VISHAY TLMK/O/S/Y330 handbook
Contents
1. 10 20 30 40 50 60 70 80 90 100 17019 Ip Forward Current mA Figure 9 Change of Dominant Wavelength vs Forward Current 1 2 1 1 Soft orange 1 0 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 560 570 580 590 600 610 620 630 640 650 660 16314 A Wavelength nm 1 yg Relative Luminous Intensity Figure 10 Relative Intensity vs Wavelength www vishay com 6 Document Number 83201 Rev 1 4 31 Aug 04 TLMK 0O S Y330 Vishay Semiconductors 10 00 w 200 Eg Soft orange D o S 150 is S 100 o E Soft oran a 1 00 50 o E P og 3 5 o g 2 5 50 w 0 10 s o 5 100 iL 150 g gt gt lt 200 0 01 TIN A MEC L O ee 1 00 10 00 100 00 17020 Tamb Ambient Temperature C 17028 I Forward Current mA Figure 11 Change of Forward Voltage vs Ambient Temperature Figure 14 Relative Luminous Intensity vs Forward Current 2 5 3 1 5 E Soft orange Soft orange 20 2 10 Z 2 2 S 05 8 15 S 0 0 4 c7 9 1 0 E o 0 5 D 2 G T 0 5 z Eu O 10 Z o 0 0 Z 1 5 50 25 02. 10 10 102 47043 lp Forward Current mA 17044 tp Pulse Length s Figure 29 Change of Dominant Wavelength vs Forward Current Figure 30 Forward Current vs Pulse Length Package Dimensions in mm qe technical drawings according to DIN specifications Mounting Pad Layout L L2 area covered with solder resist 2 6 2 8 4 at 1 6 1 9 J m 2 4 Dimensions IR and Vaporphase 3 0 15 Wave Soldering Drawing No 6 541 5025 01 4 Issue 7 05 04 04 95 11314 www vishay com Document Number 83201 10 Rev 1 4 31 Aug 04 TLMK 0O S Y330 Vishay Semiconductors ae VISHAY Ozone Depleting Substances Policy Statement It is the policy of Vishay Semiconductor GmbH to 1 Meet all present and future national and international statutory requirements 2 Regularly and continuously improve the performance of our products processes distribution and operatingsystems with respect to their impact on the health and safety of our employees and the public as well as their impact on the environment It is particular concern to control or eliminate releases of those substances into the atmosphere which are known as ozone depleting substances ODSs The Montreal Protocol 1987 and its London Amendments 1990 intend to severely restrict the use of ODSs and forbid their use within the next ten years Various national and international initiatives are pressing for an earlier
3. 160 mcd 60 AllnGaP on GaAs TLMS3301 Red Iy 160 to 400 mcd 60 AllnGaP on GaAs TLMS3302 Red ly 250 to 800 mcd 60 AllnGaP on GaAs TLMO3300 Soft orange ly gt 200 mcd 60 AllnGaP on GaAs TLMO3301 Soft orange ly 250 to 640 mcd 60 AllnGaP on GaAs TLMO3302 Soft orange ly 320 to 800 mcd 60 AllnGaP on GaAs Document Number 83201 Rev 1 4 31 Aug 04 www vishay com 1 TLMK 0O S Y330 Vishay Semiconductors WEE VISHAY Part Color Luminous Intensity Angle of Half Intensity Technology 9 TLMO3303 Soft orange ly 400 to 1250 mcd 60 AllnGaP on GaAs TLMY3300 Yellow ly gt 200 mcd 60 AllnGaP on GaAs TLMY3301 Yellow ly 250 to 640 mcd 60 AllnGaP on GaAs TLMY3302 Yellow ly 320 to 800 mcd 60 AllnGaP on GaAs TLMY3303 Yellow ly 400 to 1250 mcd 60 AllnGaP on GaAs Absolute Maximum Ratings Tamb 25 C unless otherwise specified TLMY33 TLMO33 TLMK33 TLMS33 Parameter Test condition Symbol Value Unit Reverse voltage Vn 5 V DC Forward current Tamb 73 C 400 K W lE 50 mA Power dissipation Tamb 73 C 400 K W Py 130 mW Junction temperature Tj 125 C Operating temperature range Tamb 40 to 100 C Storage temperature range Tstg 40 to 100 C Soldering temperature t lt 5s Tsa 260 C Thermal resistance junction mounted on PC board Rthua 400 K W ambient pad size g
4. Red F 20 P 1 0 3 2 05 Oo 15 2 E 5 0 0 i a o 1 0 5 z 2 05 s o 2 S E UR O 10 o 0 0 Z 1 5 50 25 0 25 50 75 100 10 20 30 40 50 60 70 80 90 100 17035 Tamb Ambient Temperature C 17038 Ir Forward Current mA Figure 18 Relative Luminous Intensity vs Amb Temperature Figure 21 Change of Dominant Wavelength vs Forward Current E 6 1 2 2 14 iS 2 P 4 2 10 P 09 S 2 3 08 a or E E A 0 5 06 5 g 05 o o 2 E 0 4 g T 03 Oo 4 02 gt o E 0 1 eR 4 6 0 0 50 25 0 25 50 75 100 600 610 620 630 640 650 660 670 680 690 700 17036 Tamp Ambient Temperature C 17045 Wavelength nm Figure 19 Change of Dominant Wavelength vs Ambient Figure 22 Relative Intensity vs Wavelength Temperature www vishay com Document Number 83201 8 Rev 1 4 31 Aug 04 TLMK O S Y330 Vishay Semiconductors 100 2 5 90 2 Red lt 80 20 E 70 mi t 3 g 60 o 15 E 8 50 S v es g 40 g 10 30 E i 20 05 o 10 gt 0 0 0 1 5 1 6 1 7 1 8 1 9 2 0 2 1 2 2 2 3 24 2 5 50 25 0 25 50 75 100 17046 Vr Forwar
5. ban on these substances Vishay Semiconductor GmbH has been able to use its policy of continuous improvements to eliminate the use of ODSs listed in the following documents 1 Annex A B and list of transitional substances of the Montreal Protocol and the London Amendments respectively 2 Class and Il ozone depleting substances in the Clean Air Act Amendments of 1990 by the Environmental Protection Agency EPA in the USA 3 Council Decision 88 540 EEC and 91 690 EEC Annex A B and C transitional substances respectively Vishay Semiconductor GmbH can certify that our semiconductors are not manufactured with ozone depleting substances and do not contain such substances We reserve the right to make changes to improve technical design and may do so without further notice Parameters can vary in different applications All operating parameters must be validated for each customer application by the customer Should the buyer use Vishay Semiconductors products for any unintended or unauthorized application the buyer shall indemnify Vishay Semiconductors against all claims costs damages and expenses arising out of directly or indirectly any claim of personal damage injury or death associated with such unintended or unauthorized use Vishay Semiconductor GmbH P O B 3535 D 74025 Heilbronn Germany Telephone 49 0 7131 67 2831 Fax number 49 0 7131 67 2423 Document Number 83201 www vishay com Rev 1 4 31 Aug 04 11
6. 25 50 75 100 10 20 30 40 50 60 70 80 90 100 17021 Tamb Ambient Temperature C 17024 Ip Forward Current mA Figure 12 Relative Luminous Intensity vs Amb Temperature Figure 15 Change of Dominant Wavelength vs Forward Current E 6 1 2 DI c Soft orange lip Red P a4 5 10 9 9 z 09 S 2 a 08 9 0 HA 06 S o 5 gt 05 8 2 04 S a E 03 Oo 24 02 gt o us 0 1 eR 4 6 0 0 50 25 0 25 50 75 100 570 580 590 600 610 620 630 640 650 660 670 17622 Tamb Ambient Temperature C 16007 A Wavelength nm Figure 13 Change of Dominant Wavelength vs Ambient Figure 16 Relative Intensity vs Wavelength Temperature Document Number 83201 www vishay com Rev 1 4 31 Aug 04 7 TLMK 0O S Y330 Vishay Semiconductors z 10 00 E 2 T Red E g 9 P Z 1 00 S 2 S E rm 3 d id o g 2 2 0 10 E E S T li g gt gt a 0 01 50 25 0 2 50 75 100 1 00 10 00 100 00 17034 Tamb Ambient Temperature C 17087 le Forward Current mA Figure 17 Change of Forward Voltage vs Ambient Temperature Figure 20 Relative Luminous Intensity vs Forward Current 2 5 f 15 B
7. Parameter Test condition Part Symbol Min Typ Max Unit Luminous intensity lp 50 mA TLMO3300 ly 200 500 mcd TLMO3301 ly 250 640 mcd TLMO3302 ly 320 800 med TLMO3303 ly 400 1250 mcd Luminous flux Luminous by ly 3 mlm intensity mcd Dominant wavelength lp 50 mA Ad 600 605 611 nm Peak wavelength lp 50 mA p 611 nm Spectral bandwidth lp 50 mA AX 17 nm at 50 lre max Angle of half intensity lp 50 mA Q x60 deg Forward voltage lp 50 mA Ve 1 85 2 1 2 55 V Reverse current VR 5V VR 0 01 10 uA Document Number 83201 www vishay com Rev 1 4 31 Aug 04 3 TLMK 0O S Y330 Vishay Semiconductors Yellow TLMY33 Parameter Test condition Part Symbol Min Typ Max Unit Luminous intensity lp 50 mA TLMY3300 ly 200 450 mcd TLMY3301 ly 250 640 mcd TLMY3302 ly 320 800 mcd TLMY3303 ly 400 1250 mcd Luminous flux Luminous oy ly 3 mlm intensity mcd Dominant wavelength lp 50 mA ha 583 588 594 nm Peak wavelength lp 50 mA p 590 nm Spectral bandwidth lp 50 mA AA 18 nm at 50 lrei max Angle of half intensity lp 50 mA 9 60 deg Forward voltage lp 50 mA Ve 1 85 2 1 2 55 V Reverse current VR 5V Vn 0 01 10 uA Forward Voltage Classification Group Forward Voltage V min max 1 1 85 2 25 2 2 15 2 55 Color Classification Group Dominant Wavelen
8. ae VISHAY TLMK 0O S Y330 Vishay Semiconductors Power SMD LED in PLCC 2 Package Description The TLM 33 series is an advanced modification of the Vishay TLM 31 series It is designed to incorpo rate larger chips therefore capable of withstanding a 50 mA drive current The package of the TLM 33 is the PLCC 2 equiva lent to a size B tantalum capacitor It consists of a lead frame which is embedded in a white thermoplast The reflector inside this package is filled up with clear epoxy Features Utilizing AS AllnGaP technology Available in 8 mm tape Luninous intensity color and forward voltage categorized per packing unit Luminous intensity ratio per packing unit lymax lvmin lt 1 6 e Thermal resistance R 400 K W e ESD class 2 e Suitable for all soldering methods according to CECC e Lead free device 19225 Pb free Applications Traffic Signals and Signs Interior and exterior lighting Dashboard illumination Indicator and backlighting purposes for audio video LCD s switches symbols illuminated advertising etc Parts Table Part Color Luminous Intensity Angle of Half Intensity Technology 9 TLMK3300 Red ly gt 200 mcd 60 AllnGaP on GaAs TLMK3301 Red ly 250 to 800 mcd 60 AllnGaP on GaAs TLMK3302 Red Iy 400 to 800 mcd 60 AllnGaP on GaAs TLMK3303 Red ly 400 to 1250 mcd 60 AllnGaP on GaAs TLMS3300 Red ly gt
9. d Voltage V 17040 Tamb Ambient Temperature C Figure 23 Forward Current vs Forward Voltage Figure 26 Relative Luminous Intensity vs Amb Temperature 100 E 3 90 5 Red Red o z 9 56 E S 60 zou Oo 50 S a bus a a 40 5 2 o o 30 D T Bg cw 20 o T 40 o4 e 0 4 5 1 4 1 5 1 6 1 7 1 8 1 9 2 0 2 1 2 2 2 3 2 4 50 25 0 25 50 75 100 17047 Vr Forward Voltage V 17041 Tamb Ambient Temperature C Figure 24 Forward Current vs Forward Voltage Figure 27 Change of Dominant Wavelength vs Ambient Temperature I 10 E r S Red E E E z 1 2 z E E 5 Z i 0 D E c lt D o Ek gt gt 0 01 50 25 0 25 50 75 100 1 10 100 17039 Tamb Ambient Temperature C 17042 Ip Forward Current mA Figure 25 Change of Forward Voltage vs Ambient Temperature Figure 28 Relative Luminous Intensity vs Forward Current Document Number 83201 www vishay com Rev 1 4 31 Aug 04 9 TLMK 0O S Y330 Vishay Semiconductors f 15 0 12 10 25 7646 S Ks 9 t amp 05 g 0 08 ty T 0 005 z a P 005 5 00 gt 0 06 0 5 a jj 5 g 0 5 0 04 g i c wu 5 1 0 0 02 gt 1 5 0 00 10 20 30 40 50 60 70 80 90 100 105 10 103 102 10
10. gth nm Red Soft Orange Yellow min max min max min max 1 611 618 598 601 581 584 2 614 622 600 603 583 586 3 602 605 585 588 4 604 607 587 590 5 606 609 589 592 6 608 611 591 594 Luminous Intensity Classification Group Luminous Intensity mcd min max Xa 160 250 Xb 200 320 Ya 250 400 Yb 320 500 Za 400 630 Zb 500 800 0a 630 1000 Ob 800 1250 www vishay com Document Number 83201 4 Rev 1 4 31 Aug 04 wu TLMK O S Y330 Vishay Semiconductors Group Name on Label Luminous Intensity Group Halfgroup Wavelength Forward Voltage Z b 2 1 One packing unit tape contains only one classification group of luminous intensity color and forward voltage Only one single classification groups is not available The given groups are not order codes customer specific group combinations require marketing agreement No color subgrouping for Super Red Typical Characteristics T4 25 C unless otherwise specified 200 2 _ 180 S 160 140 Rinsa 400K W 3 Ko lt a 120 E A 60 3 Fi ud 20 gt 0 0 25 50 75 100 125 16783 Tamb Ambient Temperature C 95 10319 Figure 1 Power Dissipation vs Ambient Temperature Figure 3 Rel Luminous Intensity vs Angular Displacement 100 1 2 90 E 11 Yellow lt 8 m E 3 5 0 9 5 60 Rihya 400K W 2 Me G 50 5
11. oe P oa uL 02 10 7 01 0 0 0 0 25 50 75 100 125 540 550 560 570 580 590 600 610 620 630 640 16784 Tamb Ambient Temperature C 16008 A Wavelength nm Figure 2 Forward Current vs Ambient Temperature Figure 4 Relative Intensity vs Wavelength Document Number 83201 Rev 1 4 31 Aug 04 www vishay com 5 TLMK 0O S Y330 Vishay Semiconductors AV Change of Forward Voltage mV 50 25 0 25 50 75 100 17015 Tamb Ambient Temperature C Figure 5 Change of Forward Voltage vs Ambient Temperature 2 5 Yellow 2 0 1 5 1 0 luigi Relative Luminous Intensity 50 25 0 25 50 75 100 17016 Tamb Ambient Temperature C Figure 6 Relative Luminous Intensity vs Amb Temperature 6 Yellow 4 2 0 2 4 6 50 25 0 25 50 75 100 17017 Tamb Ambient Temperature C Aja Change of Dom Wavelength nm Figure 7 Change of Dominant Wavelength vs Ambient Temperature 10 00 E Yellow 2 g 9 1 00 o E d o 2 0 10 T g z 0 01 1 00 10 00 100 00 17018 Ir Forward Current mA Figure 8 Relative Luminous Intensity vs Forward Current Yellow Aida Change of Dom Wavelength nm
12. t 16 mm Optical and Electrical Characteristics Tamb 25 C unless otherwise specified Red TLMK33 Parameter Test condition Part Symbol Min Typ Max Unit Luminous intensity lp 50 mA TLMK3300 ly 200 500 mcd TLMK3301 ly 250 800 mcd TLMK3302 ly 400 800 mcd TLMK3303 ly 400 1250 mcd Luminous flux Luminous dy ly 3 mlm intensity mcd Dominant wavelength lp 50 mA d 611 617 622 nm Peak wavelength lp 50 mA p 624 nm Spectral bandwidth lp 50 mA A 18 nm at 50 lrei max Angle of half intensity lp 50 mA 9 60 deg Forward voltage lp 50 mA Ve 1 85 2 1 2 55 V Reverse current VR 5V Vn 0 01 10 uA www vishay com Document Number 83201 2 Rev 1 4 31 Aug 04 TLMK 0O S Y330 Vishay Semiconductors ae VISHAY Red TLMS33 Parameter Test condition Part Symbol Min Typ Max Unit Luminous intensity lp 50 mA TLMS3300 ly 160 300 mcd TLMS3301 ly 160 400 mcd TLMS3302 ly 250 800 mcd Luminous flux Luminous by ly 3 mlm intensity mcd Dominant wavelength lp 50 mA ha 626 630 638 nm Peak wavelength lp 50 mA p 641 nm Spectral bandwidth lp 50 mA AX 17 nm at 50 liel max Angle of half intensity lp 50 mA 9 60 deg Forward voltage lp 50 mA Ve 1 85 2 1 2 55 V Reverse current VR 5V VR 0 01 10 uA Soft Orange TLMO33
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VISHAY TLMK/O/S/Y330 handbook