HLMP-CB11-TW0XX中文资料

Features•Well defined spatial radiation pattern •Viewing angle:major axis 120°minor axis 60°•High luminous output•Two red and amber intensity levels:AlInGaP (bright) and AlInGaP II (brightest)•Colors:626/630 nm red590/592 nm amber526 nm green 470 nm blue•Superior resistance to moisture •UV resistant epoxyBenefits•Viewing angle designed for wide field of view applications•Superior performance for outdoor environments•Radiation pattern matched for red, green, and blue for full color sign Applications •Full color signsDescriptionThese Precision Optical Performance Oval LEDs are specifically designed for Full Color/Video and Passenger Information signs. The oval shaped radiation pattern (60° x 120°) and high luminous intensity ensure that these devices are excellent for wide field of view outdoor applications where a wide viewing angle and readability in sunlight are essential.These lamps have very smooth, matched radiation patterns ensuring consistent color mixing in full color applications, message uniformity across the viewing angle of the sign.High efficiency LED materials are used in these lamps:Aluminum Indium Gallium Phosphide (AlInGaP) for Red and Amber color and Indium Gallium Nitride (InGaN) for Blue and Green. There are two families of red and amber lamps, AlInGaP and the higher performance AlInGaP II. Each lamp is made with an advanced optical grade epoxy offering superior high temperature and high moisture resistance in outdoor applications. The package epoxy contains both uv-a and uv-b inhibitors to reduce the effects of long term exposure to direct sunlight.Designers can select parallel (where the axis of the leads is parallel to the wide axis of the oval radiation pattern) or perpendicular orientation. Both lamps are available in tinted version.SunPower SeriesHLMP-RG10, HLMP-SG10, HLMP-RL10, HLMP-SL10,HLMP-RD11, HLMP-SD11, HLMP-RL11, HLMP-SL11,HLMP-RM11, HLMP-SM11, HLMP-RB11, HLMP-SB11CAUTION: The Blue and Green LEDs are Class 1 ESD sensitive. Please observe appropriateprecautions during handling and processing. Refer to Avago Technologies Application Note AN-1142for additional details.HLMP-RG104 mm Super Oval Precision Optical Performance AlInGaP and InGaN LEDsData SheetPackage DimensionsNotes:1.The luminous intensity is measured on the mechanical axis of the lamp package.2.The optical axis is closely aligned with the package mechanical axis.3.The dominant wavelength, λd , is derived from the CIE Chromaticity Diagram and represents the color of the lamp.Device Selection Guide for AlInGaPColor and Luminous Dominant IntensityWavelength I V (mcd) at 20 mA Leads with Leadframe Package Part Number λd (nm) Typ.Min. Max.Stand-Offs Orientation Drawing HLMP-SG10-JM000Red 626240 680Yes Perpendicular A HLMP-RG10-JM000Red 626240 680Yes Parallel B HLMP-SL10-LP0xx Amber 590400 1150Yes Perpendicular A HLMP-RL10-LP0xxAmber 590400 1150YesParallelB0.44 ± 0.20A∅(0.016+0.004–0.000)0.44 ± 0.20B∅(0.016+0.004–0.000)(0.018+0.004–0.002)DIMENSIONS ARE IN MILLIMETERS (INCHES).Device Selection Guide for AlInGaP IIColor and LuminousDominant IntensityWavelength I V (mcd) at 20 mA Leads with Leadframe Package Part Numberλd (nm) Typ.Min. Max.Stand-Offs Orientation Drawing HLMP-RD11-J0000Red 630240 -Yes Parallel B HLMP-RD11-LP000Red 630400 1150Yes Parallel B HLMP-RD11-LPT00Red 630400 1150Yes Parallel B HLMP-RL11-H0000Amber 592180 -Yes Parallel B HLMP-RL11-LP000Amber 592400 1150Yes Parallel B HLMP-RL11-LPRxx Amber 592400 1150Yes Parallel B HLMP-SD11-J0000Red 630240 -Yes Perpendicular A HLMP-SD11-LP000Red 630400 1150Yes Perpendicular A HLMP-SD11-LPT00Red 630400 1150Yes Perpendicular A HLMP-SD11-MN0xx Red 630520 880Yes Perpendicular A HLMP-SD11-MNTxx Red 630520 880Yes Perpendicular A HLMP-SL11-H0000Amber 592180 -Yes Perpendicular A HLMP-SL11-HL0xx Amber 592180 520Yes Perpendicular A HLMP-SL11-KN0xx Amber 592310 880Yes Perpendicular A HLMP-SL11-LP0xx Amber 592400 1150Yes Perpendicular A HLMP-SL11-LPRxx Amber 592400 1150Yes Perpendicular ANotes:1.The luminous intensity is measured on the mechanical axis of the lamp package.2.The optical axis is closely aligned with the package mechanical axis.3.The dominant wavelength, λd, is derived from the CIE Chromaticity Diagram and represents the color of the lamp.Device Selection Guide for InGaNColor and LuminousDominant IntensityWavelength I V (mcd) at 20 mA Leads with Leadframe Package Part Numberλd (nm) Typ.Min. Max.Stand-Offs Orientation Drawing HLMP-SM11-LP0xx Green 526400 1150Yes Perpendicular A HLMP-RM11-H00xx Green 526180 -Yes Parallel B HLMP-RM11-M00xx Green 526520 -Yes Parallel B HLMP-SB11-H00xx Blue 470180 -Yes Perpendicular A HLMP-RB11-D00xx Blue 47065 -Yes Parallel B HLMP-RB11-H00xx Blue 470180 -Yes Parallel BNotes:4.The luminous intensity is measured on the mechanical axis of the lamp package.5.The optical axis is closely aligned with the package mechanical axis.6.The dominant wavelength, λd, is derived from the CIE Chromaticity Diagram and represents the color of the lamp.Part Numbering SystemHLMP-x x xx-x x x xxMechanical Options00: Bulk PackagingDD: Ammo PackYY: Flexi-Bin; Bulk PackagingZZ: Flexi-Bin; Ammo PackColor Bin & V F Selections0: No Color Bin LimitationR: Amber Color Bins 1, 2, 4, and 6 with V F Maximum of 2.6 VT: Red Color with V F Maximum of 2.6 VMaximum Intensity Bin0: No Iv Bin LimitationMinimum Intensity BinRefer to Device Selection GuideColorB: 470 nm BlueD: 630 nm RedG: 626 nm RedL: 590/592 nm AmberM: 526 nm GreenPackageR: 4 mm 60º x 120º Oval, ParallelS: 4 mm 60º x 120º Oval, PerpendicularAbsolute Maximum RatingsT A = 25°CParameter Blue and Green Amber and RedDC Forward Current[1]30 mA50 mAPeak Pulsed Forward Current100 mA100 mAAverage Forward Current30 mA30 mAReverse Voltage (I R = 100 µA) 5 V 5 VPower Dissipation120 mW120 mWLED Junction Temperature130°C130°COperating Temperature Range–40°C to +80°C–40°C to +100°C Storage Temperature Range–40°C to +100°C–40°C to +120°CNote:1. Derate linearly as shown in Figures 6 and 7.Electrical/Optical CharacteristicsT A = 25°CParameter Symbol Min.Typ.Max.Units Test ConditionsTypical Viewing Angle[1]2θ1/2degMajor120Minor60Forward Voltage V F V I F = 20 mARed (λd = 626 nm) 1.9 2.4Red (λd = 630 nm) 2.0 2.4[2]Amber (λd = 590 nm) 2.02 2.4Amber (λd = 592 nm) 2.15 2.4[2]Blue (λd = 470 nm) 3.5 4.0Green (λd = 526 nm) 3.5 4.0Reverse Voltage V R V I R = 100 µAAmber and Red520Blue and Green5–Peak WavelengthλPEAK nm Peak of Wavelength ofRed (λd = 626 nm)635Spectral DistributionRed (λd = 630 nm)639at I F = 20 mAAmber (λd = 590 nm)592Amber (λd = 592 nm)594LED IndicatorsParameter Symbol Min.Typ.Max.Units Test ConditionsBlue (λd = 470 nm)467Green (λd = 526 nm)524Spectral Halfwidth∆λ1/2nm Wavelength Width atRed (λd = 626/630 nm)17Spectral DistributionAmber (λd = 590/592 nm)171/2 Power Point at I F = 20 mA Blue (λd = 470 nm)20Green (λd = 526 nm)35Capacitance C pF V F = 0, F = 1 MHzAll Colors40Thermal Resistance RθJ-PIN°C/W LED Junction-to-CathodeAll Colors240LeadLuminous Efficacy[3]ηv lm/W Emitted Luminous Power/Red (λd = 626 nm)150Emitted Radiant PowerRed (λd = 630 nm)155Amber (λd = 590 nm)480Amber (λd = 592 nm)500Blue (λd = 470 nm)70Green (λd = 526 nm)540Notes:1. 2θ1/2 is the off-axis angle where the luminous intensity is the on-axis intensity.2. For options -xxRxx, -xxTxx, and -xxVxx, maximum forward voltage, V F, is 2.6 V. Please refer to V F Bin Table below.3. The radiant intensity, I e, in watts per steradian, may be found from the equation I e = I v/ηv, where I v is the luminous intensity in candelas and ηv isthe luminous efficacy in lumens/watt.Figure 6. Amber, Red maximum forward current vs. ambient temperature.Figure 7. Blue, Green maximum forward current vs. ambient temperature.Figure 1. Relative intensity vs. wavelength.Figure 2. Amber, Red forward current vs.forward voltage.Figure 4. Amber, Red relative luminous intensity vs. forward current.Figure 3. Blue, Green forward current vs.forward voltage.Figure 5. Blue, Green relative luminous intensity vs. forward current.WAVELENGTH – nmR E L A T I V E I N T E N S I T Y1.00.504020I F – F O R W A R D C U R R E N T – m AV F – FORWARD VOLTAGE – V10305003015I F – F O R W A R D C U R R E N TV F – FORWARD VOLTAGE2.04.02.43.23.6520352.81025R E L A T I V E L U M I N O U S I N T E N S I T Y (N O R M A L I Z E D A T 20 m A )I F – FORWARD CURRENT – mA 20402.01.0500.51.52.53010R E L A T I V E L U M I N O U S I N T E N S I T Y (N O R M A L I Z E D A T 20 m A )I F – FORWARD CURRENT – mA030520251.5100.51.015I F – F O R W A R D C U R R E N T – m AT A – AMBIENT TEMPERATURE – °C I F – F O R W A R D C U RR E N T – m AT A – AMBIENT TEMPERATURE – °CFigure 8b. Representative spatial radiation pattern for minor axis.Intensity Bin Limits (mcd at 20 mA)Bin NameMin.Max.D 6585E 85110F 110140G 140180H180240J 240310K 310400L 400520M 520680N 680880P8801150Tolerance for each bin limit is ± 15%.Note:1.Bin categories are established forclassification of products. Products may not be available in all bin categories.Figure 8a. Representative spatial radiation pattern for major axis.R E L A T I V E I N T E N S I T Y1.00ANGULAR DISPLACEMENT – DEGREES0.80.60.2-900.4-60-30154590-45-153060-7575R E L A T I V E I N T E N S I T Y1.00ANGULAR DISPLACEMENT – DEGREES0.80.60.2-900.4-600-30154590-45-153060-7575 Bin NameMin.Max.VA 2.0 2.2VB 2.2 2.4VC 2.4 2.6Tolerance for each bin is ±0.05 V.VF Bin Table [2]Blue Color Range (nm)Bin Min.Max.1460.0464.02464.0468.03468.0472.04472.0476.05476.0480.0Note:1. All bin categories are established for classification of products. Products may not be available in all bin categories.Please contact your Avago representa-tives for further information.Color Bin Limits (nm at 20 mA)Tolerance for each bin limit is ±0.5 nm.GreenColor Range (nm)Bin ID Min.Max.1520.0524.02524.0528.03528.0532.04532.0536.05536.0540.0Tolerance for each bin limit is ±0.5 nm.AmberColor Range (nm)Bin ID Min.Max.1584.5587.02587.0589.54589.5592.06592.0594.5Tolerance for each bin limit is ±0.5 nm.Precautions Lead Forming•The leads of an LED lamp may be preformed or cut to length prior to insertion and soldering into PC board.•If lead forming is required before soldering, care must be taken to avoid any excessive mechanical stress induced to LED package. Otherwise, cut the leads of LED to length after soldering process at roomtemperature. The solder joint formed will absorb the mechanical stress of the lead cutting from traveling to the LED chip die attach and wirebond.•It is recommended that tooling made to preciselyform and cut the leads to length rather than rely upon hand operation.Soldering Conditions•Care must be taken during PCB assembly and soldering process to prevent damage to LED component.•The closest LED is allowed to solder on board is 1.59mm below the body (encapsulant epoxy) for those parts without standoff.•Recommended soldering conditions:•Wave soldering parameter must be set andmaintained according to recommended temperature and dwell time in the solder wave. Customer isadvised to periodically check on the soldering profile to ensure the soldering profile used is always conforming to recommended soldering condition.•If necessary, use fixture to hold the LED component in proper orientation with respect to the PCB during soldering process.•Proper handling is imperative to avoid excessive thermal stresses to LED components when heated.Therefore, the soldered PCB must be allowed to cool to room temperature, 25°C, before handling.•Special attention must be given to board fabrication,solder masking, surface plating and lead holes size and component orientation to assure solderability.•Recommended PC board plated through hole sizes for LED component leads:Manual Solder Wave Soldering Dipping Pre-heat Temperature 105 °C Max.–Pre-heat Time 30 sec Max.–Peak Temperature 250 °C Max.260 °C Max.Dwell Time3 sec Max.5 sec Max.LED Component Plated Through Lead SizeDiagonal Hole Diameter 0.457 x 0.457 mm 0.646 mm 0.976 to 1.078 mm (0.018 x 0.018 inch)(0.025 inch)(0.038 to 0.042 inch)0.508 x 0.508 mm 0.718 mm 1.049 to 1.150 mm (0.020 x 0.020 inch)(0.028 inch)(0.041 to 0.045 inch)Note: Refer to application note AN1027 for more information on soldering LED components.Figure 9. Recommended wave soldering profile.BOTTOM SIDE OF PC BOARD TIME – SECONDST E M P E R A T U R E – °CTOP SIDE OF PC BOARDCONVEYOR SPEED = 1.83 M/MIN (6 FT/MIN)PREHEAT SETTING = 150°C (100°C PCB)SOLDER WAVE TEMPERATURE = 245°C AIR KNIFE AIR TEMPERATURE = 390°C AIR KNIFE DISTANCE = 1.91 mm (0.25 IN.)AIR KNIFE ANGLE = 40°SOLDER: SN63; FLUX: RMANOTE: ALLOW FOR BOARDS TO BESUFFICIENTLY COOLED BEFORE EXERTING MECHANICAL FORCE.For product information and a complete list of distributors, please go to our website: Avago, Avago Technologies, and the A logo are trademarks of Avago Technologies Limited in the United States and other countries. Data subject to change. Copyright © 2006 Avago Technologies Limited. All rights reserved. Obsoletes 5989-2793EN5989-4174EN May 21, 2006。

SunPower Series HLMP-WLxx HLMP-NL06HLMP-WHxx HLMP-NH04HLMP-WGxx HLMP-NG07Features• T-1 (3 mm) and T-1 3/4(5 mm) General Purpose LED Lamps• AlInGaP SunPower Intensity • High Light Output• Clear and Tinted Diffused Lens Options• Narrow and Wide Viewing Angles• Amber, Red-Orange, and Red • Available on Tape and ReelDescriptionThis family of 3 mm and 5 mm LED lamps is specially designed for applications requiring higher levels of intensity than isachieved with a standard lamp.The 5 mm lamp is available with 15, 30, and 65 degree viewing angle options. The 3 mm lamp is available with a 60 degree viewing angle.Applications• General Purpose • Consumer Goods • Indicator LightsDevice Selection GuidesT-1 3/4 (5 mm) Lamp PackageLuminous IntensityViewing Angle Color Part Number Diff. Tint Min. mcd, If @ 20 mA2θ 1/2 (Degrees)Amber HLMP-WL1245015Amber HLMP-WL2720530Amber HLMP-WL02X X 3565Red Orange HLMP-WH1227015Red Orange HLMP-WH2715530Red Orange HLMP-WH02X X 3565Red HLMP-WG1227015Red HLMP-WG2715530Red HLMP-WG02X X 2665T-1 (3 mm) Lamp Package Luminous Intensity Viewing Angle Color Part Number Diff. Tint Min. mcd, If @ 20 mA2θ 1/2 (Degrees)Amber HLMP-NL0696.260Red Orange HLMP-NH0490.260Red HLMP-NG0790.260High Intensity AlInGaP LED Lamps Technical DataTechnical DataNotes:1. Dominant Wavelength, λd , is derived from the CIE Chromaticity Diagram, and represents the color of the lamp.2. Θ1/2 is the off-axis angle where the luminous intensity is one half the on-axis intensity.3. The luminous intensity is measured on the mechanical axis of the lamp package.4. The optical axis is closely aligned with the package mechanical axis.5. Tinting of amber lamps is yellow, red-orange lamps are tinted a reddish orange, and red lamps are tinted red.Package Dimensions(0.039)– 0ABAbsolute Maximum Ratings at T A = 25°CParameter 5 mm 3 mmDC Forward Current50 mA[1,3,4]30 mA[2,3,4]Peak Pulsed Forward Current [3,4]70 mA50 mAAverage Forward Current30 mA30 mAReverse Voltage (I R = 100 µA) 5 V 5 VLED Junction Temperature130°C110°COperating Temperature-40°C to +100°C-40°C to +80°CStorage Temperature-40°C to +120°C-40°C to +85°CDip/Drag Solder Temperature260°C for 5 secondsWave Solder Temperature245°C for 3 seconds[1.59 mm (0.060 in.) below seating plane]Notes:1. Derate linearly as shown in Figure 4.2. Derate linearly as shown in Figure 5.3.For long term performance with minimal light output degradation, drive currents between 10 and 30 mA are recommended.4. Please contact your Agilent sales representative about operating currents below 10 mA.Electrical/Optical Characteristics at T A = 25°CParameter Symbol Min.Typ.Max.Units Test Conditions Forward Voltage I F = 20 mAAmber (λd = 590 nm) 2.02Red-Orange (λd = 615 nm)V F 1.94 2.4VRed (λd = 626 nm) 1.90Reverse Voltage V R520V I R = 100 µAPeak Wavelength Peak of Wavelength of Amber592Spectral Distribution Red-OrangeλPEAK621nm at I F = 20 mARed635Spectral Halfwidth∆λ1/217nm Wavelength Width atSpectral Distribution1/2 Power point atI F = 20 mASpeed of Responseτs20ns Exponential TimeConstant, e-t/τs Capacitance C40pF V F = 0, f = 1 MHz Thermal Resistance RΘJ-PIN240°C/W LED Junction-to-CathodeLeadLuminous Efficacy[5]Emitted Luminous Amber500Power/Emitted Radiant Red-Orangeηv235lm/W PowerRed155Note:1. The radiant intensity, I e, in watts per steridian, may be found from the equation I e = I v/ηv, where I v is the luminous intensity incandelas and ηv is the luminous efficacy in lumens/watt.Figure 2. Forward Current vs.Forward Voltage.Figure 3. Relative Luminous Intensity vs. Forward Current.Figure 4. Maximum Forward Current vs. Ambient Temperature for 5 mm Lamps. Derating Based on T JMAX =130°C.Figure 5. Maximum Forward Current vs. Ambient Temperature for 3 mm Lamps. Derating Based on T JMAX =110°C.Figure 1. Relative Intensity vs. Peak Wavelength.WAVELENGTH – nmR E L A T I V E I N T E N S I T YC U R R E N T – m A1.00V F – FORWARD VOLTAGE – V2.540301.52.0603.0102050AMBER70REDR E L A T I V E L U M I N O U S I N T E N S I T Y (N O R M A L I Z E D A T 20 m A )00I F – DC FORWARD CURRENT – mA 402.52.01.00.520603.01.5I F – F O R W A R D C U R R E N T – m AT A – AMBIENT TEMPERATURE – °CI F – F O R W A R D C UR R E N T – m AT A – AMBIENT TEMPERATURE – °CFigure 7. Representative Spatial Radiation Pattern for 30°Viewing Angle T-1 3/4 (5 mm) Lamps (HLMP-WX27).Figure 8. Representative Spatial Radiation Pattern for 65° Viewing Angle Tinted/Diffused T-1 3/4 (5 mm) Lamps (HLMP-WX02).Figure 6. Representative Spatial Radiation Pattern for 15°Viewing Angle T-1 3/4 (5 mm) Lamps (HLMP-WX12).N O R M A L I Z E D I N T E N S I T Y – %1.00ANGULAR DISPLACEMENT – DEGREES0.80.60.50.70.2-80-600.10.30.4-40204060801000.9-100-20R E L A T I V E I N T E N S I T Y – %1.00ANGULAR DISPLACEMENT – DEGREES0.80.60.50.70.2-20-150.10.30.4-105101520250.9-25-5R E L A T I V E I N T E N S I T Y – %1.00ANGULAR DISPLACEMENT – DEGREES0.80.60.50.70.2-20-150.10.30.4-105101520250.9-25-5Figure 9. Representative Spatial RadiationPattern for 60° Viewing Angle T-1 (3 mm) Lamps (HLMP-NL06/NH04/NG07).N O R M A L I Z E D I N T E N S I T Y – %1000ANGULAR DISPLACEMENT – DEGREES8060507020-70-50103040-400204060809090-90-20-10-30-60-8010305070Data subject to change.Copyright © 1999 Agilent Technologies, Inc. Obsoletes 5965-9780E (7/97)5968-0947E (11/99)。

T-13/4 (5 mm) Precision Optical Performance AlInGaP LED LampsData SheetFeatures• Well Defined Spatial Radiation Patterns• Viewing Angles: 6°, 15°, 23°, 30°• High Luminous Output• Colors:590 nm Amber605 nm Orange615 nm Reddish-Orange626 nm Red• High Operating Temperature:T J LED=+130°C• Superior Resistance to Moisture• Package Options:With or Without Lead Stand-OffsBenefits• Viewing Angles Match Traffic Management Sign Requirements• Colors Meet Automotive and Pedestrian Signal Specifications• Superior Performance in Outdoor Environments• Suitable for Autoinsertion onto PC Boards Applications• Traffic Management:Traffic SignalsPedestrian SignalsWork Zone Warning LightsVariable Message Signs• Commercial OutdoorAdvertising:SignsMarquees• Automotive:Exterior and Interior LightsDescriptionThese Precision Optical Perform-ance AlInGaP LEDs providesuperior light output for excellentreadability in sunlight and areextremely reliable. AlInGaP LEDtechnology provides extremelystable light output over longperiods of time. Precision OpticalPerformance lamps utilize thealuminum indium gallium phos-phide (AlInGaP) technology.These LED lamps are untinted,nondiffused, T-13/4 packagesincorporating second generationoptics producing well definedspatial radiation patterns atspecific viewing cone angles.SunPower SeriesHLMP-ELxxHLMP-EJxxHLMP-EHxxHLMP-EGxxThese lamps are made with anadvanced optical grade epoxy,offering superior high tempera-ture and high moisture resistanceperformance in outdoor signaland sign applications. The highmaximum LED junction tempera-ture limit of +130°C enables hightemperature operation in brightsunlight conditions. The packageepoxy contains both uv-a anduv-b inhibitors to reduce theeffects of long term exposure todirect sunlight.These lamps are available in twopackage options to give thedesigner flexibility with devicemounting.Device Selection GuideTypicalViewing Color and Luminous Angle Dominant Lamps Without Standoffs Lamps With Standoffs Intensity Iv (mcd) [1,2] 2θ1/2Wavelength on Leads on Leads@ 20 mA (Deg.)[4](nm), Typ.[3] (Outline Drawing A)(Outline Drawing B)Min.Max.HLMP-EL08-VY000HLMP-EL10-VY000360013800HLMP-EL08-VYK00*360013800HLMP-EL08-VXK00*360010700HLMP-EL08-VX400**360010700HLMP-EL08-VX000360010700HLMP-EL08-WZ000HLMP-EL10-WZ000470018400HLMP-EL08-XZ400**620018400 Amber 590HLMP-EL08-XZ000620018400HLMP-EL08-XZK00*620018400HLMP-EL08-XY000620013800HLMP-EL08-XYK00*620013800HLMP-EL08-X1K00*620024100HLMP-EL08-X1000HLMP-EL10-X1000620024100 6°[5]HLMP-EJ08-WZ000HLMP-EJ10-WZ000470018400 Orange 605HLMP-EJ08-X1000HLMP-EJ10-X1000620024100HLMP-EJ08-Y2000HLMP-EJ10-Y2000800031000HLMP-EH08-UX000HLMP-EH10-UX000275010700HLMP-EH08-VY000HLMP-EH10-VY000360013800 Red-Orange 615HLMP-EH08-WZ000HLMP-EH10-WZ000470018400HLMP-EH08-X1000HLMP-EH10-X1000620024100HLMP-EH08-Y2000HLMP-EH10-Y2000800031000HLMP-EG08-VW00036008300HLMP-EG08-VY000HLMP-EG10-VY000360013800HLMP-EG08-WZ000HLMP-EG10-WZ000470018400 Red 626HLMP-EG08-X1000HLMP-EG10-X1000620024100HLMP-EG08-YZ000800018400HLMP-EG08-Y1000800024100HLMP-EG08-Y2000HLMP-EG10-Y2000800031000 Notes:1. The luminous intensity is measured on the mechanical axis of the lamp package.2.The optical axis is closely aligned with the package mechanical axis.3. The dominant wavelength, λd, is derived from the CIE Chromaticity Diagram and represents the color of the lamp.4. θ1/2 is the off-axis angle where the luminous intensity is one half the on-axis intensity.5.The intensity of narrow viewing angle lamps is measured at the intensity peak.Part numbers in bold are recommended for new designs.*HLMP-xLxx-xxK00 are selected to amber color bins 2 and 4 only.Device Selection Guide (Continued)TypicalViewing Color and Luminous Angle Dominant Lamps Without Standoffs Lamps With Standoffs Intensity Iv (mcd) [1,2] 2θ1/2Wavelength on Leads on Leads@ 20 mA (Deg.)[4](nm), Typ.[3] (Outline Drawing A)(Outline Drawing B)Min.Max.HLMP-EL15-PS000HLMP-EL17-PS0007652900HLMP-EL15-QR00010002200HLMP-EL15-QRK00*10002200HLMP-EL15-QS00010002900 Amber 590HLMP-EL15-QS400**10002900HLMP-EL15-QSK00*10002900HLMP-EL15-QT000HLMP-EL17-QT00010003700 15°HLMP-EL15-QTK00*10003700HLMP-EL15-RU000HLMP-EL17-RU00013004800HLMP-EJ15-PS0007652900 Orange 605HLMP-EJ15-RU000HLMP-EJ17-RU00013004800HLMP-EJ15-SV000HLMP-EJ17-SV00016506300 Red-Orange 615HLMP-EH15-QT000HLMP-EH17-QT00010003700HLMP-EH15-RU000HLMP-EH17-RU00013004800HLMP-EG15-PS0007652900 Red 626HLMP-EG15-QT000HLMP-EG17-QT00010003700HLMP-EG15-RU000HLMP-EG17-RU00013004800HLMP-EL24-MQ0004501730HLMP-EL24-NR000HLMP-EL26-NR0005902200HLMP-EL24-PS000HLMP-EL26-PS0007652900HLMP-EL24-PSK00*7652900HLMP-EL24-PR400**7652200HLMP-EL24-PQK00*7651730 Amber 590HLMP-EL24-QR00010002200HLMP-EL24-QRK00*10002200 23°HLMP-EL24-QS00010002900HLMP-EL24-QSK00*10002900HLMP-EL24-QS400**10002900HLMP-EL24-QT000HLMP-EL26-QT00010003700HLMP-EL24-QTK00*10003700 Notes:1. The luminous intensity is measured on the mechanical axis of the lamp package.2.The optical axis is closely aligned with the package mechanical axis.3. The dominant wavelength, λd, is derived from the CIE Chromaticity Diagram and represents the color of the lamp.4. θ1/2 is the off-axis angle where the luminous intensity is one half the on-axis intensity.5.The intensity of narrow viewing angle lamps is measured at the intensity peak.Device Selection Guide (Continued)TypicalViewing Color and Luminous Angle Dominant Lamps Without Standoffs Lamps With Standoffs Intensity Iv (mcd) [1,2] 2θ1/2Wavelength on Leads on Leads@ 20 mA (Deg.)[4](nm), Typ.[3] (Outline Drawing A)(Outline Drawing B)Min.Max.Orange 605HLMP-EJ24-QT000HLMP-EJ26-QT00010003700HLMP-EJ24-RU000HLMP-EJ26-RU00013004800HLMP-EH26-PS0007652900 Red-Orange 615HLMP-EH24-QT000HLMP-EH26-QT00010003700 23ºHLMP-EH24-RU000HLMP-EH26-RU00013004800HLMP-EG24-PS000HLMP-EG26-PS0007652900 Red 626HLMP-EG24-QT000HLMP-EG26-QT00010003700HLMP-EG24-RU000HLMP-EG26-RU00013004800HLMP-EL30-MQ000HLMP-EL32-MQ0004501730HLMP-EL30-NR000HLMP-EL32-NR0005902200HLMP-EL30-PQ0007651730HLMP-EL30-PQK00*7651730 Amber 590HLMP-EL30-PR0007652200HLMP-EL30-PR400**7652200HLMP-EL30-PRK00*7652200HLMP-EL30-PS000HLMP-EL32-PS0007652900HLMP-EL30-PSK00*7652900 30°HLMP-EJ30-MQ0004501730 Orange 605HLMP-EJ30-NR000HLMP-EJ32-NR0005902200HLMP-EJ30-PS000HLMP-EJ32-PS0007652900HLMP-EH30-MQ000HLMP-EH32-MQ0004501730 Red-Orange 615HLMP-EH30-NR000HLMP-EH32-NR0005902200HLMP-EH30-PS000HLMP-EH32-PS0007652900HLMP-EG30-KN0002701010HLMP-EG30-MQ000HLMP-EG32-MQ0004501730HLMP-EG30-NQ0005901730HLMP-EG30-NR000HLMP-EG32-NR0005902200 Red 626HLMP-EG30-PQ0007651730HLMP-EG30-PR0007652200HLMP-EG30-PS000HLMP-EG32-PS0007652900 Notes:1. The luminous intensity is measured on the mechanical axis of the lamp package.2.The optical axis is closely aligned with the package mechanical axis.3. The dominant wavelength, λd, is derived from the CIE Chromaticity Diagram and represents the color of the lamp.4. θ1/2 is the off-axis angle where the luminous intensity is one half the on-axis intensity.5.The intensity of narrow viewing angle lamps is measured at the intensity peak.Part Numbering SystemHLMP-x x xx-x x x xxMechanical Options00: Bulk PackagingDD: Ammo PackYY: Flexi-Bin; Bulk PackagingZZ: Flexi-Bin; Ammo PackColor Bin Selections0: No color bin limitation4: Amber color bin 4 onlyK: Amber color bins 2 and 4 onlyMaximum Intensity Bin0: No Iv bin limitationMinimum Intensity BinViewing Angle & Lead Stand Offs08: 6 deg without lead stand offs10: 6 deg with lead stand offs15: 15 deg without lead stand offs17: 15 deg with lead stand offs24: 23 deg without lead stand offs26: 23 deg with lead stand offs30: 30 deg without lead stand offs32: 30 deg with lead stand offsColorG: 626 nm RedH: 615 nm Red-OrangeJ: 605 nm OrangeL: 590 nm AmberPackageE: 5 mm RoundNOTES:1. ALL DIMENSIONS ARE IN MILLIMETERS (INCHES).2. LEADS ARE MILD STEEL, SOLDER DIPPED.3. TAPERS SHOWN AT TOP OF LEADS (BOTTOM OF LAMP PACKAGE) INDICATE AN EPOXY MENISCUS THAT MAY EXTEND ABOUT 1 mm (0.040 in.) DOWN THE LEADS.4. RECOMMENDED PC BOARD HOLE DIAMETERS:• LAMP PACKAGE A WITHOUT STAND-OFFS: FLUSH MOUNTING AT BASE OF LAMP PACKAGE = 1.143/1.067 (0.044/0.042).• LAMP PACKAGE B WITH STAND-OFFS: MOUNTING AT LEAD STAND-OFFS = 0.965/0.889 (0.038/0.035).5. FOR DOME HEIGHTS ABOVE LEAD STAND-OFF SEATING PLANE, d, LAMP PACKAGE B, SEE TABLE.BPackage DimensionsA(0.039)(0.039)PART NO.d HLMP-XX1012.37 ± 0.25 (0.487 ± 0.010)HLMP-XX1712.42 ± 0.25 (0.489 ± 0.010)HLMP-XX2612.52 ± 0.25 (0.493 ± 0.010)HLMP-XX3211.96 ± 0.25 (0.471 ± 0.010)Electrical/Optical Characteristics at T A = 25°CParameter SymbolMin.Typ.Max.UnitsTest Conditions Forward VoltageI F = 20 mAAmber (λd = 590 nm) 2.02Orange (λd = 605 nm)V F 1.98 2.4VRed-Orange (λd = 615 nm) 1.94Red (λd = 626 nm) 1.90Reverse Voltage V R 520VI F = 100 µAPeak Wavelength:Peak of Wavelength of Amber (λd = 590 nm)592Spectral Distribution Orange (λd = 605 nm)λPEAK 609nmat I F = 20 mARed-Orange (λd = 615 nm)621Red (λd = 626 nm)635Spectral Halfwidth∆λ1/217nmWavelength Width at Spectral Distribution 1/2 Power Point at I F = 20 mASpeed of Response τs 20ns Exponential Time Constant, e -t/τCapacitanceC 40pF V F = 0, f = 1 MHzThermal Resistance R θJ-PIN240°C/WLED Junction-to-Cathode LeadLuminous Efficacy [1]Emitted LuminousAmber (λd = 590 nm)480Power/Emitted Radiant Orange (λd = 605 nm)ηv370lm/WPowerRed-Orange (λd = 615 nm)260Red (λd = 626 nm)150Note:Absolute Maximum Ratings at T A = 25°CDC Forward Current [1,2,3]............................................................50 mA Peak Pulsed Forward Current [2,3]..............................................100 mA Average Forward Current [3].........................................................30 mA Reverse Voltage (I R = 100 µA).........................................................5 V LED Junction Temperature..........................................................130°C Operating Temperature ..............................................-40°C to +100°C Storage Temperature ..................................................-40°C to +120°C Dip/Drag Soldering Temperature...........................260°C for 6 seconds Through-the-Wave Preheat Temperature......................................145°C Through-the-Wave Solder Temperature.................245°C for 3 seconds [1.59 mm (0.060 in.) below seating plane]Notes:1. Derate linearly as shown in Figure 4.2. For long term performance with minimal light output degradation, drive currentsbetween 10 mA and 30 mA are recommended. For more information on recommended drive conditions, please refer to Application Brief I-024 (5966-3087E).3. Operating at currents below 1 mA is not recommended. Please contact your local representative for further information.sFigure 2. Forward Current vs.Forward Voltage.Figure 3. Relative Luminous Intensity vs. Forward Current.Figure 4. Maximum Forward Current vs. Ambient Temperature. Derating Based on T JMAX = 130°C.Figure 1. Relative Intensity vs. Peak Wavelength.I F – F O R W A R D C U R R E N T – m AT A – AMBIENT TEMPERATURE – °CR E L A T I V E I N T E N S I T Y – %1000θ – ANGULAR DISPLACEMENT – DEGREES8060507020-20-15103040-1051015202590-25-5WAVELENGTH – nmR E L A T I V E I N T E N S I T YR E L A T I V E L U M I N O U S I N T E N S I T Y (N O R M A L I Z E D A T 20 m A )00I F – DC FORWARD CURRENT – mA 403.02.01.51.00.520602.5C U R R E NT – m AV F – FORWARD VOLTAGE – VBin Name Min.Max.K 310400L 400520M 520680N680880P 8801150Q 11501500R 15001900S 19002500T 25003200U 32004200V 42005500W 55007200X 72009300Y 930012000Z 12000160001160002100022100027000Intensity Bin Limits (mcd at 20 mA)Tolerance for each bin limit is ± 15%.Bin Name Min.Max.1584.5587.02587.0589.54589.5592.06592.0594.5Amber Color Bin Limits (nm at 20 mA)Tolerance for each bin limit is ± 0.5 nm.Note:1.Bin categories are established for classification of products. Products Figure 7. Representative Spatial Radiation Pattern for 23° Viewing Angle Lamps.R E L A T I V E I N T E N S I T Y – %1000θ – ANGULAR DISPLACEMENT – DEGREES806050702010304090-20-15-10510152025-25-5R E L A T I V E I N T E N S I T Y – %1000θ – ANGULAR DISPLACEMENT – DEGREES806050702010304090-20-15-10510152025-25-5R E L A T I V E I N T E N S I T Y – %1000θ – ANGULAR DISPLACEMENT – DEGREES806050702010304090-20-15-10510152025-25-5Figure 6. Representative Spatial Radiation Pattern for 15° Viewing Angle Lamps.Data subject to change.Copyright © 2001 Agilent Technologies, Inc. August 13, 2001。

1-174HDome PackagesThe HLMP-6XXX Series dome lamps for use as indicators use a tinted, diffused lens to provide a wide viewing angle with a high on-off contrast ratio. High brightness lamps use anuntinted, nondiffused lens to provide a high luminous intensity within a narrow radiation pattern.ArraysThe HLMP-66XX Seriessubminiature lamp arrays are available in lengths of 3 to 8elements per array. Theluminous intensity is matched within an array to assure a 2.1to 1.0 ratio.Resistor LampsThe HLMP-6XXX Series 5 volt subminiature lamps with built in current limiting resistors are for use in applications where space is at a premium.Lead ConfigurationsAll of these devices are made by encapsulating LED chips onaxial lead frames to form molded epoxy subminiature lamppackages. A variety of package configuration options is avail-able. These include specialFeatures• Subminiature Flat Top PackageIdeal for Backlighting and Light Piping Applications • Subminiature Dome PackageDiffused Dome for Wide Viewing AngleNondiffused Dome for High Brightness • Arrays• TTL and LSTTLCompatible 5 Volt Resistor Lamps• Available in Six Colors • Ideal for Space Limited Applications • Axial Leads• Available with LeadConfigurations for Surface Mount and Through Hole PC Board MountingDescriptionFlat Top PackageThe HLMP-PXXX Series flat top lamps use an untinted, non-diffused, truncated lens toprovide a wide radiation pattern that is necessary for use in backlighting applications. The flat top lamps are also ideal for use as emitters in light pipe applications.Subminiature LED Lamps Technical Datasurface mount lead configura-tions, gull wing, yoke lead or Z-bend. Right angle lead bends at 2.54 mm (0.100 inch) and 5.08mm (0.200 inch) center spacing are available for through hole mounting. For more information refer to Standard SMT and Through Hole Lead Bend Options for Subminiature LED Lamps data sheet.HLMP-PXXX Series HLMP-QXXX Series HLMP-6XXX SeriesHLMP-70XX Series5964-9350E1-175Device Selection Guide Part Number: HLMP-XXXXPackage Dimensions(A) Flat Top LampsNOTES:1. ALL DIMENSIONS ARE IN MILLIMETERS (INCHES).2. PROTRUDING SUPPORT TAB IS CONNECTED TO CATHODE LEAD.*Refer to Figure 1 for design concerns.1-176Package Dimensions (cont.)(B) Diffused and NondiffusedFigure 1. Proper Right Angle Mounting to a PC Board to Prevent Protruding Cathode Tab from Shorting to AnodeConnection.NOTES:1. ALL DIMENSIONS ARE IN MILLIMETERS (INCHES).2. PROTRUDING SUPPORT TAB IS CONNECTED TO CATHODE LEAD.*Refer to Figure 1 for design concerns.(C) ArraysNOTES:1. ALL DIMENSIONS ARE IN MILLIMETERS (INCHES).2. PROTRUDING SUPPORT TAB IS CONNECTED TO CATHODE LEAD.1-177DH AS High HighStandard AlGaAs Eff.Perf.EmeraldParameterRedRed Red Orange Yellow Green Green Units DC Forward Current [1]50303030203030mA Peak Forward Current [2]10003009090609090mA DC Forward Voltage 6666V (Resistor Lamps Only)Reverse Voltage (I R = 100 µA)5555555V Transient Forward Current [3]2000500500500500500500mA(10 µs Pulse)Operating Temperature Range:-55 to -40 to -55 to +100-40 to -20 to Non-Resistor Lamps +100+100+100+100°CResistor Lamps-40 to +85-20 to +85Storage Temperature Range °CFor Thru Hole Devices260°C for 5 SecondsWave Soldering Temperature [1.6 mm (0.063 in.) from body]For Surface Mount Devices:Convective IR 235°C for 90 Seconds Vapor Phase215°C for 3 MinutesAbsolute Maximum Ratings at T A = 25°C-55 to +100Notes:1. See Figure 5 for current derating vs. ambient temperature. Derating is not applicable to resistor lamps.2. Refer to Figure 6 showing Max. Tolerable Peak Current vs. Pulse Duration to establish pulsed operating conditions.3. The transient peak current is the maximum non-recurring peak current the device can withstand without failure. Do not operate these lamps at this high current.Electrical/Optical Characteristics, TA= 25°CStandard RedDeviceHLMP-Parameter Symbol Min.Typ.Max.Units Test Conditions 60000.5 1.26001Luminous Intensity[1]Iv 1.3 3.2mcd IF= 10 mA6203 to0.5 1.2 6208Forward Voltage VF 1.4 1.6 2.0V IF= 10 mAAll Reverse Breakdown VR 5.012.0V IR= 100 µAVoltageP005Included Angle Between125Half Intensity Points[2]2θ1/2Deg.All90OthersPeak WavelengthλPEAK655nmDominant Wavelength[3]λd640nmSpectral Line Half Width∆λ1/224nmAll Speed of Responseτs15nsCapacitance C100pF VF= 0; f = 1 MHzThermal Resistance RθJ-PIN 170°C/W Junction-to-CathodeLeadLuminous Efficacy[4]ηv65lm/W1-1781-179Device HLMP-ParameterSymbolMin.Typ.Max.Units Test ConditionsP102 4.020.0P1058.630.0Q10122.045.0Q105Luminous IntensityI v22.055.0mcdQ150 1.0 1.8Q155 2.04.0Q101 1.8 2.2I F = 20 mA P205/P505Forward VoltageV F1.82.2V Q101/Q105Q150/Q1551.6 1.8I F = 1 mA All Reverse Breakdown V R5.015.0V I R = 100 µA VoltageP105125Q101/Q150Included Angle Between 2θ1/290Deg.Half Intensity Points [2]Q105/Q15528Peak Wavelength λPEAK 645nm Measured at PeakDominant Wavelength [3]λd 637nm Spectral Line Half Width∆λ1/220nm AllSpeed of Response τs 30ns Exponential Time Constant; e -t/τCapacitance C 30pF V F = 0; f = 1 MHz Thermal Resistance R θJ-PIN170°C/W Junction-to Cathode Lead Luminous Efficacy [4]ηv80lm/WDH AS AlGaAs Red I F = 1 mA I F = 20 mA sDeviceHLMP-Parameter Symbol Min.Typ.Max.Units Test Conditions P202 1.0 5.0P205 1.08.06300 1.010.0IF= 10 mA6305 3.424.07000Luminous Intensity[1]Iv 0.4 1.0mcd IF= 2 mA6600 1.3 5.0VF= 5.0 Volts 66200.8 2.06653 to 1.0 3.0IF = 10 mA6658All Forward Voltage VF 1.5 1.8 3.0V IF= 10 mA(Nonresistor Lamps)66009.613.0I F mA VF= 5.0 V6620 3.5 5.0All Reverse Breakdown VR 5.030.0V IR= 100 µAVoltageP2051256305Included Angle Between2θ1/228Deg.Half Intensity Points[2]All90DiffusedPeak WavelengthλPEAK635nm Measured at PeakDominant Wavelength[3]λd626nmSpectral Line Half Width∆λ1/240nmAll Speed of Responseτs90nsCapacitance C11pF VF= 0; f = 1 MHzThermal Resistance RθJ-PIN 170°C/W Junction-to-CathodeLeadLuminous Efficacy[4]ηv 145lm/WHigh Efficiency RedForward Current(Resistor Lamps)1-180DeviceHLMP-Parameter Symbol Min.Typ.Max.Units Test Conditions P402 1.0 4.0P405Luminous Intensity Iv 1.06mcd IF= 10 mAQ400 1.08Forward Voltage VF 1.5 1.9 3.0V IF= 10 mAAll Reverse Breakdown VR 5.030.0V IR= 100 µAVoltageP405Included Angle Between125Half Intensity Points[2]2θ1/2Deg.Q40090Peak WavelengthλPEAK600nmDominant Wavelength[3]λd602nm Measured at PeakSpectral Line Half Width∆λ1/240nmAll Speed of Responseτs260nsCapacitance C4pF VF= 0; f = 1 MHzThermal Resistance RθJ-PIN 170°C/W Junction-to-CathodeLeadLuminous Efficacy[4]ηv 380lm/WOrange1-181YellowDeviceHLMP-Parameter Symbol Min.Typ.Max.Units Test Conditions P302 1.0 3.0P305 1.0 4.0IF = 10 mA6400 1.09.06405Luminous Intensity[1]Iv3.620mcd70190.40.6IF= 2 mA6700 1.4 5.0VF= 5.0 Volts 67200.9 2.06753 to 1.0 3.0IF = 10 mA6758All Forward Voltage VF 2.0 2.4V IF= 10 mA(Nonresistor Lamps)67009.613.0Forward Current IF mA VF= 5.0 V6720(Resistor Lamps) 3.5 5.0All Reverse Breakdown VR 5.050.0VVoltageP3051256405Included Angle Between2θ1/228Deg.Half Intensity Points[2]All90DiffusedPeak WavelengthλPEAK583nm Measured at PeakDominant Wavelength[3]λd585nmSpectral Line Half Width∆λ1/236nmAll Speed of Responseτs90nsCapacitance C15pF VF= 0; f = 1 MHzThermal Resistance RθJ-PIN 170°C/W Junction-to-CathodeLeadLuminous Efficacy[4]ηv500lm/W1-1821-183High Performance Green Device HLMP-ParameterSymbolMin.Typ.Max.Units Test ConditionsP502 1.0 3.0P505 1.0 5.06500 1.07.0I F = 10 mA6505 4.220.07040Luminous Intensity [1]I v0.40.6mcdI F = 2 mA 6800 1.6 5.0V F = 5.0 Volts 68200.8 2.06853 to 1.03.0I F = 10 mA 6858All Forward Voltage V F2.1 2.7VI F = 10 mA(Nonresistor Lamps)68009.613.0Forward Current I F mAV F = 5.0 V 6820(Resistor Lamps) 3.5 5.0All Reverse Breakdown V R5.050.0VI R = 100 µA VoltageP5051256505Included Angle Between 2θ1/228Deg.Half Intensity Points [2]All 90DiffusedPeak Wavelength λPEAK 565nm Dominant Wavelength [3]λd 569nm Spectral Line Half Width∆λ1/228nm AllSpeed of Response τs 500ns Capacitance C 18pF V F = 0; f = 1 MHz Thermal Resistance R θJ-PIN170°C/W Junction-to-Cathode LeadLuminous Efficacy [4]ηv595lm/WNotes:1. The luminous intensity for arrays is tested to assure a2.1 to 1.0 matching between elements. The average luminous intensity for an array determines its light output category bin. Arrays are binned for luminous intensity to allow I v matching between arrays.2. θ1/2 is the off-axis angle where the luminous intensity is half the on-axis value.3. Dominant wavelength, λd , is derived from the CIE Chromaticity Diagram and represents the single wavelength that defines the color of the device.4. Radiant intensity, I e , in watts/steradian, may be calculated from the equation I e =I v /ηv , where I v is the luminous intensity in candelas and ηv is the luminous efficacy in lumens/watt.DeviceHLMP-Parameter Symbol Min.Typ.Max.Units Test ConditionsP605Luminous Intensity Iv 1.0 1.5mcd IF= 10 mAQ600 1.0 1.5Forward Voltage VF 2.2 3.0V IF= 10 mAReverse Breakdown VR 5.0V IR= 100 µAVoltageP605Included Angle Between125Half Intensity Points[2]2θ1/2Deg.Q60090Peak WavelengthλPEAK558nmDominant Wavelength[3]λd560nm Measured at PeakSpectral Line Half Width∆λ1/224nmP605/Q600Speed of Responseτs3100nsCapacitance C35pF VF= 0; f = 1 MHzThermal Resistance RθJ-PIN 170°C/W Junction-to-CathodeLeadLuminous Efficacy[4]ηv 656lm/WEmerald Green[1]Note:1. Please refer to Application Note 1061 for information comparing stnadard green and emerald green light ouptut degradation.1-1841-185Standard Red, DH As AlGaAs Red Standard Red and DH ASAlGaAs RedHigh Efficiency Red, Orange,Yellow, and High Performance GreenHER, Orange, Yellow, and High Performance Green,and Emerald GreenLow CurrentFigure 1. Relative Intensity vs. Wavelength.Figure 2. Forward Current vs. Forward Voltage. (Non-Resistor Lamp)Figure 3. Relative Luminous Intensity vs. Forward Current. (Non-Resistor Lamp)1-186Figure 4. Relative Efficiency (Luminous Intensity per Unit Current) vs. Peak Current (Non-Resistor Lamps).Figure 5. Maximum Forward dc Current vs. Ambient Temperature. Derating Based on T J MAX = 110°C (Non-Resistor Lamps).Figure 6. Maximum Tolerable Peak Current vs. Pulse Duration. (I DC MAX as per MAX Ratings) (Non-Resistor Lamps).Standard RedDH As AlGaAs RedStandard Red HER, Orange, Yellow, and HighPerformance GreenDH As AlGaAs RedHER, Orange, Yellow, and High Performance Green,and Emerald Green1-187Figure 9. Relative Intensity vs. Angular Displacement.Figure 7. Resistor Lamp Forward Current vs. Forward Voltage.Figure 8. Resistor Lamp Luminous Intensity vs.Forward Voltage.。

Agilent Subminiature High Performance TS AlGaAs Red LED Lamps Data SheetFeatures•Subminiature flat top package Ideal for backlighting and light piping applications•Subminiature dome package Diffused dome for wide viewing angleNon-diffused dome for high brightness•Wide range of drive currents500 µA to 50 mA •Ideal for space limited Applications •Axial leads•Available with lead configurations for surface mount and through hole PC board mountingDescriptionFlat Top PackageThe HLMP-Pxxx Series flat top lamps use an untinted, non-diffused, truncated lens toprovide a wide radiation pattern that is necessary for use in backlighting applications. The flat top lamps are also ideal for use as emitters in light pipe applications.Dome PackagesThe HLMP-Qxxx Series dome lamps, for use as indicators, use a tinted, diffused lens to provide a wide viewing angle with high on-off contrast ratio. High brightness lamps use anuntinted, nondiffused lens to provide a high luminous inten-sity within a narrow radiation pattern.Lead ConfigurationsAll of these devices are made by encapsulating LED chips onaxial lead frames to form molded epoxy subminiature lamppackages. A variety of package configuration options isavailable. These include special surface mount lead configura-tions, gull wing, yoke lead, or Z-bend. Right angle lead bends at 2.54 mm (0.100 inch) and 5.08mm (0.200 inch) center spacing are available for through hole mounting. For more information refer to Standard SMT and Through Hole Lead BendOptions for Subminiature LED Lamps data sheet.TechnologyThese subminiature solid state lamps utilize a highly optimized LED material technology,transparent substrate aluminum gallium arsenide (TS AlGaAs).This LED technology has a very high luminous efficiency,capable of producing high light output over a wide range of drive currents (500 µA to 50mA). The color is deep red at a dominant wavelength of 644nm deep red. TS AlGaAs is a flip-chip LED technology, dieattached to the anode lead and wire bonded to the cathode lead.Available viewing angles are 75°, 35°, and 15°.HLMP-P106/P156HLMP-Q102/Q152HLMP-Q106/Q156Device Selection GuideViewing Angle Deep Red Typical Iv Typical IvPackage Description 2 q1/2R d = 644 nm I F = 500 µa I F = 20 mA Package Outline Domed, Diffused Tinted,35HLMP-Q102100BStandard CurrentDomed, Diffused Tinted,35HLMP-Q1522BLow CurrentDomed, Nondiffused15HLMP-Q106400BUntinted, Standard CurrentDomed, Nondiffused15HLMP-Q1567BUntinted, Low CurrentFlat Top, Nondiffused,75HLMP-P106130AUntinted, Standard CurrentFlat Top, Nondiffused75HLMP-P1562AUntinted, Low CurrentOrdering InformationHLMX-XXXX-X X X X XPackagingOptionColor BinSelectionMax. Iv BinMin. Iv Bin4 x 4 Prod.PartNumberFigure 1. Proper right angle mounting to a PC board to prevent protruding anode tab from shorting to cathode c onnection.Package Dimensions A) Flat Top LampsB) Diffused and Nondiffused Dome LampsNO. CATHODE DOWN.YES. ANODE DOWN.* REFER TO FIGURE 1 FOR DESIGN CONERNS.2.082.34(0.082)(0.092)2.082.34(0.082)(0.092)0.53 (0.021)2.211.96(0.087)(0.077)NOTES:1. ALL DIMENSIONS ARE IN MILLIMETRES (INCHES).2. PROTRUDING SUPPORT TAB IS CONNECTED TO ANODE LEAD.3. LEAD POLARITY FOR THESE TS AlGaAs SUBMINIATURE LAMPS IS OPPOSITE TO THE LEAD POLARITY OF SUBMINIATURE LAMPS USING OTHER LED TECHNOLOGIES.Absolute Maximum Ratings at T A = 25°CParameters TitleDC Forward Current[1]50 mAPeak Forward Current[2]300 mAAverage Forward Current[2,3]30 mATransient Forward Current (10 µs Pulse)[4]500 mAPower Dissipation100 mWReverse Voltage 5 VJunction Temperature110°COperating Temperature-55°C to +100°CStorage Temperature-55°C to +100°CLead Soldering Temperature260°C for 5 seconds[1.6 mm (0.063 in.) from body]Reflow Soldering Temperature260°C for 20 secondsNotes:1. Derate linearly as shown in Figure 6.2. Refer to Figure 7 to establish pulsed operating conditions.3. Maximum IAVG at f = 1 kHz, DF = 10%.4. The transient peak current is the maximum non-recurring peak current the device can withstandwithout damaging the LED die and wire bonds. It is not recommended that the device beoperated at peak currents above the Absolute Maximum Peak Forward Current.Optical Characteristics at T A = 25°CLuminous Intensity Total Flux Peak Color, Dominant Viewing Angle LuminousI V (mcd)f V (mlm)Wavelength Wavelength2q1/2Efficacy Part Number@ 20 mA[1]@ 20 mA[2]l peak (nm)l d[3] (nm)Degrees[4]h v[5] HLMP-Min.Typ.Typ.Typ.Typ.Typ.(lm/w) Q106-R00xx1004002806546441585Q102-N00xx25100-6546443585P106-Q00xx631302806546447585Optical Characteristics at T A = 25°CLuminous Intensity Total Flux Peak Color, Dominant Viewing Angle Luminous Part Number I V (mcd)f V (mlm)Wavelength Wavelength2f1/2Efficacy (Low Current)@ 0.5 mA[1]@ 0.5 mA[2]l peak (nm)l d[3] (nm)Degrees[4]h v[5] HLMP-Min.Typ.Typ.Typ.Typ.Typ.(lm/w) Q156-H00xx 2.5710.56546441585Q152-G00xx 1.62-6546443585P156-EG0xx0.63210.56546447585 Notes:1. The luminous intensity, Iv, is measured at the mechanical axis of the lamp package. The actual peak of the spatial radiation pattern may not bealigned with this axis.2. f v is the total luminous flux output as measured with an integrating sphere.3. The dominant wavelength, l d, is derived from the CIE Chromaticity Diagram and represents the color of the device.4. q1/2 is the off-axis angle where the liminous intensity is 1/2 the peak intensity.5. Radiant intensity, I v, in watts/steradian, may be calculated from the equation I v = I v/h v, where I v is the luminous intensity in candelas and h v is theluminous efficacy in lumens/watt.Electrical Characteristics at T A = 25°CCapacitanceSpeed of Response Forward Voltage Reverse Breakdown C (pF)t s (ns)Part V F (Volts)V R (Volts)V F = 0,Thermal Time Constant Number @ I F = 20 mA @ I R = 100 µA f = 1 MHz Resistance e -t/t s HL MP-Typ. M ax.Min. Typ.Typ.R q J-PIN (°C/W)Typ.Q106 1.9 2.45202017045Q102 1.9 2.45202017045P1061.92.45202017045Electrical Characteristics at T A = 25°C Part CapacitanceSpeed of Response Number Forward Voltage Reverse Breakdown C (pF)t s (ns)(Low V F (Volts)V R (Volts)V F = 0,Thermal Time Constant Current)@ I F = 0.5 mA @ I R = 100 µA f = 1 MHz Resistance e -t/t s HL M P-Typ. M ax.M in. Typ.Typ.R q J-PIN (°C/W)Typ.Q156 1.6 1.95202017045Q152 1.6 1.95202017045P1561.61.95202017045Figure 5. Relative efficiency vs. peak forward current.Figure 7. Maximum average current vs. peak forward current.Figure 6. Maximum forward DC current vs.ambient temperature. Derating based on T J MAX = 110°C.ηV – R E L A T I V E E F F I C I E N C Y (N O R M A L I Z E D A T 20 m A )53000.0I PEAK – PEAK FORWARD CURRENT – mA 102050100212000.10.20.30.40.50.60.70.80.91.01.11.2Figure2. Relative intensity vs. wavelength.Figure 4. Relative luminous intensity vs. DC forward current.Figure 3. Forward current vs. forward voltage.R E L A T I V E I N T E N S I T Y 600100010-3WAVELENGTH – nm70050010-210-11.0R E L A T I V E L U M I N O U S I N T E N S I T Y (N O R M A L I Z E D A T 20 m A )20.50.01I F – DC FORWARD CURRENT – mA51020502.42.01.00.20.10.0510.5I F – F O R W A R D C U R R E N T – m A1.03.5300201V F – FORWARD VOLTAGE – V1.52.02.53.02001005010520.5I A V G = A V E R A G E F O R W A R D C U R R E N T – m AI PEAK – PEAK FORWARD CURRENT – mAI F – F O R W A R D C U R R E N T – m AT A – AMBIENT TEMPERATURE – °CN O R M A L I Z E D I N T E N S I T Y1.00ANGULAR DISPLACEMENT – DEGREES0.80.60.50.70.2100°90°0.10.30.480°70°60°50°40°20°10°0°30°10°20°30°40°50°60°70°80°90°100°0.9Figure 8. HLMP-Q106/-Q156.N O R M A L I Z E D I N T E N S I T Y1.00ANGULAR DISPLACEMENT – DEGREES0.80.60.50.70.2100°90°0.10.30.480°70°60°50°40°20°10°0°30°10°20°30°40°50°60°70°80°90°100°0.9Figure 9. HLMP-Q102/-Q152N O R M A L I Z E D I N T E N S I T Y1.00ANGULAR DISPLACEMENT – DEGREES0.80.60.50.70.2100°90°0.10.30.480°70°60°50°40°20°10°0°30°10°20°30°40°50°60°70°80°90°100°0.9Figure 10. HLMP-P106/-P156.Intensity Bin LimitsBin Min.Max.E0.63 1.25F 1.00 2.00G 1.60 3.20H 2.50 5.00J 4.008.00K 6.3012.50L10.0020.00M16.0032.00N25.0050.00P40.0080.00Q63.00125.00R100.00200.00S160.00320.00T250.00500.00U400.00800.00V630.001250.00W1000.002000.00X1600.003200.00Y2500.005000.00Color Bin LimitsPackage Bin Min.Max.Red0Full DistributionMechanical Option00Straight Leads, Bulk Packaging, Quantity of 500 Parts11Gull Wing Leads, 12 mm Tape on 7 in. Dia. Reel, 1500 Parts per Reel 12Gull Wing Lead, Bulk Packaging, Quantity of 500 Parts14Gull Wing Leads, 12 mm Tape on 13 in. Dia. Reel, 6000 Parts per Reel 21Yoke Leads, 12 mm Tape on 7 in. Dia. Reel, 1500 Parts per Reel22Yoke Leads, Bulk Packaging, Quantity of 500 Parts24Yoke Leads, 12 mm Tape on 13 in. Dia. Reel, 6000 Parts per Reel31Z-Bend Leads, 12 mm Tape on 7 in. Dia. Reel, 1500 Parts per Reel32Z-Bend Leads, Bulk Packaging, Quantity of 500 Parts34Z-Bend Leads, 12 mm Tape on 13 in. Dia. Reel, 6000 Parts per Reel Note:All Categories are established for classification of products. Products may not be available in all categories. Please contact your local Agilent representative for further clarification/information./semiconductors For product information and a complete list of distributors, please go to our web site.For technical assistance call:Americas/Canada: +1 (800) 235-0312 or (916) 788-6763Europe: +49 (0) 6441 92460China: 10800 650 0017Hong Kong: (+65) 6756 2394India, Australia, New Zealand: (+65) 6755 1939 Japan: (+81 3) 3335-8152(Domestic/Interna-tional), or 0120-61-1280(Domestic Only) Korea: (+65) 6755 1989Singapore, Malaysia, Vietnam, Thailand, Philippines, Indonesia: (+65) 6755 2044 Taiwan: (+65) 6755 1843Data subject to change.Copyright © 2005 Agilent Technologies, Inc. Obsoletes 5930-2437EJanuary 18, 20055989-1711EN。

里氏硬度计说明书篇一：TH110A里氏硬度计使用说明书TH110A里氏硬度计使用说明书1 概述 ................................................ ................................................... . (3)1.1 产品特点 ................................................ ................................................... .. 31.2 主要用途及适用范围 ................................................ (3)1.2.1主要用途................................................. (3)1.2.2适用范围................................................. ...................................................31.3 品种规格 ................................................ ................................................... .. 41.4 工作条件 ................................................ ................................................... .. 41.5 注意事项 ................................................ ................................................... .. 42 结构特征与工作原理................................................. (5)2.1结构特征 ................................................ ................................................... (5)2.1.1硬度计 ................................................ (5)2.1.2 主机 ................................................ ................................................... . (5)2.1.3 D型冲击装置 ................................................ (6)2.1.4 异型冲击装置 ................................................ .. (6)2.2工作原理 ................................................ ................................................... (6)3 技术特性 ................................................ ................................................... (7)4 仪器使用 ................................................ (8)4.1 使用前的准备和检查 ................................................ (8)4.1.1被测试样的要求 ................................................ .. (8)4.1.2仪器系统设置................................................. .. (8)4.1.3测量条件设置................................................. .. (8)4.2 测量方法 ................................................ ................................................... .. 94.2.1启动................................................. ................................................... . (9)4.2.2加载................................................. ................................................... . (9)4.2.3 定位 ................................................ ................................................... . (9)4.2.4测量................................................. ................................................... . (9)4.2.5读取测量值 ................................................ . (10)4.2.6关机................................................. ................................................... .. (10)5特别提示 ................................................ ................................................... (10)6仪器操作详解 ................................................ ................................................... .. (11)6.1开机 ................................................ ................................................... (11)6.2关机 ................................................ ................................................... (11)6.3测量 ................................................ ................................................... (11)6.3.1主显示界面说明 ................................................ . (11)6.3.2测量操作................................................. (12)6.3.3按键操作................................................. . (12)6.4 菜单结构图 ................................................ (13)6.5 测量条件设置 ................................................ .. (13)6.5.1冲击方向设置................................................. (14)6.5.2平均次数设置................................................. (14)6.5.3材料设置................................................. . (14)6.5.4硬度制设置 ................................................ . (15)6.5.5公差限设置 ................................................ . (15)6.5.6硬度/强度设置 ................................................ (15)6.6 打印功能 ................................................ ...................................................166.6.1 打印当前数值 ................................................ (16)6.6.2 打印存储数值 ................................................ (16)6.6.3 打印全部存储值 ................................................ .. (17)6.6.4 走纸（手动进纸） .............................................. . (17)6.7. 存储管理................................................. ..................................................176.7.1从第一组浏览/从最末组浏览 ................................................ (17)6.7.2从所选组浏览................................................. (17)6.7.3传输数据................................................. . (17)6.7.4删除所选组 ................................................ . (18)6.7.5全部删除................................................. . (18)6.7.6确认删除................................................. . (18)6.8数据浏览 ................................................ ....................................................186.9 系统设置 ................................................ ...................................................196.9.1液晶亮度设置................................................. (20)6.9.2时间日期设置................................................. (20)6.10 软件信息................................................. . (20)6.11 软件校准 ................................................ ..................................................216.12 背光................................................. ................................................... .. (21)6.13 自动关机................................................. . (21)6.14 打印纸卷安装................................................. (22)6.15 电池充电................................................. . (22)6.16 电池更换................................................. . (22)6.17数据传输电缆连接................................................. (23)7 故障分析与排除................................................. ..................................................238保养和维修 ................................................ ................................................... . (23)8.1冲击装置维护 ................................................ (23)8.2仪器维修程序 ................................................ (23)9仪器检定 ...................................... ................................................... (23)10 贮存条件、运输及注意事项 ................................................ . (23)附录................................................. ................................................... .. (24)附表1 .................................................................................................... . (24)附表2 ................................................. ................................................... . (25)附表3 ................................................. ................................................... . (26)附表4 ................................................. ................................................... . (27)用户须知 ................................................ ................................................... .. (28)1 概述1.1 产品特点? 依据里氏测量原理，可以对多种金属材料进行检测。

HLMP-KW50T-1 Precision Optical Performance White LEDData SheetPackage DimensionsNotes :1. All dimensions are in milimetres /inches.2. Epoxy meniscus may extend about 1mm (0.040”) down the leads.CAUTION : These devices are Class 1C ESD sensitive. Please observe appropriate precautions during handling and processing. Refer to Avago Technologies Application Note AN-1142 for additional details.NOM.DescriptionThis high intensity white LED lamp is based on InGaN material technology. A blue LED die is coated by a phosphor to produce white. The typical resulting color is described by the coordinates x = 0.27, y = 0.25 using the 1931 CIE Chromaticity Diagram.This T-1 lamp is untinted, nondiffused, and incorpo-rate precise optics which produce well defined spatial radiation patterns at specific viewing cone angle.Features• Highly Luminous White Emission • Viewing Angle : 45°Applications• Indoor Electronic Signs and Signals • Small Area Illumination • Legend Backlighting • General Purpose IndicatorsBenefit• Reduced Power Consumption, Higher Reliability, and Increased Optical/Mechanical Design Flexibility Compared to Incandescent Bulbs and Other Alternative White Light SourcesDevice Selection GuidePart Number Typical Viewing Angle Min Iv (mcd) @ 20mA Max Iv (mcd) @ 20mA Typical Chromaticity Coordinates (x,y)HLMP-KW50-QS00045°115025000.27, 0.25 Notes:1. The chromaticity coordinates are derived from the CIE 1931 Chromaticity Diagram and represent the perceived color of the device.2. θ1/2 is the off-axis angle where the luminous intensity is ½ the peak intensity.3. Tolerance for intensity bin limit is +/- 15%Absolute Maximum Ratings (T A = 25°C)Parameter Value UnitsDC Forward Current [1]30mAPeak Forward Current [2]100mAPower Dissipation111mWReverse Voltage (I R = 10μA)5VLED Junction Temperature110°COperating Temperature Range-40 to +85°CStorage Temperature Range-40 to +100°CNotes:1. Derate linearly as shown in Figure 5.2. Duty factor 10%, Frequency = 1KHz.Electrical Characteristics (T A = 25°C)Forward Voltage, V F (V) @ I F = 20 mA Reverse Breakdown,VR (V) @ I R = 10μACapacitance,C (pF), V F = 0,f = 1 MHzThermal ResistanceRθJ-PIN (°C/W)Typ.Max.Min.Typ.Typ.3.2 3.7570290WAVELENGTH –nmR E L A T I V E L U M I N O U S I N T E N S I T Y3807801.00.606805804800.40.80.201.50.3R E L A T I V E L U M I N O U S I N T EN S I T YFORWARD CURRENT -mA1.20.90.6-0.0100.02500.005-0.005Y -C O O R D I N A T E SX-COORDINATES(X,Y)VALUES @20mA REFERENCE TO (0,0)0.0150.0100.020F O R W A R D C U R R E N T -m A0FORWARD VOLTAGE -V2015353051025I F M A X .-M A X I M U M F O R W A R D C U R R E N T -m AT A -AMBIENT TEMPERATURE -C4080353010206010015255200302010Figure 1. Relative Intensity vs Wavelength Figure 2. Forward Current vs Forward VoltageFigure 3. Relative Iv vs. Forward Current Figure 4. Chromaticity shift vs. currentFigure 5. Maximum Fwd. Current vs TemperatureFigure 6. Spatial Radiation Pattern00.20.40.60.81.0SPATIAL DISPLACEMENT -DEG.R E L A T I V E I N T E N S I T YIntensity Bin Limits (mcd at 20 mA) Bin Min.Max.Q11501500R15001900S1******* Tolerance for each bin limit is ± 15%.Color Bin Limit TablesRank Limits(Chromaticity Coordinates)1xy0.3300.3600.3300.3180.3560.3510.3610.3852xy0.2870. 2950.2960.2760.3300.3180.3300.3393xy0.2640.2670.2800.2480.2960.2760.2830.3054 xy0.2830.3050.2870.2950.3300.3390.3300.360Tolerance for each color bin limit is ± 0.01Color Bin Limits with Respect to CIE 1931 Chromaticity Diagram0.260.30.340.38X-COORDINATEY-COORDINATENote:1. Bin categories are established for classification of products. Products may not be available in allbin categories. Please contact your Avago representative for information on currently availableRelative Light Output vs. Junction Temperature0.1110T J-JUNCTION TEMPERATURE-°CRELATIVELIGHTOUTPUT(NORMALIZEDATTJ=25ºC)InGaN DevicePrecautions:Lead Forming:• The leads of an LED lamp may be preformed or cut to length prior to insertion and soldering on PC board.• For better control, it is recommended to use proper tool to precisely form and cut the leads to applicable length rather than doing it manually.• If manual lead cutting is necessary, cut the leads after the soldering process. The solder connection forms a mechanical ground which prevents mechanical stress due to lead cutting from traveling into LED package. This is highly recommended for hand solder operation, as the excess lead length also acts as small heat sink.Soldering and Handling:• Care must be taken during PCB assembly and soldering process to prevent damage to the LED component. • LED component may be effectively hand soldered to PCB. However, it is only recommended under unavoidable circumstances such as rework. The closest manual soldering distance of the soldering heat source (soldering iron’s tip) to the body is 1.59mm. Soldering the LED using soldering iron tip closer than1.59mm might damage the LED.• ESD precaution must be properly applied on the soldering station and personnel to prevent ESD damage to the LED component that is ESD sensitive. Do refer to Avago application note AN 1142 for details. The soldering iron used should have grounded tip to ensure electrostatic charge is properly grounded.• Recommended soldering condition:WaveSoldering [1, 2]Manual Solder DippingPre-heat temperature 105 °C Max.-Preheat time 60 sec Max -Peak temperature 250 °C Max.260 °C Max.Dwell time3 sec Max.5 sec MaxNote:1) Above conditions refers to measurement with thermocouple mounted at the bottom of PCB.2) It is recommended to use only bottom preheaters in order to reduce thermal stress experienced by LED.• Wave soldering parameters must be set and maintained according to the recommended temperature and dwell time. Customer is advised to perform daily check on the soldering profile to ensure that it is always conforming to recommended soldering conditions.Note: Electrical connection between bottom surface of LED die and the lead frame is achieved through conductive paste.• Any alignment fixture that is being applied during wave soldering should be loosely fitted and should not apply weight or force on LED. Non metal material is recommended as it will absorb less heat during wave soldering process.• At elevated temperature, LED is more susceptible to mechanical stress. Therefore, PCB must allowed to cool down to room temperature prior to handling, which includes removal of alignment fixture or pallet.• If PCB board contains both through hole (TH) LED and other surface mount components, it is recommended that surface mount components be soldered on the top side of the PCB. If surface mount need to be on the bottom side, these components should be soldered using reflow soldering prior to insertion the TH LED.• Recommended PC board plated through holes (PTH) size for LED component leads.LED component lead sizeDiagonalPlated through hole diameter0.45 x 0.45 mm (0.018x 0.018 inch)0.636 mm (0.025 inch)0.98 to 1.08 mm (0.039 to 0.043 inch)0.50 x 0.50 mm (0.020x 0.020 inch)0.707 mm (0.028 inch)1.05 to 1.15 mm (0.041 to 0.045 inch)• Over-sizing the PTH can lead to twisted LED after clinching. On the other hand under sizing the PTH can cause difficulty inserting the TH LED.Note:1. PCB with different size and design (component density) will have different heat mass (heat capacity). This might cause a change in temperature experienced by the board if same wave soldering setting is used. So, it is recommended to re-calibrate the soldering profile again before loading a new type of PCB.2. Avago Technologies’ high brightness LED are using high efficiency LED die with single wire bond as shown below. Customer is advised to take extra precaution during wave soldering to ensure that the maximum wave temperature does not exceed 250°C and the solder contact time does not exceeding 3sec. Over-stressing the LED during soldering process might cause premature failure to the LED due to delamination.Avago Technologies LED configurationExample of Wave Soldering Temperature Profile for TH LED25020015050TIME (MINUTES)Recommended solder:Sn63(Leaded solder alloy)SAC305(Lead free solder alloy)Flux:Rosin fluxSolder bath temperature:245°C±5°C (maximum peak temperature =250°C)Dwell time:1.5sec -3.0sec (maximum =3sec)Note:Allow for board to be sufficiently cooled to room temperature before exerting mechanical force.T E M P E R A T U R E (°C )Packaging Box for Ammo PacksNote: For InGaN device, the ammo pack packaging box contains ESD logo.Packaging Label(i) Avago Mother Label: (Available on packaging box of ammo pack and shipping box)Acronyms and Definition:BIN:(i) Color bin only or VF bin only(Applicable for part number with color bins but without VF bin OR part number with VF bins and no color bin)OR(ii) Color bin incorporated with VF Bin(Applicable for part number that have both color bin and VF bin)(ii) Avago Baby Label (Only available on bulk packaging)Example:(i) Color bin only or VF bin only BIN: 2 (represent color bin 2 only) BIN: VB (represent VF bin “VB” only)(ii) Color bin incorporate with VF BinVB: VF bin “VB”2: Color bin 2 onlyDISCLAIMER: AVAGO’S PRODUCTS AND SOFTWARE ARE NOT SPECIFICALLY DESIGNED, MANUFAC-TURED OR AUTHORIZED FOR SALE AS PARTS, COMPONENTS OR ASSEMBLIES FOR THE PLANNING, CON-STRUCTION, MAINTENANCE OR DIRECT OPERATION OF A NUCLEAR FACILITY OR FOR USE IN MEDICAL DEVICES OR APPLICATIONS. CUSTOMER IS SOLELY RESPONSIBLE, AND WAIVES ALL RIGHTS TO MAKE CLAIMS AGAINST AVAGO OR ITS SUPPLIERS, FOR ALL LOSS, DAMAGE, EXPENSE OR LIABILITY IN CONNEC-TION WITH SUCH USE.For product information and a complete list of distributors, please go to our web site: Avago, Avago Technologies, and the A logo are trademarks of Avago Technologies Limited in the United States and other countries.Data subject to change. Copyright © 00 - 008 Avago Technologies Limited. All rights reserved. Obsoletes 989- 1 EN AV0 -0 EN - April 8, 008。

HLMP-AD16-P0000HLMP-AL16-N0000Agilent HLMP-ABxx, HLMP-BBxx, HLMP-ADxx, HLMP-BDxx, HLMP-AGxx, HLMP-BGxx, HLMP-ALxx, HLMP-BLxx,HLMP-AMxx, HLMP-BMxx T-13/4 (5 mm)Oval Precision Optical Performance AlInGaP and InGaN Lamps Data SheetFeatures•Well defined spatial radiation pattern•Viewing angles:Major axis 70°Minor axis 35°•High luminous output•Red and Amber Intensity are available for:AlInGaP (Bright)AlInGaP II (Brightest)•Colors:472 nm blue 526 nm green 626 nm red 630 nm red 590 nm amber 592 nm amber•Superior resistance to moisture •UV resistant epoxyBenefits•Viewing angle designed for wide field of view application•Red, green, and blue radiation patterns matched for full color sign•Superior performance in outdoor environments Applications•Full color/video signsDescriptionThese Precision O ptical Performance Oval LEDs are specifically designed for full color/video and passenger information signs. The oval shaped radiation pattern(35°x 70°) and high luminous intensity ensure that these devices are excellent for wide field of view outdoor application where a wide viewing angle and readability in sunlight areessential. These lamps have very smooth, matched radiation patterns ensuring consistent color mixing in full colorapplications, message uniformity across the viewing angle of the sign.High efficiency LED material is used in these lamps: Aluminum Indium Gallium Phosphide (AlInGaP) for amber and red,and Indium Gallium Nitride(InGaN) for blue and green. Each lamp is made with an advance optical grade epoxy offering superior high temperature and high moisture resistance in outdoor applications. The package epoxy contains both UV-A and UV-B inhibitors to reduce the effects of long term exposure to direct sunlight.Designers can select parallel or perpendicular orientation. Both lamps are available in tinted version.CAUTION: The blue and green LEDs are Class 1 ESD sensitive. Please observe appropriate precautions during handling and processing. Refer to Agilent Application Note AN-1142 for additio nal details.Table 1. Device Selection Guide for AlInGaP IIColor and Luminous Luminous ForwardDominant Intensity,Intensity,Voltage,LeadsWavelength I v (mcd) at I v (mcd) at V f (V)with Leadframe Package Part Numberλd (nm) Typ.20 mA Min.20 mA Max.Max.Stand-offs Orientation Drawing HLMP-AD06-P00xx Red 630880 2.4No Parallel A HLMP-AD06-P0Txx Red 630880 2.6No Parallel A HLMP-AD16-P00xx Red 630880 2.4Yes Parallel B HLMP-AD16-P0Txx Red 630880 2.6Yes Parallel B HLMP-AD16-RS0xx Red 63015002500 2.6Yes Parallel B HLMP-AD16-RSTxx Red 63015002500 2.6Yes Parallel B HLMP-AD16-RU0xx Red 63015004200 2.4Yes Parallel B HLMP-AD16-RUTxx Red 63015004200 2.6Yes Parallel B HLMP-AD16-ST0xx Red 63019003200 2.4Yes Parallel B HLMP-AD16-STTxx Red 63019003200 2.6Yes Parallel B HLMP-AL06-L00xx Amber 592400 2.4No Parallel A HLMP-AL06-L0Rxx Amber 592400 2.6No Parallel A HLMP-AL06-N00xx Amber 592680 2.4No Parallel A HLMP-AL06-N0Rxx Amber 592680 2.6No Parallel A HLMP-AL16-N00xx Amber 592680 2.4Yes Parallel B HLMP-AL16-N0Rxx Amber 592680 2.6Yes Parallel B HLMP-AL16-PSRxx Amber 5928802500 2.6Yes Parallel B HLMP-AL16-QR0xx Amber 59211501900 2.4Yes Parallel B HLMP-AL16-QRRxx Amber 59211501900 2.6Yes Parallel B HLMP-BD06-P00xx Red 630880 2.4No Perpendicular C HLMP-BD06-P0Txx Red 630880 2.6No Perpendicular C HLMP-BD06-RS0xx Red 63015002500 2.4No Perpendicular C HLMP-BD06-RSTxx Red 63015002500 2.6No Perpendicular C HLMP-BD16-P00xx Red 630880 2.4Yes Perpendicular D HLMP-BD16-P0Txx Red 630880 2.6Yes Perpendicular D HLMP-BD16-RU0xx Red 63015004200 2.4Yes Perpendicular D HLMP-BD16-RUTxx Red 63015004200 2.6Yes Perpendicular D HLMP-BD16-ST0xx Red 63019003200 2.4Yes Perpendicular D HLMP-BD16-STTxx Red 63019003200 2.6Yes Perpendicular D HLMP-BL06-N00xx Amber 592680 2.4No Perpendicular C HLMP-BL06-N0Rxx Amber 592680 2.6No Perpendicular C HLMP-BL06-QRKxx Amber 59211501900 2.4No Perpendicular C HLMP-BL06-QRSxx Amber 59211501900 2.6No Perpendicular C HLMP-BL16-N00xx Amber 592680 2.4Yes Perpendicular D HLMP-BL16-N0Rxx Amber 592680 2.6Yes Perpendicular D HLMP-BL16-PS0xx Amber 5928802500 2.4Yes Perpendicular D HLMP-BL16-PSRxx Amber 5928802500 2.6Yes Perpendicular DTable 2. LED IndicatorsDevice Selection Guide for AlInGaPColor and Luminous LuminousDominant Intensity,Intensity,LeadsWavelength I v (mcd) at I v (mcd) at with Leadframe Package Part Numberλd (nm) Typ.20 mA Min.20 mA Max.Stand-offs Orientation Drawing HLMP-AG01-K00xx Red 626310No Parallel A HLMP-AG11-KN0xx Red 626310880Yes Parallel B HLMP-AL01-K00xx Amber 590310No Parallel A HLMP-AL01-LP0xx Amber 5904001150No Parallel A HLMP-AL01-NR0xx Amber 5906801900No Parallel A HLMP-AL11-KN0xx Amber 590310880Yes Parallel B HLMP-AL11-NR0xx Amber 5906801900Yes Parallel B HLMP-BG01-LM0xx Red 626400520No Perpendicular C HLMP-BG01-MN0xx Red 626520880No Perpendicular C HLMP-BG11-KN0xx Red 626310880Yes Perpendicular D HLMP-BL01-NR0xx Amber 5906801900No Perpendicular C HLMP-BL11-KN0xx Amber 590310880Yes Perpendicular D HLMP-BL11-NR0xx Amber 5906801900Yes Perpendicular DTable 3. Device Selection Guide for InGaNColor and Dominant Luminous Intensity,Leads with Leadframe Package Part Number Wavelength λd (nm) Typ. Iv (mcd) at 20 mA Min.Stand-offs Orientation Drawing HLMP-AB01-J00xx Blue 472240No Parallel A HLMP-AB01-K0Dxx Blue 472310No Parallel A HLMP-BB11-J00xx Blue 472240Yes Perpendicular D HLMP-BB11-K00xx Blue 472310Yes Perpendicular D HLMP-BM11-L00xx Green 526400Yes Perpendicular D HLMP-BM11-Q00xx Green 5261150Yes Perpendicular D HLMP-AB11-J00xx Blue 472240Yes Parallel B HLMP-AM01-Q00xx Green 5261150No Parallel A HLMP-BB01-J0Bxx Blue 472240No Perpendicular C HLMP-BM01-L00xx Green 526400No Perpendicular C Tolerance for intensity range limit is ±15%.Part Numbering SystemHLMP-X X X X - X X X XXMechanical Options00: Bulk PackagingDD: Ammo PackYY: Flexi-Bin; Bulk PackagingZZ: Flexi-Bin; Ammo PackColor Bin0: No Color Bin LimitationB: Color bin 2 and 3 onlyK: Color bins 2 and 4 onlyR: Color Bins 1, 2, 4, and 6 with V F max of 2.6 VS: Color bins 2 and 4 with VF max of 2.6 VT: Red Color with V F max of 2.6 VMaximum Intensity Bin0: No Iv Bin LimitationMinimum Intensity BinTint Option1 or 6: Matching Color TintsStandoff Option0: Without1: WithColorB: 472 nm BlueD: 630 nm RedG: 626 nm RedL: 590 or 592 nm AmberM: 526 nm GreenPackageA: 5 mm Mini Oval, ParallelB: 5 mm Mini Oval, PerpendicularPackage Dimensions5.00 ±(0.197 ±8.71 ± 0.200.50 ± 0.10SQ. TYP.5.00 ±(0.197 ±5.00 ±(0.197 ±5.00 ±(0.197 ±ABCDNOTES:1. ALL DIMENSIONS ARE IN MILLIMETERS (INCHES).2. LEADS ARE MILD STEEL, SOLDER DIPPED.3. TAPERS SHOWN AT TOP OF LEADS (BOTTOM OF LAMP PACKAGE) INDICATE AN EPOXY MENISCUS THAT MAY EXTEND ABOUT 1 mm (0.040 IN.) DOWN THE LEADS.4. RECOMMENDED PC BOARD HOLE DIAMETERS:– LAMP PACKAGES A AND C WITHOUT STAND-OFFS: FLUSH MOUNTING AT BASE OF LAMP PACKAGE = 1.143/1.067 mm (0.044/0.042 IN.).– LAMP PACKAGES B AND D WITH STAND-OFFS: MOUNTING AT LEAD STAND-OFFS.Absolute Maximum Ratings at T A = 25˚CParameter Blue and Green Red and Amber DC Forward Current[1]30 mA50 mAPeak Pulsed Forward Current[2]100 mA100 mAAverage Forward Current30 mA30 mAReverse Voltage (I R = 100 µA) 5 VReverse Voltage (I R = 10 µA) 5 VPower Dissipation120 mW120 mWLED Junction Temperature130°C130°COperating Temperature Range–40°C to +80°C–40°C to +100°C Storage Temperature Range–40°C to +100°C–40°C to +120°C Dip Soldering Temperature[3]260°C for 5 seconds260°C for 5 seconds Wave Soldering Temperature[3]250°C for 3 seconds250°C for 3 seconds Notes:1. Derate linearity from Figures 6 & 7.2. Duty factor 30% KHz.3. 1.59 mm (0.060 in) below body.Electrical/Optical Characteristics at T A = 25°CParameter Symbol Min.Typ.Max.Units Test Conditions Typical Viewing AngleMajor2θ1/270degMinor35Forward Voltage V F V I F = 20 mARed (λd = 626 nm) 2.0 2.4Red (λd = 630 nm)Option xx0xx 2.2 2.4Option xxTxx 2.3 2.6Amber (λd = 590 nm) 2.0 2.4Amber (λd = 592 nm)Option xx0xx 2.2 2.4Option xxRxx, xxSxx 2.3 2.6Blue (λd = 472 nm) 3.5 4.0Green (λd = 526 nm) 3.5 4.0Reverse VoltageAmber, Red V R520V I R = 100 µABlue, Green5–I R = 10 µAPeak Wavelength Peak of Wavelength of Amber (λd = 592 nm)λpeak594nm Spectral Distribution Red (λd = 630 nm)639at I F = 20 mABlue (λd = 472 nm)470Green (λd = 526 nm)524Spectral Halfwidth Wavelength Width Amber (λd = 592 nm)∆λ1/217nm at Spectral Distribution Red (λd = 630 nm)171/2 Power Point at Blue (λd = 472 nm)35I F = 20 mAGreen (λd = 526 nm)47Capacitance V F = 0, F = 1 MHz Amber, Red C40pFBlue, Green43Luminous Efficacy Emitted Luminous Amber (λd = 592 nm)ηv500lm/W Power/Emitted Radiant Red (λd = 630 nm)155Power at I F = 20 mA Blue (λd = 472 nm)75Green (λd = 526 nm)520Thermal Resistance RΘJ-PIN240°C/W LED Junction-to-Cathode LeadNotes:1.2θ1/2 is the off-axis angle where the luminous intensity is 1/2 the on-axis intensity.2.The radiant intensity, I e in watts per steradian, may be found from the equation I e = I v/ηv where I v is the luminous intensity in candelas and ηv isthe luminous efficacy in lumens/watt.3.The luminous intensity is measured on the mechanical axis of the lamp package.4.The optical axis is closely aligned with the package mechanical axis.5.The dominant wavelength, λd, is derived from theCIE Chromaticity Diagram and represents the color of the lamp.6.For Options -xxRxx, -xxSxx and -xxTxx, max. forward voltage (Vf) is 2.6 V. Refer to Vf bin table.Figure 1. Relative intensity vs. wavelength.Figure 2. Blue, green forward current vs.forward voltage.WAVELENGTH – nmR E L A T I V E I N T E N S I T Y1.00.500.40.30.20.10.60.70.80.9030251510I F – F O R W A R D C U R R E N T – m AV F – FORWARD VOLTAGE – V2.42.83.2 3.6520 2.6 3.0 3.4Figure 3a. Amber, red forward current vs.forward voltage.Figure 4. Blue, green relative luminous intensity vs. forward current.1.50.5I N T E N S I T Y N O R M A L I Z E D A T 20 m AI F – FORWARD CURRENT – mA01020301.051525C U R R E N T – m AV F – FORWARD VOLTAGE – V Figure 3b. Forward current vs. forward voltage for option -xxTxx red, and option -xxRxx and -xxSxx amber.D C F O R W A R D C U R RE N T – m AFORWARD VOLTAGE – VFigure 6. Blue, green maximum forward current vs. ambient temperature.Figure 7. Amber, red maximum forward current vs. ambient temperature.I F – F O R W A R D C U R R E N T – m AT A – AMBIENT TEMPERATURE – °C40804020102060301005152535I F – F O R W A R D C U R RE N T – m AT A – AMBIENT TEMPERATURE – °CFigure 5. Amber, red relative luminous intensity vs. forward current.R E L A T I V E I N T E N S I T Y (N OR M A L I Z E D A T 20 m A )FORWARD CURRENT – mAFigure 8. Spatial radiation pattern – 35 x 70 degree lamps.R E L A T I V E I N T E N S I T Y – %1000VERTICAL ANGULAR DISPLACEMENT – DEGREES8060507020501030404020-10-30-50903010-20-40R E L A T I V E I N T E N S I T Y – %1000HORIZONTAL ANGULAR DISPLACEMENT – DEGREES8060507020501030404020-10-30-50903010-20-40Intensity Bin Limits (mcd at 20 mA)Bin Name Min.Max.G 140180H 180240J 240310K 310400L 400520M 520680N 680880P 8801150Q 11501500R 15001900S 19002500T 25003200U19002500Tolerance for each bin limit is ±15%.Amber Color Bin Limits (nm at 20 mA)Bin Name Min.Max.1584.5587.02587.0589.54589.5592.06592.0594.5Tolerance for each bin limit is ± 0.5 nm.Notes:1.All bin categories are established for classifi-cation of products. Products may not beavailable in all bin categories. Please contact your Agilent representative for further information.2. Vf bin table only available for those numbers with options -xxRxx, -xxSxx, -xxTxx.Blue Color Bin Limits (nm at 20 mA)Bin Name Min.Max.1460.0464.02464.0468.03468.0472.04472.0476.05476.0480.0Tolerance for each bin limit is ± 0.5 nm.Green Color Bin Limits (nm at 20 mA)Bin Name Min.Max.1520.0524.02524.0528.03528.0532.04532.0536.05536.0540.0Tolerance for each bin limit is ±0.5 nm.Vf Bin Table [2] (V at 20mA)Bin Id Min.Max.VA 2.0 2.2VB 2.2 2.4VC 2.42.6/semiconductors For product information and a complete list of distributors, please go to our web site.For technical assistance call:Americas/Canada: +1 (800) 235-0312 or (916) 788-6763Europe: +49 (0) 6441 92460China: 10800 650 0017Hong Kong: (+65) 6756 2394India, Australia, New Zealand: (+65) 6755 1939 Japan: (+81 3) 3335-8152(Domestic/Interna-tional), or 0120-61-1280(Domestic Only) Korea: (+65) 6755 1989Singapore, Malaysia, Vietnam, Thailand, Philippines, Indonesia: (+65) 6755 2044 Taiwan: (+65) 6755 1843Data subject to change.Copyright © 2004 Agilent Technologies, Inc. Obsoletes 5988-9224ENJune 29, 20055989-1903ENHLMP-AD16-P0000HLMP-AL16-N0000。

REV 1.191 / 68HLW8110/HLW8112用户手册REV 1.19REV 1.192 / 68智能计量IC1应用领域 ⏹ 智能家电设备 ⏹ 漏电检测设备 ⏹ 计量电表⏹ 计量插座 ⏹ WIFI 插座 ⏹ 充电桩 ⏹ PDU 设备 ⏹ LED 照明 ⏹ 交通路灯REV 1.193 / 682修订历史时间 修改记录版本 2018-03-16 初始版本 REV 1.00 2018-04-10 增加图表附录 REV 1.01 2018-05-25 增加协议资料 REV 1.02 2018-09-26 修改PIN 脚说明 REV 1.05 2018-09-28 重新排版 REV 1.06 2018-12-25 增加相角计算公式 REV 1.07 2019-02-13 修改字体REV 1.08 2019-02-18 更正输入通道信号输入范围值 REV 1.09 2019-02-20 增加B 通道比较器描述 REV 1.10 2019-05-21 电气特性参数修改REV 1.12 2019-10-03 增加UART 复位条件，删除uart 4800bps 设置选项 REV 1.16 2020-03-02 修改漏电检测电路 REV 1.17 2020-08-28 修订版本REV 1.18 2020-11-20 修改原理图，1K 和33NF 变更为100R 和330NF REV 1.19REV 1.194 / 68目录1 应用领域 .........................................................................................................................................2 2 修订历史 .........................................................................................................................................3 3 特性 ................................................................................................................................................. 74 概述 ................................................................................................................................................. 85 功能框图 ......................................................................................................................................... 8 6引脚配置和功能描述 (9)6.1 HLW8110芯片管脚描述 ............................................................................................................ 9 6.2 HLW8110典型应用 .................................................................................................................. 10 6.3 HLW8112芯片管脚描述 .......................................................................................................... 10 6.4HLW8112典型应用 (12)7电气特性 (12)7.1 推荐工作条件 ......................................................................................................................... 12 7.2 模拟特性 ................................................................................................................................. 13 7.3 数字特性 ................................................................................................................................. 14 7.4 极限额定值 ............................................................................................................................. 15 7.5可靠性 (15)8功能概述 (16)8.1 复位系统 ................................................................................................................................. 16 8.2 时钟系统 ................................................................................................................................. 17 8.3 模数转换 ................................................................................................................................. 17 8.4 通道切换 ................................................................................................................................. 18 8.5 有功功率 ................................................................................................................................. 18 8.6 有效值 ..................................................................................................................................... 19 8.7 视在功率和功率因素 ............................................................................................................. 20 8.8 能量计算 ................................................................................................................................. 20 8.9 过零检测、相角、电压频率测量 ......................................................................................... 21 8.10 峰值检测 ................................................................................................................................. 23 8.11 过流、过压、有功功率过载检测 ......................................................................................... 25 8.12 电压聚降检测 ......................................................................................................................... 27 8.13 均值信号 ................................................................................................................................. 29 8.14 瞬时信号和采样波形 ............................................................................................................. 30 8.15 温度传感器 ............................................................................................................................. 30 8.16比较器 (31)9寄存器说明 (32)REV 1.195 / 689.1.1 系统控制寄存器 ............................................................................................................. 34 9.1.2 计量控制寄存器 ............................................................................................................. 35 9.1.3 计量控制寄存器2 .......................................................................................................... 36 9.1.4 脉冲频率寄存器 ............................................................................................................. 37 9.1.5 无负载有功功率（潜动与启动）阈值寄存器PstartPA 、PstartPB ......................... 38 9.1.6 有功功率和视在功率增益校正寄存器 ......................................................................... 38 9.1.7 相位校正寄存器 .............................................................................. 错误！未定义书签。

Agilent HLMP-CxxxT-13/4 (5mm) Extra Bright Precision Optical Performance InGaN LED Lamps Data SheetDescriptionThese high intensity blue and green LEDs are based on the most efficient and cost effective InGaN material technology. The 470 nm typical dominant wave–length for blue and 525 nm typical wavelength for green is well suited to color mixing in full color signs. The 505 nm typical dominant wavelength for cyan is suitable for traffic signal application.These LED lamps are untinted, non-diffused, T-13/4 packagesFeatures•Well defined spatial radiationpattern•High luminous output•Available in blue, green, and cyancolor•Viewing angle: 15°, 23°and 30°•Standoff or non-standoff leads•Superior resistance to moistureApplications•Traffic signals•Commercial outdoor advertising•Front panel backlighting•Front panel indicator incorporating second generationoptics which produce well-definedspatial radiation patterns atspecific viewing cone angles.These lamps are made with anadvanced optical grade epoxy,offering superior temperatureand moisture resistance inoutdoor signal and signapplications. The high maximumLED junction temperature limitof +110°C enables hightemperature operation in brightsunlight conditions.HLMP-CB11, HLMP-CB12, HLMP-CM11, HLMP-CM12, HLMP-CE11,HLMP-CE12, HLMP-CB26, HLMP-CB27, HLMP-CM26, HLMP-CM27,HLMP-CE26, HLMP-CE27, HLMP-CB36, HLMP-CB37, HLMP-CM36,HLMP-CM37, HLMP-CE36, HLMP-CE37CAUTION: Devices are Class I ESD sensitive. Please observe appropriate precautions during handling and processing. Refer to Application Note AN-1142 for additional details.Package DimensionsPackage APackage B5.80 ± 0.20(0.228 ±∅ CATHODEFLATMIN.SQ. TYP.NOTES:1. MEASURED JUST ABOVE FLANGE.2. ALL DIMENSIONS ARE IN MILLIMETERS (INCHES).3. EPOXY MENISCUS MAY EXTEND ABOUT 1 mm (0.040") DOWN THE LEADS.4. IF HEAT SINKING APPLICATION IS REQUIRED, THE TERMINAL FOR HEAT SINK IS ANODE.Device Selection GuideTypicalViewing Angle,Intensity (cd) at 20 mA PackagePart Number Color2q1/2 (Degree)Min.Max.Standoff Dimension Lens HLMP-CB11-TW0xx Blue15 2.57.2No A Clear HLMP-CB11-UVAxx Blue15 3.2 5.5No A Clear HLMP-CB12-TW0xx Blue15 2.57.2Yes B Clear HLMP-CM11-Y20xx Green159.327.0No A Clear HLMP-CM11-Z1Cxx Green1512.021.0No A Clear HLMP-CM12-Y20xx Green159.327.0Yes B Clear HLMP-CE11-X10xx Cyan157.221.0No A Clear HLMP-CE12-X10xx Cyan157.221.0Yes B Clear HLMP-CB26-SV0xx Blue23 1.9 5.5No A Clear HLMP-CB26-TUDxx Blue23 2.5 4.2No A Clear HLMP-CB27-SV0xx Blue23 1.9 5.5Yes B Clear HLMP-CM26-X10xx Green237.221.0No A Clear HLMP-CM26-YZCxx Green239.316.0No A Clear HLMP-CM27-X10xx Green237.221.0Yes B Clear HLMP-CE26-WZ0xx Cyan23 5.516.0No A Clear HLMP-CE27-WZ0xx Cyan23 5.516.0Yes B Clear HLMP-CB36-QT0xx Blue30 1.15 3.2No A Clear HLMP-CB36-RSAxx Blue30 1.5 2.5No A Clear HLMP-CB37-RU0xx Blue30 1.5 4.2Yes B Clear HLMP-CB37-RSDxx Blue30 1.5 2.5Yes B Clear HLMP-CM36-X10xx Green307.221.0No A Clear HLMP-CM36-XYCxx Green307.212.0No A Clear HLMP-CM37-X10xx Green307.221.0Yes B Clear HLMP-CM37-XYCxx Green307.212.0Yes B Clear HLMP-CM37-XYDxx Green307.212.0Yes B Clear HLMP-CE36-WZ0xx Cyan30 5.516.0No A Clear HLMP-CE37-WZ0xx Cyan30 5.516.0Yes B ClearNotes:1.Tolerance for luminous intensity measurement is ±15%.2.The luminous intensity is measured on the mechanical axis of the lamp package.3.The optical axis is closely aligned with the package mechanical axis.4.LED light output is bright enough to cause injuries to the eyes. Precautions must be taken to prevent looking directly at the LED without propersafety equipment.5. 2q1/2 is the off-axis angle where the luminous intensity is 1/2 the on-axis intensity.Part Numbering SystemHLMP-x x xx-x x x xxMechanical Options00: BulkDD: Ammo PackColor Bin Options0: Full Color Bin DistributionA: Color Bin 1 and 2C: Color Bin 3 and 4D: Color Bin 4 and 5Maximum Intensity Bin0: No Maximum Intensity Bin LimitationOthers: Refer to Device Selection GuideMinimum Intensity BinRefer to Device Selection GuideViewing Intensity Bin11: 15° Without Standoff12: 15°With Standoff26: 23°Without Standoff27: 23°With Standoff36: 30°Without standoff37: 30°With StandoffColorB: Blue 470 nmM: Green 525 nmE: Cyan 505 nmPackageC: T-13/4 (5 mm) Round LampAbsolute Maximum Rating at T A = 25°CParameters Value UnitDC Forward Current [1]30mAPeak Pulsed Forward Current[3]100mAAverage Forward Current30mAPower Dissipation120mWLED Junction Temperature110°COperating Temperature Range–40 to +85°CStorage Temperature Range–40 to +100°CWave Soldering Temperature[2]250 for 3 secs°CNotes:1.Derate linearly as shown in Figure2.2.1.59 mm (0.060 inch) below body.3.Duty factor 10%, frequency 1 KHz.Electrical/Optical CharacteristicsT A = 25o CBlue Green CyanParameters Symbol Min.Typ.Max.Min.Typ.Max.Min.Typ.Max.Units Test Condition Forward Voltage V F 3.5 4.0 3.6 4.0 3.5 4.0V I F = 20 mA Reverse Voltage[1]V R 5.0 5.0 5.0V I R = 10 µA Thermal Resistance R q J-PIN240240240o C/W LED Junction toAnode Lead Dominant l d460470480520525540490505510nm I F = 20 mA Wavelength[2]Peak Wavelength l PEAK464516501nm Peak of Wavelengthof Spectral Distribu-tion at I F = 20 mA Spectral Half Width Dl1/2233230nm Wavelength Widthat Spectral Distribu-tion Power Pointat I F = 20 mA Luminous Efficacy[3]h v74484319lm/W Emitted LuminousPower/EmittedRadiant Power Notes:1.The reverse voltage of the product is equivalent to the forward voltage of the protective chip at I R = 10 µA.2.The dominant wavelength, l d, is derived from the Chromaticity Diagram and represents the color of the lamp.3.The radiant intensity, Ie in watts/steradian, may be found from the equation Ie = Iv/h v, where Iv is the luminous intensity in candelas and h v is theluminous efficacy in lumens/watt.Figure 5. Relative intensity vs. DC forward current.Figure 4. Relative dominant wavelength vs. DC forward current.DC FORWARD CURRENT – mAR E L A T I V E D O M I N A N T W A V E L E N G T H (N O R M A L I Z E D A T 20 m A )1020301.0250.9901.0151.0201.0101.0051.0000.995GREENBLUER E L A T I V E I N T E N S I T Y (N O R M A L I Z E D A T 20 m A )FORWARD CURRENT – mAFigure 1. Relative intensity vs. wavelength.Figure 3. Forward current vs. forward voltage.Figure 2. Forward current vs. ambient temperature.WAVELENGTH – nmR E L A T I V E I N T E N S I T Y1.0000.800.600.400.20030103.0202.01.0F O R W A R D C U R R E N T – m AFORWARD VOLTAGE – V 4.0CYANGREENBLUEI F – F O R W A R D C U R R E N T – m AV F – FORWARD VOLTAGE – VOLTSFigure 6. Spatial radiation pattern for Cx11 and Cx12.R E L A T I V E L U M I N O U S I N T E N S I T Y10ANGULAR DISPLACEMENT – DEGREES0.5-90-600-30306090Figure 7. Spatial radiation pattern for Cx26 and Cx27.Figure 8. Spatial radiation pattern for Cx36 and Cx37.R E L A T I V E L U M I N O U S I N T E N S I T Y10ANGULAR DISPLACEMENT – DEGREES0.5-90-600-30306090R E L A T I V E L U M I N O U S I N T E N S I T Y10ANGULAR DISPLACEMENT – DEGREES0.5-90-600-30306090Intensity Bin Limit TableIntensity (mcd) at 20 mA Bin Min MaxN680880P8801150Q11501500R15001900S1*******T25003200U32004200V42005500W55007200X72009300Y930012000Z1200016000 11600021000 Tolerance for each bin limit is ±15%.Blue Color Bin TableBin Min Dom Max Dom Xmin Ymin Xmax Ymax 1460.0464.00.14400.02970.17660.09660.18180.09040.13740.0374 2464.0468.00.13740.03740.16990.10620.17660.09660.12910.0495 3468.0472.00.12910.04950.16160.12090.16990.10620.11870.0671 4472.0476.00.11870.06710.15170.14230.16160.12090.10630.0945 5476.0480.00.10630.09450.13970.17280.15170.14230.09130.1327 Tolerance for each bin limit is ±0.5 nm.Cyan Color Bin TableBin Min Dom Max Dom Xmin Ymin Xmax Ymax 1490.0495.00.04540.29450.11640.38890.13180.3060.02350.4127 2495.0500.00.03450.41270.10570.47690.11640.38890.00820.5384 3500.0505.00.00820.53840.10270.55840.10570.47690.00390.6548 4505.0510.00.00390.65480.10970.62510.10270.55840.01390.7502 7498.0503.00.01320.48820.10280.52730.10920.44170.00400.6104 8503.0508.00.00400.61040.10560.60070.10280.52730.00800.7153 Tolerance for each bin limit is ±0.5 nm.Green Color Bin TableBin Min Dom Max Dom Xmin Ymin Xmax Ymax 1520.0524.00.07430.83380.18560.65560.16500.65860.10600.8292 2524.0528.00.10600.82920.20680.64630.18560.65560.13870.8148 3528.0532.00.13870.81480.22730.63440.20680.64630.17020.7965 4532.0536.00.17020.79650.24690.62130.22730.63440.20030.7764 5536.0540.00.20030.77640.26590.60700.24690.62130.22960.7543 Tolerance for each bin limit is ±0.5 nm./semiconductors For product information and a complete list of distributors, please go to our web site.For technical assistance call:Americas/Canada: +1 (800) 235-0312 or (916) 788-6763Europe: +49 (0) 6441 92460China: 10800 650 0017Hong Kong: (+65) 6756 2394India, Australia, New Zealand: (+65) 6755 1939 Japan: (+81 3) 3335-8152(Domestic/Interna-tional), or 0120-61-1280(Domestic Only) Korea: (+65) 6755 1989Singapore, Malaysia, Vietnam, Thailand, Philippines, Indonesia: (+65) 6755 2044 Taiwan: (+65) 6755 1843Data subject to change.Copyright © 2004 Agilent Technologies, Inc. December 7, 20045989-1022EN。

HLMP资料元器件交易网T-13/4 (5 mm) Precision OpticalPerformance AlInGaP LEDLampsData SheetFeaturesWell Defined SpatialRadiation PatternsViewing Angles: 6°, 15°,23°, 30°High Luminous Output Colors:590 nm Amber605 nm Orange615 nm Reddish-Orange626 nm RedHigh OperatingTemperature:TJLED=+130°CSuperior Resistance toMoisturePackage Options:With or Without Lead Stand-OffsBenefitsViewing Angles MatchTraffic Management SignRequirementsColors Meet Automotive andPedestrian SignalSpecificationsSuperior Performance inOutdoor Environments Suitable for Autoinsertiononto PC BoardsApplicationsTraffic Management:Traffic SignalsPedestrian SignalsWork Zone Warning LightsVariable Message Signs Commercial OutdoorAdvertising:SignsMarquees Automotive:Exterior and Interior LightsDescriptionThese Precision Optical Perform-ance AlInGaP LEDs providesuperior light output for excellentreadability in sunlight andareextremely reliable. AlInGaP LEDtechnology provides extremelystable light output over longperiods of time. Precision OpticalPerformance lamps utilize thealuminum indium gallium phos-phide (AlInGaP) technology.These LED lamps are untinted,nondiffused, T-13/4 packagesincorporating second generationoptics producing well definedspatial radiation patterns atspecific viewing cone angles.SunPower SeriesHLMP-ELxxHLMP-EJxxHLMP-EHxxHLMP-EGxx These lamps are made with anadvanced optical grade epoxy,offering superior high tempera-ture and high moisture resistanceperformance in outdoor signaland sign applications. The highmaximum LED junction tempera-ture limit of +130°C enables hightemperature operation in brightsunlight conditions. The packageepoxy contains both uv-a anduv-b inhibitors to reduce theeffects of long term exposure todirect sunlight.These lamps are available in twopackage options to give thedesigner flexibility with devicemounting.Device Selection GuideTypicalViewingAngle2θ1/2(Deg.)Color andDominantWavelength(nm), Typ.LuminousIntensity Iv (mcd) [1,2]@ 20 mAMin.Max.***-********-*****3600HLMP-EL10-WZ000***-********-********-*****6200HLMP-EL10-X1000HLMP-EJ10-*****MP-EJ10-X1000HLMP-EJ10-Y2000HLMP-EH10-*****MP-EH10-*****MP-EH10-*****MP-EH10-X1000HLMP-EH10-Y2000HLMP-EG10-*****MP-EG10-*****MP-EG10-X1000***-********-********-********-********-********-********-*****8000HLMP-EG10-Y20008000********-*****0**********8400********-*****0*************-*****0********-*****08300*****4100*****1000Lamps Without Standoffson Leads(Outline Drawing A)HLMP-EL08-*****MP-EL08-VYK00*HLMP-EL08-VXK00*HLMP-EL08-VX400**HLMP-EL08-*****MP-EL08-*****MP-EL08-XZ400**Lamps With Standoffson Leads(Outline Drawing B)HLMP-EL10-VY000Amber 590HLMP-EL08-*****MP-EL08-XZK00*HLMP-EL08-*****MP-EL08-XYK00*HLMP-EL08-X1K00*HLMP-EL08-X1000 6°Orange 605HLMP-EJ08-*****MP-EJ08-X1000HLMP-EJ08-Y2000HLMP-EH08-*****MP-EH08-VY000Red-Orange 615HLMP-EH08-*****MP-EH08-X1000HLMP-EH08-Y2000HLMP-EG08-*****MP-EG08-*****MP-EG08-WZ000Red 626HLMP-EG08-X1000HLMP-EG08-*****MP-EG08-Y1000HLMP-EG08-Y2000Notes:1. The luminous intensity is measured on the mechanical axis ofthe lamp package.2. The optical axis is closely aligned with the package mechanical axis.3. The dominant wavelength, λd, is derived from the CIE Chromaticity Diagram and represents the color of the lamp.4. θ1/2 is the off-axis angle where the luminous intensity is one half the on-axis intensity.5.The intensity of narrow viewing angle lamps is measured at the intensity peak.Part numbers in bold are recommended for new designs.*HLMP-xLxx-xxK00 are selected to amber color bins 2 and 4 only.**HLMP-xLxx-xx400 are selected to amber color bin 4 only.Device Selection Guide (Continued)TypicalViewingAngle2θ1/2(Deg.)Color andDominantWavelength(nm), Typ.Lamps Without Standoffson Leads(Outline Drawing A)HLMP-EL15-*****MP-EL15-*****MP-EL15-QRK00*HLMP-EL15-QS000Amber 590HLMP-EL15-QS400**HLMP-EL15-QSK00*HLMP-EL15-QT00015°HLMP-EL15-QTK00*HLMP-EL15-*****MP-EJ15-PS000Orange 605Red-Orange 615HLMP-EJ15-*****MP-EJ15-*****MP-EH15-*****MP-EH15-*****MP-EG15-PS000Red 626HLMP-EG15-*****MP-EG15-*****MP-EL24-*****MP-EL24-*****MP-EL24-*****MP-EL24-PSK00*HLMP-EL24-PR400**HLMP-EL24-PQK00*Amber 59023°HLMP-EL24-*****MP-EL24-QRK00*HLMP-EL24-*****MP-EL24-QSK00*HLMP-EL24-QS400**HLMP-EL24-*****MP-EL24-QTK00* HLMP-EL26-*****MP-EL26-*****MP-EL26-*****MP-EG17-*****MP-EG17-*****MP-EJ17-*****MP-EJ17-*****MP-EH17-*****MP-EH17-*****MP-EL17-*****MP-EL17-QT000Lamps With Standoffson Leads(Outline Drawing B)HLMP-EL17-PS000LuminousIntensity Iv (mcd) [1,2]@ 20 mAMin.Max.***-********-********-********-******************-*************-********-********-********-********-********-********-********-********-********-********-********-********-*****4800********-*****0********-********-*****03700 Notes:1. The luminous intensity is measured on the mechanical axis of the lamp package.2. The optical axis is closely aligned with the package mechanical axis.3. The dominant wav elength, λd, is derived from the CIE Chromaticity Diagram and represents the color of the lamp.4. θ1/2 is the off-axis angle where the luminous intensity is one half the on-axis intensity.5.The intensity of narrow viewing angle lamps is measured at the intensity peak.Part numbers in bold are recommended for new designs.*HLMP-xLxx-xxK00 are selected to amber color bins 2 and 4 only.**HLMP-xLxx-xx400 are selected to amber color bin 4 only.Device Selection Guide (Continued)TypicalViewingAngle2θ1/2(Deg.)Color andDominantWavelength(nm), Typ.Orange 605Lamps Without Standoffson Leads(Outline Drawing A)HLMP-EJ24-*****MP-EJ24-RU000Red-Orange 61523Red 626HLMP-EH24-*****MP-EH24-*****MP-EG24-*****MP-EG24-*****MP-EG24-*****MP-EL30-*****MP-EL30-*****MP-EL30-*****MP-EL30-PQK00*Amber 590HLMP-EL30-*****MP-EL30-PR400**HLMP-EL30-PRK00*HLMP-EL30-*****MP-EL30-PSK00*30°Orange 605HLMP-EJ30-*****MP-EJ30-*****MP-EJ30-*****MP-EH30-MQ000Red-Orange 615HLMP-EH30-*****MP-EH30-*****MP-EG30-*****MP-EG30-*****MP-EG30-NQ000Red 626HLMP-EG30-*****MP-EG30-*****MP-EG30-*****MP-EG30-PS000HLMP-EG32-*****MP-EG32-*****MP-EG32-*****MP-EJ32-*****MP-EJ32-*****MP-EH32-*****MP-EH32-*****MP-EH32-*****MP-EL32-PS000Lamps With Standoffson Leads(Outline Drawing B)HLMP-EJ26-*****MP-EJ26-*****MP-EH26-*****MP-EH26-*****MP-EH26-*****MP-EG26-*****MP-EG26-*****MP-EG26-*****MP-EL32-*****MP-EL32-NR000LuminousIntensity Iv (mcd) [1,2]@ 20 mAMin.Max.1000******************-********-********-********-********-********-********-*****765***-********-********-********-**********0********-*****02900*****0*****01010*****0*****0Notes:1. The luminous intensity is measured on the mechanical axis of the lamp package.2. The optical axis is closely aligned with the package mechanical axis.3. The dominant wavelength, λd, is derived from the CIE Chromaticity Diagram and represents the color of the lamp.4. θ1/2 is the off-axis angle where the luminous intensity is one half the on-axis intensity.5.The intensity of narrow viewing angle lamps is measured at the intensity peak.Part numbers in bold are recommended for new designs.*HLMP-xLxx-xxK00 are selected to amber color bins 2 and 4 only.**HLMP-xLxx-xx400 are selected to amber color bin 4 only.Part Numbering SystemHLMP--xxMechanical Options00: Bulk PackagingDD: Ammo Pack YY: Flexi-Bin; Bulk PackagingZZ: Flexi-Bin; Ammo PackColor Bin Selections0: No color bin limitation4: Amber color bin 4 only K: Amber color bins 2 and 4 onlyMaximum Intensity Bin0: No Iv bin limitationMinimum Intensity BinViewing Angle Lead Stand Offs08: 6 deg without lead stand offs10: 6 deg with lead stand offs15: 15 deg without lead stand offs17: 15 deg with lead standoffs24: 23 deg without lead stand offs26: 23 deg with lead stand offs30: 30 deg without lead stand offs32: 30 deg with lead stand offsColorG: 626 nm RedH: 615 nm Red-OrangeJ: 605 nm OrangeL: 590 nm AmberPackageE: 5 mm RoundPackage DimensionsAB(0.039)(0.039)NOTES:1. ALL *****ONS ARE IN *****TERS (INCHES).2. LEADS ARE MILD STEEL, SOLDER DIPPED.3. TAPERS SHOWN AT TOP OF LEADS (BOTTOM OF LAMP *****) *****E AN EPOXY *****S THAT MAY EXTEND ABOUT 1 mm (0.040 in.) DOWN THE LEADS.4. *****NDED PC BOARD HOLE *****RS: LAMP ***** A ***** STAND-OFFS: FLUSH *****G AT BASE OF LAMP ***** = 1.143/1.067 (0.044/0.042).LAMP ***** B WITH STAND-OFFS: *****G AT LEAD STAND-OFFS = 0.965/0.889 (0.038/0.035).5. FOR DOME ***** ABOVE LEAD STAND-OFF ***** PLANE, d, LAMP ***** B, SEE TABLE.PART NO.HLMP-XX10HLMP-XX26HLMP-XX32d12.37 ± 0.25 (0.487 ± 0.010)(0.489 ± 0.010)12.52 ± 0.25 (0.493 ± 0.010)11.96 ± 0.25 (0.471 ± 0.010)Absolute Maximum Ratings at TA = 25°CDC Forward Current[1,2,3] (50)mAPeak Pulsed Forward Current[2,3] (100)mAAverage Forward Current (30)mAReverse Voltage (IR = 100 A).........................................................5 VLED Junction Temperature..........................................................130°COperating Temperature..............................................-40°C to +100°CStorage Temperature..................................................-40°C to +120°CDip/Drag Soldering Temperature...........................260°C for 6 secondsThrough-the-Wave Preheat Temperature......................................145°CThrough-the-Wave Solder Temperature.................245°C for 3 seconds[1.59 mm (0.060 in.) below seating plane]Notes:1. Derate linearly as shown in Figure 4.2. For long term performance with minimal light output degradation, drive currentsbetween 10 mA and 30 mA are recommended. For more information on recommendeddrive conditions, please refer to Application Brief I-024 (5966-3087E).3. Operating at currents below 1 mA is not recommended. Please contact your localrepresentative for further information.Electrical/Optical Characteristics at TA = 25°CParameterForward VoltageAmber (λd = 590 nm)Orange (λd = 605 nm)Red-Orange (λd = 615 nm)Red (λd = 626 nm)Reverse VoltagePeak Wavelength:Amber (λd = 590 nm)Orange (λd = 605 nm)Red-Orange (λd = 615 nm)Red (λd = 626 nm)Spectral Halfwidth SymbolMin.Typ.2.021.981.941.***-********-*****17Max.UnitsTest ConditionsIF = 20 mAVFVRλPEAK λ1/252.4VVnmIF = 100 APeak of Wavelength ofSpectral Distributionat IF = 20 mAWavelength Width atSpectral Distribution1/2 Power Point atIF = 20 mAExponential TimeConstant, e-t/τsVF = 0, f = 1 MHzLED Junction-to-CathodeLeadEmitted LuminousPower/Emitted RadiantPowernmSpeed of ResponseCapacitanceThermal ResistanceLuminous EfficacyAmber (λd = 590 nm)Orange (λd = 605 nm)Red-Orange (λd = 615 nm)Red (λd = 626 nm)τsCRθJ-PIN***-*****nspF°C/Wηv***-*****0150lm/WNote:1. The radiant intensity, Ie, in watts per steradian, may be found from the equation Ie = Iv/ηv, where Iv is the luminous intensity incandelas and ηv is the luminous efficacy in lumens/watt.*****E *****TYCURRENT C mA*****GTH C nmVF C ***** ***** C VFigure 1. Relative Intensity vs. Peak Wavelength.Figure 2. Forward Current vs.Forward Voltage.3.0*****E *****S *****TY(*****ZED AT 20 mA)2.52.01.51.00.50IF C ***** ***** C mA***-*****IF C DC ***** ***** C mATA C ***** *****TURE C °CFigure 3. Relative Luminous Intensityvs. Forward Current.Figure 4. Maximum Forward Currentvs. Ambient Temperature. DeratingBased on TJMAX = 130°C.**********E *****TY C %***-********-*****0-25-20-15-10-55101520θ C ***** *****EMENT C *****Figure 5. Representative Spatial Radiation Pattern for 6° ViewingAngle Lamps.元器件交易网*****%80C *****60ETN50I *****30LER*****-25-20-15-10-5510152025θ C ***** *****EMENT C *****Figure 6. Representative Spatial Radiation Pattern for 15° ViewingAngle Lamps.*****%80C *****60ETN50I *****30LER*****-25-20-15-10-55101520θ C ***** *****EMENT C *****Figure 7. Representative Spatial Radiation Pattern for 23° ViewingAngle Lamps.*****%80C *****60ETN50I *****30LER*****-25-20-15-10-5510152025θ C ***** *****EMENT C *****Figure 8. Representative Spatial Radiation Pattern for 30° ViewingAngle Lamps.Intensity Bin Limits(mcd at 20 mA)BinNameMin.Max.K*****L*****M*****N*****P***-*****Q***-*****R***-*****S***-*****T***-*****U***-*****V***-*****W***-*****X***-*****Y***-*****0Z*************** **********Tolerance for each bin limit is ± 15%.Amber Color Bin Limits(nm at 20 mA)BinNameMin.Max.1584.5587.02587.0589.*****.5592.06592.0594.5Tolerance for each bin limit is± 0.5 nm.Note:1.Bin categories are established forclassification of products. Productsmay not be available in all bincategories.元器件交易网Data subject to change.Copyright 2001 Agilent Technologies, Inc.August 13, 2001Obsoletes 5968-4744E (11/99)5988-0524EN。

T-13/4 (5 mm), T-1 (3 mm),Ultra-Bright LED LampsTechnical Data HLMP-3707, -3807, -3907HLMP-3750, -3850, -3950,-3960HLMP-3390, -3490, -3590HLMP-1340, -1440, -1540HLMP-D640HLMP-K640Features• Improved Brightness• Improved Color Performance • Available in Popular T-1 and T-13/4 Packages• New Sturdy Leads• IC Compatible/Low Current Capability• Reliable and Rugged• Choice of 3 Bright Colors High Efficiency RedHigh Brightness YellowHigh Performance Green Applications• Lighted Switches• Backlighting Front Panels• Light Pipe Sources• Keyboard IndicatorsDescriptionThese non-diffused lamps out-perform conventional LED lamps.By utilizing new higher intensitymaterial, we achieve superiorproduct performance.The HLMP-3750/-3390/-1340Series Lamps are GalliumArsenide Phosphide onGallium Phosphide red lightemitting diodes. The HLMP-3850/-3490/-1440 Series are GalliumArsenide Phosphide on GalliumPhosphide yellow light emittingdiodes. The HLMP-3950/-3590/-3960/-1540/-D640/-K640 SeriesLamps are Gallium Phosphidegreen light emitting diodes.Selection GuideLuminous Intensity Iv (mcd) @ 20mAPackage Device Package Description Color HLMP-Min.Typ.Max.2θ1/2 Degree Outline T-13/4Red3707-L00xx90.2--24F375090.2125.0-24A3750-L00xx90.2125.0-24A Yellow3807-K00xx96.2--24F385096.2140.0-24A3850-K00xx96.2140.0-24A3850-KL0xx96.2150.0294.024A Green3907-K00xx111.7--24F3914-K00xx111.7--24D3950111.7265.0-24A3950-K00xx111.7265.0-24A3950-LM0xx170.0300.0490.024A3960-K0xxx111.7265.0-24E Emerald Green D640-E00xx 6.721.0-24DT-13/4 Low Profile Red339035.255.0-32B Yellow349037.655.0-32B3490-I00xx37.655.0-32B Green359043.655.0-32B3590-I00xx43.655.0-32BT-1Red134035.255.0-45C1340-H00xx8.615.027.645C1340-J00xx35.255.0-45C1340-JK0xx35.255.0112.845C Yellow144023.545.0-45C1440-H00xx23.545.0-45C1440-HI0xx23.5-75.245C1440-HIB0023.5-75.245C Green154027.345.0-45C1540-H00xx27.345.0-45C1540-IJ0xx43.660.0139.645C Emerald Green K640 4.221.0-45CK640-D00xx 4.221.0-45CK640-FGNxx10.620.034.045CNOM.PACKAGE OUTLINE "D"HLMP-D6401.52 (0.060)1.02 (0.040)SQUAREPACKAGE OUTLINE "E"HLMP-39601.52 (0.060)1.02 (0.040)PACKAGE OUTLINE "F"HLMP-3707/-3807/-3907Absolute Maximum Ratings at T= 25°CNotes:1. See Figure 2 to establish pulsed operating conditions.2. For Red and Green series derate linearly from 50°C at 0.5 mA/°C. For Yellow series derate linearly from 50°C at 0.2 mA/°C.3. The transient peak current is the maximum non-recurring peak current the devices can withstand without damaging the LED die and wire bonds. It is not recommended that the device be operated at peak currents beyond the Absolute Maximum Peak Forward Current.HLMP -x x xx -x x x xxMechanical Options 00: Bulk01: Tape & Reel, Crimped Leads 02, Bx: Tape & Reel, Straight LeadsA1,B1: Right Angle Housing, Uneven Leads A2,B2: Right Angle Housing, Even Leads Dx, Ex: Ammo Pack, Straight LeadsFH: 2 Iv bin select with Inventory Control Vx: Ammo Pack, Crimped Leads Color Bin Options0: Full color bin distribution B: Color bin 2&3 only N: Color bin 6&7 onlyMaximum Iv Bin Options 0: Open (No. max. limit)Others: Please refer to the Iv bin table Minimum Iv Bin Options Please refer to the Iv bin table Color Options 3,7: GaP HER4,8: GaP Yellow (except K4xx series)5,9: GaP Green6: GaP Emerald Green Package Option 1,K: T-1 (3 mm)3,D: T-13/4 (5 mm)Part Numbering SystemElectrical/Optical Characteristics at T A = 25°CT-13/4 TestSymbol Description T-13/4Low Dome T-1Min.Typ.Max.Units Conditions λPEAK Peak37xx33901340635nm MeasurementWavelength38xx34901440583at Peak39xx35901540565D640K640558λd Dominant37xx33901340626nm Note 1 Wavelength38xx3490144058539xx35901540569D640K640560∆λ3/4Spectral Line37xx3390134040nmHalfwidth38xx349014403639xx3590154028D640K64024τs Speed of37xx3390134090nsRespond38xx349014409039xx35901540500D640K6403100C Capacitance37xx3390134011pF V F = 0,38xx3490144015 f = 1 MHz39xx3590154018D640K64035RθJ-PIN Thermal37xx3390210°C/W Junction to Resistance38xx3490210Cathode Lead39xx3590210D640510134029014402901540290K640290V F Forward37xx33901340 1.5 1.9 2.6V I F = 20 mA Voltage38xx34901440 1.5 2.1 2.6(Figure 3)39xx35901540 1.5 2.2 3.0D640K640 2.2 3.0V R Reverse37xx33901340 5.0V I F = 100 µA Breakdown38xx34901440Voltage39xx35901540D640K640ηv Luminous37xx33901340145Lumens Note 2 Efficacy38xx34901440500Watt39xx35901540595D640K640655Notes:1. The dominant wavelength, ld , is derived from the CIE chromaticity diagram and represents the single wavelength which defines thecolor of the device.2. The radiant intensity, Ie , in watts per steradian, may be found from the equation Ie = IV /hV , where IV is the luminous intensity incandelas and hV is the luminous efficacy in lumens/watt.Figure 1. Relative Intensity vs. Wavelength.Red, Yellow, and GreenFigure 4. Relative Luminous Intensity vs. Forward Current.Figure 5. Relative Efficiency (Luminous Intensity per Unit Current) vs. Peak Current.WAVELENGTH – nmRE LA TI V E I N T E N S I T Y1.00.5Figure 2. Maximum Tolerable Peak Current vs. Pulse Duration. (I DC MAX as per MAX Ratings).Figure 3. Forward Current vs. Forward Voltage.Figure 6. Relative Luminous Intensity vs. Angular Displacement. T-13/4 Lamp.Figure 7. Relative Luminous Intensity vs. Angular Displacement. T-13/4 Low Profile Lamp.Figure 8. Relative Luminous Intensity vs. AngularDisplacement. T-1 Lamp.Intensity Bin LimitsIntensity Range (mcd)Color Bin Min.Max.RedG 9.715.5H 15.524.8I 24.839.6J 39.663.4K 63.4101.5L 101.5162.4M 162.4234.6N 234.6340.0O 340.0540.0P 540.0850.0Q 850.01200.0R 1200.01700.0S 1700.02400.0T 2400.03400.0U 3400.04900.0V 4900.07100.0W 7100.010200.0X 10200.014800.0Y 14800.021400.0Z 21400.030900.0Maximum tolerance for each bin limit is ±18%.Intensity Bin LimitsLambda (nm)ColorCat #Min.Max.Emerald Green9552.5555.58555.5558.57558.5561.56561.5564.5Green6561.5564.55564.5567.54567.5570.53570.5573.52573.5576.5Yellow1582.0584.53584.5587.02587.0589.54589.5592.05592.0593.0Orange1597.0599.52599.5602.03602.0604.54604.5607.55607.5610.56610.5613.57613.5616.58616.5619.5Maximum tolerance for each bin limit is ±0.5nm.Color CategoriesIntensity Range (mcd)Color Bin Min.Max.YellowH 26.542.3I 42.367.7J 67.7108.2K 108.2173.2L 173.2250.0M 250.0360.0N 360.0510.0O 510.0800.0P 800.01250.0Q 1250.01800.0R 1800.02900.0S 2900.04700.0T 4700.07200.0U 7200.011700.0V 11700.018000.0W 18000.027000.0Green/A 1.1 1.8EmeraldB 1.8 2.9GreenC 2.9 4.7D 4.77.6E 7.612.0F 12.019.1G 19.130.7H 30.749.1I 49.178.5J 78.5125.7K 125.7201.1L 201.1289.0M 289.0417.0N 417.0680.0O 680.01100.0P 1100.01800.0Q 1800.02700.0R 2700.04300.0S 4300.06800.0T 6800.010800.0U 10800.016000.0V 16000.025000.0W25000.040000.0Maximum tolerance for each bin limit is ±18%.Intensity Bin Limits (continued)Mechanical Option MatrixMechanicalOption Code Definition00Bulk Packaging, minimum increment 500 pcs/bag01Tape & Reel, crimped leads, min. increment 1300 pcs/bag for T-13/4,1800 pcs/bag for T-102Tape & Reel, straight leads, min. increment 1300 pcs/bag for T-13/4,1800 pcs/bag for T-1A1T-1, Right Angle Housing, uneven leads, minimum increment 500 pcs/bagA2T-1, Right Angle Housing, even leads, minimum increment 500 psc/bagB1T-13/4, Right Angle Housing, uneven leads, minimum increment 500 pcs/bagB2T-13/4, Right Angle Housing, even leads, minimum increment 500 psc/bagBJ T-1, Tape & Reel, straight leads, minimum increment 2000 pcs/bagEG Ammo Pack, straight leads in 5 K incrementFH Devices that require inventory control and 2 I v bin selectVR Ammo Pack, crimped leads, min. increment 2 k for T-13/4 and T-1Note:All categories are established for classification of products. Products may not be available in all categories. Please contact your local Agilent representative for further clarification/information./semiconductors For product information and a complete list of distributors, please go to our web site.For technical assistance call:Americas/Canada: +1 (800) 235-0312 or(408) 654-8675Europe: +49 (0) 6441 92460China: 10800 650 0017Hong Kong: (+65) 6756 2394India, Australia, New Zealand: (+65) 6755 1939 Japan: (+81 3) 3335-8152(Domestic/International), or 0120-61-1280(Domestic Only)Korea: (+65) 6755 1989Singapore, Malaysia, Vietnam, Thailand, Philippines, Indonesia: (+65) 6755 2044 Taiwan: (+65) 6755 1843Data subject to change.Copyright © 2003 Agilent Technologies, Inc. Obsoletes 5988-8520ENApril 8, 20035988-9363EN。

HLMP-CB30-K0000..Agilent Sun Power SeriesHLMP-CB15, HLMP-CM15, HLMP-CB30,HLMP-CM30 T-13/4 (5 mm) Precision Optical Performance InGaN Blue and Green LampsData SheetFeatures•Well defined spatial radiation pattern •Viewing angles: 15˚ and 30˚•High luminous output •Colors: 472 nm Blue,526 nm Green•Superior resistance to moisture •UV resistant epoxy Benefits•Superior performance in outdoor environments •Wavelengths suitable for color mixing in full color (RGB) signs Applications•Commercial outdoor signs •Automotive interior lights •Front panel indicators •Front panel backlightingDescriptionThese high intensity blue and green LEDs are based on InGaN material technology. InGaN is the mostefficient and cost effective material for LEDs in the blue and greenregion of the spectrum. The 472 nm typical dominant wavelength for blue and 526 nm typical dominant wavelength for green are well suited to color mixing in full color signs.These LED lamps are untinted,nondiffused, T-13/4 packages incorporating second generation optics producing well definedspatial radiation patterns at specific viewing cone angles.CAUTION: HLMP-CBxx and HLMP-CMxx LEDs are Class 1 ESD sensitive. Please observe appropriate precautions during handling and processing. Refer to Agilent Application Note AN-1142 for additional details.These lamps are made with an advanced optical grade epoxy,offering superior hightemperature and high moisture resistance performance in outdoor signal and signapplications. The high maximum LED junction temperature limit of +130˚C enables hightemperature operation in bright sunlight conditions. The package epoxy contains both UV-A and UV-B inhibitors to reduce the effects of long term exposure to direct sunlight.These lamps are available in twoviewing angle options to give the designer flexibility with optical design.LED IndicatorsDevice Selection GuideTypical Color and Dominant Luminous Intensity,Leads with Package Part Number Viewing Angle Wavelength λd (nm) Typ.Iv (mcd) Min.Stand-Offs Drawing HLMP-CB15-P00xx15˚Blue 472880No A HLMP-CB15-R00xx15˚Blue 4721500No A HLMP-CB16-P00xx15°Blue 472880Yes B HLMP-CB30-K00xx30˚Blue 472310No A HLMP-CB30-M00xx30˚Blue 472520No A HLMP-CB31-M00xx30°Blue 472520Yes B HLMP-CM15-S00xx15˚Green 5261900No A HLMP-CM15-W00xx15˚Green 5265500No A HLMP-CM16-S00xx15°Green 5261900Yes B HLMP-CM30-M00xx30˚Green 526520No A HLMP-CM30-S00xx30˚Green 5261900No A HLMP-CM31-M00xx30°Green 526520Yes BPart Numbering SystemHLMP - X X XX - X X X XXMechanical Options00: BulkDD: Ammo PackColor Bin Selection0: Full color rangeMaximum Intensity Bin0: No maximum Iv bin limitMinimum Intensity BinRefer to device selection guideViewing Angle and Standoff Options15: 15 degree without standoff16: 15 degree with standoff30: 30 degree without standoff31: 30 degree with standoffColorB: BlueM: GreenPackageC: T-1 3/4 (5 mm) round lamp23Notes:1. Dimensions in mm.2. Tolerance ±0.1 mm unless otherwise noted.5.80 ± 0.20 (0.039)HLMP-Cx15 and HLMP-Cx30Package Dimensions5.80 ± 0.20 (0.039)HLMP-Cx16 and HLMP-Cx31HLMP-Cx16HLMP-Cx31d = 12.60 ± 0.25 (0.496 ± 0.010) d = 12.22 ± 0.50 (0.481 ± 0.020)Absolute Maximum Ratings at T A = 25˚CParameter Blue and GreenDC Forward Current[1]30 mAPeak Pulsed Forward Current100 mAAverage Forward Current30 mAReverse Voltage (I R = 100 µA) 5 VPower Dissipation120 mWLED Junction Temperature130˚COperating Temperature Range–40˚C to +80˚CStorage Temperature Range–40˚C to +100˚CSoldering Temperature260˚C for 5 secondsElectrical/Optical Characteristics at T A = 25˚CParameter Symbol Min.Typ.Max.Units Test Conditions Forward VoltageHLMP-CB1x-P0000V F 3.8 4.0V IF = 20 mAHLMP-CB15-R0000 3.5 4.0HLMP-CB3x-K0000 3.8 4.0HLMP-CB3x-M0000 3.8 4.0HLMP-CM1x-S0000 3.8 4.0HLMP-CM15-W0000 3.5 4.0HLMP-CM3x-M0000 3.8 4.0HLMP-CM30-S0000 3.5 4.0Reverse Voltage V R5I R = 100 µAPeak Wavelength Peak of Wavelength of Blue (λd = 472 nm)λpeak470nm Spectral Distribution Green (λd = 526 nm)524at I F = 20 mA Spectral Halfwidth Wavelength Width Blue (λd = 472 nm)∆λ1/235nm at Spectral Power Green (λd = 526 nm)47Point at I F = 20 mA Capacitance C43pF V F = 0, F = 1 MHz Luminous Efficacy Emitted Luminous Blue (λd = 472 nm)ηv75lm/W Power/Emitted Radiant Green (λd = 526 nm)520PowerThermal Resistance RΘJ-PIN240˚C/W LED Junction-to-Cathode Lead45Figure 1. Relative intensity vs. wavelength.Figure 2. Forward current vs. forward voltage (for HLMP-CB15-R0000, HLMP-CM15-W0000and HLMP-CM30-S0000).Figure 4. Relative luminous intensity vs.forward current.WAVELENGTH – nmR E L A T I V E I N T E N S I T Y1.0 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.100302515102.0 3.2520 2.82.4 3.6F O R W A R D C U R R E N TFORWARD VOLTAGE2.62.23.0 3.4 3.81.50.5I N T E N S I T Y N O R M A L I Z E D A T 20 m AI F – FORWARD CURRENT – mA 0515301.0102520Figure 5. Maximum forward current vs.ambient temperature.Figure 6. Spatial radiation pattern – 15˚ lamps.Figure 7. Spatial radiation pattern – 30˚ lamps.I F – F O R W A R D C U R R E N T – m AT A – AMBIENT TEMPERATURE – °C 40804035251510206010052030N O R M A L I Z E D I N T E N S I T Y1.00ANGULAR DISPLACEMENT – DEGREES0.80.60.2-300.41020-20-100300.90.70.50.30.1N O R M A L I Z E D I N T E N S I T Y1.0ANGULAR DISPLACEMENT – DEGREES 0.80.60.2-400.41020-20-10400.90.70.50.30.1-3030D O M I N A N T W A VE L E N G T H – n mFORWARD CURRENT – mA 540525535545Figure 8. Color vs. forward current.Figure 9. Normalized Iv vs. T (green).0.881.020.90N O R M A L I Z E D I N T E N S I T YDEGREES C20601001.0040800.980.960.940.5Figure 3. Forward current vs. forward voltage (for HLMP-CB1x-P0000, HLMP-CB30-K0000,HLMP-CB3x-M0000, HLMP-CM1x-S0000 and HLMP-CM3x-M0000).2.03.4V F – FORWARD VOLTAGE – V102530 I F – F O R W A R D C U R R E N T – m A4.2515202.43.0 3.82.2 2.83.24.02.63.6Intensity Bin Limits Bin NameMin.Max.K 310400L 400520M 520680N 680880P 8801150Q 11501500R 15001900S 19002500T 25003200U 32004200V 42005500W55007200Tolerance of each minimum and maximum is± 15%.Color Bin Limits (nm at 20 mA)Blue Color Range (nm)Bin ID Min.Max.1460.0464.02464.0468.03468.0472.04472.0476.05476.0480.0Tolerance for each bin limit is ± 0.5 nm.Green Color Range (nm)Bin ID Min.Max.1520.0524.02524.0528.03528.0532.04532.0536.05536.0540.0Tolerance for each bin limit is ± 0.5 nm.Note:1.All bin categories are established for classification of products. Products may not be available in all bin categories.Please contact your Agilent represen-tatives for further information.6/semiconductors For product information and a complete list of distributors, please go to our web site.For technical assistance call:Americas/Canada: +1 (800) 235-0312 or (408) 654-8675Europe: +49 (0) 6441 92460China: 10800 650 0017Hong Kong: (+65) 6271 2451India, Australia, New Zealand: (+65) 6271 2394 Japan: (+81 3) 3335-8152(Domestic/Interna-tional), or 0120-61-1280(Domestic Only) Korea: (+65) 6271 2194Malaysia, Singapore: (+65) 6271 2054 Taiwan: (+65) 6271 2654Data subject to change.Copyright © 2003 Agilent Technologies, Inc. Obsoletes 5988-7309ENJanuary 16, 20035988-8658ENHLMP-CB30-K0000..。

AgilentT-13/4 (5 mm), T-1 (3 mm),High Intensity, Double Heterojunction AlGaAs Red LED LampsData SheetHLMP-D101/D105, HLMP-K101/K105DescriptionThese solid state LED lamps utilize newly developed doubleheterojunction (DH) AlGaAs/GaAs material technology. This LED material has outstanding lightoutput efficiency over a wide rangeFeatures• Exceptional brightness • Wide viewing angle• Outstanding material efficiency • Low forward voltage • CMOS/MOS compatible • TTL compatible • Deep red colorApplications• Bright ambient lighting conditions • Moving message panels • Portable equipment • General useof drive currents. The color is deep red at the dominantwavelength of 637 nanometres.These lamps may be DC or pulse driven to achieve desired light output.Package DimensionsA B CSelection GuideLuminous IntensityIv (mcd) at 20 mA2θ1/2[1]Package Package Description Device HLMP-Min.Typ.Max.Degree Outline T-1 3/4 Red Tinted Diffused D10135.270.0–65AD101-J00xx35.270.0–65AD101-JK0xx35.270.0112.865AT-1 3/4 Red Untinted Non-diffused D105138.0240.0–24BD105-M00xx138.0240.0–24BD105-NO0xx200.0290.0580.024BT-1 Red Tinted Diffused K10122.045.0–60CK101-100xx22.045.0–60CK101-IJ0xx22.045.070.460CT-1 Red Untinted Non-diffused K10535.265.0–45CK105-J00xx35.265.0–45CK105-KL0xx56.4110.0180.445CNote:1. θ1/2 is the off axis angle from lamp centerline where the luminous intensity is 1/2 the on-axis value.Part Numbering SystemHLMP - x x xx - x x x xxMechanical Option00: Bulk01: Tape & Reel, Crimped Leads02: Tape & Reel, Straight LeadsA1: Right Angle Housing, Uneven Leads, T1A2: Right Angle Housing, Even Leads, T1B1: Right Angle Housing, Uneven Leads, T-1 3/4B2: Right Angle Housing, Even Leads, T-1 3/4DD, UQ: Ammo PackColor Bin Options0: Full Color Bin DistributionMaximum Iv Bin Options0: Open (no max. limit)Others: Please refer to the Iv Bin TableMinimum Iv Bin OptionsPlease refer to the Iv Bin TableLens Type01: Tinted, Diffused05: Untinted, NondiffusedColor Options1: AlGaAs RedPackage OptionsD: T-1 3/4K: T-1Absolute Maximum Ratings at T A = 25°CParameter ValuePeak Forward Current[1,2]300 mAAverage Forward Current[2]20 mADC Current[3]30 mAPower Dissipation87 mWReverse Voltage (I R = 100 µA) 5 VTransient Forward Current (10 µs Pulse)[4]500 mALED Junction Temperature110°COperating Temperature Range-20 to +100°C Storage Temperature Range-55 to +100°C Wave Soldering Temperature [1.59 mm (0.063 in.) from body]250°C for 3 seconds Lead Solder Dipping Temperature [1.59 mm (0.063 in.) from body]260°C for 5 seconds Notes:1.Maximum I PEAK at f = 1 kHz, DF = 6.7%.2.Refer to Figure 6 to establish pulsed operating conditions.3.Derate linearly as shown in Figure 5.4.The transient peak current is the maximum non-recurring peak current the device can withstand without damaging the LED die and wire bonds. It isnot recommended that the device be operated at peak currents beyond the Absolute Maximum Peak Forward Current.Electrical/Optical Characteristics at T A = 25°CSymbol Description Min.Typ.Max.Unit Test ConditionV F Forward Voltage 1.8 2.2V I F = 20 mAV R Reverse Breakdown Voltage 5.015.0V I R = 100 µAλp Peak Wavelength645nm Measurement at Peakλd Dominant Wavelength637nm Note 1∆λ1/2Spectral Line Halfwidth20nmτS Speed of Response30ns Exponential TimeConstant, e-t/T SC Capacitance30pF V F = 0, f = 1 MHzRθJ-PIN Thermal Resistance260[3]°C/W Junction to Cathode Lead210[4]290[5]ηV Luminous Efficacy80Im/W Note 2Notes:1.The dominant wavelength, λd, is derived from the CIE chromaticity diagram and represents the color of the device.2.The radiant intensity, I e, in watts per steradian, may be found from the equation I e = l V/ηV, where I V is the luminous intensity in candelas and ηV isluminous efficacy in lumens/watt.3.HLMP-D101.4.HLMP-D105.5.HLMP-K101/-K105.Figure 3. Relative luminous intensity vs. dc forward current.Figure 4. Relative efficiency vs. peak forward current.Figure 7. Relative luminous intensity vs. angular displacement. HLMP-D101.Figure 8. Relative luminous intensity vs. angular displacement. HLMP-K101.Intensity Bin LimitsIntensity Range (mcd)Color Bin Min.Max.Red I24.839.6J39.663.4K63.4101.5L101.5162.4M162.4234.6N234.6340.0O340.0540.0P540.0850.0Q850.01200.0R1200.01700.0S1700.02400.0T2400.03400.0U3400.04900.0V4900.07100.0W7100.010200.0X10200.014800.0Y14800.021400.0Z21400.030900.0Maximum tolerance for each bin limit is ± 18%.Mechanical Option MatrixMechanical Option Code Definition00Bulk Packaging, minimum increment 500 pcs/bag01Tape & Reel, crimped leads, minimum increment 1300 pcs (T-1 3/4)/1800 pcs (T-1) 02Tape & Reel, straight leads, minimum increment 1300 pcs (T-1 3/4)/1800 pcs (T-1) A1Right Angle Housing, uneven leads, minimum increment 500 pcs/bagA2Right Angle Housing, even leads, minimum increment 500 pcs/bagB1Right Angle Housing, uneven leads, minimum increment 500 pcs/bagB2Right Angle Housing, even leads, minimum increment 500 pcs/bagDD Ammo Pack, straight leads in 2K incrementUQ Ammo Pack, horizontal leads in 2K incrementNote:All categories are established for classification of products. Products may not be available in all categories. Please contact your local Agilent representative for further clarification/information./semiconductors For product information and a complete list of distributors, please go to our web site.For technical assistance call:Americas/Canada: +1 (800) 235-0312 or (916) 788-6763Europe: +49 (0) 6441 92460China: 10800 650 0017Hong Kong: (+65) 6756 2394India, Australia, New Zealand: (+65) 6755 1939 Japan: (+81 3) 3335-8152 (Domestic/Interna-tional), or 0120-61-1280 (Domestic Only) Korea: (+65) 6755 1989Singapore, Malaysia, Vietnam, Thailand, Philippines, Indonesia: (+65) 6755 2044 Taiwan: (+65) 6755 1843Data subject to change.Copyright © 2004 Agilent Technologies, Inc. Obsoletes 5968-1440ENovember 12, 20045988-2230EN。

DescriptionThese non-diffused lamps are designed to produce a bright light source and smooth radiationpattern. A slight tint is added to the lens for easy color identification.This lamp has been designed with aHLMP-C115, HLMP-C117, HLMP-C123, HLMP-C215, HLMP-C223,HLMP-C315, HLMP-C323, HLMP-C415, HLMP-C423, HLMP-C515,HLMP-C523, HLMP-C615, HLMP-C623Features•Very high intensity •Exceptional uniformity •Microtint lens for color identification•Consistent viewability All colors: AlGaAs RedHigh Efficiency Red Yellow Orange GreenEmerald Green •15° and 25° family•Tape and reel options available •Binned for color and intensity Applications•Ideal for backlighting front panels*•Used for lighting switches •Adapted for indoor and outdoor signsAgilentT-13/4 Super Ultra-Bright LED LampsData Sheet20mil lead frame, enhanced flange, and tight meniscus controls, making it compatible with radial lead automated insertion equipment.Selection GuidePart Number Luminous Intensity Iv (mcd) Color2θ1/2[1]Standoff Leads HLMP-Min.Max.DH AS AlGaAs15No C115290.0–C115-O00xx290.0–C115-OP0xx290.01000.0Yes C117-OP0xx290.01000.025No C12390.2–C123-L00xx90.2–Red15No C215138.0–C215-M00xx138.0–C215-MN0xx138.0400.025No C22390.2–C223-L00xx90.2–C223-MN0xx138.0400.0 Yellow15No C315147.0–C315-L00xx147.0–C315-LM0xx147.0424.025No C32396.2–C323-K00xx96.2–C323-KL0xx96.2294.0 Orange15No C415138.0–C415-M00xx138.0–C415-M0D0xx138.0–C415-MN0xx138.0400.025No C42390.2–C423-L00xx90.2–C423-LM0xx90.2276.0 Green15No C515170.0–C515-L00xx170.0C515-LM0xx170.0490.025No C52369.8–C523-J00xx69.8–C523-KL0xx111.7340.0 Emerald Green15No C61517.0–C615-G00xx17.0–25No C623 6.7–C623-E00xx 6.7–Part Numbering SystemHLMP - C x xx - x x x xxMechanical Options00: Bulk01: Tape & Reel, Crimped Leads02: Tape & Reel, Straight LeadsB2: Right Angle Housing, Even LeadsUQ: Ammo Pack, Horizontal LeadsColor Bin Options0: Full Color Bin DistributionD: Color Bins 4 & 5 onlyMaximum Iv Bin Options0: Open (No Maximum Limit)Others: Please refer to the Iv Bin TableMinimum Iv Bin OptionsPlease refer to the Iv Bin TableViewing Angle & Standoffs Options15: 15 Degree, without Standoffs17: 15 Degree, with Standoffs23: 25 Degree, without StandoffsColor Options1. AS AlGaAs Red2. High Efficiency Red3. Yellow4. Orange5. Green6. Emerald GreenPackage OptionsC: T-1 3/4 (5 mm)Absolute Maximum Ratings at T A = 25°CHighHighDH AS Efficiency Performance AlGaAs Red and Green and ParameterRed Orange Yellow Emerald Green Units DC Forward Current [1]30302030mA Transient Forward Current [2]500500500500mA (10 µsec Pulse)Reverse Voltage (Ir = 100 µA)5555V LED Junction Temperature 110110110110°C Operating Temperature Range –20 to +100–55 to +100–20 to +100°C Storage Temperature Range –55 to +100°CWave Soldering Temperature 250°C for 3 seconds [1.59 mm (0.063 in.) from body]Lead Solder Dipping Temperature 260°C for 5 seconds[1.59 mm (0.063 in.) from body]Notes:1. See Figure 5 for maximum current derating vs. ambient temperature.2. The transient current is the maximum nonrecurring peak current the device can withstand without damaging the LED die and wire bond.Package DimensionsHLMP-Cx15 and HLMP-Cx23HLMP-Cx17(0.039)NOTES:1. ALL DIMENSIONS ARE IN MILLIMETERS (INCHES).2. LEADS ARE MILD STEEL, SOLDER DIPPED.3. AN EPOXY MENISCUS MAY EXTEND ABOUT 0.5 mm (0.020 in.) DOWN THE LEADS.± 0.20± 0.008)Electrical Characteristics at T A = 25°CForward Reverse Capacitance Speed of ResponseVoltage Breakdown C (pF)Thermalτs (ns)Vf (Volts)Vr (Volts)Vf = 0Resistance Time Constant@ If = 20 mA@ Ir = 100 µA f = 1 MHz RθJ-PIN e-t/τsPart Number Typ.Max.Min.Typ.(°C/W)Typ.HLMP-C115 1.8 2.253021030HLMP-C117HLMP-C123HLMP-C215 1.9 2.651121090HLMP-C223HLMP-C315 2.1 2.651521090HLMP-C323HLMP-C415 1.9 2.654210280HLMP-C423HLMP-C515 2.2 3.0518210260HLMP-C523HLMP-C615 2.2 3.0518210260HLMP-C623Optical Characteristics at T A = 25°CLuminous Color,ViewingIntensity Peak Dominant Angle LuminousIv (mcd)Wavelength Wavelength2θ1/2Efficacy@ 20 mA[1]λpeak (nm)λd[2] (nm)(Degrees)[3]ηvPart Number Min.Typ.Typ.Typ.Typ.(lm/w) HLMP-C1152906006456371180HLMP-C117HLMP-C1239020026HLMP-C215138300635626171459017023HLMP-C315146300583585175009617025HLMP-C415138300600602173809017023HLMP-C515170300568570205956917028HLMP-C61517455585602065662728Notes:1. The luminous intensity, Iv, is measured at the mechanical axis of the lamp package. The actual peak of the spatial radiation pattern may not bealigned with this axis.2. The dominant wavelength, λd, is derived from the CIE Chromaticity Diagram and represents the color of the device.3. 2θ1/2 is the off-axis angle where the luminous intensity is 1/2 the on-axis intensity.Figure 1. Relative intensity vs. wavelength.Figure 2. Forward current vs. forward voltage (non-resistor lamp).Figure 3. Relative luminous intensity vs. forward current.WAVELENGTH – nmR E L A T I V E I N T E N S I T Y1.00.50I F – F O R W A R DC U R R E N T – m AV F – FORWARD VOLTAGE – VI F – F O R W A R D C U R R E N T – m AV F – FORWARD VOLTAGE – VHIGH EFFICIENCY RED, ORANGE,YELLOW, AND HIGH PERFORMANCEGREEN, EMERALD GREENR E L A T I V E L U M I N O U S I N TE N S I T Y (N O R M A L I Z E D A T 20 m A )I F – DC FORWARD CURRENT – mA R E L A T I V E L U M I N O U S I N T E N S I T Y (N O R M A L I Z E D A T 20 m A )0I DC – DC CURRENT PER LED – mA10201.60.80.4515301.2250.20.61.01.4HER, ORANGE, YELLOW, AND HIGH PERFORMANCE GREEN, EMERALD GREENFigure 5. Maximum forward dc current vs. ambient temperature. Derating based on T j MAX = 110°C.Figure 4. Relative efficiency (luminous intensity per unit current) vs. peak current.Figure 6. Relative luminous intensity vs. angular displacement. 15 degree family.R E L A T I V E E F F I C I E N C Y (N O R M A L I Z E D A T 20 m A )0I PEAK – PEAK FORWARD CURRENT – mA0.60.8300201001.21.00.20.45020010DH As AlGaAs REDηP E A K – R E L A T I V E E F F I C I E N C Y (N O R M A L I Z E D A T 20 m A )I PEAK – PEAK FORWARD CURRENT – mAHER, ORANGE, YELLOW, HIGHPERFORMANCE GREEN, EMERALD GREENI F – F O R W A R D C U R R E NT – m AT A – AMBIENT TEMPERATURE – °C DH As AlGaAs REDI F – F O R W A R D C U R R E N T – m AT A – AMBIENT TEMPERATURE – °CHER, ORANGE, YELLOW, AND HIGH PERFORMANCE GREEN, EMERALD GREEN N O R M A L I Z E D L U M I N O U S I N T E N S I T Y10ANGULAR DISPLACEMENT – DEGREES0.80.60.50.70.2450.10.30.4403530252010515-5-10-15-20-25-30-35-40-450.9Figure 7. Relative luminous intensity vs. angular displacement. 25 degree family.Intensity Bin Limits Intensity Range (mcd)ColorBin Min.Max.L 101.5162.4M 162.4234.6N 234.6340.0O 340.0540.0P 540.0850.0Q 850.01200.0R 1200.01700.0Red/OrangeS 1700.02400.0T 2400.03400.0U 3400.04900.0V 4900.07100.0W 7100.010200.0X 10200.014800.0Y 14800.021400.0Z 21400.030900.0L 173.2250.0M 250.0360.0N 360.0510.0O 510.0800.0P 800.01250.0YellowQ 1250.01800.0R 1800.02900.0S 2900.04700.0T 4700.07200.0U 7200.011700.0V 11700.018000.0W18000.027000.0N O R M A L I Z E D L U M I N O U S I N T E N S I T Y10ANGULAR DISPLACEMENT – DEGREES0.80.60.50.70.2450.10.30.4403530252010515-5-10-15-20-25-30-35-40-450.9Intensity Bin Limits, continuedIntensity Range (mcd) Color Bin Min.Max.E7.612.0F12.019.1G19.130.7H30.749.1I49.178.5J78.5125.7K125.7201.1L201.1289.0 Green/M289.0417.0 Emerald Green N417.0680.0O680.01100.0P1100.01800.0Q1800.02700.0R2700.04300.0S4300.06800.0T6800.010800.0U10800.016000.0V16000.025000.0W25000.040000.0 Maximum tolerance for each bin limit is ± 18%.Color CategoriesLambda (nm)Color Category #Min.Max.6561.5564.55564.5567.5 Green4567.5570.53570.5573.52573.5576.51582.0584.53584.5587.0 Yellow2587.0589.54589.5592.05592.0593.01597.0599.52599.5602.03602.0604.5 Orange4604.5607.55607.5610.56610.5613.57613.5616.58616.5619.5 Tolerance for each bin limit is ± 0.5 nm.Mechanical Option MatrixMechanical Option Code Definition00Bulk Packaging, minimum increment 500 pcs/bag01Tape & Reel, crimped leads, minimum increment 1300 pcs/bag02Tape & Reel, straight leads, minimum increment 1300 pcs/bagB2Right Angle Housing, even leads, minimum increment 500 pcs/bagUQ Ammo Pack, horizontal leads, in 1K minimum incrementNote:All categories are established for classification of products. Products may not be available in all categories. Please contact your local Agilent representative for further clarification/information./semiconductorsFor product information and a complete list ofdistributors, please go to our web site.For technical assistance call:Americas/Canada: +1 (800) 235-0312 or(916) 788-6763Europe: +49 (0) 6441 92460China: 10800 650 0017Hong Kong: (+65) 6756 2394India, Australia, New Zealand: (+65) 6755 1939Japan: (+81 3) 3335-8152 (Domestic/Interna-tional), or 0120-61-1280 (Domestic Only)Korea: (+65) 6755 1989Singapore, Malaysia, Vietnam, Thailand,Philippines, Indonesia: (+65) 6755 2044Taiwan: (+65) 6755 1843Data subject to change.Copyright © 2004 Agilent Technologies, Inc.Obsoletes 5965-6165ENovember 11, 20045988-2149EN。

SunPower Series HLMP-ELxx HLMP-EHxx HLMP-EDxxPrecision Optical Performance AlInGaP II LED Lamps Technical DataFeatures• Well Defined Spatial Radiation Patterns • Viewing Angles: 15°,23°, 30°• High Luminous Output • Colors:592 nm Amber617 nm Reddish-Orange 630 nm Red• High Operating Temperature:T JLED =+130°C• Superior Resistance to MoistureBenefits• Viewing Angles Match Traffic Management Requirements• Colors Meet Automotive and Traffic Signal Specifications • Superior Light Output Performance in Outdoor Environments• Suitable for Autoinsertion into PC BoardsApplications• Traffic Management:Traffic SignalsWork Zone Warning Lights Variable Message Signs • Commercial Outdoor Advertising:Signs Marquees • Automotive:Exterior and Interior LightsDescriptionPrecision Optical Performance AlInGaP II (aluminum indium gallium phosphide) LEDs offer superior light output for excellent readability in sunlight and dependable performance. The AlInGaP II technology provides extremely stable light output over long periods of time.These LED lamps are untinted,nondiffused, T-13/4 packages incorporating second generation optics which produce well defined radiation patterns at specific viewing cone angles.These lamps are made with an advanced optical grade epoxy offering superior high tempera-ture and high moisture resistance performance in outdoor signal and sign applications. Themaximum LED junction tempera-ture limit of +130°C enables high temperature operation in bright sunlight conditions. The epoxy contains both uv-a and uv-binhibitors to reduce the effects of long term exposure to directsunlight.Part Numbering Scheme HLMP-E(1)(2)(3)-(4)(5)(6)(7)(8)where (1) = Color“L”=592 nm Amber“H”=615 nm Reddish-orange“D”=630 nm Redwhere (2)(3) = Viewing Angle and Lead Standoffs“16”=15 degree without leadstandoffs“18”=15 degree with leadstandoffs“25”=23 degree without leadstandoffs“27”=23 degree with leadstandoffs“31”=30 degree without leadstandoffs“33”=30 degree with leadstandoffswhere (4) = MinimumIntensity Bin (refer totable on page 7)where (5) = MaximumIntensity Bin (refer totable on page 7)where (6) = Color BinSelection“0”=no color bin limitation“K”=amber color bins 2and 4 only (refer totable on page 7)“4”=amber color bin 4 only(refer to table onpage 7)where (7)(8) = Mechanicalor Packaging Option“00”=bulk packaging,minimum increment500/bag“DD”=ammo pack, minimumincrement 2000/box.Available for productsshown in BOLD inselection guide.Refer to the device selectionguides for availablecombinations.T-13/4 (5 mm) Precision Optical Performance AlInGaP II LED LampsSelection GuideTypicalViewing Color and Luminous Angle Dominant Intensity Iv (mcd) [3,4] 2θ1/2Wavelength Lamps Without Standoffs Lamps With Standoffs@ I(f) = 20 mA (Deg.)[2](nm), Typ.[1](Outline Drawing A)Outline Drawing B)Min.Max.HLMP-EL16-VW00036008300HLMP-EL16-VWK00*36008300HLMP-EL16-VX000360010700 Amber 592HLMP-EL16-VX400**360010700HLMP-EL16-VXK00*360010700 15°HLMP-EL16-VY000HLMP-EL18-VY000360013800HLMP-EL16-VYK00*360013800HLMP-EL16-WZ000HLMP-EL18-WZ000470018400 Red-Orange 615HLMP-EH16-TW000HLMP-EH18-TW00021708300HLMP-EH16-UX000HLMP-EH18-UX000275010700 Red 630HLMP-ED16-TW000HLMP-ED18-TW00021708300HLMP-ED16-UX000HLMP-ED18-UX000275010700Notes:1. Dominant Wavelength, λd, is derived from the CIEChromaticity Diagram and represents the color of the lamp.2. θ1/2 is the off-axis angle where the luminous intensity is onehalf the on-axis intensity.3. The luminous intensity is measured on the mechanical axis ofthe lamp package.4. The optical axis is closely aligned with the packagemechanical axis.Part numbers in bold are recommended for new designs.*HLMP-xLxx-xxK00 are selected to amber color bins 2 and 4 only. **HLMP-xLxx-xx400 are selected to amber color bin 4 only.T-13/4 (5 mm) Precision Optical Performance AlInGaP II Led Lamps (Continued) Selection GuideTypicalViewing Color and Luminous Angle Dominant Intensity Iv (mcd) [3,4] 2θ1/2Wavelength Lamps Without Standoffs Lamps With Standoffs@ I(f) = 20 mA (Deg.)[2](nm), Typ.[1](Outline Drawing A)Outline Drawing B)Min.Max.HLMP-EL25-ST00016503700HLMP-EL25-STK00*16503700HLMP-EL25-SU00016504800HLMP-EL25-SU400**16504800 Amber 592HLMP-EL25-SUK00*16504800HLMP-EL25-SVK00*16506300 23°HLMP-EL25-SV000HLMP-EL27-SV00016506300HLMP-EL25-TW000HLMP-EL27-TW00021708300HLMP-EL25-TWK00*21708300 Red-Orange 615HLMP-EH25-SV000HLMP-EH27-SV00016506300HLMP-EH25-TW000HLMP-EH27-TW00021708300 Red 630HLMP-ED25-SV000HLMP-ED27-SV00016506300HLMP-ED25-TW000HLMP-ED27-TW00021708300HLMP-EL31-SV000HLMP-EL33-SV00016506300HLMP-EL31-ST00016503700HLMP-EL31-STK00*16503700 Amber 592HLMP-EL31-SUK00*16504800HLMP-EL31-SU400**16504800HLMP-EL31-SU00016504800 30°HLMP-EL31-SVK00*16506300 Red-Orange 615HLMP-EH31-RU000HLMP-EH33-RU00013004800HLMP-EH31-SV000HLMP-EH33-SV00016506300HLMP-ED31-ST00016503700 Red 630HLMP-ED31-SU00016504800HLMP-ED31-RU000HLMP-ED33-RU00013004800HLMP-ED31-SV000HLMP-ED33-SV00016506300 Notes:1. Dominant Wavelength, λd, is derived from the CIEChromaticity Diagram and represents the color of the lamp.2. θ1/2 is the off-axis angle where the luminous intensity is onehalf the on-axis intensity.3. The luminous intensity is measured on the mechanical axis ofthe lamp package.4. The optical axis is closely aligned with the packagemechanical axis.Part numbers in bold are recommended for new designs.*HLMP-xLxx-xxK00 are selected to amber color bins 2 and 4 only. **HLMP-xLxx-xx400 are selected to amber color bin 4 only.Absolute Maximum Ratings at T A = 25°CDC Forward Current [1,2,3]............................................................50 mA Peak Pulsed Forward Current [2,3]..............................................100 mA Average Forward Current ............................................................30 mA Reverse Voltage (I R = 100 µA).........................................................5 V LED Junction Temperature..........................................................130°C Operating Temperature ..............................................-40°C to +100°C Storage Temperature ..................................................-40°C to +120°C Dip/Drag Solder Temperature................................260°C for 6 seconds Through-the-Wave Preheat Temperature.....................................145°C Through-the-Wave Solder Temperature.................245°C for 3 seconds[1.59 mm (0.060 in.) below seating plane]Notes:1. Derate linearly as shown in Figure 4.2. For long term performance with minimal light output degradation, drive currentsbetween 10 mA and 30 mA are recommended. For more information on recommended drive conditions, please refer to Application Brief I-024 (5966-3087E).3. Please contact your sales representative about operating currents below 10 mA.AB(0.039)CATHODEFLATPackage Dimensions (0.039)CATHODEFLATBElectrical/Optical Characteristics at T A = 25°CParameter SymbolMin.Typ.Max.UnitsTest Conditions Forward VoltageI F = 20 mAAmber (λd = 592 nm)2.15Red-Orange (λd = 617 nm)V F 2.08 2.4V Red (λd = 630 nm) 2.00Reverse Voltage V R 520VI R = 100 µAPeak Wavelength Peak of Wavelength of Amber594Spectral Distribution Red-Orange λPEAK 623nm at I F = 20 mARed639Spectral Halfwidth∆λ1/217nmWavelength Width at Spectral Distribution 1/2 Power Point at I F = 20 mASpeed of Response τs 20ns Exponential Time Constant, e -t/τCapacitanceC 40pF V F= 0, f = 1 MHzThermal Resistance R ΘJ-PIN240°C/WLED Junction-to-Cathode LeadLuminous Efficacy [1]Emitted LuminousAmber500Power/Emitted Radiant Red-Orange ηv235lm/WPower at I f = 20 mARed155Note:1. The radiant intensity, I e , in watts per steradian, may be found from the equation I e = I v /ηv , where I v is the luminous intensity in candelas and ηv is the luminous efficacy in lumens/watt.sFigure 1. Relative Intensity vs. Peak Wavelength.WAVELENGTH – nmR E L A T I V E I N T E N S I T YFigure 2. Forward Current vs.Forward Voltage.C U R R E N T – m AV F – FORWARD VOLTAGE – VFigure 6. Representative Spatial Radiation Pattern for 24° Viewing Angle Lamps.N O R M A L I Z E D I N T E N S I T Y1.000ANGULAR DISPLACEMENT – DEGREES0.800.600.500.700.20-20-150.100.300.40-105101520250.90-25-5Figure 3. Relative Luminous Intensity vs. Forward Current.Figure 4. Maximum Forward Current vs. Ambient Temperature. Derating Based on T JMAX = 130°C.I F – F O R W A R D C U R R E N T –m AT A – AMBIENT TEMPERATURE – °CR E L A T I V E L U M I N O U S I N T E N S I T Y (N O R M A L I Z E D A T 20 m A )00I F – DC FORWARD CURRENT – mA402.01.51.00.520502.51030Figure 5. Representative Spatial Radiation Pattern for 15° Viewing Angle Lamps.N O R M A L I Z E D I N T E N S I T Y1.000ANGULAR DISPLACEMENT – DEGREES0.800.600.500.700.20-20-150.100.300.40-105101520250.90-25-5Bin Name Min.Max.1584.5587.02587.0589.54589.5592.06592.0594.5Bin Name Min.Max.P 8801150Q 11501500R 15001900S 19002500T 25003200U 32004200V 42005500W 55007200X 72009300Y 930012000Z1200016000Intensity Bin Limits (mcd at 20 mA)Tolerance for each bin limit is ± 15%.HLMP-xLxx Color Bin Limits (nm at 20 mA)Tolerance for each bin limit is ± 0.5 nm.Note:1.Bin categories are established for classification of products. Products may not be available in all bin categories.N O R M A L I Z E D I N T E N S I T YANGULAR DISPLACEMENT – DEGREESFigure 7. Representative Spatial Radiation Pattern for 30° Viewing Angle Lamps. Data subject to change.Copyright © 1999 Agilent Technologies Obsoletes 5968-7180E5968-4303E (11/99)。

HLMP-RL20, HLMP-SL20Precision Optical Performance Amber New 4mm Superwide Oval LEDData SheetDescriptionThe Precision Optical Performance Oval LED is specifically designed for variable message signs and passenger infor-mation signs. The oval shaped radiation pattern and high luminous intensity ensure that these devices are excellent for wide field of view outdoor applications where a wide viewing angle and readability in sunlight are essential.Features• Well defined spatial radiation pattern • High brightness material • Available in amber– Amber AlInGaP 590nm • Superior resistance to moisture • Typical viewing angle 60° x 120°• Standoff PackageApplications• Variable message signs • Commercial outdoor advertisingNotes:All dimensions in millimeters (inches).Package DimensionsPackage Drawing APackage Drawing BPart Numbering SystemDevice Selection GuidePart NumberColor and Dominant Wavelength l d (nm) TypLuminous Intensity Iv (mcd) at 20 mA-MinLuminous Intensity Iv (mcd) at 20 mA-MaxPackage DrawingHLMP-RL20-MP0DD Amber 5905201150A HLMP-SL20-MP0DDAmber 5905201150BTolerance for each intensity limit is ± 15%.Notes:1. The luminous intensity is measured on the mechanical axis of the lamp package.2. The optical axis is closely aligned with the package mechanical axis.Note:Please refer to AB 5337 for complete information about part numbering system.Packaging OptionDD: Ammo pack 00 : BulkColor Bin Selection0: Full color bin distributionMaximum Intensity BinRefer to Intensity Bin Limit TableMinimum Intensity BinRefer to Intensity Bin Limit TableColorL: Amber 590PackageR: 4mm Oval 60° x 120°, ParallelS: 4mm Oval 60° x 120°, PerpendicularElectrical / Optical Characteristics T A = 25°CParameterSymbolMin.Typ.Max.UnitsTest ConditionsForward Voltage V F 1.80 2.022.40V I F = 20 mA Reverse Voltage V R 5V I R = 100 µA Dominant Wavelength [1]l d 584.5594.5nm I F = 20 mAPeak Wavelength l PEAK 594nm Peak of Wavelength of Spectral Distribution at I F = 20 mA Thermal Resistance R θJ-PIN 240°C/W LED Junction-to-Cathode Lead Luminous Efficacy [2]Amber ηV 480lm/W Emitted Luminous Flux/Emitted Radiant Flux Luminous Flux ϕv 500mlm I F = 20 mALuminous Efficiency [3]ηe12lm/WEmitted Luminous Flux/Electrical Power I F = 20 mANotes:1. The dominant wavelength is derived from the chromaticity Diagram and represents the color of the lamp.2. The radiant intensity, I e in watts per steradian, may be found from the equation Ie = I V /ηV where I V is the luminous intensity in candelas and ηV is the luminous efficacy in lumens/watt.3. ηe = ϕV / I F x V F , where ϕV is the emitted luminous flux, I F is electrical forward current and V F is the forward voltage.Absolute Maximum Ratings T A = 25°CParameterAmberUnitDC Forward Current [1]50mA Peak Forward Current [2]100mA Average Forward Current 30mA Reverse Voltage (I R = 100 µA) 5V LED Junction Temperature 130°C Operating Temperature Range -40 to +100°C Storage Temperature Range-40 to +100°CNotes:1. Derate linearly as shown in Figure 4.2. Duty Factor 30%, frequency 1KHz.Figure 1. Relative Intensity vs Wavelength Figure 2. Forward Current vs Forward VoltageFigure 3. Relative Intensity vs Forward Current Figure 4. Maximum Forward Current vs Ambient TemperatureFigure 5. Representative Radiation Pattern – Major Axis Figure 6. Representative Radiation Pattern – Minor AxisT A - AMBIENT TEMPERATURE - °CI F - F O R W A R D C U R R E N T - m A0.00.10.20.30.40.50.60.70.80.91.0500550600650700WAVELENGTH - nmR E L A T I V E I N T E N S I T Y10203040500123FORWARD VOLTAGE - VF O R W A R D C U R R E N T - m A5101520253035404550550204060801001200.511.5201020304050DC FORWARD CURRENT - mAR E L A T I V E L U M I N O U S I N T E N S I T Y (N O R M A L I Z E D A T 20 m A )0.10.20.30.40.50.60.70.80.91-90-60-300306090ANGULAR DISPLACEMENT - DEGREESN O R M A L I Z E D I N T E N S I T Y0.10.20.30.40.50.60.70.80.91-90-60-300306090ANGULAR DISPLACEMENT - DEGREESN O R M A L I Z E D I N T E N S I T YIntensity Bin Limit TableBin Name Min.Max. M520680 N680880 P8801150 Q11501500 Tolerance for each bin limit is ± 15%Color Bin LimitBin ID Min.Max. 1584.5587.0 2587.0589.5 4589.5592.0 6592.0594.5 Tolerance for each bin limit is ±1.0 nmPrecautions:Lead Forming:•The leads of an LED lamp may be preformed or cut to length prior to insertion and soldering on PC board.•For better control, it is recommended to use proper tool to precisely form and cut the leads to applicable length rather than doing it manually.•If manual lead cutting is necessary, cut the leads after the soldering process. The solder connection forms a mechanical ground which prevents mechanical stress due to lead cutting from traveling into LED package. This is highly recommended for hand solder operation, as the excess lead length also acts as small heat sink. Soldering and Handling:•Care must be taken during PCB assembly and soldering process to prevent damage to the LED component. •LED component may be effectively hand soldered to PCB. However, it is only recommended under unavoidable circumstances such as rework. The closest manual soldering distance of the soldering heat source (soldering iron’s tip) to the body is 1.59mm. Soldering the LED using soldering iron tip closer than 1.59mmmight damage the LED.•ESD precaution must be properly applied on the soldering station and personnel to prevent ESD damage to the LED component that is ESD sensitive. Do refer to Avago application note AN 1142 for details. The soldering iron used should have grounded tip to ensure electrostatic charge is properly grounded.•Recommended soldering condition:Wave Soldering [1, 2]Manual Solder DippingPre-heat temperature105°C Max.–Preheat time60 sec Max–Peak temperature250°C Max.260°C Max.Dwell time 3 sec Max. 5 sec MaxNote:1) Above conditions refers to measurement with thermocouplemounted at the bottom of PCB.2) It is recommended to use only bottom preheaters in order toreduce thermal stress experienced by LED.•Wave soldering parameters must be set and maintained according to the recommended temperature and dwell time. Customer is advised to perform daily check on the soldering profile to ensure that it is always conforming to recommended soldering conditions. Note:1. PCB with different size and design (component density) will havedifferent heat mass (heat capacity). This might cause a change intemperature experienced by the board if same wave solderingsetting is used. So, it is recommended to re-calibrate the solderingprofile again before loading a new type of PCB.2. Avago Technologies’ high brightness LED are using high efficiencyLED die with single wire bond as shown below. Customer isadvised to take extra precaution during wave soldering to ensurethat the maximum wave temperature does not exceed 250°C andthe solder contact time does not exceeding 3sec. Over-stressingthe LED during soldering process might cause premature failureto the LED due to delamination.the lead frame is achieved through conductive paste.•Any alignment fixture that is being applied during wave soldering should be loosely fitted and should not apply weight or force on LED. Non metal material is recommended as it will absorb less heat during wave soldering process.•At elevated temperature, LED is more susceptible to mechanical stress. Therefore, PCB must allowed to cool down to room temperature prior to handling, which includes removal of alignment fixture or pallet.•If PCB board contains both through hole (TH) LED and other surface mount components, it is recommended that surface mount components be soldered on the top side of the PCB. If surface mount need to be on the bottom side, these components should be soldered using reflow soldering prior to insertion the TH LED.•Recommended PC board plated through holes (PTH) size for LED component leads.LED componentlead size DiagonalPlated throughhole diameter0.45 x 0.45 mm(0.018x 0.018 inch)0.636 mm(0.025 inch)0.98 to 1.08 mm(0.039 to 0.043 inch)0.50 x 0.50 mm(0.020x 0.020 inch)0.707 mm(0.028 inch)1.05 to 1.15 mm(0.041 to 0.045 inch)•Over-sizing the PTH can lead to twisted LED after clinching. On the other hand under sizing the PTH can cause difficulty inserting the TH LED.Refer to application note AN5334 for more information about soldering and handling of high brightness TH LED lamps.Example of Wave Soldering Temperature Profile for TH LEDAmmo Packs Drawing25020015010050TIME (SECONDS)Recommended solder: Sn63 (Leaded solder alloy)SAC305 (Lead free solder alloy)Flux: Rosin uxSolder bath temperature: 245°C± 5°C (maximum peak temperature = 250°C)Dwell time: 1.5 sec - 3.0 sec (maximum = 3sec)Note: Allow for board to be su ciently cooled to room temperature before exerting T E M P E R A T U R E (°C )mechanical force.Packaging Box for Ammo PacksNote: The dimension for ammo pack is applicable for the device with standoff and without standoff.Packaging Label:(i) Avago Mother Label: (Available on packaging box of ammo pack and shipping box)For product information and a complete list of distributors, please go to our web site: Avago, Avago Technologies, and the A logo are trademarks of Avago Technologies in the United States and other countries.Data subject to change. Copyright © 2005-2014 Avago Technologies. All rights reserved. AV02-2258EN - July 18, 2014Acronyms and Definition:BIN:(i) Color bin only or VF bin only(Applicable for part number with color bins but without VF bin OR part number with VF bins and no color bin)OR(ii) Color bin incorporated with VF Bin(Applicable for part number that have both color bin and VF bin)Example:(i) Color bin only or VF bin only BIN: 2 (represent color bin 2 only) BIN: VB (represent VF bin “VB” only)(ii) Color bin incorporate with VF BinVB: VF bin “VB”2: Color bin 2 only(ii) Avago Baby Label (Only available on bulk packaging)。

时代HLN-11系列里氏硬度仪使用说明书北京时代润宝科技发展有限责任公司公司网址：ｗｗｗ．ｓｄｒｂ．ｃｏｍ．ｃｎ前言亲爱的用户，感谢您购买了我公司生产的时代HLN-11系列里氏硬度计，（以下简称“硬度计”）。

在您开始使用本仪器之前，请您务必详细阅读这本“使用说明书”，它的每段话都会为您能够正确使用本仪器提供必要的帮助，能使您满意。

HLN-11系列包含两种型号：HLN-11AHLN-11C两者的特点是：HLN-11A仅可配国产D型冲击装置；HLN-11C可配D型和各种异型冲击装置；两种型号的使用方法相同；HLN-11系列硬度计符合以下三个标准：《里氏硬度计技术条件》 ZB N71 010-90《里氏硬度计》检定规程 JJG 747-91《金属里氏硬度试验方法》 GB/T 17394-1998北京时代润宝科技发展有限责任公司公司网址：ｗｗｗ．ｓｄｒｂ．ｃｏｍ．ｃｎ目录1、硬度计各部分名称 (2)2、硬度计性能及应用 (3)3、里氏硬度计测试原理 (4)4、试件的预处理 (9)5、使用与操作 (11)6、保养 (17)7、影响测试精度的几个问题 (18)8、故障分析与维修 (22)9、非保修零件清单 (25)10、“标准里代硬度块”的使用说明 (26)11、里氏硬度计的“检修、检定”服务 (27)北京时代润宝科技发展有限责任公司公司网址：ｗｗｗ．ｓｄｒｂ．ｃｏｍ．ｃｎ1、硬度计各部分名称1．1主机与打印机1．2 D型冲击装置1 2 3 4 5 6 71 释放按钮2 加载套3 导管4 线圈部件5 导线6 冲击体7 支承环1.3 冲击装置D DC DL C D+15E G1．4冲击装置技术参数冲击装置技术参数一览表冲击装置D/DC/DL D+15 C G E冲击能量冲击体质量11Nmm5.5g/5.5g/7.3g11Nmm7.8g2.7Nmm3.0g90Nmm20g11Nmm5.5g球头硬度: 球头直径: 球头材料: 1600HV3mm碳化钨1600HV3mm碳化钨1600HV3mm碳化钨1600HV5mm碳化钨000HV3mm金刚石冲击装置直径: 冲击装置长度: 冲击装置重量: 20mm147/86mm75/50g20mm162mm80g20mm141mm75g30mm254mm250g20mm155mm80g试件最大硬度 940HV 940HV1000HV650HV1200HV 试件表面平均粗糙度Ra: 2μm2μm0.4μm7μm2μm 试件最小重量:可直接测量需稳定支撑需密实耦合5Kg2Kg0.1Kg5Kg2Kg0.1Kg1.5Kg0.5Kg0.02Kg15Kg5Kg0.5Kg5Kg2Kg0.1Kg试件最小厚度:密实耦合硬化层最小厚度3mm0.8mm3mm0.8mm1mm0.8mm10mm1.2mm3mm0.8mm球头压痕尺寸：硬度300HV时压痕直径压痕深度0.54mm24μm0.54mm24μm0.38mm12μm1.03mm53μm0.54mm24μm硬度600HV时压痕直径压痕深度0.54mm17μm0.54mm17μm0.32mm8μm0.90mm41μm0.54mm17μm硬度800HV时压痕直径压痕深度0.35mm10μm0.35mm10μm0.35mm7μm0.35mm10μm冲击装置适用范围：∆型测量通用件∆Χ型测量孔或园柱筒内DL型测量细长窄槽或孔D+15型测量沟槽或凹入的表面C型测量小轻薄部件及表面硬化层。