T5050

Data Sheets of AVA Technology SMD Type White LED Model : T5050 AVA Technology Co. 2640 S. Myrtle Ave. Suite 6 Monrovia, CA 91016 P: 626-574-7726 F: 626-574-7732 http://www.led4life.com AVA Technology 1. FEATURES · · · · · · · · High intensity with small package, ideal for backlighting Wide viewing angle ( 120° ) Package Outline (L×W×H)=5.0×5.0×1.5 mm Technology : InGaN Color coordinates CIE(x,y) : (0.31,0.31) according to CIE 1931. Suitable for all SMT assembly methods Suitable for all soldering methods Delivery on 12mm tape reels T5050 Top View LED with Reflector 2. APPLICATIONS · · · · · · · Automotive: indoor/outdoor lighting. Signal and symbol lightings Backlighting (Large LCD…..) All applications in notice high intensities are required Strobe Light Channel Letter Decorative Light 3. DEVICES PACKAGE ITEM Package Encapsulating Electrodes MATERIALS Heat-Resistant Polymer Heat Resistance Resin Ag Plating Copper Alloy Type T5050 Color of Emission White Color of the Light Emitting Area Colored Luminous intensity Iv (mcd) IF =20mA 3000 ~ 6000 Doc. No. : RD-EDS-0031 Version 1.0 Date : 2007.01.10 Page: 1 of 14 AVA Technology 4. OUTLINE DIMENSION: T5050 Note: 1. Unit: mm 2. Tolerance: Dimension ± 0.1 / Angle ± 0.5˚ Doc. No. : RD-EDS-0031 Version 1.0 Date : 2007.01.10 Page: 2 of 14 AVA Technology 5. ABSOLUTE MAXIMUM RATINGS ( TA=25℃ ) Parameter Reverse Voltage Forward Current Operating Temperature Storage Temperature Soldering Temperature Power Dissipation Peak Forward Current (Duty 1/10 @ 1KHz) Junction temperature Thermal Resistance (Junction to ambient) Symbol VR IF Topr Tstg Tsol PD IF(peak) Tj Rth, JA Absolute Max. Rating 5 40 -30 ~ +85 -40 ~ +100 260 (for 5 sec) 432 (3 chips ON) 240 (3 chips ON) 110 450 T5050 Unit V mA ℃ ℃ ℃ mW mA ℃ ℃/W 6. ELECTRONIC OPTICAL CHARACTERISTICS Parameter Chromaticity coordinate x acc. To CIE 1931 Chromaticity coordinate y acc. To CIE 1931 Viewing Angle Forward Voltage Leakage Current Symbol x y 2θ1/2 VF IR Condition IF=20/20/20mA IF=20/20/20mA IF=20/20/20mA IF=20/20/20mA VR= -5V Min. ----------Typ. Max. Unit 0.31 0.31 120 3.30 --------3.60 50 ----Deg V μA Doc. No. : RD-EDS-0031 Version 1.0 Date : 2007.01.10 Page: 3 of 14 AVA Technology 7. LUMINOUS INTENSITY GROUPS: Luminous intensity group W5 W4 W3 W2 Measurement condition Luminous intensity Iv(mcd) 5000-6000 4250-5000 3600-4250 3000-3600 T5050 IF = 20/20/20 mA * Luminous intensity group includes 4 groups W2 to W5. * Luminous intensity is tested at a current pulse duration of 25ms and a tolerance of ± 10% Doc. No. : RD-EDS-0031 Version 1.0 Date : 2007.01.10 Page: 4 of 14 AVA Technology 8. CHROMATICITY COORDINATES RANKS : T5050 CIE x 0.2650 0.2690 a31 0.2790 0.2760 0.2690 0.2770 a32 0.2850 0.2790 0.2790 a33 0.2850 (b71) 0.2950 0.2900 0.2760 0.2790 a34 0.2900 0.2870 0.2770 0.2840 a36 0.2910 0.2850 0.2470 0.2670 e00 0.2810 0.2650 0.2850 0.2910 b72 0.3000 0.2950 0.2950 0.3000 b73 0.3080 0.3060 Rank y 0.2670 0.2625 0.2760 0.2810 0.2625 0.2535 0.2665 0.2760 0.2760 0.2665 0.2785 0.2885 0.2810 0.2760 0.2885 0.2950 0.2535 0.2460 0.2570 0.2665 0.2370 0.2190 0.2490 0.2670 0.2665 0.2570 0.2690 0.2785 0.2785 0.2690 0.2790 0.2875 Rank b74 (b52) b82 b83 b84 (b62) b51 b53 (b81) b54 b61 Forward Current, IF=20mA CIE CIE CIE Rank Rank x y x y x y 0.2900 0.2885 0.3190 0.3180 0.3177 0.3350 0.2950 0.2785 0.3200 0.3050 0.3185 0.3270 b63 b43 0.3060 0.2875 0.3300 0.3170 0.3300 0.3390 0.3020 0.3000 0.3300 0.3300 0.3300 0.3490 0.3060 0.2875 0.3185 0.3270 0.3172 0.3452 0.3080 0.2790 0.3190 0.3180 0.3177 0.3350 b64 b44 0.3130 0.2850 0.3300 0.3300 0.3300 0.3490 0.3110 0.2940 0.3300 0.3390 0.3300 0.3600 0.3110 0.2940 0.2830 0.3070 0.3300 0.3600 0.3130 0.2850 0.2853 0.3000 0.3300 0.3390 b31 d1 0.3210 0.2940 0.2980 0.3150 0.3400 0.3390 0.3200 0.3050 0.2960 0.3210 0.3400 0.3600 0.3085 0.3075 0.2853 0.3000 0.3300 0.3390 0.3110 0.2940 0.2870 0.2950 0.3300 0.3170 b32 d2 0.3200 0.3050 0.3000 0.3080 0.3400 0.3170 0.3190 0.3180 0.2980 0.3150 0.3400 0.3390 0.2870 0.2950 0.2980 0.3150 0.3400 0.3390 0.2900 0.2885 0.3000 0.3080 0.3400 0.3170 b33 d3 0.3020 0.3000 0.3070 0.3150 0.3500 0.3170 0.3000 0.3080 0.3055 0.3220 0.3500 0.3390 0.3020 0.3000 0.2960 0.3210 0.3400 0.3600 0.3060 0.2875 0.2980 0.3150 0.3400 0.3390 b34 d4 0.3110 0.2940 0.3055 0.3220 0.3500 0.3390 0.3085 0.3075 0.3040 0.3300 0.3500 0.3600 0.3000 0.3080 0.3040 0.3300 0.3020 0.3000 0.3055 0.3220 b41 0.3085 0.3075 0.3177 0.3350 0.3070 0.3150 0.3172 0.3452 0.3070 0.3150 0.3055 0.3220 0.3085 0.3075 0.3070 0.3150 b42 0.3190 0.3180 0.3185 0.3270 0.3185 0.3270 0.3177 0.3350 * CIE rank can be sorted by 0.008~0.015 * Tolerance of the chromaticity coordinate is ±0.007 Doc. No. : RD-EDS-0031 Version 1.0 Date : 2007.01.10 Page: 5 of 14 AVA Technology 9. TYPICAL ELECTRO-OPTICAL CHATACTERISTIC CURVES: * Chromaticity Coordinates (CIE 1931 system) T5050 Doc. No. : RD-EDS-0031 Version 1.0 Date : 2007.01.10 Page: 6 of 14 AVA Technology * Forward Voltage vs. Forward Current @25℃ 120 100 80 I F ( m A) T5050 Forward Current vs. Relative Luminosity@25℃ 2.5 2.0 Iv (%) 1.5 1.0 0.5 0.0 60 40 20 0 1 1.5 2 2.5 3 3.5 4 4.5 5 VF (Volt) 0 20 40 60 IF (mA) 80 100 120 * Ambient Temperature vs. Allowable Forward Current * Ambient Temperature vs. Forward Voltage@20mA 50 40 IF (mA) 4.50 4.25 4.00 VF (Volt) 0 20 40 60 80 Ta(℃) 100 120 30 20 10 0 3.75 3.50 3.25 3.00 2.75 2.50 -60 -40 -20 0 20 40 60 80 100 120 Ta(℃) Doc. No. : RD-EDS-0031 Version 1.0 Date : 2007.01.10 Page: 7 of 14 AVA Technology * Forward Current vs. Chromaticity diagram @ 25℃ 0.34 5mA T5050 * Spectrum @ 20mA, 25℃ 100 80 0.33 10mA C IE y 0.32 0.31 0.3 0.29 0.29 0.3 0.31 60 20mA 30mA 50mA 80mA 100mA 40 20 0 0.32 0.33 0.34 380 480 580 680 780 CIE x * Ambient Temperature vs. Chromaticity Diagram @ 20mA * Radiation Characteristic (@ 25℃, 20mA) 0.340 -40℃ 0.330 C IE y 0℃ 20℃ 0.320 25℃ 0.310 100℃ 60℃ 80℃ 0.300 0.300 0.310 CIE x 0.320 0.330 Doc. No. : RD-EDS-0031 Version 1.0 Date : 2007.01.10 Page: 8 of 14 AVA Technology 10. REEL PACKAGE: T5050 Note: 1. Unit: mm 2. 1,000 pcs / reel Doc. No. : RD-EDS-0031 Version 1.0 Date : 2007.01.10 Page: 9 of 14 AVA Technology 11. RELIABILITY PLAN: * The reliability of products shall be satisfied with items listed below. Confidence Level : 90 % , LTPD : 10 % Sample size 22 T5050 No Test Item Description & Condition Tsld =2355℃, 10sec, 1 time Ac/Re Failure Criteria 1 Solderability 0/1 2 Room Temperature Ta = 25 °C operating IF = 60mA 1000 hrs 22 0/1 IV < L* 0.6 (IF: 20mA) VF > U * 1.1 (IF: 20mA) IR > U * 2.0 (VR:5V) L: Lower Spec. Level U: Upper Spec. Level 3 Room Temperature Ta = 25 °C operating IF = 90mA Low Temperature Storage High Temperature Storage Temperature Cycle 500 hrs 22 0/1 4 5 Ta = -40 °C Ta = 100 °C -40°C ~ 25°C ~ 100°C ~ 25 °C 30min 5min 30min 5 min Ta = 60 °C RH=90% IF = 45mA 1000 hrs 1000 hrs 22 22 0/1 0/1 6 100 cycles 22 0/1 7 High Humidity Heat 500 hrs 22 0/1 Doc. No. : RD-EDS-0031 Version 1.0 Date : 2007.01.10 Page: 10 of 14 AVA Technology 12. SOLDERING CONDITIONS: (1) Recommended Re-flow profile T5050 Temp. (℃) 235 ℃ Max. 240 2.5~ 5℃ /sec Pre-heating 150 2.5~ 5℃ /sec 90 120 sec Max. 10sec Recommended Soldering Pad (Unit : mm) (2) Re-flow soldering should not be done more than two times. (3) It is recommended that the user use the nitrogen reflow method. (4) When soldering, don’t put stress on the LEDs during heating. (5) After soldering, don’t warp the circuit board. (6) It is recommended that isopropyl alcohol (IPA) be used as a solvent for cleaning the LEDs. Doc. No. : RD-EDS-0031 Version 1.0 Date : 2007.01.10 Page: 11 of 14 AVA Technology 13.CAUTIONS: T5050 (1)Storage ‧Before opening the package : The LEDs should be kept at 30℃ or less and 30%RH~85%RH. The LEDs should be used within a year. When storing the LEDs, moisture proof packaging with desiccant (Silica gel)is recommended. ‧After opening the package : The LEDs should be kept at 30℃ or less and 30%RH~70%RH.The LEDs should be soldered within 168hours (7days) after opening the package. If unused LEDs remain, they should be stored in moisture proof packages, such as sealed containers with packages of moisture desiccant (Silica ge1), or reseal the moisture proof bag again. If the moisture desiccant (Silica ge1)has faded away or the LEDs have exceeded the storage time, baking treatment should be performed using the fo1lowing conditions. Baking treatment: more than 24 hours at 65℃. Please avoid conditions which may cause the LED to corrode, tarnish or disco1or. This corrosion or discoloration might lower solderability or might effect on optical characteristics.-Please avoid rapid transitions in ambient temperature, especially in high humidity environments where condensation can occur. ‧Moisture Proof package When moisture is absorbed into the SMT package it may vaporize and expand during soldering. There is a possibility that this can cause exfoliation of the contacts and damage to the optical characteristics of the LEDs. For this reason, the moisture proof package is used to keep moisture to a minimum in the package. A package of a moisture desiccant (silica gel)is inserted into the moisture proof bag-The silica gel changes its color from blue to pink as it absorbs moisture. (2)Static Electricity ‧Static electricity or surge voltage damages the LEDs. It is recommended that a wrist band or an anti-electrostatic glove and shoe be used when handling the LEDs. ‧All devices, equipment and machinery must be properly grounded. It is recommended that measures be taken against surge voltage to the equipment that mounts the LEDs. ‧when inspecting the final products in which LEDs were assembled, it is recommended to check whether the assembled LEDs are damaged by static electricity or not. It is easy to End static-damaged LEDs by a light-on test or a VF test at a lower current (below l mA). ‧ Damaged LEDs will show some unusual characteristics such as the leak current remarkably increases, the forward voltage becomes lower, or the LEDs do not light at the low current. (Criteria : VF>2.0V at IF=0.5mA.) (3)Heat Generation ‧Please consider the heat generation of the LED when making the system design that it’s very importance. The coefficient of temperature increase per input electric power is effected by the thermal resistance of the circuit board and density of LED placement on the board, and other components. It is necessary to avoid intense heat generation and operate within the maximum ratings given in this specification. ‧ The operating current should be decided after considering the ambient maximum temperature of LEDs. Doc. No. : RD-EDS-0031 Version 1.0 Date : 2007.01.10 Page: 12 of 14 AVA Technology T5050 (4)Others ‧Care must be taken to ensure that the reverse voltage will not exceed the absolute maximum rating when using the LEDs with matrix drive. ‧The LED light output is strong enough to injure human eyes. Precautions must be taken to prevent looking directly for more than a few seconds. Flashing lights have been known to cause discomfort in people; you can prevent this by taking precautions during use. Also, people should be cautious when using equipment that has had LEDs incorporated into it. Doc. No. : RD-EDS-0031 Version 1.0 Date : 2007.01.10 Page: 13 of 14 AVA Technology Copyright, Trademarks and Patents T5050 AVA TECHNOLOGY CO. MAKES NO WARRANTY, REPRESENTATION OF GUARANTEE, EXPRESS OR IMPLIED, REGARDING THE SUITABILITY OF ITS PRODUCTS FOR ANY PARTICULAR PURPOSE, NOR THAT THE USE OR APPLICATION AND SPECIFICALLY DISCLAIMS ANY AND ALL LIABILITY ARISING OUT OF ANY SUCH USE OR APPLICATION, INCLUDING BUT NOT LIMITED TO, CONSEQUENTIAL OR INCIDENTAL DAMAGES. AVA Technology Co. are not designed, intended or authorized for use as components in systems intended for surgical implant into the body, or other applications intended to support or sustain life, or for any other application in which the failure of the AVA Technology Co. Product could create a situation where personal injury or death may occur. AVA Technology Co. reserves the right to make changes to or discontinue any product or service described herein without notice. AVA Technology Co. World Wide Web http://www.led4life.com Doc. No. : RD-EDS-0031 Version 1.0 Date : 2007.01.10 Page: 14 of 14