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| Specification for Approval ( Version 1.0 ) Part No. : LFH1036 comments LUXPIA Co., Ltd. Designed by Checked by Approved by Approved by Approved by Approved by / / / / / / Date : . . . Date : . . . 948-1, Dunsan-Li Bongdong-Eup, Wanju-Gun, JeonBuk, Korea Tel 82-63-260-4500 Fax 82-63-261-8255 LUXPIA CO.,LTD. 1. Features CONTENTS - 2. Package Outline Dimensions and Materials 3. Absolute Maximum Ratings 4. Electro-Optical Characteristics 5. Materials 6. Taping 7. Packing 8. Reliability 9. Cautions 10. Warranty 11. Others 12. Characteristic Diagrams 1/15 1. Features * * * * * Package : SMD Top View Type (3chips in 1) Dimension : 3.5 x 2.8 x 0.9 mm (LxWxH) Small size surface mount type Viewing angle : extremely wide(120) Soldering methods : IR reflow soldering 2. Package Outline Dimensions and Recommended Solder Patterns 3. Absolute Maximum Ratings Parameter Forward Current Peak Forward Current1) Reverse Voltage Power dissipation Operating Temperature Storage Temperature 1) (Ta = 25 ) Value Blue 30 100 110 Green 30 100 5 110 -30+85 -40+100 75 Red 30 100 Unit mA mA V mW Symbol IF IFP VR PD Topr Tstg IFP conditions : pulse width 10msec & duty ratio 1/10 2/15 4. Electro-Optical Characteristics 4.1. Blue Item Rank 0 Forward Voltage2) 1 2 Dominant Wavelength Luminous intensity3) Reverse Current D Iv IR IF= 20mA IF= 20mA VR=5V VF IF= 20mA Symbol Test Condition Min. 3.0 3.2 3.4 450 70 Typ. 457 150 Max. 3.2 3.4 3.6 470 350 50 (Ta = 25 ) Item Rank 0 Forward Voltage2) 1 2 Dominant Wavelength Luminous intensity3) Reverse Current D Iv IR IF= 20mA IF= 20mA VR=5V VF IF= 20mA Symbol Test Condition Min. 3.0 3.2 3.4 520 300 Typ. 525 800 Max. 3.2 3.4 3.6 535 1400 50 nm mcd V Unit nm mcd V (Ta = 25 ) Unit 4.2. Green 4.3 . Red Item Rank 0 Forward Voltage2) 1 2 Dominant Wavelength Luminous intensity3) Reverse Current 2) 3) (Ta=25 ) Symbol Test Condition Min. 1.8 VF IF= 20mA 2.0 2.2 D Iv IR IF= 20mA IF= 20mA VR=5V 615 150 Typ. 620 350 Max. 2.0 2.2 2.4 635 850 50 nm mcd V Unit - Forward voltages are tested at a current pulse duration of 10 ms and an accuracy within 0.1V. The allowance of luminous intensity measurement is within 11%. 3/15 5. Materials item LED chip wire lead frame encapsulation heat-resistant polymer material InGaN, AlInGap gold copper alloy/Ni/Ag plating Silicone resin PPA 6. Taping 6.1. tape (material : PS conductive, 104~105) (Units : mm) 4/15 6.2. wheel (color : black, material : PS conductive, 109~1012) (Units : mm) - quantity per reel 6.3. label LFH1036 : 3,500 pcs part no. size (L X W) : 85mm x 50mm Red VF rank Green VF rank Blue VF rank 5/15 7. Packing * The LEDs are packed in cardboard boxes after taping. The label shows part number, lot number, rank, and quantity. * In order to protect the LEDs from mechanical shock, they are packed with cardboard boxes for transportation. * The LEDs may be damaged if the boxes are dropped or receive a strong impact against them, so cautions must be taken to prevent any possible damage. * The boxes are not water-resistant and, therefore, must be kept away from water and moisture. * When the LEDs are transported, it is recommended that the same packing method as Luxpia's is used. * If noticeable damage on a box appears upon arrival at the user's warehouse, the user should submit a claim to Luxpia within one week after arrival of the products. 6/15 8. Reliability 8.1. test items and results NO Test Item Resistance to Soldering Heat (Reflow Soldering) Solderability (Reflow Soldering) Standard Test Method JEITA ED-4701 300 301 JEITA ED-4701 300 303 JEITA ED-4701 100 105 JEITA ED-4701 200 201 JEITA ED-4701 100 103 JEITA ED-4701 200 202 Test Conditions Tsld=260c, 10sec. (Pre treatment 30c,70%,12hrs) Tsld=2155c, 3sec (Lead Solder) ~25 ~100 ~25 30min. 5min. 30min. 5min Ta=100 Ta=60 , RH=90% -40 Note Number of Damaged 0/22 1. 1 times 1 time over 95% 2 0/22 3 Temperature Cycle 100 cycles 0/22 4 5 6 High Temperature Storage Temperature Humidity Storage Low Temperature Storage Steady State Operating Life Condition Steady State Operating Life of High Temperature Steady State Operating Life of High Humidity Heat Steady State Operating Life of Low Temperature 500 hrs 500 hrs 500 hrs 0/22 0/22 0/22 Ta=-40 Ta=25 , Each IF=20mA Ta=85 , Each IF=5mA 60 , RH=90%, Each IF=10mA Ta=-30 , Each IF=20mA 7 500 hrs 0/22 8 - 500 hrs 0/22 9 - 500 hrs 0/22 10 - 500 hrs 0/22 * LED with Luxpia standard circuit board 7/15 8.2. criteria for judging the damage item symbol test condition Each IF = 20mA Each IF = 20mA criteria for judgement min L.S.L.5) x 0.5 max U.S.L.4) x 1.1 - forward voltage luminous intensity 4) 5) VF IV U.S.L. : upper standard level L.S.L. : lower standard level 9. Cautions White LEDs are devices which are materialized by combining Blue LEDs and special phosphors. Consequently, the color of White LEDs is subject to change a little by an operating current. Care should be taken after due consideration when using LEDs. (1) Moisture-Proof Package * When moisture is absorbed into the SMT package it may vaporize and expand products during soldering. There is a possibility that this may 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-absorbent material (silica gel) is inserted into the shielding bag. The silica gel changes its color from blue to pink as it absorbs moisture. (2) Storage * Storage Conditions - Before opening the package : The LEDs should be kept at 30 or less and 90%RH or less. The LEDs should be used within a year. When storing the LEDs, moisture-proof packaging with moisture-absorbent material (silica gel) is recommended. - After opening the package : The LEDs should be kept at 30 or less and 70%RH or less. The LEDs should be soldered within 168 hours (7 days) after opening the package. If unused LEDs remain, they should be stored in moisture-proof packages, such as sealed containers with packages of moisture-absorbent material (silica gel). It is also recommended to return the LEDs to the original moisture-proof bag and to reseal the moisture-proof bag again. * If the moisture-absorbent material (silica gel) has faded away or the LEDs have exceeded the rocommended storage time, baking treatment should be performed using the following conditions. - Baking treatment : more than 24 hours at 655 8/15 * Luxpia's LED electrode sections are comprised of a silver-plated copper alloy. The silver surface may be affected by environments which contain corrosive gases and so on. Please avoid condition which may cause difficulty during soldering operations. It is recommended that the User use the LEDs as soon as possible. * Please avoid rapid transitions in ambient temperature, especially in high humidity environments where condensation can occur. (3) Heat Generation * Thermal design of the end product is of paramount importance. Please consider the heat generation of the LED when the system is designed. The coefficient of temperature increase per input electric power is affected by the thermal resistance of the circuit board and density of LED placement on the board, as well as other components. It is necessary to avoid intense heat generation and operate within the maximum ratings given in the specification. * The operating current should be decided after considering the ambient maximum temperature of LEDs. (4) Soldering Conditions * The LEDs can be soldered in place using the reflow soldering method. Luxpia does not make any guarantee on the LEDs after they have been assembled using the dip soldering method. * The LEDs can be soldered in place using the reflow soldering method. Luxpia does not make any guarantee on the LEDs after they have been assembled using the dip soldering method. * Recommended soldering conditions Reflow Soldering Lead Solder pre-heat pre-heat time peak temperature soldering time condition 120~150 120sec max 240 max 10sec max refer to profile Lead-free Solder 180~200 120sec max 260 max 5sec max refer to profile temperature soldering time 350 max 3sec max (one time only) Hand Soldering * After reflow soldering, rapid cooling should be avoided. [temperature-profile (surface of circuit board)] Use the conditions shown to the following figures. < : Lead Solder> < : Lead-free Solder> 9/15 * Occasionally there is a brightness decrease caused by the influence of heat or ambient atmosphere during air reflow. It is recommended that the User use the nitrogen reflow method. * Repairing should not be done after the LEDs have been soldered. When repairing is unavoidable, a double-head soldering iron should be used. It should be confirmed beforehand whether the characteristics of the LEDs will or will not be damaged by repairing. * Reflow soldering should not be done more than two times. * When soldering, do not put stress on the LEDs during heating. * After soldering, do not warp the circuit board. (5) Cleaning * It is recommended that isopropyl alcohol be used as a solvent for cleaning the LEDs. When using other solvents, it should be confirmed beforehand whether the solvents will dissolve the package and the resin or not. Freon solvents should not be used to clean the LEDs because of worldwide regulations. Do not clean the LEDs by the ultrasonic. When it is absolutely necessary, the influence of ultrasonic cleaning on the LEDs depends on factors such as ultrasonic power and the assembled condition. Before cleaning, a pretest should be done to confirm whether any damage to the LEDs will occur. (6) Static Electricity * Static electricity or surge voltage damages the LEDs. It is recommended that a wrist band or an anti-electrostatic glove be used when handling the LEDs. * All devices, equipment and machinery must be properly grounded. It is recommended that measurements 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 find staticdamaged LEDs by a light-on test or a VF test at a lower current (below 1mA is recommended). * 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=0.5 (7) 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 at the LEDs with unaided eyes 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. 10. Warranty (1) Luxpia warrants that its LEDs conform to the foregoing specifications and that Luxpia will convey good title to all LEDs sold. (2) LUXPIA disclaims all other warranties including the implied warranties of merchantability and fitness for a particular purpose. (3) In the event any LED supplied by Luxpia is found not to conform to the foregoing specifications within ninety days of receipt, Luxpia will repair or replace the LED, at Luxpia's discretion, provided that the User (a) promptly notifies Luxpia in writing of the details of the defect (b) ships the LEDs at the User's expense to Luxpia for examination, and (c) the defect is due to the negligence of Luxpia and not mishandling or misuse by the User. 10/15 (4) Luxpia will not take responsibility for any trouble that is caused by using the LEDs at conditions exceeding our specifications. (5) These specifications are applied only when a LED stands alone and it is strongly recommended that the User of the LEDs confirms the properties upon assembly. Luxpia is not responsible for failures caused during and after assembling. It will be excepted from the rule if the failure would caused undoubtedly by Luxpia. (6) A claim report stating details about the defect shall be made when returning defective LEDs. Luxpia will investigate the report immediately and inform the user of the results. (7) The LEDs described in the specification are intended to be used for ordinary electronic equipment (such as office equipment, communications equipment, on the applications in which exceptional quality and reliability are required, particularly when the failure or malfunction of the LEDs may directly jeopardize life or health (such as for airplanes, aerospace, submersible repeaters, nuclear reactor control systems, automobiles, traffic control equipment, life support systems and safety devices) (8) LUXPIA's liability for defective lamps shall be limited to replacement and in no event shall LUXPIA be liable for consequential damage or lost profits. 11. Others (1) The warranties of quality set forth herein are exclusive. All previous negotiations and agreements not specifically incorporated herein are superseded and rendered null and void. (2) Both parties shall sincerely try to find a solution when any disagreement occurs regarding these specifications. (3) User shall not reverse engineer by disassembling or analysis of the LEDs without having prior written consent from Luxpia. When defective LEDs are found, the User shall inform Luxpia directly before disassembling or analysis. (4) These specifications can be revised upon mutual agreement. (5) Luxpia understands that the User accepts the content of these specifications, if the User does not return these specifications with signatures within 3 weeks after receipt. 11/15 12. Characteristic Diagrams 12.1. Blue (1) forward voltage vs. forward current 80 70 (2) forward current vs. relative luminosity 1.8 1.6 (Ta=25 ) (Ta=25 ) relative luminosity [a.u.] forward current IF [mA] 60 50 40 30 20 10 0 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 1.4 1.2 1.0 0.8 0.6 0.4 0.2 0.0 0 10 20 30 40 50 forward voltage VF[V] (3) ambient temperature vs. allowable forward current 35 forward current IF[mA] (4) ambient temperature vs. relative luminosity 10 (IF=20 ) allowable forward current IAF[mA] 30 25 20 relative luminosity[a.u.] 1 15 10 5 0 0 20 40 60 80 100 0.1 -40 -20 0 20 40 60 80 100 ambient temperature Ta[ ] ambient temperature Ta[ 12/15 ] 12.2. Green (1) forward voltage vs. forward current 80 70 (2) forward current vs. relative luminosity 1.8 1.6 (Ta=25 ) (Ta=25 ) relative luminosity [a.u.] forward current IF [mA] 60 50 40 30 20 10 0 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 1.4 1.2 1.0 0.8 0.6 0.4 0.2 0.0 0 10 20 30 40 50 forward voltage VF[V] (3) ambient temperature vs. allowable forward current 35 forward current IF[mA] (4) ambient temperature vs. relative luminosity (IF=20 ) 10 allowable forward current IAF[mA] 30 25 20 relative luminosity[a.u.] 1 15 10 5 0 0 20 40 60 80 100 0.1 -40 -20 0 20 40 60 80 100 ambient temperature Ta[ ] ambient temperature Ta[ ] 13/15 12.3 Red (1) forward voltage vs. forward current (Ta=25 ) (2) forward current vs. relative luminosity (2) Max. Permissible Forward Current 1.6 1.4 (Ta=25 ) forward current IF [mA] relative luminosity [a.u.] 1.2 1.0 0.8 0.6 0.4 0.2 0.0 0 5 10 15 20 25 30 forward voltage VF[V] (3) ambient temperature vs. allowable forward current 35 forward current IF[mA] (4) ambient temperature vs. relative luminosity (IF=20 ) 10 allowable forward current IAF[mA] 30 25 20 relative luminosity[a.u.] 1 15 10 5 0 0 20 40 60 80 100 0.1 -40 -20 0 20 40 60 80 100 ambient temperature Ta[ ] ambient temperature Ta[ ] 14/15 (5) relative spectral emission V() = standard eye response curve (Ta=25 , IF=20mA) Blue Green Red Intensity [a.u] Wavelength (6) radiation characteristics [nm] (Ta=25 , IF=20mA) 15/15 |
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