. The
full range of battery voltage, 9 V to
16 V, is below the operating forward
voltage of the LED strings.
The advantage of using two LED
drivers with two 10-LED strings,
instead of a single 20-LED string, is
that the maximum switch voltage
remains that of a single 10-LED
string (42 V maximum switch voltage, 36 V maximum output voltage).
Efficiency, as shown in Figure 6, is
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AUTO ELECTRONICS | MARCH/APRIL 2006
approximately 90% over the operating range of the battery. If the battery
voltage drops down to 4 V, the boost
LED driver will still operate, but possibly in a current-limited state,
depending on the programmed LED
current and number of LEDs in the
strings. Not only is the operating
efficiency high, but the converter
shutdown current consumption is
less than 1 µA (typically 100 nA),
merely sipping from the car battery
when it is off. The LED current is
set by selecting the external sense
resistor value based on a very low
200 mV sense resistor voltage for
maximum efficiency. The LED current can be adjusted separately on
either string with an analog signal
on the CTRL pin for a 10:1 accurate
dimming ratio or with a PWM signal
for very high dimming ratio.
For nighttime viewing of the
extremely bright displays that are
also used during daylight hours, a
1000:1 dimming ratio is very useful.
Exterior signal, tail and headlights require the highest power dcdc LED drivers because they have
the brightest and most numerous
LEDs. Although extremely bright
LED headlights are not yet as common due to thermal and regulatory
constraints, red and amber brake
and signal lighting are increasingly
common based on their excellent
aesthetic properties and durability.
Driving high-power strings of amber
and red LEDs poses similar challenges for interior and trim lighting,
but on a different scale. Typically,
high dimming ratios are not necessary, but simple on/off and high/low
brightness functions are useful. The
high power LED string voltage usually crosses over the full voltage
range of the car battery, creating
the need for an LED driver with
both step-up and step-down (buckboost) capability. Such a buck-boost
LED driver shown in Figure 7 drives
two high power LEDs at 1 A. The
LEDs do not need to be groundreferred and are connected between
what would typically be the converter output and the battery input.
The LT3477 has two unique, floating
100 mV current-sense input pins
that are connected to a non-groundreferred current sense resistor in
series with the string of LEDs.
Accurate LED current regulation is
provided at up to 1 A over the operating voltage range of the car battery
and below. Its shutdown pin is
used for on/off function of the lights
and for reducing the input current
to 1 µA (typically 100 nA) when not
in use. The I ADJ pin is used for
dimming for brake and taillight
applications such as the rear signal
or brake lights. True color PWM
dimming is not necessary for these
applications.
Automotive taillights use more
red LEDs at higher currents, up to
1.5 A. A string of 6–10 LEDs is fairly
common for different lights, producing a total of up to 140 lumens per
LED and around 1000 or more lumens
per string. These lights not only need
to provide very high current, but
high voltage as well. These lights are
driven directly from the car battery
with no possibility of failing from
high battery voltage transients.
Being far from the battery, these
lights are subject to wide-ranging
input voltages.
The LTC3783, high-power LED
driver powers 6–10 3 W red LEDs in
a buck-boost topology as shown in
Figure 8. The external switching
MOSFET and switching current
sense resistor provide maximum
design flexibility for high power and
high-voltage LED driver designs. The
9 V to 36 V input and up-to-25 V LED
string output at 1.5 A require a 100 V
switch rating and greater than 8 A
peak switch current capability if the
battery drops below 9 V. The constant
1.5 A battery current is well-regulated
over the entire car battery voltage
range. For brake and taillight dimming, the LED current can be reduced
to up to 200:1 dimming ratio with a
PWM signal tied directly to the PWM
pin of the driver at 100 Hz. At 1 kHz,
this dimming ratio is reduced to 20:1,
sufficient for taillight applications.
An adjustment to the ILIM pin can
also reduce the LED current.
High efficiency is most important in the highest power applications of the vehicle. With up to 36 W
output in this application, the 93%
efficiency reduces the draw on the
battery during braking, especially
when the car is not running. The
RUN pin, used for on/off control of
the brake lights, reduces the LED
current to 20 µA. The flexibility of the
LTC3783 high-power LED driver
enables it to turn into a high-power
boost regulator to drive an even
higher voltage string of LEDs of up
to 60 W by connecting the string of
LEDs to GND as opposed to V IN and
turning the topology into a boost
converter. This requires that the
LED string voltage is greater than the
battery voltage maximum of 36 V,
and that LED disconnect is provided
via a PWM pin while the light is
turned off. High lumen headlight
applications using bright white LEDs
will soon adopt this high-power LED
driving boost topology.
CONCLUSION
There are many different automotive LED applications that require
a dedicated high power, yet simple
and efficient LED driver. Wide input
voltage range, low current consumption during off-time, high PWM and
analog dimming ratios, and excellent LED current regulation are often
required in different combinations
depending on the application.
ABOUT THE AUTHOR
Keith Szolusha is an applications
engineer with Linear Technology Corp.,
Milpitas, Calif. He holds a BSEE ’97 and
MSEE ’98 from MIT, Cambridge, Mass.