Features
Subminiature at top package
ideal for backlighting and light piping applications
Subminiature dome package
di used dome for wide viewing angle
nondi used dome for high brightness
TTL and LSTTL compatible 5 volt resistor lamps
Available in six colors
Ideal for space limited applications
Axial leads
Available with lead con gurations for surface mount
and through hole PC board mounting
Description
Flat Top Package
The HLMP-Pxxx Series  at top lamps use an untinted, non-
di used, truncated lens to provide a wide radiation pat-
tern that is necessary for use in backlighting applications.
The  at top lamps are also ideal for use as emitters in light
pipe applications.
Dome Packages
The HLMP-6xxx Series dome lamps for use as indicators
use a tinted, di used lens to provide a wide viewing angle
with a high on-o contrast ratio. High brightness lamps
use an untinted, nondi used lens to provide a high lumi-
nous intensity within a narrow radiation pattern.
Resistor Lamps
The 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 Con gurations
All of these devices are made by encapsulating LED chips
on axial lead frames to form molded epoxy subminiature
lamp packages. A variety of package con guration op-
tions is avail able. These include special sur face mount
lead con gura tions, gull wing, yoke lead or Z-bend. Right
angle lead bends at 2.54 mm (0.100 inch) and 5.08 mm
(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 Series, HLMP-70xx Series
Subminiature LED Lamps
Data Sheet
2
Device Selection Guide
Part Number: HLMP-xxxx
DH AS High High Device
Standard AlGaAs E ciency Perf. Emerald Outline
Red Red Red Orange Yellow Green Green Device Description[1] Drawing
P005 P105 P205 P405 P305 P505 P605 Untinted, Nondi used, A
Flat Top
P102 P202 P402 P302 P502 Untinted, Di used, Flat Top A
6000 Q100 6300 Q400 6400 6500 Q600 Tinted, Di used B
Q105 6305 Q405 6405 6505 Q605 Untinted, Nondi used, B
High Brightness
Q150 7000 7019 7040 Tinted, Di used, Low Current B
Q155 Nondi used, Low Current B
6600 6700 6800 Tinted, Di used, Resistor, B
5 V, 10 mA
6620 6720 6820 Di used, Resistor, 5 V, 4 mA B
Ordering Information
HLMX-XXXX-X X X X X
4 x 4 Prod.
Part Number
Min. Iv Bin
Max. Iv Bin
Color Bin
Selection
Packaging
Option
3
0.50 (0.020) REF.
0.94
1.24
(0.037)
(0.049)
2.92 (0.115)
MAX.
0.76
0.89
(0.030)
(0.035) R.
0.63
0.38
(0.025)
(0.015)
2.03 (0.080)
1.78 (0.070)
0.79 (0.031)
0.53 (0.021)
0.46
0.56
(0.018)
(0.022)
0.25 (0.010) MAX.
NOTE 2
0.20 (0.008) MAX.
CATHODE
1.65
1.91
(0.065)
(0.075) DIA.
ANODE
11.68
10.67
(0.460)
(0.420)
BOTH SIDES
0.18
0.23
(0.007)
(0.009)
2.08
2.34
(0.082)
(0.092)
CATHODE
STRIPE
2.21
1.96
(0.087)
(0.077)
(B) Di used and Nondi used
Figure 1. Proper right angle mounting to a PC board to prevent protruding cathode tab from shorting to anode connection.
Package Dimensions
(A) Flat Top Lamps
NO. ANODE DOWN. YES. CATHODE DOWN.
CATHODE
TAB
NOTES:
1. ALL DIMENSIONS ARE IN MILLIMETRES (INCHES).
2. PROTRUDING SUPPORT TAB IS CONNECTED TO CATHODE LEAD.
3. LEAD POLARITY FOR AlGaAs LAMPS IS OPPOSITE TO THE LEAD
POLARITY OF SUBMINIATURE LAMPS USING OTHER TECHNOLOGIES.
0.46
0.56
(0.018)
(0.022)
1.40
1.65
(0.055)
(0.065)
0.25 (0.010) MAX.
NOTE 2
0.20 (0.008) MAX.
0.50 (0.020) REF.
CATHODE
1.65
1.91
(0.065)
(0.075) DIA.
ANODE
11.68
10.67
(0.460)
(0.420)
BOTH SIDES
1.14
1.40
(0.045)
(0.055) 0.63
0.38
(0.025)
(0.015)
2.21
1.96
(0.087)
(0.077)
0.18
0.23
(0.007)
(0.009)
0.79 (0.031) MAX.
2.44
1.88
(0.096)
(0.074)
2.08
2.34
(0.082)
(0.092)
CATHODE
STRIPE
4
Absolute Maximum Ratings at TA = 25°C
DH AS High
Standard AlGaAs E . High Perf. Emerald
Parameter Red Red Red Orange Yellow Green Green Units
DC Forward Current[1] 50 30 30 30 20 30 30 mA
Peak Forward Current[2] 1000 300 90 90 60 90 90 mA
DC Forward Voltage 6 6 6 6 V
(Resistor Lamps Only)
Reverse Voltage (IR = 100 μA) 5 5 5 5 5 5 5 V
Transient Forward Current[3] 2000 500 500 500 500 500 500 mA
(10 μs Pulse)
Operating Temperature Range:
Non-Resistor Lamps -55 to +100 -40 to +100 55 to +100 -40 to +100 -20 to +100 °C
Resistor Lamps -40 to +85 -20 to +85
Storage Temperature Range -55 to +100 °C
For Thru Hole Devices 260°C for 5 seconds
Wave Soldering Temperature
[1.6 mm (0.063 in.) from body]
For Surface Mount Devices: 260°C for 20 seconds
Re ow Soldering Temperature
Notes:
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.
5
Electrical/Optical Characteristics, TA = 25°C
Standard Red
Device
HLMP- Parameter Symbol Min. Typ. Max. Units Test Conditions
6000-E00xx 0.63 1.2
6000-G00xx Luminous Intensity[1] I
V 1.60 3.2 mcd IF = 10 mA
P005-F00xx 1.0 2.5
Forward Voltage VF 1.4 1.6 2.0 V IF = 10 mA
All Reverse Breakdown VR 5.0 12.0 V IR = 100 μA
Voltage
6000 Included Angle Between 21/2 90 Deg.
P005 Half Intensity Points[2] 125
Peak Wavelength PEAK 655 nm
Dominant Wavelength[3] d 640 nm
Spectral Line Half Width 1/2 24 nm
All Speed of Response s 15 ns
Capacitance C 100 pF VF = 0; f = 1 MHz
Thermal Resistance RJ-PIN 170 °C/W Junction-to-Cathode Lead
Luminous E cacy[4] v 65 lm/W
6
DH AS AlGaAs Red
Device
HLMP- Parameter Symbol Min. Typ. Max. Units Test Conditions
P102-F00xx 1.0 20.0
P105-L00xx 10.0 30.0
P105-NP000 25 80
Q100-M00xx 16 45
Q100-N00xx Luminous Intensity IV 25.0 45.0 mcd I
F = 20 mA
Q100-PQ000 40 125
Q105-P00xx 40 200
Q105-ST000 160 500
Q150-F00xx 1.0 1.8 IF = 1 mA
Q155-F00xx 1.0 4.0
Q100 Forward Voltage VF 1.8 2.2 V IF = 20 mA
Q150/Q155 1.6 1.8 IF = 1 mA
All Reverse Breakdown Voltage VR 5.0 15.0 V IR = 100 μA
P105 125
Q100/Q150 Included Angle Between 21/2 90 Deg.
Q105/Q155
Half Intensity Points[2]
28
Peak Wavelength PEAK 645 nm Measured at Peak
Dominant Wavelength[3] d 637 nm
Spectral Line Half Width 1/2 20 nm
All Speed of Response s 30 ns Exponential Time
Constant; e-t/s
Capacitance C 30 pF VF = 0; f = 1 MHz
Thermal Resistance RJ-PIN 170 °C/W Junction-to Cathode Lead
Luminous E cacy[4] v 80 lm/W
7
High E ciency Red
Device
HLMP- Parameter Symbol Min. Typ. Max. Units Test Conditions
P202-F00xx 1.0 5.0
P205-F00xx 1.0 8.0
P205-JK000 4.0 12.5 IF = 10 mA
6300-F00xx 1.0 10.0
6300-KL000 Luminous Intensity[1] I
V 6.3 20.0 mcd
6305-L00xx 10.0 40.0
7000-D00xx 0.4 1.0 IF = 2 mA
6600-G00xx 1.6 5.0 VF = 5.0 Volts
6620-F00xx 1.0 2.0
All Forward Voltage VF 1.5 1.8 3.0 V IF = 10 mA
(Nonresistor Lamps)
6600 Forward Current IF 9.6 13.0 mA VF = 5.0 V
6620 (Resistor Lamps) 3.5 5.0
All Reverse Breakdown Voltage VR 5.0 30.0 V IR = 100 μA
P205 125
6305 Included Angle Between 21/2 28 Deg.
All Di used
Half Intensity Points[2]
90
Peak Wavelength PEAK 635 nm Measured at Peak
Dominant Wavelength[3] d 626 nm
Spectral Line Half Width 1/2 40 nm
All Speed of Response s 90 ns
Capacitance C 11 pF VF = 0; f = 1 MHz
Thermal Resistance RJ-PIN 170 °C/W Junction-to-Cathode Lead
Luminous E cacy[4] v 145 lm/W
8
Orange
Device
HLMP- Parameter Symbol Min. Typ. Max. Units Test Conditions
P402-F00xx 1.0 4.0
P405-F00xx 1.0 6
P405-JK000 Luminous Intensity IV 4.0 12.5 mcd IF = 10 mA
Q400-F00xx 1.0 8
Q405-H00xx 2.5 14
All Forward Voltage VF 1.5 1.9 3.0 V IF = 10 mA
Reverse Breakdown Voltage VR 5.0 30.0 V IR = 100 μA
P40x Included Angle Between 21/2 125 Deg.
Q40x Half Intensity Points[2] 90
Peak Wavelength PEAK 600 nm
Dominant Wavelength[3] d 602 nm Measured at Peak
Spectral Line Half Width 1/2 40 nm
All Speed of Response s 260 ns
Capacitance C 4 pF VF = 0; f = 1 MHz
Thermal Resistance RJ-PIN 170 °C/W Junction-to-Cathode Lead
Luminous E cacy[4] v 380 lm/W
9
Yellow
Device
HLMP- Parameter Symbol Min. Typ. Max. Units Test Conditions
P302-F00xx 1.0 3.0
P305-F00xx 1.0 4.0
6400-F00xx 1.0 9.0
6400-JK000 4.0 12.5 IF = 10 mA
6405-J00xx Luminous Intensity[1] I
V 3.6 20 mcd
6405-MN0xx 16 50
7019-D00xx 0.4 0.6 IF = 2 mA
6700-G00xx 1.4 5.0 VF = 5.0 Volts
6720-F00xx 0.9 2.0
All Forward Voltage VF 2.0 2.4 V IF = 10 mA
(Nonresistor Lamps)
6700 Forward Current IF 9.6 13.0 mA VF = 5.0 V
6720 (Resistor Lamps) 3.5 5.0
All Reverse Breakdown VR 5.0 50.0 V
Voltage
P305 Included Angle Between 125
6405 Half Intensity Points[2] 21/2 28 Deg.
All Di used 90
Peak Wavelength PEAK 583 nm Measured at Peak
Dominant Wavelength[3] d 585 nm
Spectral Line Half Width 1/2 36 nm
All Speed of Response s 90 ns
Capacitance C 15 pF VF = 0; f = 1 MHz
Thermal Resistance RJ-PIN 170 °C/W Junction-to-Cathode Lead
Luminous E cacy[4] v 500 lm/W
10
High Performance Green
Device
HLMP- Parameter Symbol Min. Typ. Max. Units Test Conditions
P502-F00xx 1.0 3.0
P505-G00xx 1.6 6.3 IF = 10 mA
6500-F00xx 1.0 7.0
6505-L00xx Luminous Intensity[1] I
v 10.0 40.0 mcd
7040-D00xx 0.4 0.6 IF = 2 mA
6800-G00xx 1.6 5.0 VF = 5.0 Volts
6820-F00xx 1.0 2.0
All Forward Voltage VF 2.1 2.7 V IF = 10 mA
(Nonresistor Lamps)
6800 Forward Current IF 9.6 13.0 mA VF = 5.0 V
6820 (Resistor Lamps) 3.5 5.0
All Reverse Breakdown Voltage VR 5.0 50.0 V IR = 100 μA
P505 Included Angle Between 125
6505 Half Intensity Points[2] 21/2 28 Deg.
All Di used 90
Peak Wavelength PEAK 565 nm
Dominant Wavelength[3] d 569 nm
Spectral Line Half Width 1/2 28 nm
All Speed of Response s 500 ns
Capacitance C 18 pF VF = 0; f = 1 MHz
Thermal Resistance RJ-PIN 170 °C/W Junction-to-Cathode Lead
Luminous E cacy[4] v 595 lm/W
Notes:
1. The luminous intensity for arrays is tested to assure a 2.1 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 Iv matching between arrays.
2. 1/2 is the o -axis angle where the luminous intensity is half the on-axis value.
3. Dominant wavelength, d, is derived from the CIE Chromaticity Diagram and represents the single wavelength that de nes the color of the
device.
4. Radiant intensity, Ie, in watts/steradian, may be calculated from the equation Ie = Iv/v, where Iv is the luminous intensity in
candelas and v is the luminous e cacy in lumens/watt.
11
Emerald Green[1]
Device
HLMP- Parameter Symbol Min. Typ. Max. Units Test Conditions
P605-F00xx 1.0 1.5
Q600-F00xx Luminous Intensity IV 1.0 1.5 mcd IF = 10 mA
Q605-F00xx 1.0 7.5
All Forward Voltage VF 2.2 3.0 V IF = 10 mA
Reverse Breakdown Voltage VR 5.0 V IR = 100 μA
P605 Included Angle Between 21/2 125 Deg.
Q60x Half Intensity Points[2] 90
Peak Wavelength PEAK 558 nm
Dominant Wavelength[3] d 560 nm Measured at Peak
Spectral Line Half Width 1/2 24 nm
P605/Q600 Speed of Response s 3100 ns
Capacitance C 35 pF VF = 0; f = 1 MHz
Thermal Resistance RJ-PIN 170 °C/W Junction-to-Cathode Lead
Luminous E cacy[4] V 656 lm/W
Note:
1. Please refer to Application Note 1061 for information comparing standard green and emerald green light output degradation.
12
Standard Red, DH As AlGaAs Red
Standard Red and DH AS
AlGaAs Red
High E ciency Red, Orange, Yellow, High
Performance Green, and Emerald Green
HER, Orange, Yellow, and
High Performance Green,
and Emerald Green
Low Current
Figure 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).
FORWARD CURRENT – mA
100
0
FORWARD VOLTAGE – V
80
60
50
70
20
0
10
30
40
0.5 1 1.5 2 2.5 3 3.5
90
HIGH
PERFORMANCE
GREEN,
EMERALD
GREEN
YELLOW
HIGH EFFICIENCY
RED/ORANGE
13
Figure 4. Relative e ciency (luminous intensity per unit current) vs. peak current (non-resistor lamps).
Figure 5. Maximum forward dc current vs. ambient temperature. Derating based on TJ MAX = 110°C (non-resistor lamps).
Figure 6. Maximum tolerable peak current vs. pulse duration (IDC MAX as per MAX ratings) (non-resistor lamps).
Standard Red
DH As AlGaAs RedStandard Red
HER, Orange, Yellow, and High Performance
Green DH As AlGaAs Red
HER, Orange, Yellow, and
High Performance Green,
and Emerald Green
14
Figure 9. Relative intensity vs. angular displacement.
Figure 7. Resistor lamp forward current vs. forward voltage. Figure 8. Resistor lamp luminous intensity vs. forward voltage.
15
Intensity Bin Limits
Bin Min. Max.
A 0.10 0.20
B 0.16 0.32
C 0.25 0.50
D 0.40 0.80
E 0.63 1.25
F 1.00 2.00
G 1.60 3.20
H 2.50 5.00
J 4.00 8.00
K 6.30 12.50
L 10.00 20.00
M 16.00 32.00
N 25.00 50.00
P 40.00 80.00
Q 63.00 125.00
R 100.00 200.00
S 160.00 320.00
T 250.00 500.00
U 400.00 800.00
V 630.00 1250.00
W 1000.00 2000.00
X 1600.00 3200.00
Y 2500.00 5000.00
Color Bin Limits
Package Bin Min. Max.
Emerald Green 0 Full Distribution
9 552 556
8 555 559
7 558 562
6 561 565
Green 0 Full Distribution
6 561 565
5 564 568
4 567 571
3 570 574
2 573 577
Yellow 0 Full Distribution
1 581.5 585.0
3 584.0 587.5
2 586.5 590.0
4 589.0 592.5
5 591.5 593.5
6 591.5 595.0
7 594.0 597.5
Orange 0 Full Distribution
1 596.5 600.0
2 599.0 602.5
3 601.5 604.0
4 603.8 608.2
5 606.8 611.2
6 609.8 614.2
7 612.8 617.2
8 615.8 620.2
Ordering Information
HLMx-XXXX-X X X X X
4 x 4 Prod.
Part
Number
Min. Iv Bin
Max. Iv Bin
Color Bin
Selection
Packaging
Option
Mechanical Option
00 Straight Leads, Bulk Packaging, Quantity of 500 Parts
10 Right Angle Housing, Bulk Packaging, Quantity of 500 Parts
11 Gull Wing Leads, 12 mm Tape on 7 in. Dia. Reel, 1500 Parts per Reel
12 Gull Wing Lead, Bulk Packaging, Quantity of 500 Parts
14 Gull Wing Leads, 12 mm Tape on 13 in. Dia. Reel, 6000 Parts per Reel
21 Yoke Leads, 12 mm Tape on 7 in. Dia. Reel, 1500 Parts per Reel
22 Yoke Leads, Bulk Packaging, Quantity of 500 Parts
24 Yoke Leads, 12 mm Tape on 13 in. Dia. Reel, 6000 Parts per Reel
31 Z-Bend Leads, 12 mm Tape on 7 in. Dia. Reel, 1500 Parts per Reel
32 Z-Bend Leads, Bulk Packaging, Quantity of 500 Parts
34 Z-Bend Leads, 12 mm Tape on 13 in. Dia. Reel, 6000 Parts per Reel
1L 2.54 mm (0.100 inch) Center Lead Spacing, Long Leads; 10.4 mm (0.410 in.)
1S 2.54 mm (0.100 inch) Center Lead Spacing, Short Leads; 3.7 mm (0.145 in.)
2L 5.08 mm (0.200 inch) Center Lead Spacing, Long Leads; 10.4 mm (0.410 in.)
2S 5.08 mm (0.200 inch) Center Lead Spacing, Short Leads; 3.7 mm (0.145 in.)
Note:
All Categories are established for classi cation of products. Products may not be available in all categories. Please contact your local Avago represen-
tative for further clari cation/information.
For product information and a complete list of distributors, please go to our web site: www.avagotech.com
Avago, Avago Technologies, and the A logo are trademarks of Avago Technologies in the United States and other countries.
Data subject to change. Copyright © 2005-2012 Avago Technologies. All rights reserved. Obsoletes 5989-1708EN
AV02-3609EN - June 12, 2012