HLMP-6505 [AGILENT]
Subminiature LED Lamps; 超小型LED灯
| 型号: | HLMP-6505 |
| 厂家: | 
AGILENT TECHNOLOGIES, LTD. |
| 描述: | Subminiature LED Lamps |
| 文件: | 总14页 (文件大小:241K) |
| 中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
H
Subminiature LED Lamps
Technical Data
HLMP-PXXX Series
HLMP-QXXX Series
HLMP-6XXX Series
HLMP-70XX Series
Features
Dome Packages
• Subminiature Flat Top
Package
The 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 an
untinted, nondiffused lens to
provide a high luminous
intensity within a narrow
radiation pattern.
Ideal for Backlighting and
Light Piping Applications
• Subminiature Dome
Package
Diffused Dome for Wide
Viewing Angle
Nondiffused Dome for High
Brightness
• Arrays
Arrays
• TTL and LSTTL
Compatible 5 Volt Resistor
Lamps
• Available in Six Colors
• Ideal for Space Limited
Applications
The HLMP-66XX Series
subminiature lamp arrays are
available in lengths of 3 to 8
elements per array. The
luminous intensity is matched
within an array to assure a 2.1
to 1.0 ratio.
surface mount lead configura-
tions, gull wing, yoke lead or Z-
bend. Right angle lead bends at
2.54 mm (0.100 inch) and
5.08 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.
• Axial Leads
• Available with Lead
Configurations for Surface
Mount and Through Hole
PC Board Mounting
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.
Description
Flat Top Package
The HLMP-PXXX Series flat top
lamps use an untinted, non-
diffused, truncated lens to
provide 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.
Lead Configurations
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
configuration options is avail-
able. These include special
5964-9350E
1-174
Device Selection Guide
Part Number: HLMP-XXXX
DH AS
High
High
Perf. Emerald
Orange Yellow Green
Device
Outline
Standard AlGaAs Efficiency
Red
Red
Red
Green
Device Description[1] Drawing
P105
P205
P405
P402
Q400
P305
P505
P502
P605
Untinted, Nondiffused,
Flat Top
A
B
P102
P202
P302
Untinted, Diffused,
Flat Top
6000/6001
Q101
Q105
6300
6305
6400
6405
6500
6505
Q600
Tinted, Diffused
Untinted, Nondiffused,
High Brightness
Q150
Q155
7000
7019
7040
Tinted, Diffused, Low
Current
B
Nondiffused, Low
Current
6600
6620
6700
6720
6800
6820
Tinted, Diffused,
Resistor, 5 V, 10 mA
Diffused, Resistor, 5 V,
4 mA
6203
6204
6205
6206
6208
6653
6654
6655
6656
6658
6753
6754
6755
6756
6758
6853
6854
6855
6856
6858
3 Element Matched
Array,
4 Element
Tinted,
Diffused
5 Element
6 Element
8 Element
C
Package Dimensions
(A) Flat Top Lamps
NOTES:
1. ALL DIMENSIONS ARE IN MILLIMETERS (INCHES).
2. PROTRUDING SUPPORT TAB IS CONNECTED TO CATHODE LEAD.
*Refer to Figure 1 for design concerns.
1-175
Package Dimensions (cont.)
(B) Diffused and Nondiffused
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) Arrays
NOTES:
1. ALL DIMENSIONS ARE IN MILLIMETERS (INCHES).
2. PROTRUDING SUPPORT TAB IS CONNECTED TO CATHODE LEAD.
Figure 1. Proper Right Angle Mounting to a PC Board to Prevent Protruding Cathode Tab from Shorting to Anode
Connection.
1-176
Absolute Maximum Ratings at TA = 25°C
DH AS
Standard AlGaAs
High
Eff.
High
Perf. Emerald
Parameter
DC Forward Current[1]
Peak Forward Current[2]
Red
Red
Red
Orange Yellow Green Green Units
50
30
30
90
6
30
90
20
60
6
30
90
6
30
90
6
mA
mA
V
1000
300
DC Forward Voltage
(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 +85
-40 to
+100
-20 to
+100
°C
°C
Resistor Lamps
-20 to
+85
Storage Temperature Range
-55 to +100
For Thru Hole Devices
260°C for 5 Seconds
Wave Soldering Temperature
[1.6 mm (0.063 in.) from body]
For Surface Mount Devices:
Convective IR
235°C for 90 Seconds
215°C for 3 Minutes
Vapor Phase
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.
1-177
Electrical/Optical Characteristics, TA = 25°C
Standard Red
Device
HLMP-
6000
Parameter
Symbol Min. Typ. Max. Units
Test Conditions
0.5
1.3
0.5
1.2
3.2
1.2
6001
Luminous Intensity[1]
Iv
mcd IF = 10 mA
6203 to
6208
Forward Voltage
VF
VR
1.4
5.0
1.6
2.0
V
V
IF = 10 mA
All
Reverse Breakdown
Voltage
12.0
IR = 100 µA
P005
Included Angle Between
Half Intensity Points[2]
125
90
2θ1/2
Deg.
All
Others
Peak Wavelength
λPEAK
λd
655
640
24
nm
nm
nm
ns
Dominant Wavelength[3]
Spectral Line Half Width
Speed of Response
Capacitance
∆λ1/2
τs
All
15
C
100
170
pF
VF = 0; f = 1 MHz
Thermal Resistance
RθJ-PIN
°C/W Junction-to-Cathode
Lead
Luminous Efficacy[4]
ηv
65
lm/W
1-178
DH AS AlGaAs Red
Device
HLMP-
Parameter
Symbol Min. Typ. Max. Units Test Conditions
P102
P105
Q101
4.0
8.6
20.0
30.0
IF = 20 mA
22.0 45.0
22.0 55.0
Q105
Q150
Q155
Q101
Luminous Intensity
Iv
mcd
1.0
2.0
1.8
4.0
1.8
1.8
IF = 1 mA
2.2
2.2
IF = 20 mA
P205/P505 Forward Voltage
Q101/Q105
VF
VR
V
V
Q150/Q155
1.6
1.8
IF = 1 mA
All
Reverse Breakdown
Voltage
5.0
15.0
IR = 100 µA
P105
125
90
Q101/Q150 Included Angle Between
2θ1/2
Deg.
Half Intensity Points[2]
Q105/Q155
28
645
637
20
Peak Wavelength
Dominant Wavelength[3]
λPEAK
λd
nm
nm
nm
ns
Measured at Peak
Spectral Line Half Width
∆λ1/2
τs
All
Speed of Response
30
Exponential Time
Constant; e-t/τ s
Capacitance
C
30
pF
VF = 0; f = 1 MHz
Thermal Resistance
RθJ-PIN
170
°C/W Junction-to
Cathode Lead
Luminous Efficacy[4]
ηv
80
lm/W
1-179
High Efficiency Red
Device
HLMP-
P202
P205
6300
6305
7000
6600
6620
Parameter
Symbol Min. Typ. Max. Units
Test Conditions
1.0
1.0
1.0
3.4
0.4
1.3
0.8
1.0
5.0
8.0
10.0
24.0
1.0
IF = 10 mA
Luminous Intensity[1]
Iv
mcd IF = 2 mA
VF = 5.0 Volts
5.0
2.0
6653 to
6658
3.0
IF = 10 mA
IF = 10 mA
All
Forward Voltage
(Nonresistor Lamps)
VF
1.5
1.8
9.6
3.0
V
6600
13.0
5.0
Forward Current
(Resistor Lamps)
IF
mA
V
VF = 5.0 V
6620
All
3.5
Reverse Breakdown
Voltage
VR
5.0
30.0
IR = 100 µA
P205
6305
125
28
Included Angle Between
Half Intensity Points[2]
2θ1/2
Deg.
All
Diffused
90
Peak Wavelength
λPEAK
λd
635
626
40
nm
nm
nm
ns
Measured at Peak
VF = 0; f = 1 MHz
Dominant Wavelength[3]
Spectral Line Half Width
Speed of Response
Capacitance
∆λ1/2
τs
All
90
C
11
pF
Thermal Resistance
RθJ-PIN
170
°C/W Junction-to-Cathode
Lead
Luminous Efficacy[4]
ηv
145
lm/W
1-180
Orange
Device
HLMP-
Parameter
Luminous Intensity
Forward Voltage
Symbol Min. Typ. Max. Units
Test Conditions
P402
P405
Q400
1.0
1.0
1.0
1.5
5.0
4.0
6
Iv
mcd IF = 10 mA
8
VF
VR
1.9
30.0
3.0
V
V
IF = 10 mA
All
Reverse Breakdown
Voltage
IR = 100 µA
P405
Q400
Included Angle Between
Half Intensity Points[2]
125
2θ1/2
Deg.
90
600
602
40
Peak Wavelength
λPEAK
λd
nm
nm
nm
ns
Dominant Wavelength[3]
Spectral Line Half Width
Speed of Response
Capacitance
Measured at Peak
VF = 0; f = 1 MHz
∆λ1/2
τs
All
260
4
C
pF
Thermal Resistance
RθJ-PIN
170
°C/W Junction-to-Cathode
Lead
Luminous Efficacy[4]
ηv
380
lm/W
1-181
Yellow
Device
HLMP-
Parameter
Symbol Min. Typ. Max. Units
Test Conditions
P302
P305
6400
6405
7019
6700
6720
1.0
1.0
1.0
3.6
0.4
1.4
0.9
1.0
3.0
4.0
9.0
20
IF = 10 mA
Luminous Intensity[1]
Iv
mcd
0.6
5.0
2.0
3.0
IF = 2 mA
VF = 5.0 Volts
6753 to
6758
IF = 10 mA
IF = 10 mA
All
Forward Voltage
(Nonresistor Lamps)
VF
2.0
9.6
2.4
V
6700
13.0
5.0
Forward Current
(Resistor Lamps)
IF
mA
V
VF = 5.0 V
6720
All
3.5
Reverse Breakdown
Voltage
VR
5.0
50.0
P305
6405
125
28
Included Angle Between
Half Intensity Points[2]
2θ1/2
Deg.
All
Diffused
90
Peak Wavelength
λPEAK
λd
583
585
36
nm
nm
nm
ns
Measured at Peak
VF = 0; f = 1 MHz
Dominant Wavelength[3]
Spectral Line Half Width
Speed of Response
Capacitance
∆λ1/2
τs
All
90
C
15
pF
Thermal Resistance
RθJ-PIN
170
°C/W Junction-to-Cathode
Lead
Luminous Efficacy[4]
ηv
500
lm/W
1-182
High Performance Green
Device
HLMP-
P502
P505
6500
6505
7040
6800
6820
Parameter
Symbol Min. Typ. Max. Units
Test Conditions
1.0
1.0
1.0
4.2
0.4
1.6
0.8
1.0
3.0
5.0
7.0
20.0
0.6
5.0
2.0
3.0
IF = 10 mA
Luminous Intensity[1]
Iv
mcd IF = 2 mA
VF = 5.0 Volts
6853 to
6858
IF = 10 mA
IF = 10 mA
All
Forward Voltage
(Nonresistor Lamps)
VF
2.1
9.6
2.7
V
6800
13.0
5.0
Forward Current
(Resistor Lamps)
IF
mA
V
VF = 5.0 V
6820
All
3.5
Reverse Breakdown
Voltage
VR
5.0
50.0
IR = 100 µA
P505
6505
125
28
Included Angle Between
Half Intensity Points[2]
2θ1/2
Deg.
All
Diffused
90
Peak Wavelength
λPEAK
λd
565
569
28
nm
nm
nm
ns
Dominant Wavelength[3]
Spectral Line Half Width
Speed of Response
Capacitance
∆λ1/2
τs
All
500
18
C
pF
VF = 0; f = 1 MHz
Thermal Resistance
RθJ-PIN
170
°C/W Junction-to-Cathode
Lead
Luminous Efficacy[4]
ηv
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. 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, Ie, in watts/steradian, may be calculated from the equation Ie =Iv/ηv, where Iv is the luminous intensity in
candelas and ηv is the luminous efficacy in lumens/watt.
1-183
Emerald Green[1]
Device
HLMP-
Parameter
Symbol Min. Typ. Max. Units
Test Conditions
P605
Luminous Intensity
Iv
1.0
1.0
1.5
1.5
2.2
mcd IF = 10 mA
Q600
Forward Voltage
VF
VR
3.0
V
V
IF = 10 mA
Reverse Breakdown
Voltage
5.0
IR = 100 µA
P605
Q600
Included Angle Between
Half Intensity Points[2]
125
2θ1/2
Deg.
90
558
560
24
Peak Wavelength
λPEAK
λd
nm
nm
nm
ns
Dominant Wavelength[3]
Spectral Line Half Width
Speed of Response
Capacitance
Measured at Peak
VF = 0; f = 1 MHz
∆λ1/2
τs
P605/
Q600
3100
35
C
pF
Thermal Resistance
RθJ-PIN
170
°C/W Junction-to-Cathode
Lead
Luminous Efficacy[4]
ηv
656
lm/W
Note:
1. Please refer to Application Note 1061 for information comparing stnadard green and emerald green light ouptut degradation.
1-184
Figure 1. Relative Intensity vs. Wavelength.
High Efficiency Red, Orange,
Yellow, and High
Standard Red and DH AS
AlGaAs Red
Performance Green
Figure 2. Forward Current vs. Forward Voltage. (Non-Resistor Lamp)
HER, Orange, Yellow, and
High Performance Green,
and Emerald Green
Standard Red, DH As AlGaAs Red
Low Current
Figure 3. Relative Luminous Intensity vs. Forward Current. (Non-Resistor Lamp)
1-185
HER, Orange, Yellow, and
High Performance Green,
and Emerald Green
Standard Red
DH As AlGaAs Red
Figure 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 TJ MAX = 110°C
(Non-Resistor Lamps).
HER, Orange, Yellow, and High
Standard Red
Performance Green
DH As AlGaAs Red
Figure 6. Maximum Tolerable Peak Current vs. Pulse Duration. (IDC MAX as per MAX Ratings) (Non-Resistor
Lamps).
1-186
Figure 7. Resistor Lamp Forward Current vs. Forward
Voltage.
Figure 8. Resistor Lamp Luminous Intensity vs.
Forward Voltage.
Figure 9. Relative Intensity vs. Angular Displacement.
1-187
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