HP HLMA-VL00 HLMP-V100 HLMP-V500 HLMA-VH00 T-13/4 (5 mm) Wide Viewing Angle High Intensity LED Lamps Technical Data
Contents
1. E ORANGE amp AMBER 2 GREEN W H z o 3 z E RED ul gt g 7 mi W tc 20 30 40 50 60 IF FORWARD CURRENT mA Figure 3 Relative Luminous Intensity vs Forward Current 13 1 2 1 1 1 0 0 9 0 8 0 7 NORMALIZED AT 40 mA 0 6 npEAK RELATIVE EFFICIENCY 0 5 0 4 M 0 20 40 60 80 100 120 140 160 180 Ipeak PEAK FORWARD CURRENT mA Figure 4c Relative Efficiency vs Peak Forward Current HLMP V500 1 58 600 200 100 10 lp FORWARD CURRENT mA BOTH DIE POWERED SIMULTANEOUSLY 1 1 5 2 0 2 5 3 0 3 5 4 0 4 5 VF FORWARD VOLTAGE V Figure 2b Forward Current vs Forward Voltage HLMP V100 2 6 24 2 2 2 0 1 8 1 6 1 4 1 2 1 0 0 8 0 6 0 4 0 2 NORMALIZED AT 40 mA ny RELATIVE EFFICIENCY 0 0 40 80 120 160 200 240 280 320 360 400 Ipeak PEAK FORWARD CURRENT mA Figure 4a Relative Efficiency vs Peak Forward Current HLMA VL00 VH00 RO q 350 CW R6jA2480 C W F Ip FORWARD CURRENT mA BOTH DIE POWERED SIMULTANEOUSLY 0 20 40 60 80 100 TA AMBIENT TEMPERATURE C Figure 5a Maximum Forward DC Curr2. O HLMA VHOO O D ickano T 13 4 5 mm Wide Viewing Angle High Intensity LED Lamps HLMA VH00 Technical Data HLMA VLOO HLMP V100 HLMP V500 Features Description Outstanding LED Material These high intensity LED lamps Efficiency provide the user with an Extremely Wide Horizontal extremely wide 60 horizontal Viewing Angle by 30 vertical oval shaped High Light Output over a radiation pattern Available in TS Wide Range of Currents AlGaAs red AlInGaP amber Untinted Non diffused Lens M AlInGaP orange and GaP green Choice of Four Colors 644 201013 these untinted non nm Red 590 nm Amber 570 ETT 5 Ino LEDS ot Applications an excellent choice for outdoor nm Green and 615 nm applications requiring an Outdoor Message Boards ran z x i i i Orange extremely wide field of vision and Safety Lighting B upmen high brightness Changeable Message Signs Alternative to Incandescent Lamps Outline Drawing Device Selection Guide i Amber Red Orange Red Green e q 590 nm a 615 nm q 644 nm a 570 nm erd fee 9949 0 015 HLMA VLOO HLMA VH00 HLMP V100 HLMP V500 a Y 1 02 MAX 9 040 NOTE 1 20 32 0 800 MIN j ala 0 51 SQUARE 0 020 NOMINAL NOTES 2 54 0 76 Y i 1 LEAD ORIENTATION 0 100 0 030 i Ern ACE 2 54 0 25 DEVICE TYPE CENTER LEAD OUTER LEADS 10 100 5 0 019
3. HLMP V100 COMMON ANODE CATHODE 2 544 025 HLMP V500 COMMON CATHODE ANODE 0 100 0 010 HLMA VLOO COMMON CATHODE ANODE HLMA VH0O COMMON CATHODE ANODE 5 08 0 25 0 200 0 010 2 ALL DIMENSIONS ARE IN MM INCHES 5 59 0 25 0 220 0 010 1 56 5964 9292E Absolute Maximum Ratings at T 25 C Parameter HLMA VL00 HLMA VHOO HLMP V100 HLMP V500 Units DC Forward Current 1 3 60145 60145 60 50 mA Peak Forward Currenti2 3 400 400 600 180 mA Average Input Powerl 120 120 120 110 mW Reverse Voltage Ip 200 uA 5 5 5 5 V Operating Temperature Range 40 to 100 40 to 100 55 to 85 20 to 100 C Storage Temperature Range 55 to 100 55to 100 55to 100 55 to 100 C Junction Temperature 110 C Soldering Temperature 260 C for 5 seconds 1 59 mm 0 06 in below seating plane Notes 1 Derate linearly as shown in Figure 5 2 Any pulsed operation cannot exceed the Absolute Max Peak Forward Current or the Max Allowable Average Power as specified in Figure 6 3 Specified with both die powered simultaneously 4 Drive Currents between 10 mA and 30 mA are recommended for best long term performance 5 Operation at currents below 10 mA is not recommended please contact your Hewlett Packard sales representative Optical Characteristics at T 25 C Luminous Color Viewing Intensity
4. Peak Dominant Angle Luminous I med Wavelength Wavelength 201 2 Efficacy Q 40 mA peak rum Aal nm Degrees Nv Part Number Min Typ Typ Typ Im w HLMA VLOO 212 460 592 590 60 horizontal 480 HLMA VH0O 200 460 621 615 an 263 HLMP V100 500 1000 654 644 60 horizontal 85 30 vertical HLMP V500 112 270 568 570 60 horizontal 595 30 vertical Notes 1 The luminous intensity Iy is measured at the mechanical axis of the lamp package The actual peak of the spatial radiation pattern may not be aligned with this axis 2 The dominant wavelength A4 is derived from the CIE Chromaticity Diagram and represents the color of the device 3 2 01 2 is the off axis angle where the luminous intensity is 1 2 the on axis intensity Electrical Characteristics at T4 25 C Forward Reverse Capacitance Speed of Response Voltage Breakdown C F Thermal Ts ns Vr Volts Vg Volts Vr 0 Resistance Time Constant Ip 40 mA Q Ip 200 uA 1 MHz RO PIN et ts Part Number Typ Max Min Typ C W Typ HLMA VLOO 1 90 2 4 5 120 100 13 HLMA VH0O 1 90 2 4 5 120 100 13 HLMP V100 1 85 2 4 5 50 115 26 HLMP V500 2 20 3 0 5 20 100 171 400 360 320 280 240 200 160 120 80 40 IF FORWARD CURRENT mA 0 1 0 1 5 2 0 2 5 3 0 Vr FORWARD VOLTAGE V Figure 2a Forward Current vs Forward Voltage HLMA VL00 VH00
5. GULAR DISPLACEMENT DEGREES Figure 8b Relative Intensity vs Angle HLMP V100 Vertical Axis NORMALIZED LUMINOUS INTENSITY o a 100 80 60 40 20 0 20 40 60 80 100 ANGULAR DISPLACEMENT DEGREES Figure 9a Relative Intensity vs Angle HLMP V500 Horizontal Axis 1 60 NORMALIZED LUMINOUS INTENSITY o u 100 80 60 40 20 0 20 40 60 80 100 ANGULAR DISPLACEMENT DEGREES Figure 9b Relative Intensity vs Angle HLMP V500 Vertical Axis 1 61
6. LMP V500 140 120 f gt 100 Hz 100 TIME AVERAGE POWER mW BOTH DIE POWERED SIMULTANEOUSLY 20 40 80 100 TA AMBIENT TEMPERATURE C Figure 6a Maximum Allowable Average Power vs Ambient Temperature HLMA VL00 VH00 TIME AVERAGE POWER mW BOTH DIE POWERED SIMULTANEOUSLY 140 120 100 f gt 100 Hz R6jA 350 CW RO Jq 480 C W 7 85 Figure 6b Maximum Allowable Average Power vs Ambient Temperature HLMP V100 NORMALIZED LUMINOUS INTENSITY o u 40 20 0 20 40 ANGULAR DISPLACEMENT DEGREES 60 100 Figure 7a Relative Intensity vs Angle HLMA VL00 VH00 Horizontal Axis NORMALIZED LUMINOUS INTENSITY 40 20 0 20 40 ANGULAR DISPLACEMENT DEGREES 60 100 Figure 7b Relative Intensity vs Angle HLMA VL00 VH00 Vertical Axis 100 Ta AMBIENT TEMPERATURE C 1 59 NORMALIZED LUMINOUS INTENSITY o a 100 80 60 40 20 0 20 40 60 80 100 ANGULAR DISPLACEMENT DEGREES Figure 8a Relative Intensity vs Angle HLMP V100 Horizontal Axis NORMALIZED LUMINOUS INTENSITY o in 100 80 60 40 20 0 20 40 60 80 100 AN
7. ent vs Ambient Temperature HLMA VL00 VH00 200 100 10 Ir FORWARD CURRENT mA BOTH DIE POWERED SIMULTANEOUSLY 1 17 19 20 22 24 26 28 30 32 Vp FORWARD VOLTAGE V Figure 2c Forward Current vs Forward Voltage HLMP V500 1 3 1 2 1 1 1 0 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 ny RELATIVE EFFICIENCY NORMALIZED AT 40 mA 1 4 10 20 40 100 200 400 600 Ipgak PEAK FORWARD CURRENT mA Figure 4b Relative Efficiency vs Peak Forward Current HLMP V100 RO q 350 C W ROyq4 480 CW Ip FORWARD CURRENT mA BOTH DIE POWERED SIMULTANEOUSLY 0 20 40 60 80 100 85 Ta AMBIENT TEMPERATURE C Figure 5b Maximum Forward DC Current vs Ambient Temperature HLMP V100 IF FORWARD CURRENT mA BOTH DIE POWERED SIMULTANEOUSLY 0 20 40 60 80 100 Ta AMBIENT TEMPERATURE C Figure 5c Maximum Forward DC Current vs Ambient Temperature HLMP V500 140 f2100Hz 120 100 RO q 350 C W ROya 480 C W TIME AVERAGE POWER mW BOTH DIE POWERED SIMULTANEOUSLY 0 20 40 60 80 100 Ta AMBIENT TEMPERATURE C Figure 6c Maximum Allowable Average Power vs Ambient Temperature H
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