HLMA-DL00中文资料

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1-37HDescriptionThese untinted, non-diffused, solid state lamps utilize the latest absorbing/transparent substrate aluminum indium gallium phos-phide (AS/TS AlInGaP) LED tech-nology . These materials have a very high luminous efficiency , capable of producing high light output over a wide range of drive currents. In addition, these LED lamps are at wavelengths ranging from amber to reddish orange and at viewing angles ranging from 7 to 45degrees.Features• Outstanding LED Material Efficiency• High Light Output over a Wide Range of Currents • Low Electrical Power Dissipation• CMOS/MOS Compatible • Colors: 590/592 nm Amber,615/617nm and 622 nm Reddish-Orange• Variety of Packages AvailableApplications• Outdoor Message Boards • Safety Lighting Equipment • Signaling Applications • Emitter for Emitter/Detector Applications• Changeable Message Signs • Portable Equipment • Medical Equipment • Automotive Lighting• Alternative to Incandescent LampsSunPower Series HLMA-CX00 Series HLMA-DX00 Series HLMA-KX00 Series HLMT-CX00 Series HLMT-DX00 SeriesT-13/4 (5 mm), T-1 (3 mm), High Performance AlInGaP LED Lamps Technical Data5963-2323E1-38NOTES:1. ALL DIMENSIONS ARE IN MILLIMETERS (INCHES).2. THE LEADS ARE MILD STEEL, SOLDER DIPPED.3. AN EPOXY MENISCUS MAY EXTEND ABOUT 1 MM (0.040") DOWN THE LEADS, UNLESS OTHERWISE NOTED.Package Dimensions1.27 (0.050)NOTESABCAbsolute Maximum Ratings at T A = 25°C(T-13/4 Package)DC Forward Current[1,4,5]...........................................................50 mAPeak Forward Current[2]...........................................................200 mATime Average Input Power[2]...................................................103 mWTransient Forward Current[3] (10 µs Pulse)..............................500 mAReverse Voltage (I R = 100 µA).........................................................5 VOperating Temperature Range..........................................-40 to 100°CStorage Temperature.........................................................-40 to 120°CJunction Temperature.................................................................130°CSoldering Temperature..........................................260°C for 5 seconds[1.59 mm (0.06 in.) below seating plane]Notes:1. Derate linearly as shown in Figure 4.2. Any pulsed operation cannot exceed the Absolute Max Peak Forward Current or theMax Allowable Time Average Power as specified in Figure 5.3. The transient peak current is the maximum nonrecurring peak current the device canwithstand without damaging the LED die and wire bonds.4. Drive Currents between 10 and 30 mA are recommended for best long termperformance.5. Operation at currents below 10 mA is not recommended, please contact yourHewlett-Packard sales representative.Absolute Maximum Ratings at T A = 25°C (T-1 Package)DC Forward Current[1,4,5]...........................................................50 mAPeak Forward Current[2]...........................................................200 mATime Average Input Power[2]...................................................103 mWTransient Forward Current[3] (10 µs Pulse)..............................500 mAReverse Voltage (I R = 100 µA).........................................................5 VOperating Temperature Range..........................................-40 to 100°CStorage Temperature.........................................................-40 to 100°CJunction Temperature..................................................................110°CSolder Temperature................................................260°C for 5 seconds[1.59 mm (0.06 in.) below seating plane]Notes:1. Derate linearly as shown in Figure 4.2. Any pulsed operation cannot exceed the Absolute Max Peak Forward Current or theMax Allowable Time Average Power as specified in Figure 5.3. The transient peak current is the maximum nonrecurring peak current the device canwithstand without damaging the LED die and wire bonds.4. Drive Currents between 10 mA and 30 mA are recommended for best long termperformance.5. Operation at currents below 10 mA is not recommended, please contact yourHewlett-Packard sales representative.1-39Optical Characteristics at T A = 25°CTS-AlInGaP T-13/4Notes:1. The luminous intensity, I V, is measured at the peak of the spatial radiation pattern which may not be aligned with the mechanical axisof the lamp package.2. The dominant wavelength, λd, is derived from the CIE Chromaticity Diagram and represents the color of the device.3. θ1/2 is the off-axis angle where the luminous intensity is 1/2 the peak intensity.4. The luminous intensity, I v, is measured at the mechanical axis of the lamp package. The actual peak of the spatial radiation patternmay not be aligned with this axis.AS-AlInGaP T-13/4Notes:1. The luminous intensity, I V, is measured at the peak of the spatial radiation pattern which may not be aligned with the mechanical axisof the lamp package.2. The dominant wavelength, λd, is derived from the CIE Chromaticity Diagram and represents the color of the device.3. θ1/2 is the off-axis angle where the luminous intensity is 1/2 the peak intensity.4. The luminous intensity, I v, is measured at the mechanical axis of the lamp package. The actual peak of the spatial radiation patternmay not be aligned with this axis.AS-AlInGaP T-1Notes:1. The luminous intensity, I v, is measured at the mechanical axis of the lamp package. The actual peak of the spatial radiation patternmay not be aligned with this axis.2. The dominant wavelength, λd, is derived from the CIE Chromaticity Diagram and represents the color of the device.3. θ1/2 is the off-axis angle where the luminous intensity is 1/2 the peak intensity.1-401-41AS-AlInGaP T-1Speed of Forward ReverseCapacitanceResponse Voltage Breakdown C (pF)τs (ns)Part V F (Volts)V R (Volts)V F = 0,Thermal Time ConstantNumber @ I F = 20 mA @ I R = 100 µA f = 1 MHz Resistance e -t/τs HLMA-Typ. Max.Min.Typ.Typ.R θJ-PIN (°C/W)Typ.KL00 1.9 2.452540290 13KH00 1.9 2.45254029013Electrical Characteristics at T A = 25°CTS-AlInGaP T-13/4Speed of Forward ReverseCapacitanceResponse Voltage Breakdown C (pF)τs (ns)Part V F (Volts)V R (Volts)V F = 0,Thermal Time ConstantNumber @ I F = 20 mA @ I R = 100 µA f = 1 MHz Resistance e -t/τs HLMT-Typ. Max.Min.Typ.Typ.R θJ-PIN (°C/W)Typ.CL00 2.0 2.452570210 13CH00 2.0 2.45257021013DL00 2.0 2.45257026013DH00 2.0 2.45257026013AS-AlInGaP T-13/4Speed of Forward ReverseCapacitanceResponse Voltage Breakdown C (pF)τs (ns)Part V F (Volts)V R (Volts)V F = 0,Thermal Time ConstantNumber @ I F = 20 mA @ I R = 100 µA f = 1 MHz Resistance e -t/τs HLMA-Typ. Max.Min.Typ.Typ.R θJ-PIN (°C/W)Typ.CL00 1.9 2.452540210 13CH00 1.9 2.45254021013DL00 1.9 2.45254026013DH00 1.9 2.452540260 13DG00 1.9 2.452540260131-42Figure 2b. Forward Current vs.Forward Voltage, TS-AlInGaP.Figure 3. Relative Luminous Intensity vs. Forward Current. Derating Based on T J MAX.Figure 4a. Maximum DC Current vs.Ambient Temperature for AS T-13/4Lamps. Derating Based on T J MAX =130°C.T A – AMBIENT TEMPERATURE – °C0I F – F O R W A R D C U R R E N T – m A10203040502040608010012014060T A – AMBIENT TEMPERATURE – °C0I F – F O R W A R D C U R R E N T – m A10203040502040608010012014060Figure 1. Relative Intensity vs. Wavelength.WAVELENGTHR E L A T I V E I N T E N S I T Y1.00.50Figure 2a. Forward Current vs.Forward Voltage, AS-AlInGaP.I F – F O R W A R D C U R R E N T – m A1.00V F – FORWARD VOLTAGE – V2.520012080 1.52.0160 3.0402060100140180I F – F O R W A R D C U R R E N T – m A1.5V F – FORWARD VOLTAGE – V3.01006040 2.02.580 3.520103050709020T A – AMBIENT TEMPERATURE – °C 51535050304510050I F – F O R W A R D C UR R E N T – m A10204090602530407080100504020100I A V G – A V E R A G E C U R R E N T – m AI PEAK – PEAK FORWARD CURRENT – mA30Figure 4c. Maximum Forward Current vs. Ambient Temperature for T-1Lamps. Derating Based on T J Max = 110 °C.Figure 5. Maximum Average Current vs. Peak Forward Current.Figure 4b. Maximum DC Current vs.Ambient Temperature for TS T-13/4Lamps. Derating Based on T J MAX =130°C. 2.52.01.51.00.001050204030I F – DC 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 )0.51-43N O R M A L I Z E D I N T E N S I T Y1.00.90.80.70.60.50.40.30.20.120°16°12°8°4°0°4°8°12°16°20°θ – ANGULAR DISPLACEMENT – DEGREES18°14°10°6°2°2°6°10°14°18°Figure 6. Normalized Luminous Intensity vs. Angular Displacement,HLMT-CH00/CL00.θ – ANGULAR DISPLACEMENT – DEGREESN O R M A L I Z E D I N T E N S I T Y1.00.90.80.70.60.50.40.30.20.1100°90°80°70°60°50°40°30°20°10°0°10°20°30°40°50°60°70°80°90°100°Figure 8. Normalized Luminous Intensity vs. Angular Displacement, HLMA-KH00/-KL00.Figure 7. Normalized Luminous Intensity vs. Angular Displacement,HLMA-DG00/-DH00/-DL00.N O R M A L I Z E D I N T E N S I T Y1000θ – ANGULAR DISPLACEMENT – DEGREES80605070202018103040161412108426246810121416182090。