Luxeon-3watt datasheetIII

8/3/2019 Luxeon-3watt datasheetIII

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Technical Datasheet DS45

Introduction

Luxeon III is a revolutionary, energy efficient and ultra compact new light

source, combining the lifetime and reliability advantages of Light EmittingDiodes with the brightness of conventional lighting.

Luxeon III is rated for up to 1400mA operation, delivering increased lumens

per package.

Luxeon Emitters give you total design freedom and unmatched brightness,

creating a new world of light.

Luxeon Emitters can be purchased in reels for high volume assembly.

For more information, consult your local Lumileds representative.

For high volume applications, custom Luxeon power light source designs

are available upon request, to meet your specific needs.

Luxeon III EmitterFeatures Highest flux per LED family

in the world

Very long operating life (up to

100k hours)

Available in 5500K white,green, blue, royal blue, cyan,

red, redorange, and amber

Lambertian and side emittingradiation patterns

More energy efficient thanincandescent and most

halogen lamps

Low voltage DC operated Cool beam, safe to the touch Instant light (less than 100 ns) Fully dimmable No UV Superior ESD protection

Typical Applications Reading lights (car, bus, aircraft) Portable (flashlight, bicycle) Miniaccent/Uplighters/

Downlighters/Orientation

Fiber optic alternative/Decorative/Entertainment

Bollards/Security/Garden Cove/Undershelf/Task

Automotive rear combinationlamps

Traffic signaling/Beacons/ Railcrossing and Wayside

Indoor/Outdoor Commercialand Residential Architectural

Edgelit signs (Exit, point of sale) LCD Backlights/Light Guides

power light source


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Luxeon III Emitter DS45 (3/05) 2

Mechanical Dimensions

Lambertian

Notes:

1.The anode side of the device is denoted by a hole in the lead frame. Electrical insulation between the case and the board is

requiredslug of device is not electrically neutral. Do not electrically connect either the anode or cathode to the slug.

2.All dimensions are in millimeters.

3.All dimensions without tolerances are for reference only.

Side Emitting

Notes:

1.The anode side of the device is denoted by a hole in the lead frame. Electrical insulation between the case and the board is

requiredslug of device is not electrically neutral. Do not electrically connect either the anode or cathode to the slug.

2.Caution must be used in handling this device to avoid damage to the lens surfaces that will reduce optical efficiency.



Drawings not to scale

Drawings not to scale


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Flux Characteristics at 700mA, Junction Temperature, TJ = 25C

Table 1.

Minimum Luminous Typical LuminousFlux (lm) or Flux (lm) orRadiometric Radiometric

Luxeon Power (mW) Power (mW) RadiationColor Emitter V

[1,2] V[2] Pattern

White LXHLPW09 60.0 65Green LXHLPM09 51.7 64 LambertianCyan LXHLPE09 51.7 64Blue[3] LXHLPB09 13.9 23

Royal Blue[4] LXHLPR09 275 mW 340 mW

White LXHLDW09 51.7 58Green LXHLDM09 51.7 58 Side EmittingBlue[3] LXHLDB09 13.9 21


Table 2.

Typical Luminous Flux (lm)or Radiometric Power (mW)

Luxeon V[1,2] Radiation

Color Emitter 1000 mA Pattern

White LXHLPW09 80Green LXHLPM09 80 LambertianCyan LXHLPE09 80Blue[3] LXHLPB09 30

Royal Blue[4] LXHLPR09 450 mW

White LXHLDW09 70Green LXHLDM09 70 Side EmittingBlue[3] LXHLDB09 27

Notes for Tables 1 & 2:

1.Minimum luminous flux or radiometric power performance guaranteed within published operating conditions. Lumileds main

tains a tolerance of 10% on flux and power measurements.

2.Luxeon types with even higher luminous flux levels will become available in the future. Please consult your Lumileds Authorized

Distributor or Lumileds sales representative for more information.

3.Typical flux value for 470nm devices. Due to the CIE eye response curve in the short blue wavelength range, the minimum

luminous flux will vary over the Lumileds blue color range. Luminous flux will vary from a typical of 17lm for the 460465nm bin

to a typical of 30lm for the 475480 nm bin due to this effect. Although the luminous power efficiency is lower in the short blue

wavelength range, radiometric power efficiency increases as wavelength decreases. For more information, consult the Luxeon

Design Guide, available upon request.

4.Royal Blue product is binned by radiometric power and peak wavelength rather than photometric lumens and dominant

wavelength.



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Table 3.

Minimum Luminous Typical LuminousLuxeon Flux (lm) Flux (lm) Radiation

Color Emitter FV[1,2] FV

[2] Pattern

Red LXHLPD09 90 140RedOrange LXHLPH09 120 190 Lambertian

Amber LXHLPL09 70 110

Red LXHLDD09 90 125RedOrange LXHLDH09 120 170 Side Emitting

Amber LXHLDL09 70 100

Notes for Table 3:

1.Minimum luminous flux performance guaranteed within published operating conditions. Lumileds maintains a

tolerance of 10% on flux measurements.

2.Luxeon types with even higher luminous flux levels will become available in the future. Please consult your Lumileds Authorized

Distributor or Lumileds sales representative for more information.


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5Luxeon III Emitter DS45 (3/05)

Optical Characteristics at 700mA, Junction Temperature, TJ = 25C

Table 4.

Dominant Wavelength[1] Temperature

D, Coefficient of Total

Peak Wavelength[2] P, Spectral Dominant Included Viewing

or Color Temperature[3] Halfwidth[4] Wavelength Angle[5] Angle[6]

Radiation CCT (nm) (nm/ oC) (degrees) (degrees)

Pattern Color Min. Typ. Max. 1/2 D/TJ 0.90V 2 1/2

White 4500K 5500K 10000K

Green 520nm 530nm 550nm 35 0.04 160 140

Lambertian Cyan 490nm 505nm 520nm 30 0.04 160 140

Blue 460nm 470nm 490nm 25 0.04 160 140

Royal Blue[2] 440nm 455nm 460nm 20 0.04 160 140

Optical Characteristics at 700mA, Junction Temperature, TJ = 25CContinued

Table 5.

Temperature Typical

Dominant Wavelength[1] Coefficient of Total Flux Typical

D, Spectral Dominant Percent Angle

or Color Temperature[3] Halfwidth[4] Wavelength within of Peak

Radiation CCT (nm) (nm/ oC) first 45 [7] Intensity [8]

Pattern Color Min. Typ. Max. Cum 45 D/TJ Cum 45 Peak

White 4500K 5500K 10000K


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Optical Characteristics at 1400mA, Junction Temperature, TJ = 25C

Table 6.

Temperature

Coefficient of Total

Spectral Dominant Included Viewing

Dominant Wavelength[1] Halfwidth[2] Wavelength Angle[3] Angle[4]

Radiation D (nm) (nm/oC) (degrees) (degrees)

Pattern Color Min. Typ. Max. 1/2 D/TJ 0.90V 2 1/2

Red 620.5nm 627nm 645nm 20 0.05 170 130

Lambertian RedOrange 613.5nm 617nm 620.5nm 18 0.06 170 130

Amber 584.5nm 590nm 597nm 17 0.09 170 130

Optical Characteristics at 1400mA, Junction Temperature, TJ = 25C,Continued

Table 7.

Temperature Typical

Coefficient of Total Flux TypicalSpectral Dominant Percent Angle

Dominant Wavelength[1] Halfwidth[2] Wavelength within of Peak

Radiation D (nm) (nm/ oC) first 45 [5] Intensity [6]

Pattern Color Min. Typ. Max. 1/2 D/TJ Cum 45 Peak

Red 620.5nm 627nm 645nm 20 0.05


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Electrical Characteristics at 1000mA, Junction Temperature, TJ = 25C

Table 9.

Typical Forward Voltage

VF (V)[1]

Color 1000 mA

White 3.90

Green 3.90

Cyan 3.90

Blue 3.90

Royal Blue 3.90

Notes for Table 9:

1.Lumileds maintains a tolerance of 0.06V on forward voltage measurements.


Table 8.

Temperature

Coefficient of Thermal

Forward Resistance,

Forward Voltage VF[1] Dynamic Voltage[3] Junction

(V) Resistance[2] (mV/oC) to Case

Color Min. Typ. Max. () RD VF/TJ (oC/W) RJC

White 3.03 3.70 4.47 0.8 2.0 13

Green 3.03 3.70 4.47 0.8 2.0 13

Cyan 3.03 3.70 4.47 0.8 2.0 13

Blue 3.03 3.70 4.47 0.8 2.0 13

Royal Blue 3.03 3.70 4.47 0.8 2.0 13

Notes for Table 8:


2.Dynamic resistance is the inverse of the slope in linear forward voltage model for LEDs. See Figures 3a and 3b.

3.Measured between 25

o

C

TJ

110

o

C at IF = 700mA.


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Table 10.

Temperature

Coefficient of Thermal

Forward Resistance,

Dynamic Voltage[3] Junction

Forward Voltage VF (V)[1] Resistance[2] (mV/oC) to Case

Color Min. Typ. Max. () RD VF/TJ (oC/W) RJC

Red 2.31 2.95 3.51 0.7 2.0 6

RedOrange 2.31 2.95 3.51 0.7 2.0 6

Amber 2.31 2.95 3.51 0.7 2.0 6

Notes for Table 10:


2.Dynamic resistance is the inverse of the slope in linear forward voltage model for LEDs. See Figure 3.

3.Measured between 25C TJ 110C at IF = 1400mA.

Absolute Maximum Ratings

Table 11.

White/Green/ Red/

Cyan/Blue/ RedOrange/

Parameter Royal Blue Amber

DC Forward Current (mA)[1] 1000 1540

Peak Pulsed Forward Current (mA) 1000 2200

Average Forward Current (mA) 1000 1400

LED Junction Temperature (C) 135 135

Storage Temperature (C) 40 to +120 40 to +120

Soldering Temperature (C)[2]

260 for 260 for5 seconds max 5 seconds max

ESD Sensitivity [3] 16,000V HBM 16,000V HBM

Notes for Table 11:

1.Proper current derating must be observed to maintain junction temperature below the maximum. For more

information, consult the Luxeon Design Guide, available upon request.

2.Measured at leads, during lead soldering and slug attach, body temperature must not exceed 120C. Luxeon Emitters cannot

be soldered by general IR or Vaporphase reflow, nor by wave soldering. Lead soldering is limited to selective heating of the

leads, such as by hotbar reflow, fiber focussed IR, or hand soldering. The package back plane (slug) may not be attached by

soldering, but rather with a thermally conductive adhesive. Electrical insulation between the slug and the board is required.

Please consult Lumileds' Application Brief AB10 on Luxeon Emitter Assembly Information for further details on assembly

methods.3.LEDs are not designed to be driven in reverse bias. Please consult Lumileds' Application Brief AB11 for further information.


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Wavelength Characteristics, TJ = 25C

Figure 1b. White Color Spectrum of Typical 5500K CCT Part, Integrated Measurement.

0.0

0.2

0.4

0.6

0.8

1.0

350 400 450 500 550 600 650 700 750 800

Wavelength (nm)

Relative

SpecrtalPower

D

istribution

Figure 1a. Relative Intensity vs. Wavelength


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Light Output Characteristics

50

60

70

80

90

100

110

120

130

140

150

-20 0 20 40 60 80 100 120

Junction Temperature, TJ

(oC)

RelativeLightOutput(%)

Green Photometric

Cyan Phot ometric

Blue Phot ometric

White Pho tometric

Royal Blue Radiomet ric

Figure 2. Relative Light Output vs. Junction Temperature

for White, Green, Cyan, Blue and Royal Blue.

Figure 3. Relative Light Output vs. Junction Temperature

or Red, RedOrange and Amber.

0

2040

60

80

100

120

140

160

180

200

-20 0 20 40 60 80 100 120

Junction Temperature, T J (oC)

Re

lativeLightOutput(%)

Red

Red-Orange

Amber


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Forward Current Characteristics, TJ = 25C

Note:

Driving these high power devices at currents less than the test conditions may produce unpredictable results and may be subject

to variation in performance. Pulse width modulation (PWM) is recommended for dimming effects.

0

200

400

600

800

1000

1200

1400

1600

1800

2000

2200

1.00 1.25 1.50 1.75 2.00 2.25 2.50 2.75 3.00 3.25 3.50 3.75 4.00

Vf - Forward Voltage (Volts)

AverageForwardCurrent(m

Figure 5. Forward Current vs. Forward Voltage for Red,

RedOrange and Amber.

0100200300400500600700800900

10001100

0 1 2 3 4 5f - Forward Voltage (Volts)

AverageForwardCurrent(mA)

Figure 4. Forward Current vs. Forward Voltage for White,

Green, Cyan, Blue, and Royal Blue.


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Forward Current Characteristics, TJ = 25C, Continued

Note:

Driving these high power devices at currents less than the test conditions may produce unpredictable results and may be subject

to variation in performance. Pulse width modulation (PWM) is recommended for dimming effects.

0.0

0.2

0.4

0.6

0.8

1.0

1.2

1.4

1.6

0 200 400 600 800 1000 1200 1400 1600 1800 2000 2200

If - Forward Current (mA)

NormalizedRelativeLuminousFlu

Figure 7. Relative Luminous Flux vs. Forward Current for Red,

RedOrange and Amber at TJ = 25C maintained.

0.0

0.2

0.4

0.6

0.8

1.0

1.2

1.4

0 200 400 600 800 1000

If- Forward Current (mA)

NormalizedLuminousFlux

Figure 6. Relative Luminous Flux vs. Forward Current for White,

Green, Cyan, Blue, and Royal Blue at TJ = 25C maintained.


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Current Derating Curves

0100200300400500600700800900

10001100

0 25 50 75 100 125 150

TA - Ambient Temperature (C)

IF-ForwardCurrent(mA)

RJ-A=30oC/W

RJ-A=25oC/W

RJ-A=20oC/W

RJ-A=15oC/W

0

200

400

600

800

1000

1200

1400

1600

0 25 50 75 100 125 150

TA

- Ambient Temperature ( oC)

IF-Forward

Current(mA)

RJ-A=25o

C/WRJ-A=20

oC/W

RJ-A=15oC/W

RJ-A=10oC/W

Figure 8. Maximum Forward Current vs. Ambient Temperature.

Derating based on TJMAX = 135C for White, Green, Cyan, Blue, and Royal Blue. Since Luxeon III may be driven at up to 1000mA,

derating curves may not be applicable for all operating conditions.

Figure 9. Maximum Forward Current vs. Ambient Temperature

derating based on TJMAX = 135C for Red, RedOrange, and Amber.


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Typical Lambertian Representative Spatial Radiation Pattern

Note:

For more detailed technical information regarding Luxeon radiation patterns, please consult your Lumileds Authorized Distributor

or Lumileds sales representative.

0

10

20

30

40

50

60

70

80

90

100

-100 -80 -60 -40 -20 0 20 40 60 80 100

Angular Displacment (Degrees)

RelativeIntensity(%)

Typical Upper Bound

Typical Lower Bound

Figure 10. Typical Representative Spatial Radiation Pattern

for Luxeon Emitter White, Green, Cyan, Blue and Royal Blue.


for Luxeon Lambertian Emitter Red, RedOrange and Amber.

0%

10%

20%

30%

40%

50%

60%

70%

80%

90%

100%

-100 -80 -60 -40 -20 0 20 40 60 80 100

Angular Displacement (Degrees)

RelativeIntensit


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Typical Side Emitting Representative Spatial Radiation Pattern

Average Lumen Maintenance CharacteristicsLifetime for solidstate lighting devices (LEDs) is typically defined in terms of lumen maintenancethe percentage of

initial light output remaining after a specified period of time. Lumileds projects that white, green, cyan, blue, and royal blue

Luxeon III products will deliver, on average, 70% lumen maintenance at 50,000 hours of operation at a 700 mA forward currentor 50% lumen maintenance at 20,000 hours of operation at a 1000 mA forward current. Lumileds projects that red, redorange,

and amber Luxeon III products will deliver, on average 50% lumen maintenance at 20,000 hours of operation at a 1400 mA

forward current. This performance is based on independent test data, Lumileds historical data from tests run on similar material

systems, and internal Luxeon reliability testing. This projection is based on constant current operation with junction temperature

maintained at or below 90C. Observation of design limits included in this data sheet is required in order to achieve this

projected lumen maintenance.


for Luxeon Emitter White, Green and Blue.


for Luxeon Emitter Red, RedOrange and Amber.

0

10

20

30

40

50

60

70

80

90

100

-120 -100 -80 -60 -40 -20 0 20 40 60 80 100 120


RelativeIntensity

(%

Side Emitting Radiation Pattern

0%

10%

20%

30%

40%

50%

60%

70%

80%

90%

100%

-120 -100 -80 -60 -40 -20 0 20 40 60 80 100 120


RelativeIntensit


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Emitter Reel Packaging

Notes:

1.Luxeon emitters should be picked up by the body (not the lens) during placement. The inner diameter of the pickup collet

should be greater than or equal to 6.5 mm. Please consult Lumileds' Application Brief AB10 on Luxeon Emitter assembly

information for further details on assembly methods.

2.Drawings not to scale.



Figure 14. Reel dimensions and orientation.

LambertianSide Emitting

Figure 15. Tape dimensions for Lambertian and

Side Emitting radiation pattern.

Luxeon-3watt datasheetIII

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