H Surface Mount LED Indicator Technical Data HSMD-TX HSME-TX HSMG-TX HSMH-TX HSMS-TX HSMY-TX Feature Compatible with Automatic Placement Equipment Compatible with Infrared and Vapor Phae Reflow Solder Procee Packaged in 12 mm or 8 mm tape on 7" or 13" Diameter Reel EIA Standard Package Low Package Profile Nondiffued Package Excellent for Backlighting and Coupling to Light Pipe Device Selection Guide Decription Thee olid tate urface mount indicator are deigned with a flat top and ide to be eaily handled by automatic placement equipment. A glue pad i provided for adheive mounting procee. They are compatible with convective IR and vapor phae reflow oldering and conductive epoxy attachment procee. The package ize and configuration conform to the EIA-535 BAAC tandard pecification for cae ize 3528 tantalum capacitor. The folded lead permit dene placement and provide an external older joint for eae of inpection. Thee device are nondiffued, providing high intenity for application uch a backlighting, light pipe illumination, and front panel indication. DH AS High High AlGaA Efficiency Performance Emerald Red Red Orange Yellow Green Green HSMH- HSMS- HSMD- HSMY- HSMG- HSME- Decription T4 T4 T4 T4 T4 T4 12 mm Tape, 7" Reel, 2 Device T5 T5 T5 T5 T5 T5 12 mm Tape, 13" Reel, 8 Device T6 T6 T6 T6 T6 T6 8 mm Tape, 7" Reel, 2 Device T7 T7 T7 T7 T7 T7 8 mm Tape, 13" Reel, 8 Device 1-24 5964-9359E
Package Dimenion 3.5 ±.2 (.138 ±.8) 2.8 ±.2 (.11 ±.8) 2.2 (.87) NOM. 2.7 (.16) NOM. NOTES: 1. ALL DIMENSIONS ARE IN MILLIMETERS (INCHES). 2. THE LEADS ARE COPPER ALLOY, 85% Sn/15% Pb PLATING. CATHODE NOTCH 3.1 (.122) NOM..7 (.28) MIN. 1.9 ±.2 (.75 ±.8).1 (.4) NOM..8 ±.3 (.31 ±.12) (2 PLACES) 1.3 (.5) MIN. Tape and Reel Specification Hewlett Packard urface mount LED are packaged tape and reel in accordance with EIA-481A, Taping of Surface Mount 2.2 ±.1 (.87 ±.4) Component for Automatic Placement. Thi packaging ytem i compatible with tapefed automatic pick and place ytem. Each reel i ealed in a vapor barrier bag for added protection. Bulk packaging in vapor barrier bag i available upon pecial requet. USER FEED DIRECTION CATHODE PITCH: 4 mm (.157 IN.) hp HEWLETT PACKARD REEL DIAMETER: 178 mm (7 IN.) OR 33 mm (13 IN.) CARRIER TAPE WIDTH: 12 mm (.472 IN.) OR 8 mm (.315 IN.) 1-25
Abolute Maximum Rating at T A = 25 C DH AS High High AlGaA Efficiency Perf. Emerald Parameter Red Red Orange Yellow Green Green Unit DC Forward 3 3 3 3 3 3 ma Current [1] Peak Forward 3 9 9 6 9 9 ma Current [2] Average 2 25 25 2 25 25 ma Forward Current [2] LED Junction 95 C Temperature Tranient Forward Current [3] (1 µ Pule) 5 ma Revere Voltage 5 V (I R = 1 ma) Operating -4 to +85-2 to +85 C Temperature Range Storage -4 to +85 C Temperature Range Reflow Soldering Temperature Convective IR 235 C Peak, above 185 C for 9 econd. Vapor Phae 215 C for 3 minute. Note: 1. Derate dc current linearly from 5 C: For AlGaA red, high efficiency red, and green device at.67 ma/ C. For yellow device at.44 ma/ C. 2. Refer to Figure 5 howing Maximum Tolerable Peak Current v. Pule duration to etablih puled operating condition. 3. The tranient peak current i the maximum non-recurring peak current the device can withtand without damaging the LED die and wire bond. The device hould not be operated at peak current above the Abolute Maximum Peak Forward Current. 1-26
Electrical/Optical Characteritic at T A = 25 C DH AS AlGaA Red HSMH-TX Parameter Symbol Min. Typ. Max. Unit Tet Condition Luminou Intenity I v 9. 17. mcd I F = 1 ma Forward Voltage V F 1.8 2.2 V I F = 1 ma Revere Breakdown Voltage V R 5. 15. V I R = 1 µa Half Intenity Point [1] 2θ 1/2 12 deg. Peak Wavelength λ PEAK 645 nm Dominant Wavelength [2] λ d 637 nm Spectral Line Half Width λ 1/2 2 nm Speed of Repone τ 3 n Time Contant, e -t/τ Capacitance C 3 pf V F =, f = 1 MHz Thermal Reitance Rθ J-pin 18 C/W Junction-to-Cathode Luminou Efficacy [3] η v 8 lm/w High Efficiency Red HSMS-TX Parameter Symbol Min. Typ. Max. Unit Tet Condition Luminou Intenity I v 2. 6. mcd I F = 1 ma Forward Voltage V F 1.9 2.5 V I F = 1 ma Revere Breakdown Voltage V R 5. 3. V I R = 1 µa Half Intenity Point [1] 2θ 1/2 12 deg. Peak Wavelength λ PEAK 635 nm Dominant Wavelength [2] λ d 626 nm Spectral Line Half Width λ 1/2 4 nm Speed of Repone τ 9 n Time Contant, e -t/τ Capacitance C 11 pf V F =, f = 1 MHz Thermal Reitance Rθ J-pin 16 C/W Junction-to-Cathode Luminou Efficacy [3] η v 145 lm/w Note: 1. θ 1/2 i the off-axi angle where the luminou intenity i half the on-axi value. 2. The dominant wavelength, λ d, i derived from the CIE Chromaticity Diagram and repreent the color of the device. 3. The radiant intenity, I e, in watt per teradian, may be found from the equation I e = I v / η v, where I v i the luminou intenity in candela and η v i luminou efficacy in lumen/watt. 1-27
Orange HSMD-TX Parameter Symbol Min. Typ. Max. Unit Tet Condition Luminou Intenity I v 1.5 5. mcd I F = 1 ma Forward Voltage V F 1.9 2.5 V I F = 1 ma Revere Breakdown Voltage V R 5. 3. V I R = 1 µa Half Intenity Point [1] 2θ 1 /2 12 deg. Peak Wavelength λ PEAK 6 nm Dominant Wavelength [2] λ d 62 nm Spectral Line Half Width λ 1/2 4 nm Speed of Repone τ 26 n Time Contant, e -t/τ Capacitance C 4 pf V F =, f = 1 MHz Thermal Reitance Rθ J-pin 16 C/W Junction-to-Cathode Luminou Efficacy [3] η v 38 lm/w Yellow HSMY-TX Parameter Symbol Min. Typ. Max. Unit Tet Condition Luminou Intenity I v 2. 5. mcd I F = 1 ma Forward Voltage V F 2. 2.5 V I F = 1 ma Revere Breakdown Voltage V R 5. 5. V I R = 1 µa Half Intenity Point [1] 2θ 1 /2 12 deg. Peak Wavelength λ PEAK 583 nm Dominant Wavelength [2] λ d 585 nm Spectral Line Half Width λ 1/2 36 nm Speed of Repone τ 9 n Time Contant, e -t/τ Capacitance C 15 pf V F =, f = 1 MHz Thermal Reitance Rθ J-pin 16 C/W Junction-to-Cathode Luminou Efficacy [3] η v 5 lm/w Note: 1. θ 1 /2 i the off-axi angle where the luminou intenity i half the on-axi value. 2. The dominant wavelength, λ d, i derived from the CIE Chromaticity Diagram and repreent the color of the device. 3. The radiant intenity, I e, in watt per teradian, may be found from the equation I e = I v / η v, where I v i the luminou intenity in candela and η v i luminou efficacy in lumen/watt. 1-28
High Performance Green HSMG-TX Parameter Symbol Min. Typ. Max. Unit Tet Condition Luminou Intenity I v 4. 1. mcd I F = 1 ma Forward Voltage V F 2. 2.5 V I F = 1 ma Revere Breakdown Voltage V R 5. 5. V I R = 1 µa Half Intenity Point [1] 2θ 1 /2 12 deg. Peak Wavelength λ PEAK 57 nm Dominant Wavelength [2] λ d 572 nm Spectral Line Half Width λ 1/2 28 nm Speed of Repone τ 5 n Time Contant, e -t/τ Capacitance C 18 pf V F =, f = 1 MHz Thermal Reitance Rθ J-pin 16 C/W Junction-to-Cathode Luminou Efficacy [3] η v 595 lm/w Note: 1. θ 1/2 i the off-axi angle where the luminou intenity i half the on-axi value. 2. The dominant wavelength, λ d, i derived from the CIE Chromaticity Diagram and repreent the color of the device. 3. The radiant intenity, I e, in watt per teradian, may be found from the equation I e = I v / η v, where I v i the luminou intenity in candela and η v i luminou efficacy in lumen/watt. Emerald Green HSME-TX Parameter Symbol Min. Typ. Max. Unit Tet Condition Luminou Intenity I v 1. 1.5 mcd I F = 1 ma Forward Voltage V F 2.2 2.27 V I F = 1 ma Revere Breakdown Voltage V R 5. 5. V I R = 1 µa Half Intenity Point [1] 2θ 1 /2 12 deg. Peak Wavelength λ PEAK 558 nm Dominant Wavelength [2] λ d 56 nm Spectral Line Half Width λ 1/2 28 nm Speed of Repone τ 5 n Time Contant, e -t/τ Capacitance C 52 pf V F =, f = 1 MHz Thermal Reitance Rθ J-pin 12 C/W Junction-to-Cathode Luminou Efficacy [3] η v 68 lm/w Note: 1. θ 1 /2 i the off-axi angle where the luminou intenity i half the on-axi value. 2. The dominant wavelength, λ d, i derived from the CIE Chromaticity Diagram and repreent the color of the device. 3. The radiant intenity, I e, in watt per teradian, may be found from the equation I e = I v / η v, where I v i the luminou intenity in candela and η v i luminou efficacy in lumen/watt. 4. Refer to Application Note 161 for information comparing high performance green with emerald green light output degradation. 1-29
1. EMERALD GREEN ORANGE DH AlGaA RED T = 25 C A RELATIVE INTENSITY.5 HIGH PERFORMANCE GREEN YELLOW HIGH EFFICIENCY RED 5 55 6 65 7 75 WAVELENGTH nm Figure 1. Relative Intenity v. Wavelength. DH AS AlGaA RED HER, ORANGE, YELLOW, HIGH PERFORMANCE GREEN AND EMERALD GREEN I FORWARD CURRENT ma F 3 28 26 24 22 2 18 16 14 12 1 8 6 4 2.5 1. 1.5 2. 2.5 3. I F FORWARD CURRENT ma 9 8 7 6 5 4 3 2 1 GREEN EMERALD GREEN HIGH EFFICIENCY RED, ORANGE YELLOW.5 1. 1.5 2. 2.5 3. 3.5 4. V FORWARD VOLTAGE V F V FORWARD VOLTAGE V F Figure 2. Forward Current v. Forward Voltage. DH AS AlGaA RED HER, ORANGE, YELLOW, HIGH PERFORMANCE GREEN AND EMERALD GREEN 3. 4. RELATIVE LUMINOUS INTENSITY (NORMALIZED AT 1 ma) 2.5 2. 1.5 1..5 RELATIVE LUMINOUS INTENSITY (NORMALIZED AT 1mA) 3. 2. 1. GREEN EMERALD GREEN YELLOW HIGH EFFICIENCY RED, ORANGE. 5 1 15 2 25 3 I F DC FORWARD CURRENT ma. 5 1 15 2 25 3 I DC FORWARD CURRENT ma F Figure 3. Relative Luminou Intenity v. Forward Current. 1-21
HER, ORANGE, YELLOW, HIGH PERFORMANCE GREEN AND EMERALD GREEN η v RELATIVE EFFICIENCY (NORMALIZED AT 1 ma) 1.5 1.4 1.3 1.2 1.1 1..9.8.7.6.5.4.3.2.1 YELLOW GREEN HIGH EFFICIENCY RED, ORANGE EMERALD GREEN 1 2 3 4 5 6 7 8 9 I PEAK PEAK FORWARD CURRENT ma Figure 4. Relative Efficiency (Luminou Intenity per Unit Current) v. Peak Current. HER, ORANGE, YELLOW, HIGH PERFORMANCE GREEN AND EMERALD GREEN Figure 5. Maximum Tolerable Peak Current v. Pule Duration (I DC MAX per MAX Rating). Figure 6. Relative Intenity v. Angular Diplacement. 1-211