Datasheet

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LUXEON

Rebel

LUXEON Rebel

Direct Color Portfolio

High power

colored LEDs

Technical Datasheet DS65

Introduction

The LUXEON

Rebel Direct Color portfolio LEDs in this datasheet are ideal for a

wide variety of lighting, signaling, signage and entertainment applications. These ﬂux

differentiated parts, like all other LUXEON Rebel LEDs, provide the industry’s best

lumen maintenance, superior reliability and quality light. Using the information in this

document you can begin designing applications to your unique speciﬁcations.

LUXEON Rebel Direct Color LEDs

Deliver more usable light and higher ﬂux density•

Optimize applications to reduce size and cost•

Tightly pack the LEDs for mixing•

Engineer more robust applications•

Utilize standard FR4 PCB technology•

Simplify manufacturing through the use of surface mount technology.•

Direct Color Portfolio

Summary of content (29 pages)

PAGE 1
LUXEON Rebel Direct Color Portfolio High power colored LEDs Technical Datasheet DS65 LUXEON® Rebel Direct Color Portfolio Introduction The LUXEON® Rebel Direct Color portfolio LEDs in this datasheet are ideal for a wide variety of lighting, signaling, signage and entertainment applications. These flux differentiated parts, like all other LUXEON Rebel LEDs, provide the industry’s best lumen maintenance, superior reliability and quality light.
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Table of Contents Product Nomenclature..................................................................................................................................................3 Average Lumen Maintenance Characteristics..........................................................................................................3 Environmental Compliance...........................................................................................................................................
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Product Nomenclature LUXEON Rebel is tested and binned at 350 mA.
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Flux Characteristics Flux Characteristics for LUXEON Rebel, Thermal Pad Temperature=25°C Table 1.
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Flux Characteristics, Continued Flux Characteristics for LUXEON Rebel, Continued Notes for Table 1: 1. Minimum luminous flux or radiometric power performance guaranteed within published operating conditions. Philips Lumileds maintains a tolerance of ± 6.5% on flux and power measurements. 2. Typical luminous flux or radiometric power performance when device is operated within published operating conditions.
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Optical Characteristics Lambertian LUXEON Rebel at Test Current [1] Thermal Pad Temperature = 25°C Table 2. Dominant Wavelength [2] lD , Typical [3] Peak Wavelength lP , Spectral or Color Temperature [4] Half-width[5] CCT (nm) Color Min. Typ. Max. Dl1/2 Green Cyan Blue Royal-Blue [3] Red Red-Orange Amber 520 nm 490 nm 460 nm 440 nm 620.5 nm 613.5 nm 584.5 nm 530 nm 505 nm 470 nm 447.
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Electrical Characteristics Electrical Characteristics at 350 mA for LUXEON Rebel, Part Numbers LXML-Pxx1-0xxx, Thermal Pad Temperature = 25ºC Table 3. Forward Voltage Vf [1] (V) Color Min. Typ. Max. Green Cyan Blue Royal-Blue Red Red-Orange Amber 2.55 2.55 2.55 2.55 2.31 2.31 2.31 3.15 3.15 3.15 3.15 2.9 2.9 2.9 3.99 3.99 3.99 3.99 3.51 3.51 3.
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Absolute Maximum Ratings Table 5.
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Reflow Soldering Characteristics JEDEC 020c Table 7.
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Mechanical Dimensions Figure 1. Package outline drawing. Notes for Figure 1: 1. Do not handle the device by the lens—care must be taken to avoid damage to the lens or the interior of the device that can be damaged by excessive force to the lens. 2. Drawings not to scale. 3. All dimensions are in millimeters. 4. The thermal pad is electrically isolated from the anode and cathode contact pads.
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Pad Configuration Figure 2. Pad configuration. Note for Figure 2: 1. The thermal pad is electrically isolated from the anode and cathode contact pads. Solder Pad Design Note for Figure 3: The photograph below shows the recommended LUXEON Rebel layout on printed circuit board (PCB). This design easily achieves a thermal resistance of 7K/W. Application Brief AB32 provides extensive details for this layout. In addition, the .dwg files are available upon request. Figure 3. Solder pad layout.
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Wavelength Characteristics Relative Spectral Power Distribution Green, Cyan, Blue, Royal-Blue, Red, Red-Orange and Amber at Test Current Thermal Pad Temperature = 25°C 1.0 Cyan 0.8 Royal Blue 0.6 RedOrange Green Blue Amber Red 0.4 0.2 0.0 400 450 500 550 600 650 700 Wavelength (nm) Figure 4. Relative intensity vs. wavelength.
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Typical Light Output Characteristics over Temperature Cyan, Blue and Royal-Blue at Test Current 1.2 Relative e Luminous Flux (lm / mW) 1.1 1.0 0.9 Blue Photometric 0.8 Green Photometric 0.7 Cyan Photometric Royal-Blue Radiometric 0.6 0.5 -20 0 20 40 60 80 100 120 140 Thermal Pad Temperature (°C) Figure 5. Relative light output vs. thermal pad temperature for green, cyan, blue and royal-blue. Red, Red-Orange and Amber at Test Current 1.75 Amber Photometric 1.
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Typical Forward Current Characterisics Green, Cyan, Blue and Royal-Blue Thermal Pad Temperature = 25ºC 1200 Forward ward Current (mA) 1000 800 600 400 200 0 2.8 28 3 3.2 32 Forward Voltage (V) 3.4 34 3.6 36 Figure 7. Forward current vs. forward voltage for green, cyan, blue and royal-blue. Red, Red-Orange and Amber Thermal Pad Temperature = 25ºC 800 700 Forward Current (mA) 600 500 400 300 200 100 0 2.2 2.4 2.6 2.8 3 3.2 3.4 3.6 3.8 Forward Voltage (V) Figure 8.
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Typical Relative Luminous Flux Typical Relative Luminous Flux vs. Forward Current for Green, Cyan, Blue and Royal-Blue Thermal Pad Temperature = 25ºC 2.50 2.25 Normalized zed Luminous Flux (lm) 2.00 1.75 1.50 1.25 1.00 0 75 0.75 0.50 0.25 0.00 0 200 400 600 800 1000 1200 F Forward d Current C t (mA) ( A) Figure 9. Relative luminous flux or radiometric power vs. forward current for green, cyan, blue and royal-blue at Thermal Pad = 25ºC maintained, test current 350 mA.
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Current Derating Curves Current Derating Curve for 350 mA Drive Current Green, Cyan, Blue and Royal-Blue 400 350 IF - Forward ward Current (mA) 300 250 15°C/W 200 25°C/W 150 35°C/W 100 45°C/W 50 0 0 25 50 75 100 125 150 175 TA - Ambient Temperature (°C) Figure 11. Maximum forward current vs. ambient temperature, based on TJMAX = 150ºC.
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Current Derating Curves, Continued Current Derating Curve for 700 mA Drive Current Green, Cyan, Blue and Royal-Blue 800 IF - Forward Current (mA) 700 600 500 15°C/W 400 25°C/W 300 35°C/W 200 100 0 0 25 50 75 100 125 150 175 TA - Ambient Temperature (°C) Figure 13. Maximum forward current vs. ambient temperature, based on TJMAX = 150ºC.
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Current Derating Curves, Continued Current Derating Curve for 1000 mA Drive Current Green, Cyan, Blue and Royal-Blue 1200 IF - Forward Current (mA) A) 1000 800 600 15°C/W 400 25°C/W 200 0 0 25 50 75 100 125 150 175 TA - Ambient Temperature (°C) Figure 15. Maximum forward current vs. ambient temperature, based on TJMAX = 135ºC.
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Typical Radiation Patterns Typical Representative Spatial Radiation Pattern for Green, Cyan, Blue and Royal-Blue Lambertian 1.2 1.0 Relative ve Intensity (%) 0.8 0.6 0.4 Typical Upper Bound 0.2 Typical Lower Bound 0.0 -90 -70 -50 -30 -10 10 30 50 70 90 Angular Displacement (deg) Figure 16. Typical representative spatial radiation pattern for green and royal-blue lambertian.
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Typical Radiation Patterns, Continued Typical Representative Spatial Radiation Pattern for Red, Red-Orange and Amber Lambertian 100% 90% Relative ative Intensity (%) 80% 70% 60% 50% 40% 30% 20% 10% 0% -90 -75 -60 -45 -30 -15 0 15 30 45 60 75 90 Angular Displacement (deg) Figure 18.Typical representative spatial radiation pattern for red, red-orange and amber lambertian.
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Emitter Pocket Tape Packaging 50 500 120 Figure 20. Emitter pocket tape packaging.
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Emitter Reel Packaging Figure 21. Emitter reel packaging.
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Product Binning and Labeling Purpose of Product Binning In the manufacturing of semiconductor products, there is a variation of performance around the average values given in the technical data sheets. For this reason, Philips Lumileds bins the LED components for luminous flux, color and forward voltage (Vf). Decoding Product Bin Labeling LUXEON Rebel Emitters are labeled using a three or four digit alphanumeric code (CAT code) depicting the bin values for emitters packaged on a single reel.
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Luminous Flux Bins Table 8 lists the standard photometric luminous flux bins for LUXEON Rebel emitters (tested and binned at 350 mA). Although several bins are outlined, product availability in a particular bin varies by production run and by product performance. Not all bins are available in all colors. Table 8. Bin Code Flux Bins All Colors (except Royal-Blue) Minimum Photometric Flux (lm) Maximum Photometric Flux (lm) A 8.2 10.7 B C D E F G H J K L M N P Q R S T U V W X 10.7 13.9 18.
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Luminous Flux Bins, Continued Table 9.
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Forward Voltage Bins Table 10 lists minimum and maximum Vf bin values per emitter. Although several bins are outlined, product availability in a particular bin varies by production run and by product performance. Bin Code A B C D E F G LUXEON Rebel Color Datasheet DS65 (09/07/20) Table 10. Vf Bins Minimum Forward Voltage (V) Maximum Forward Voltage (V) 2.31 2.55 2.79 3.03 3.27 3.51 3.75 2.55 2.79 3.03 3.27 3.51 3.75 3.
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Color Bins Green, Cyan and Blue LUXEON Rebel Emitters are tested and binned for dominant wavelength. Dominant Wavelength Bin Structure for Green Emitters Table 11. Bin Code Minimum Dominant Wavelength (nm) Maximum Dominant Wavelength (nm) 1 2 3 4 5 520 525 530 535 540 525 530 535 540 545 6 545 550 Dominant Wavelength Bin Structure for Cyan Emitters Table 12.
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Color Bins, Continued Red, Red-Orange and Amber LUXEON Rebel Emitters are tested and binned for dominant wavelength. Dominant Wavelength Bin Structure for Red Emitters Table 15. Bin Code 4 5 Minimum Dominant Wavelength (nm) Maximum Dominant Wavelength (nm) 620.5 631.0 631.0 645.0 Dominant Wavelength Bin Structure for Red-Orange Emitters Table 16. Bin Code 2 Minimum Dominant Wavelength (nm) Maximum Dominant Wavelength (nm) 613.5 620.
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Company Information Philips Lumileds is the world’s leading provider of power LEDs for everyday lighting applications. The company’s records for light output, efficacy and thermal management are direct results of the ongoing commitment to advancing solid-state lighting technology and enabling lighting solutions that are more environmentally friendly, help reduce CO2 emissions and reduce the need for power plant expansion.