LED current independent on supply voltage variation with e.g. BCR402R (AN066)

A pp l ic a t io n N o t e, R e v . 2. 0 , J a n. 2 00 7
A p p li c a t i o n N o t e N o . 0 6 6
B C R 4 0 2 R : L i g h t E m i t ti n g D i o d e ( L E D ) D r i v er I C
P r o v i d e s C o ns t a n t L E D C u r r e n t I n d e p e nd e n t o f
S u pp l y V ol t a g e V a r i a t i o n
S m a l l S i g n a l D i s c r et e s
Edition 2007-01-04
Published by
Infineon Technologies AG
81726 München, Germany
© Infineon Technologies AG 2007.
All Rights Reserved.
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Application Note No. 066
Application Note No. 066
Revision History: 2007-01-04, Rev. 2.0
Previous Version: 2000-02-03
Page
Subjects (major changes since last revision)
All
Document layout change
Trademarks
SIEGET® is a registered trademark of Infineon Technologies AG.
Application Note
3
Rev. 2.0, 2007-01-04
Application Note No. 066
BCR402R: Light Emitting Diode (LED) Driven IC Provides Constant LED
1
BCR402R: Light Emitting Diode (LED) Driven IC Provides Constant
LED Current Independent of Supply Voltage Variation
Features
•
•
•
•
•
•
Supplies stable bias current for Light Emitting Diodes (LEDs)
Low Voltage Drop of 0.75 V maximizes system DC efficiency
LED drive current adjustable via single external resistor
(20 - 60 mA range)
Negative temperature coefficient protects LEDs against thermal
runaway
Low Cost, Low External Parts Count, Easy-to-use, Fast
Time-To-Market
Small Surface-Mount SOT143R packaging
(2.9 x 1.6 x 1.1 mm inc, leads)
4
3
1
2
3
2
4
1
BCR402R_Pin_configuration.vsd
Figure 1
PIN configuration
1.1
Introduction
Light-Emitter Diodes (LEDs) and LED displays suffer form varying illumination levels as a result of changes in
power supply voltages. This is true for displays used in automotive applications, battery-operated handheld
devices, or fixed (architectural) installations. To keep LED brightness constant, it is necessary to stabilize the
LED’s current over the anticipated power supply voltage variation range.
Often a resistor in series with the LED(s) is used to stabilize current. However, this method has some serious
drawbacks. To achieve good LED current stability over the varying supply voltage range, the resistor must take
on a large value (infinite resistance, in the ideal case) to make the power supply plus series resistor combination
approach the traits of an ideal constant current source having infinite output impedance. In such cases. there is a
large voltage drop across this series resistor. For a particular supply voltage, this voltage drop
1. Reduces the number of LEDs that can be driven by one resistor, requiring additional parallel resistors with
which to drive a given number of LEDs, thereby increasing system current consumption
2. Power is “burned” or wasted as heat in these series resistors.
Infineon’s LED driver family, consisting of the BCR401R, BCR402R, BCR402U and BCR405U, offers an easy,
cost-effective and reliable way to achieve LED current stabilization while overcoming the drawbacks inherent in
using a series resistor. These LED driver IC’s cover the most commonly used LED supply current ranges - 10 mA,
20 mA, and 50 mA. Refer to Table 1 and Figure 2. In each devices, the nominal driver current may the easily
adjusted upward from the nominal value by adding a single external resistor- for BCR401R / BCR402R, connect
this resistor between pins 3 and 4.
Application Note
4
Rev. 2.0, 2007-01-04
Application Note No. 066
BCR402R: Light Emitting Diode (LED) Driven IC Provides Constant LED
Table 1
Infineon LED Current Driven Family Recommended Current Ranges
Device
Package
Recommended Current Range
Maximum Power Dissipation
BCR401R
SOT143R
10 - 60 mA
330 mW
BCR402R
SOT143R
20 - 60 mA
330 mW
BCR402U
SC74
20 - 65 mA
500 mW
BCR405U
SC74
50 - 65 mA
500 mW
For selecting the proper resistor value to increase BCR402 driven current above the nominal level of 20 mA. refer
to Figure 3, which is also found in the BCR402R data sheet. Two cases are shown: “open” e.g. R1 is omitted (no
R1 used), showing nominal current to be 20 mA and R1 = 68 Ω, yielding 30 mA. For current up to 60 mA, R1 will
take on values less than 68 Ω, and R1 can be determined experimentally. Note that in all cases:
1. BCR402 output current should be limited to 60 mA
2. Total power dissipation of BCR402R should be limited to less than 330 mW for device soldering point
temperatures (TS) equal to or less than 87 °C
The power dissipation is simply calculated by multiplying the voltage drop across the device (e.g. voltage between
pins 2 and 3) times the device current. A good general reference for use when determining if a given circuit design
falls within device power dissipation guidelines may be found at [1]
AN066_Output_Current.vsd
Figure 2
Nominal Output Currents of Devices in the Infineon LED Driver Family. Current can be
adjusted from these nominal values via use of a single external resistor
Application Note
5
Rev. 2.0, 2007-01-04
Application Note No. 066
BCR402R: Light Emitting Diode (LED) Driven IC Provides Constant LED
AN066_Iout(VS).vsd
Figure 3
BCR402R Output Current vs. Supply Voltage for external resistor = OPEN and external
resistor = 68 Ω
1.2
Application Circuit
The application circuit is designed to demonstrate the difference between stabilizing LED current using an Infineon
LED driver IC, versus using a series resistance to stabilize current. This particular circuit has been initially set up
to operate over a supply voltage range to 9 V to 16 V. The switch may be used to easily toggle between BCR402R
mode “resistor” mode. Please refer to Figure 4.
Vcc
SW1
R1
4
3
Q1 BCR402R
1
R2
R3
2
D1
D2
D3
D4
AN066_Schematic.vsd
Figure 4
Application Circuit Schematic. Switch SW1 permits comparison of BCR402R vs. “Resistor
Method”
Application Note
6
Rev. 2.0, 2007-01-04
Application Note No. 066
BCR402R: Light Emitting Diode (LED) Driven IC Provides Constant LED
BCR402R has a typical output current of 20 mA without using external resistor R1. Current may be increased
above this nominal value by using R1, and in this case, R1 was set to 82 Ω to achieve an output current of 29 mA.
Based on the fact that the minimum supply voltage is 9 V and that there is a voltage drop of approximately 0.75 V
across the BCR402R at minimum supply voltage, it is possible to drive four red LEDs. On the right side of the circuit
shown in the schematic (“resistor mode”), two parallel resistors (560 Ω) had to be used instead of one, so as to
not exceed the maximum power dissipation of the 1208 SMD resistors while achieving a net resistance of 280 Ω.
This brings up a key issue: overall system efficiency.
Table 2
Comparison of Power Dissipation in BCR402R LED Bias controller vs. Resistor Biasing
Method
Power Dissipation in BCR402R1)
Power Dissipation in (R2 + R3)1)
22 mW
1) For VS = 16 V, I = 29 mA, R2||R3 = 280 Ω
235 mW
Compare results in Table 2 for both sides of the application circuit (e.g. BCR402R method versus Resistor
method), for the condition of VS = 16 V, I = 29 mA. When the “resistor method” is used to drive the same number
of LEDs as the BCR402R, more than ten times the DC power is wasted in the resistor as is burned in the
BCR402R. The difference in power dissipation between the two methods, 213 mW, may seem trivial, unless one
considers the effect of using larger numbers of such LED circuits in a large display. If the net series resistor value
is reduced, DC power wasted when using the “resistor method” could be reduced, but the already poor current
regulation of the “resistor method” gets even worse. If the net series resistor value is increased to 410 Ω (two
parallel 820 Ω resistors), the current stability is improved slightly, but the larger voltage drop across the larger net
series resistance reduced the number of LEDs that can be driven form four to just two.
For a given number of LEDs in a display, this means that the user of the resistor method would than have to add
additional resistor + LED branches to the display, requiring additional current and further increasing power
dissipation. In the example given here, the current consumption would have to double in order to drive a total of
four red LEDs with 410 Ω series resistance.
Figure 5 shows the effect on current stabilization using the BCR402R and different series resistor values (280,
340, 410 Ω, resulting from parallel combinations of R1 + R2). Note the nice flat curve showing nearly constant
current over the entire 9 V to 16 V supply range when the BCR402R LED Bias Controller is used, while the series
resistance method shows very limited current stabilization - even with large resistor values. Again, such large
resistor values not only reduce the number of LEDs that can be driven, but waste additional DC power.
AN066_ICC(VCC).vsd
Figure 5
LED Current Stabilization Effect using BCR402R versus Different Series Resistor Values for
“Resistor Method”. Note flat current curve over supply voltage when BCR402R is used
Application Note
7
Rev. 2.0, 2007-01-04
Application Note No. 066
BCR402R: Light Emitting Diode (LED) Driven IC Provides Constant LED
1.3
Safe Operation of BCR402R in Systems with supply Voltages in Excess of
Device Maximum Ratings - e.g. Fixed of Architectural Applications (24 V)
For some LED applications, including fixed or “architectural” displays, voltages greater than the 18 V maximum
rating (pin 3) of the BCR402R may be encountered. For example +24 V is frequently used in so-called architectural
display. This section describes the advantages of using BCR402R in such systems, and how BCR402R may be
safely employed in such higher voltage applications by using a “trick”.
These system typically employ switch-mode power supplies with precise voltage outputs. eliminating the problem
of supply voltage variation encountered in automotive or portable applications. However, unless an LED driver like
the BCR402R is used, another problem can arise as a result of the typically large variation in LED forward voltage
(VF). For example, one type of amber-color LED in widespread use today has a specified forward voltage range
of 1.90 to 2.50 volts. Large displays in architectural applications often have many parallel branches of LEDs. In a
display using only resistors for current stabilization, if one branch or “stack” of LEDs consists of diodes with VF’s
in the low-end of the specified range, and another stack consists of LEDs with higher VF’s, the stack with the lower
forward voltages can “hog” or draw more current than the other stack(s). This can create a situation where the
customer may readily see differences in brightness between the adjacent stacks of LEDs. To make matters worse,
LEDs have a negative temperature coefficient for forward voltage as regular PN functions do - but frequently
higher in magnitude (e.g. -4 mV / °C for an LED, versus -2.3 mV / °C for a typical PN junction). Since the stack of
LEDs consisting of diodes with lower forward voltage will draw more current, they will tend to heat up more than
adjacent branches, which will further decrease their forward voltage, making them draw more current, and so on,
potentially creating a thermal runaway condition and failure mode. The key point: if each stack of LEDs were fed
with an LED Driver device like BCR402R instead of employing a resistor, the current through each stack of diodes
would be stabilized, and LED stack currents would be more uniform regardless of the normal variation in LED
forward voltages. The light outputs of adjacent LED stacks would be equalized, and the potential thermal runaway
failure mechanism discussed above would be eliminated.
For operation in excess of BCR402R’s specified maximum voltage of 18 V, one “trick” is to stack a sufficient
number of LEDs between the power supply voltage +VS and the DC input of the BCR402R (pin 3) such that the
voltage seen at pin 3 is less than 18 V. In other words, simply use additional LEDs to drop the voltage fed to the
BCR402R below its maximum rating, and then finish up the string of LEDs with additional LEDs placed between
pin 2 and ground, in the usual way. Refer to Figure 6. Note that the exact number of diodes required for the top
or “voltage dropping” stack of LEDs (D1, D2,... Dn) will depend on
1. The supply voltage +VS
2. The voltage drops across the particular LEDs being used.(Red, Amber, Blue and White LEDs have varying
diode forward voltages.)
When used in this way, the BCR402R acts as a “current sink” for the diodes D1, D2...Dn on the top stack of LEDs,
and as a “current source” for the diodes below, e.g. Dn+1, Dn+2,...Dn+x. As there is only one current path,
stabilization is maintained for both upper and lower stacks of LEDs. There is a vanishingly small difference or
“error” in terms of the current difference between LEDs in the top stack and the bottom stack, this difference being
created by the base current consumed by the internal PNP transistor in the BCR402R. This base current, and
therefore the current difference between top and bottom LED stacks, is only about 400 microamps at a nominal
20 mA LED current. As such, the human eye will not be able to discern any differences in brightness in LEDs
between top and bottom stacks due to this effect. In fact, there is far more variation in brightness between
individual LEDs of the same type, if they are all driven with identical currents, than could be attributed to this small
“error” current due to the BCR402R’s PNP transistor base current.
In closing, for either the high voltage application, or standard application, an external NPN transistor (Q1) may be
used as an ON / OFF switch for the LED circuit, if desired, Infineon Technologies markets a broad range of
switching transistors suitable for this purpose, and the best choice will depend on the voltage present at pin 1 of
the BCR402R, e.g. select a switching transistor with sufficient collector-emitter and collector-base breakdown
voltages.
Application Note
8
Rev. 2.0, 2007-01-04
Application Note No. 066
BCR402R: Light Emitting Diode (LED) Driven IC Provides Constant LED
+V
S
D1
D1, D2, ..., DN:
D2
Use enough LEDs in
"top LED stack" such
that voltage at pin 3 of
BCR402R is < 18V
Note: maximum possible number of LEDs that can be used in
entire circuit depends upon +V S & voltage drop across particular
diode types. Q1 and R2 are optional, if it is desired to switch
LED stack on and off at this point. If switch is not needed,
ground pin 1 of BCR402R. Be sure Q1 can handle voltage
present at pin 1 of BCR402R given the value of +V S selected.
Infineon produces a broad range of switching transistors suitable
for Q1.
DN
R1
4
3
W6s
1
ON / OFF
Control
(High = ON)
R2
1K
Q1
BCR402R
2
D N+1
D N+2
D N+X
D N+1, D N+2, ..., DN+X :
Use maximum number of
LEDs in "bottom stack" that
permits sufficient voltage
between pin 2 and ground to
drive them.
AN066_Operation_BCR402R.vsd
Figure 6
Operation of BCR402R at “High” Voltage e.g. > 18 V
1.4
Temperature Compensation, Negative Temperature Coefficient of BCR402R
and Protection of LEDs from Thermal Runaway
For this section, please refer to the internal schematic diagram of the BCR402R shown Figure 7 in below.
Note that, as a rough rule-of-thumb, the base-emitter forward junction voltage of a Silicon PN junction has a
temperature coefficient of something like -2.3 mV / °C. In other words, as temperature increases, the emitter-base
voltage of the internal PNP transistor in BCR402R decreases at a rate of about 2 millivolts per degree C.
Application Note
9
Rev. 2.0, 2007-01-04
Application Note No. 066
BCR402R: Light Emitting Diode (LED) Driven IC Provides Constant LED
A N066_Internal_Schematic_BCR402R.vs
Figure 7
BCR402R Internal Schematic (inside box formed by dotted line)
Ordinarily, this temperature coefficient could create the following problem: for a given operation point, as we go
from cold to hot, the PNP transistor’s VBE will decrease, making the transistor “turn on harder”, thereby making the
BCR402R provide more current from pin 2 (IOUT) as we get hotter, creating the potential to have a thermal runaway
condition in our LED display circuit. To prevent this, two internal series diodes are placed between the +VS node
and the internal PNP transistor’s base. Since each of these two internal diodes also has a temperature coefficient
of the same value (-2.3 mV / °C), as we go hotter, the PNP transistor’s base voltage will rise, tending to “throttle
back” the PNP transistor. If only one diode junction were used, we would more or less evenly temperature
compensate for the PNP transistor’s B-E junction and maintain a fairly constant BCR402R output current over
temperature. The addition of the second diode “over-compensates” or actually causes the BCR402R to “source”
slightly less current as one goes hot - providing negative feedback and thereby preventing a potentially dangerous
thermal runaway condition for the LEDs in the display circuit. This is especially useful for LED displays subjected
to wide temperature variations, e.g. those found in automotive applications.
1.5
PCB Layout Details
The top view of the Application Board is given in Figure 8 on the next page. An enlarged picture including
component placement is provided in Figure 10. Note that there are two positions in which to place R1, in order to
accommodate either 0402 or 1208 case size resistors. Open connections to ground on the left of the LED stack
make it easy to modify the board for use with less than four LEDs. Figure 9 shows an enlarged view of the PCB
section where the LED driver is placed. The top and the bottom metal layers are shown. This reveals the heat sink
(metal area) for the BCR402R on the backplane or bottom metal layer of the PC board. The PC board footprint
was designed to fit the SOT143R package used by BCR401R and BCR402R, but it will also accommodate the
SC74 package as used by the BCR405U without modification. Please note that this particular PCB does not
accommodate the “High Voltage” application described in Chapter 1.3.
Application Note
10
Rev. 2.0, 2007-01-04
Application Note No. 066
BCR402R: Light Emitting Diode (LED) Driven IC Provides Constant LED
AN066_Application_PCBoard.vs
Figure 8
Top View of Application PC Board
A N066_Top_Metal_Layer.vsd
Figure 9
Close-In View of Top Metal Layer with “Heat Sink” on Backplane
Application Note
11
Rev. 2.0, 2007-01-04
Application Note No. 066
Conclusions
Board size: 35mm x 65mm
Board material: FR4
Board thickness: 1mm
SW1
R2
R3
R1
Q1
D
1
D
2
D
3
D
4
AN066_Parts_Placement.vsd
Figure 10
Enlarged Top View of PCB Showing Parts Placement
2
Conclusions
Infineon Technologies’ LED Driver family offers the end user an easy, cost-effective way to stabilize LED current
in fixed, portable or automotive LED display applications. DC power consumption is minimized, as compared to
LED driver circuit employing resistors for current stabilization. The negative temperature coefficient of these LED
Drivers helps to prevent thermal runaway conditions in LED displays.
3
[1]
References
Application Note 077, “Thermal Resistance Calculations” Infineon Technologies AG, Silicon Discretes Group.
(The Application Note gives an overview of thermal overstress issues.
Application Note
12
Rev. 2.0, 2007-01-04