AN1149-4 Lumileds Lighting, LLC, AN1149-4 Datasheet - Page 7
AN1149-4
Manufacturer Part Number
AN1149-4
Description
Thermal Management Considerations for SuperFlux LEDs
Manufacturer
Lumileds Lighting, LLC
Datasheet
1.AN1149-4.pdf
(14 pages)
Lumileds plots these curves for different values
of R
maximum drive current of 70 mA, and their
intersection with the maximum ambient
temperature of 100 °C and includes this graph
in all LED data sheets. This graph is typically
Light Output and Forward Current
The relationship between light output and
forward current for different thermal resistances
is shown in Figure 4.5. For LED assemblies with
low thermal resistances (R
relative flux increases almost proportionally to
the forward current. However, for LED
assemblies with high thermal resistances
(R
Derating Example Cases
Case 1—Class 1 LED CHMSL
Consider an LED CHMSL application using 12 HPWT
MH00 LEDs in a row, with a current limiting resistor in the
wire connector. The auto manufacturer has specified a
maximum ambient temperature of 75 °C.
From Table 4.2 the thermal resistance can be estimated
as Rθja = 325 °C/W. Using Figure 4.4, the maximum
allowable forward current through each LED is 55 mA
at T
Case 2—Class 4 LED Rear Combination Lamp (RCL)
Consider an LED RCL application using 36 HPWTMH00
LEDs in a 6x6 pattern, with the drive circuitry on the same
PCB as the LEDs. The auto manufacturer has specified a
maximum ambient temperature of 75 °C.
θ
a (max)
ja
θ
= 600 °C/W), the relative flux can actually
ja
along with their intersection with the
= 75 °C.
θ
ja
= 200 °C/W), the
7
referred to as the derating curves. The derating
curves for HPWT xx00 devices, are shown in
Figure 4.4. Derating curves for HPWAxx00
devices are provided in the SuperFlux LED
Technical Data Sheet. Refer to side bar Derating
Example Cases for further explanation.
decrease as forward current is increased. For
assemblies with high R
occurs resulting in high junction temperatures.
In these cases, the effects of increasing junction
temperature can offset the effects of increasing
forward current. Proper thermal management
and drive current selection is critical to
maximizing the performance of LEDs.
From Table 4.2 the thermal resistance can be estimated
as Rθja = 650 °C/W. Using Figure 4.4, the maximum
allowable forward current through each LED is 30 mA at
Ta(max) = 75 °C.
As can be seen from these simplified sample cases, the
Rθja has a major impact on junction temperature, and thus
maximum allowable forward current. The different
applications using the same LED have a difference in
maximum forward current of nearly 2:1.
A more detailed determination of maximum forward current is
presented in Application Brief 20 3 Electrical Design
Considerations for SuperFlux LEDs.
θ
ja
, a great deal of heating
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