LED HIGH POWER C08 Product Series LED HIGH POWER C08 C08 Product Product Series Series Data Data Sheet Sheet Created CreatedDate: Date:03 03//08 08//2013 2013 Revision: Revision:1.4, 1.3,05 03//08 15//2013 2013 1 BNC-OD-C131/A4 Created Date : 05/26/2007 Revison : 1.01, 05/26/2008 LED HIGH POWER C08 Product Series 1. Description The LiteON C08 Product series is a revolutionary, energy efficient and ultra-compact new light source, combining the lifetime and reliability advantages of Light Emitting Diodes with the brightness of conventional lighting. It gives you total design freedom and unmatched brightness, creating a new opportunities for solid state lighting to displace conventional lighting technologies. 1.1 Features Compact high flux density light source Uniform high quality illumination Streamlined thermal path MacAdam compliant binning structure More energy efficient than incandescent, halogen and fluorescent lamps Instant light with unlimited dimming RoHS compliant and Pb free DC 12V/24V/48V, HV 100V/200V application Enhanced optical control Clean white light without pixilation Uniform consistent white light Significantly reduced thermal resistance and increased operating temperatures Lower operating costs Reduced maintenance costs ESD rating is 8KV in HBM 1.2 Available Part Numbers Nominal CCT Minimum CRI Forward Voltage Part Number 2700K 80 100V LTPL-C08DZS27 3000K 80 100V LTPL-C08DZS30 4000K 70 12V LTPL-C08EXS40 2700K 80 12V LTPL-C08EZS27 3000K 80 12V LTPL-C08EZS30 4000K 80 12V LTPL-C08EZS40 3000K 90 12V LTPL-C08EQS30 02 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 2. Outline Dimensions 2.1 Form Factor of C08 LTPL-C08DXXXX LTPL-C08EXXXX Notes 1. All dimensions are in millimeters and dimension tolerances are ± 0.2mm except lens height and ceramic length / width dimension tolerance are ± 0.1mm. 2. Thermal pad of the device is electrically neutral from the anode and cathode pads. 03 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 3. Rating and Characteristics 3.1 Absolute Maximum Ratings at Ta=25°C. Parameter Symbol Rating Unit Power Dissipation (100V) Po 6.5 W Power Dissipation (12V) Po 10 W DC Forward Current (100V) IF 60 mA DC Forward Current (12V) IF 720 mA ESD Sensitivity VB 8 kV Junction Temperature Tj 125 °C Thermal Resistance, Junction-Case(100V) Rth, J-C 4.5 °C / W Thermal Resistance, Junction-Case (12V) Rth, J-C 3.3 °C / W Operating Temperature Range Topr -40~+85 °C Storage Temperature Range Tstg -55~+100 °C Notes 1. 2. 3. 4. 5. The pulse mode condition is 1 KHz with 0.1msec pulse width.. Forbid to operating at reverse voltage condition ESD spec is reference to AEC-Q101-001 HBM. The unit of Rth is °C/W electrical. Thermal resistance measurement tolerance is ± 10% 04 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 3.2 Electro-Optical Characteristics LTPL-C08DXXXX Nominal CCT Minimum CRI Current (mA) Typ. VF (V) @25°C Typ. Flux(lm) @25°C Typ. VF (V) @85°C Typ. Flux(lm) @85°C Eff.(lm/W) @25°C Eff.(lm/W) @85°C 2700K 80 40 100 360 94 324 90 86 3000K 80 40 100 378 94 340 95 90 LTPL-C08EXXXX Nominal CCT Minimum CRI Current (mA) Typ. VF (V) @25°C Typ. Flux(lm) @25°C Typ. VF (V) @85°C Typ. Flux(lm) @85°C Eff.(lm/W) @25°C Eff.(lm/W) @85°C 4000K 70 350 12 567 11.6 510 135 125 2700K 80 350 12 460 11.6 414 110 102 3000K 80 350 12 483 11.6 435 115 107 4000K 80 350 12 506 11.6 455 120 112 3000K 90 350 12 386 11.6 348 92 85 Notes 1. 2. 3. 4. 5. All of the VF value are typical and the real bin range please refer page 10 ”VF Binning Parameter”. All of the Flux value are typical and the real Bin range please refer page 11 ”Flux Binning Parameter”. Tolerance of Flux is ±7%, Tolerance of VF is ±3%, tolerance of CCx/CCy is ±0.01, tolerance of CRI is ±3. LEDs are lighted up and measured with externally parallel connecting leads of LED. Typical viewing angle is 130deg. 05 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 4. Typical Electrical/Optical Characteristics Curve Efficiency Comparison Table (CRI 80 Series) 4.1 Relative Flux vs. Current of LTPL-C08DXXXX at 25°C 180% Relative Luminous Fux (%) 160% 140% 120% 100% 80% 60% 40% 20% 0% 0 20 40 60 80 100 Current (mA) Fig 1. Typical relative luminous flux vs. forward current of LTPL-C08DXXXX Current VF Current VF Current VF Lumen (lm) (mA) (V) (mA) (V) (mA) (V) 2700K 3000K 5 192.6 10 96.3 20 48.1 105 111 10 202.4 20 101.2 40 50.6 199 209 15 209.4 30 104.7 60 52.3 284 298 20 214.8 40 107.4 80 53.7 360 378 25 219.8 50 109.9 100 55.0 429 451 30 224.0 60 112.0 120 56.0 493 517 Notes 1. Black current-voltage data is gotten by using external parallel connection of 4 strings; deep gray one is by 2 series 2 parallel connection; and gray one is by 4 series connection. 2. The drawing is based on the data of 2 series 2 parallel connection configuration. 06 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 4.2 Relative Flux vs. Current of LTPL-C08EXXXX at 25°C 180% Relative Luminous Fux (%) 160% 140% 120% 100% 80% 60% 40% 20% 0% 0 100 200 300 400 500 600 700 Current (mA) Fig 2. Typical relative luminous flux vs. forward current of LTPL-C08EXXXX Current VF Current VF Current VF Lumen (lm) (mA) (V) (mA) (V) (mA) (V) 2700K 3000K 4000K 20 43.0 40 21.5 80 10.7 114 120 126 40 44.3 80 22.2 160 11.1 223 234 248 60 45.5 120 22.7 240 11.4 326 342 362 80 46.4 160 23.2 320 11.6 423 444 470 87.5 46.8 175 23.4 350 11.7 460 483 506 100 47.4 200 23.7 400 11.8 516 541 572 120 48.3 240 24.1 480 12.1 603 634 670 140 49.2 280 24.6 561 12.3 687 722 763 160 50.0 320 25.0 641 12.5 770 809 855 Notes 1. Black current-voltage data is gotten by using external parallel connection of 4 strings; deep gray one is by 2 series 2 parallel connection; and gray one is by 4 series connection. 2. The drawing is based on the data of parallel connection configuration. 07 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 4.3 Relative Spectral Distribution vs. Wavelength Characteristics at 25°C & 85°C Warm White 25degC Cool White, CRI 80 85degC CRI 80 25degC 85degC Fig 3. Relative Spectral Distribution at Tj = 25°C & 85°C 4.4 Typical Spatial Radiation Pattern 0° 100% 90% 30° Relative Intensity (%) 80% 70% 60% 60° 50% 40% 30% 20% 10% 0% 90° 60 30° 0° 50 100 Fig 4. Radiation Characteristics 08 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 4.5 Forward Current vs. Forward Voltage at 25°C 90 80 Current (mA) 70 60 50 40 30 20 10 0 90.00 95.00 100.00 105.00 110.00 115.00 120.00 Voltage (V) Fig 5. Forward Current vs. Forward Voltage of LTPL-C08DXXXX 700 Current (mA) 600 500 400 300 200 100 0 10.50 11.00 11.50 12.00 12.50 13.00 Voltage (V) Fig 6. Forward Current vs. Forward Voltage of LTPL-C08EXXXX 09 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 4.6 Maximum Forward Current vs. Ambient Temperature 45 Forward Current (mA) 40 35 30 25 20 15 10 5 0 0 20 40 60 80 100 120 140 Ambient Temperature (°C) Fig 7. Forward Current Degrading Curve of LTPL-C08DXXXX 400 Forward Current (mA) 350 300 250 200 150 100 50 0 0 20 40 60 80 100 120 140 Ambient Temperature (°C) Fig 8. Forward Current Degrading Curve of LTPL-C08EXXXX 010 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 5. VF Bin Definition 5.1 Forward Voltage Binning Parameter at 25°C LTPL-C08DXXXX Parameter Bin Symbol Min Max Unit Condition Forward Voltage HV1 VF 97 101 V IF = 40mA Forward Voltage HV2 VF 101 105 V IF = 40mA Forward Voltage HV3 VF 105 109 V IF = 40mA Forward Voltage HV4 VF 109 113 V IF = 40mA Parameter Bin Symbol Min Max Unit Condition Forward Voltage DC1 VF 11 11.3 V IF = 350mA Forward Voltage DC2 VF 11.3 11.7 V IF = 350mA Forward Voltage DC3 VF 11.7 12.1 V IF = 350mA Forward Voltage DC4 VF 12.1 12.6 V IF = 350mA LTPL-C08EXXXX 011 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 6. Flux Bin Definition 6.1 Luminous Flux Binning Parameter at 25°C LTPL-C08DXXXX CRI 80 Series 2700K Parameter Bin Symbol Min Max 315 345 345 375 HJ 375 405 JL 405 435 Min Max 345 375 375 405 JL 405 435 LN 435 465 Min Max 405 435 435 465 NP 465 495 PR 495 535 Min Max 435 465 465 495 JL 495 535 LN 535 575 DF Luminous Flux FH ΦV Unit condition lm If=40mA Unit condition lm If=40mA Unit condition lm If=350mA Unit condition lm If=350mA 3000K Parameter Bin Symbol FH Luminous Flux HJ ΦV LTPL-C08EXXXX CRI 80 Series 2700K Parameter Bin Symbol JL Luminous Flux LN ΦV 3000K Parameter Bin Symbol FH Luminous Flux HJ ΦV 012 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 4000K Parameter Bin Symbol Min Max 450 480 480 515 QS 515 555 SU 555 600 Min Max 360 390 390 420 420 450 Min Max 515 555 555 600 600 650 MO Luminous Flux OQ ΦV Unit condition lm If=350mA Unit condition lm If=350mA Unit condition lm If=350mA CRI 90 Series 3000K Parameter Bin Symbol GI Luminous Flux IK ΦV KM CRI 70 Series 4000K Parameter Bin Symbol QS Luminous Flux SU UW ΦV 013 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 7. Color Bin Definition 7.1 Chromaticity Coordinate Groups at 25°C Notes 1. 2. The Chromaticity Coordinate Groups follow ANSI 7-Step MacAdam Quadrangle The (CIEx, CIEy) center follow ANSI Quadrangle 014 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 7.2 Chromaticity Coordinate Category Code Table at 25°C 2700K Series 0.44 0.42 2700K CIE-Y 3000K 0.40 black body 25°C FP1 25°C FP2 85°C 0.38 0.43 0.45 0.47 0.49 CIE-X Center point(25C) ZCA ZCB Center point(85C) X Y 0.4585 0.4124 0.4653 0.4257 0.4543 0.4203 0.4627 0.4045 0.4693 0.4183 0.4653 0.4257 0.4543 0.4203 0.4477 0.4063 0.4517 0.3991 0.4627 0.4045 0.4543 0.4203 0.4578 0.4101 015 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 3000K Series Center point(25C) ZDA/QDA ZDB/QDB Center point(85C) X Y 0.4345 0.4053 0.4413 0.4186 0.4303 0.4132 0.4387 0.3974 0.4453 0.4112 0.4413 0.4186 0.4303 0.4132 0.4237 0.3992 0.4277 0.3920 0.4387 0.3974 0.4303 0.4132 0.4338 0.4030 016 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 4000K Series Center point(25C) ZFA/XFA ZFB/XFB Center point(85C) X Y 0.3825 0.3820 0.3949 0.3915 0.3905 0.3978 0.3772 0.3891 0.3877 0.3743 0.3949 0.3915 0.3877 0.3743 0.3744 0.3664 0.3699 0.3728 0.3772 0.3891 0.3877 0.3743 0.3818 0.3797 017 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 8. Reflow Soldering Characteristics Profile Feature Lead Free Assembly Average Ramp-Up Rate (TSmax to TP) 3°C / second max Preheat Temperature Min (TSmin) 150°C Preheat Temperature Max (TSmax) 200°C Preheat Time (tSmin to tSmax) 60 – 180 seconds Time Maintained Above Temperature (TL) 217°C Time Maintained Above Time (tL) 60 – 150 seconds Peak / Classification Temperature (TP) 255°C Time Within 5°C of Actual Peak Temperature (tP) 5 seconds Ramp – Down Rate 6°C / second max Time 25°C to Peak Temperature 8 minutes max 018 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series Notes: 1. The LEDs can be soldered using the reflow soldering or hand soldering method. The recommended hand soldering condition is 350°C max. and 2secs max. for one time only, and the recommended reflow soldering condition is 260°C max. and 5secs max. for three times max. 2. All temperatures refer to topside of the package, measured on the package body surface. 3. The soldering condition referring to J-STD-020B. The storage ambient for the LEDs should not exceed 30°C temperature or 70% relative humidity. It is recommended that LEDs out of their original packaging are soldered within one week. For extended storage out of their original packaging, it is recommended that the LEDs were stored in a sealed container with appropriate desiccant, or desiccators with nitrogen ambient. If the LEDs were unpacked more than 168hrs, baking the LEDs at 60℃ for 60 mins before soldering process. 4. The soldering profile could be further referred to different soldering grease material characteristic. The grease vendor will provide this information. 5. A rapid-rate process is not recommended for the LEDs cooling down from the peak temperature. 6. Although the recommended reflow conditions are specified above, the reflow or hand soldering condition at the lowest possible temperature is desirable for the LEDs. 7. LiteOn cannot make a guarantee on the LEDs which have been already assembled using the dip soldering method. 019 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 9. Reliability Test Plan LTPL-C08DXXXX Number No Test item Condition Duration of Failed High Temperature Operating Life Tc=105°C, IF=40mA DC (HTOL) (0, 250, 500, 750, 1000hrs) High Temperature Operating Life Tc=85°C, IF=40mA DC (HTOL) (0, 250, 500, 750, 1000hrs) Room Temperature Operating Life Tc=55°C, IF=40mA DC (RTOL) (0, 250, 500, 750, 1000hrs) Wet High Temperature Operating 85°C/85%RH, (WHTOL) IF=40mA DC 30 min ON/OFF 1 2 3 4 1K hrs 0/20 1K hrs 0/20 1K hrs 0/20 1K hrs 0/20 1K cycles 0/20 1K cycles 0/20 -40°C to 105°C 5 Power Temperature Cycle (PTMCL) 15minutes dwell/15minutes transfer 5 minutes ON/5 minutes OFF IF=40mA DC -40°C to 125°C 30minutes dwell, <10 seconds transfer 6 Non-Operating Thermal Shock (TMSK) measure each 250 cycles (continues to fail, more than 1k cycles) 40000cycles, 2 mins On/Off, Room 40K 7 Fast switch Cycling Test temperature(25°C+/-5°C), measurement in every 0/20 cycles 5000cycles Notes: 1. Operating life test are mounted on thermal heat sink 2. Storage item are only component, not put on heat sink. Criteria for Judging the Damage Criteria for Judgment Item Symbol Test Condition Min. Max. Forward Voltage Vf IF=Typical Current -10% +10% Luminous Flux Lm IF=Typical Current -15% +15% 020 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series CCX&CCY X,Y IF=Typical Current -0.007 +0.007 LTPL-C08EXXXX Number No Test item Condition Duration of Failed High Temperature Operating Life Tc=105°C, IF=350mA DC (HTOL) (0, 250, 500, 750, 1000hrs) High Temperature Operating Life Tc=85°C, IF=350mA DC (HTOL) (0, 250, 500, 750, 1000hrs) Room Temperature Operating Life Tc=55°C, IF=350mA DC (RTOL) (0, 250, 500, 750, 1000hrs) Wet High Temperature Operating 85°C/85%RH, (WHTOL) IF=350mA DC 30 min ON/OFF 1 2 3 4 1K hrs 0/20 1K hrs 0/20 1K hrs 0/20 1K hrs 0/20 1K cycles 0/20 1K cycles 0/20 -40°C to 105°C 5 Power Temperature Cycle (PTMCL) 15minutes dwell/15minutes transfer 5 minutes ON/5 minutes OFF IF=350mA DC -40°C to 125°C 30minutes dwell, <10 seconds transfer 6 Non-Operating Thermal Shock (TMSK) measure each 250 cycles (continues to fail, more than 1k cycles) 40000cycles, 2 mins On/Off, Room 40K 7 Fast switch Cycling Test temperature(25°C+/-5°C), measurement in every 0/20 cycles 5000cycles Notes: 3. Operating life test are mounted on thermal heat sink 4. Storage item are only component, not put on heat sink. Criteria for Judging the Damage Criteria for Judgment Item Symbol Test Condition Min. Max. Forward Voltage Vf IF=Typical Current -10% +10% Luminous Flux Lm IF=Typical Current -15% +15% 021 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series CCX&CCY X,Y IF=Typical Current -0.007 +0.007 10. Recommend Soldering Pad Layout Notes: 1. Suggest stencil thickness is maximum 0.10mm 022 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 023 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 11. Package Dimensions of Tape and Reel Reel Packaging Note: 1. All dimensions are in millimeters. 2. Empty component pockets sealed with top cover tape. 024 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series 12. Cautions 12.1 An LED is a current-operated device. In order to ensure intensity uniformity on multiple LEDs connected in parallel in an application, it is recommended that a current limiting resistor be incorporated in the drive circuit, in series with each LED as shown in Circuit below. LED Circuit model A LED Circuit model B (A) Recommended circuit. (B) The brightness of each LED might appear different due to the differences in the I-V characteristics of those LEDs. 12.2 Do not put any pressure on the light emitting surface either by finger or any hand tool and do not stack the COB products. Stress or pressure may cause damage to the wires of the LED array. 12.3 This product is not designed for the use under any of the following conditions, please confirm the performance and reliability are well enough if you use it under any of the following conditions ・Do not use sulfur-containing materials in commercial products including the materials such as seals and adhesives that may contain sulfur. ・Do not put this product in a place with a lot of moisture (over 85% relative humidity), dew condensation, briny air, and corrosive gas (Cl, H2S, NH3, SO2, NOX, etc.), exposure to a corrosive environment may affect silver plating. ESD (Electrostatic Discharge) Static Electricity or power surge will damage the LED. Suggestions to prevent ESD damage: Use of a conductive wrist band or anti-electrostatic glove when handling these LEDs. All devices, equipment, and machinery must be properly grounded. Work tables, storage racks, etc. should be properly grounded. Use ion blower to neutralize the static charge which might have built up on surface of the LED’s plastic lens as a result of friction between LEDs during storage and handling. ESD-damaged LEDs will exhibit abnormal characteristics such as high reverse leakage current, low forward voltage, or “no light up” at low currents. To verify for ESD damage, check for “light up” and VF of the suspect LEDs at low currents. 025 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013 LED HIGH POWER C08 Product Series Lens Handling Remark The LED should only be picked up by making contact with the sides of the LED body. It should not put any pressure on the lens either by finger or any hand tool. Do not puncture or push the lens. Below figure illustrate correct and incorrect handling. Storage The storage ambient for the LEDs should not exceed 30°C temperature or 85% relative humidity. 13. Recommended Circuit Application 13.1 LTPL-C08ExSxx 13.2 LTPL-C08DxSxx 026 BNC-OD-C131/A4 Created Date : 03/08/2013 Revison : 0.3, 05/08/2013