HLCP-H100-BC000 [ETC]
LED Light Bars ; LED灯条\n型号: | HLCP-H100-BC000 |
厂家: | ETC |
描述: | LED Light Bars
|
文件: | 总16页 (文件大小:417K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
LED Light Bars
HLCP-A100, -B100, -C100,
-D100, -E100, -F100, -G100,
-H100
Technical Data
HLMP-2300, -2350, -2400,
-2450, -2500, -2550, -2600,
-2620, -2635, -2655, -2670,
-2685, -2700, -2720, -2735,
-2755, -2770, -2785, -2800,
-2820, -2835, -2855, -2870,
-2885, -2950, -2965
Features
Description
• Large Bright, Uniform Light
Emitting Areas
The HLCP-X100 and HLMP-2XXX
series light bars are rectangular
light sources designed for a
variety of applications where a
large bright source of light is
required. These light bars are
configured in single-in-line and
dual-in-line packages that contain
either single or segmented light
emitting areas. The AlGaAs Red
HLCP-X100 series LEDs use
double heterojunction AlGaAs on
a GaAs substrate. The HER
HLMP-2300/2600 and Yellow
HLMP-2400/2700 series LEDs
have their p-n junctions diffused
into a GaAsP epitaxial layer on a
GaP substrate. The Green HLMP-
2500/2800 series LEDs use a
liquid phase GaP epitaxial layer
on a GaP substrate. The bicolor
HLMP-2900 series use a
• Choice of Colors
• Categorized for Light Output
• Yellow and Green
Categorized for Dominant
Wavelength
• Excellent ON-OFF Contrast
• X-Y Stackable
• Flush Mountable
• Can be Used with Panel and
Legend Mounts
• Light Emitting Surface
Suitable for Legend
Attachment per Application
Note 1012
• HLCP-X100 Series Designed
for Low Current Operation
• Bicolor Devices Available
Applications
• Business Machine
Message Annunciators
• Telecommunications
Indicators
combination of HER/Yellow or
HER/Green LEDs.
• Front Panel Process Status
Indicators
• PC Board Identifiers
• Bar Graphs
2
Selection Guide
Light Bar Part Number
Number
of
Corresponding
Panel and
Legend Mount
Part No. HLMP-
Size of
Light Emitting Areas
Package
Outline
HLCP-
HLMP-
Light
Emitting
Areas
AlGaAs HER
Yellow
Green
A100
B100
D100
E100
F100
C100
G100
H100
2300
2350
2600
2620
2635
2655
2670
2685
2950
2965
2400
2500
8.89 mm x 3.81 mm
(.350 in. x .150 in.)
1
A
2599
2598
2898
2899
2899
2898
2899
2899
2898
2898
2450
2700
2720
2735
2755
2770
2785
2950
2550
2800
2820
2835
2855
2870
2885
19.05 mm x 3.81 mm
(.750 in. x .150 in.)
1
B
D
E
F
C
G
H
I
8.89 mm x 3.81 mm
(.350 in. x .150 in.)
2
8.89 mm x 3.81 mm
(.350 in. x .150 in.)
4
3.81 mm x 19.05 mm
(.150 in. x .750 in.)
2
8.89 mm x 8.89 mm
(.350 in. x .350 in.)
1
2
8.89 mm x 8.89 mm
(.350 in. x .350 in.)
8.89 mm x 19.05 mm
(.350 in. x .750 in.)
1
8.89 mm x 8.89 mm
(.350 in. x .350 in.)
Bicolor
Bicolor
2965
8.89 mm x 8.89 mm
(.350 in. x .350 in.)
I
3
Part Numbering System
HLCP - xx xx - xx x xx
HLMP - xx xx - xx x xx
Mechanical Options[1]
00: No mechanical option
Color Bin Options[1,2]
0: No color bin limitation
B: Color bins 2 & 3 (applicable for yellow devices only)
C: Color bins 3 & 4 only (applicable for green devices only)
Maximum Intensity Bin[1,2]
0: No maximum intensity bin limitation
Minimum Intensity Bin[1,2]
0: No minimum intensity bin limitation
Device Specific Configuration[1]
Refer to respective data sheet
Color[1]
x1: AlGaAs Red (applicable for HLCP-x100 only)
23: High Efficiency Red
24: Yellow
25: Green
26: High Efficiency Red
27: Yellow
28: Green
29: Bicolor (High Efficiency Red/Yellow) OR (High Efficiency Red/Green)
Notes:
1. For codes not listed in the figure above, please refer to the respective data sheet or contact your nearest Agilent representative
for details.
2. Bin options refer to shippable bins for a part-number. Color and Intensity Bins are typically restricted to 1 bin per tube
(exceptions may apply). Please refer to respective data sheet for specific bin limit information.
4
Package Dimensions
NOTES:
1. DIMENSIONS IN MILLIMETRES (INCHES). TOLERANCES ±0.25 mm (±0.010 IN.) UNLESS OTHERWISE INDICATED.
2. FOR YELLOW AND GREEN DEVICES ONLY.
5
Internal Circuit Diagrams
I
6
Absolute Maximum Ratings
HER
Yellow
Green
HLMP-2500/
2800/2965
Series
AlGaAs Red
HLCP-X100
Series
HLMP-2300/ HLMP-2400/
Parameter
2600/29XX
Series
2700/2950
Series
Average Power Dissipated per LED Chip
Peak Forward Current per LED Chip
Average Forward Current per LED Chip
DC Forward Current per LED Chip
Reverse Voltage per LED Chip
37 mW[1]
45 mA[4]
135 mW[2]
90 mA[5]
25 mA
85 mW[3]
60 mA[5]
20 mA
135 mW[2]
90 mA[5]
25 mA
15 mA
15 mA[1]
30 mA[2]
25 mA[3]
6 V[6]
30 mA[2]
5 V
Operating Temperature Range
–20°C to +100°C[7]
–40°C to +85°C
–20°C to +85°C
Storage Temperature Range
–40°C to +85°C
Lead Soldering Temperature 1.6 mm
(1/16 inch) Below Seating Plane3
260°C for 3 seconds[8]
Notes:
1. Derate above 87°C at 1.7 mW/°C per LED chip. For DC operation, derate above 91°C at 0.8 mA/°C.
2. Derate above 25°C at 1.8 mW/°C per LED chip. For DC operation, derate above 50°C at 0.5 mA/°C.
3. Derate above 50°C at 1.8 mW/°C per LED chip. For DC operation, derate above 60°C at 0.5 mA/°C.
4. See Figure 1 to establish pulsed operation. Maximum pulse width is 1.5 mS.
5. See Figure 6 to establish pulsed operation. Maximum pulse width is 2 mS.
6. Does not apply to bicolor parts.
7. For operation below –20°C, contact your local Agilent sales representative.
8. Maximum tolerable component side temperature is 134°C during solder process.
Electrical/Optical Characteristics at TA = 25°C
AlGaAs Red HLCP-X100 Series
Parameter
HLCP-
Symbol Min. Typ. Max. Units Test Conditions
A100/D100/E100
B100/C100/F100/G100
H100
IV
3
6
7.5
15
mcd
mcd
mcd
nm
nm
V
IF = 3 mA
Luminous Intensity
per Lighting Emitting
Area[1]
12
30
Peak Wavelength
λPEAK
λd
645
637
1.8
15
Dominant Wavelength[2]
Forward Voltage per LED
VF
2.2
IF = 20 mA
Reverse Breakdown Voltage per LED
Thermal Resistance LED Junction-to-Pin
VR
5
V
IR = 100 µA
RθJ-PIN
250
°C/W/
LED
7
High Efficiency Red HLMP-2300/2600/2900 Series
Parameter
HLMP-
2300/2600/2620
Symbol Min. Typ. Max. Units Test Conditions
IV
6
23
45
mcd
mcd
IF = 20 mA
Luminous Intensity
per Lighting Emitting
2350/2635/2655/2670/2950[3]
13
Area[1]
2965[4]
2685
19
22
45
mcd
80
mcd
nm
Peak Wavelength
λPEAK
λd
635
Dominant Wavelength[2]
Forward Voltage per LED
626
2.0
15
nm
V
VF
2.6
IF = 20 mA
Reverse Breakdown Voltage per LED[5]
Thermal Resistance LED Junction-to-Pin
VR
6
V
IR = 100 µA
RθJ-PIN
150
°C/W/
LED
Yellow HLMP-2400/2700/2950 Series
Parameter
HLMP-
2400/2700/2720
Symbol Min. Typ. Max. Units Test Conditions
IV
6
20
38
mcd
mcd
IF = 20 mA
Luminous Intensity
per Lighting Emitting
2450/2735/2755/2770/2950[3]
13
Area[1]
2785
26
70
mcd
nm
Peak Wavelength
λPEAK
λd
583
Dominant Wavelength[2]
Forward Voltage per LED
585
2.1
15
nm
V
VF
2.6
IF = 20 mA
Reverse Breakdown Voltage per LED[5]
Thermal Resistance LED Junction-to-Pin
VR
6
V
IR = 100 µA
RθJ-PIN
150
°C/W/
LED
8
High Performance Green HLMP-2500/2800/2965 Series
Parameter
HLMP-
2500/2800/2820
Symbol Min. Typ. Max. Units Test Conditions
IV
5
25
50
mcd
mcd
mcd
mcd
nm
IF = 20 mA
Luminous Intensity
per Lighting Emitting
Area[1]
2550/2835/2855/2870
11
25
22
2965[4]
2885
50
100
565
572
Peak Wavelength
λPEAK
λd
Dominant Wavelength[2]
Forward Voltage per LED
nm
VF
2.2
15
2.6
V
V
IF = 20 mA
Reverse Breakdown Voltage per LED[5]
Thermal Resistance LED Junction-to-Pin
VR
6
IR = 100 µA
RθJ-PIN
150
°C/W/
LED
Notes:
1. These devices are categorized for luminous intensity. The intensity category is designated by a letter code on the side of the package.
2. The dominant wavelength, λd, is derived from the CIE chromaticity diagram and is the single wavelength which defines the color of the
device. Yellow and Green devices are categorized for dominant wavelength with the color bin designated by a number code on the side
of the package.
3. This is an HER/Yellow bicolor light bar. HER electrical/optical characteristics are shown in the HER table. Yellow electrical/optical
characteristics are shown in the Yellow table.
4. This is an HER/Green bicolor light bar. HER electrical/optical characteristics are shown in the HER table. Green electrical/optical
characteristics are shown in the Green table.
5. Does not apply to HLMP-2950 or HLMP-2965.
9
AlGaAs Red
Figure 1. Maximum Allowable Peak Current vs. Pulse Duration.
Figure 2. Maximum Allowed DC Current per LED vs.
Ambient Temperature, TJMAX = 110°C.
Figure 3. Relative Efficiency (Luminous Intensity per Unit
Current) vs. Peak LED Current.
Figure 5. Relative Luminous Intensity vs. DC Forward
Current.
Figure 4. Forward Current vs. Forward Voltage.
10
HER, Yellow, Green
Figure 6. Maximum Allowed Peak Current vs. Pulse
Duration.
Figure 7. Maximum Allowable DC Current per LED vs.
Ambient Temperature, TJ MAX = 100°C.
Figure 8. Relative Efficiency (Luminous Intensity per Unit
Current) vs. Peak LED Current.
Figure 9. Forward Current vs. Forward Voltage
Characteristics.
Figure 10. Relative Luminous Intensity vs. DC Forward
Current.
For a detailed explanation on the use of data sheet information and recommended soldering procedures,
see Application Notes 1005, 1027, and 1031.
11
Intensity Bin Limits (mcd)
HLMP-2300/2600/2620 Annunciators (.2 x .4 HER/AlGaAs),
HLCP-A100/D100/E100
IV Bin Category
Min.
Max.
A
B
C
D
E
F
3.00
5.60
4.50
8.20
6.80
12.10
18.50
27.80
45.50
73.80
10.10
15.30
22.80
36.90
G
Notes:
1. Minimum category A for Red L/C AlGaAs (-A100/-D100/-E100).
2. Minimum category C for HER (-2300/-2600/-2620).
HLMP-2350/2635/2655/2670 Annunciators (.2 x .8 HER/AlGaAs),
HLCP-B100/C100/F100/G100 (.4 x .4 HER/AlGaAs)
IV Bin Category
Min.
5.40
Max.
10.90
16.00
24.00
36.10
54.20
88.80
143.80
A
B
C
D
E
F
9.00
13.10
19.70
29.60
44.90
71.90
G
Notes:
1. Minimum category A for Red L/C AlGaAs (-B100/-C100/-F100/-G100).
2. Minimum category C for HER (-2350/-2635/-2670).
HLMP-2685/HLCP-H100 Annunciators (.4 x .8 HER/AlGaAs)
IV Bin Category
Min.
10.80
18.00
22.00
33.30
50.00
75.10
121.70
Max.
22.00
27.10
40.80
61.10
91.80
150.00
243.40
A
B
C
D
E
F
G
Notes:
1. Minimum category A for Red L/C AlGaAs (-H100).
2. Minimum category C for HER (-2685).
12
HLMP-2400/2700/2720 Annunciators (.2 x .4 Yellow)
IV Bin Category
Min.
Max.
11.20
16.80
25.30
41.40
67.20
C
D
E
F
6.10
9.20
13.80
20.70
33.60
G
HLMP-2450/2735/2755/2770 Annunciators (.2 x .8 Yellow & .4 x .4 Yellow)
IV Bin Category
Min.
13.00
18.00
27.00
40.50
65.60
Max.
22.00
33.00
50.00
81.00
131.20
C
D
E
F
G
HLMP-2785 Annunciators (.4 x .8 Yellow)
IV Bin Category
Min.
26.00
36.00
54.00
81.00
131.40
Max.
44.40
66.00
99.00
162.00
262.80
C
D
E
F
G
HLMP-2500/2800/2820 Annunciators (.2 x .4 Yellow)
IV Bin Category
Min.
5.60
Max.
10.20
15.30
23.10
37.80
61.20
97.90
158.40
C
D
E
F
G
H
I
8.40
12.60
18.90
30.60
49.50
80.10
HLMP-2550/2835/2855/2870 Annunciators (.2 x .8/.4 x .4 Green)
IV Bin Category
Min.
11.30
17.00
25.40
38.10
61.60
99.81
161.73
Max.
20.60
31.00
46.50
76.20
123.20
197.67
320.21
C
D
E
F
G
H
I
13
HLMP-2885 Annunciators (.4 x .8 Green)
IV Bin Category
Min.
22.20
33.40
50.10
75.10
121.10
196.10
313.70
Max.
40.80
C
D
E
F
G
H
I
61.20
91.90
150.30
242.20
383.50
613.60
HLMP-2950 Bi-Color Annunciators (.4 x .4 HER/Yellow)
IV Bin Category
Min.
Red Iv Categories
11.30
Max.
C
D
E
F
20.60
31.00
46.50
76.20
123.20
17.00
25.40
38.10
G
61.60
Yellow Iv Categories
13.00
C
D
E
F
22.00
33.00
50.00
81.00
131.20
18.00
27.00
40.50
G
65.60
HLMP-2965 Bi-Color Annunciators (.4 x .4/.2 x .8 HER/Green)
IV Bin Category
Min.
Red Iv Categories
19.70
Max.
D
E
F
36.10
54.20
88.80
143.80
29.60
44.90
G
71.90
Green Iv Categories
7.50
B
C
D
E
F
13.90
20.60
31.00
46.50
76.20
123.20
200.00
11.30
17.00
25.40
38.10
61.60
G
H
100.00
Notes:
1. Minimum category D for LPE Green (-2965).
2. In green mode, the devices are to be color binned into standard color bins, per
Table 2. (-2685).
14
Color Categories
Dominant Wavelength (nm)
Color
Bin
0
1
Min.
579.0
581.5
584.0
586.5
589.0
591.5
573.00
570.00
567.00
564.00
Max.
582.5
585.0
587.5
590.0
592.5
595.0
577.00
574.00
571.00
568.00
Yellow
3
2
4
5
Green
2
3
4
5
Note:
All categories are established for classification of products. Products
may not be available in all categories. Please contact your local
Agilent representatives for further clarification/information.
15
may be calculated using the
following VFMAX models:
dissipation is the product of the
maximum forward voltage and the
maximum forward current. For
pulsed operation, the maximum
power dissipation is the product
of the maximum forward voltage
at the peak forward current times
the maximum average forward
current. Maximum allowable
power dissipation for any given
ambient temperature and thermal
resistance (RθJ-A) can be deter-
mined by using Figure 2 or 7. The
solid line in Figure 2 or 7 (RθJ-A of
600/538 C/W) represents a typical
thermal resistance of a device
socketed in a printed circuit
board. The dashed lines represent
achievable thermal resistances
that can be obtained through
improved thermal design. Once
the maximum allowable power
dissipation is determined, the
maximum pulsed or DC forward
current can be calculated.
Electrical
These light bars are composed of
two, four, or eight light emitting
diodes, with the light from each
LED optically scattered to form
an evenly illuminated light
emitting surface.
AlGaAs Red HLCP-X100 series
VFMAX = 1.8 V + IPeak (20 Ω)
For: IPeak ≤ 20 mA
VFMAX = 2.0 V + IPeak (10 Ω)
For: 20 mA ≤ IPeak ≤ 45 mA
The anode and cathode of each
LED is brought out by separate
pins. This universal pinout
arrangement allows the LEDs to
be connected in three possible
configurations: parallel, series, or
series parallel. The typical
forward voltage values can be
scaled from Figures 4 and 9.
These values should be used to
calculate the current limiting
resistor value and typical power
consumption. Expected maximum
VF values for driver circuit design
and maximum power dissipation,
HER (HLMP-2300/2600/2900),
Yellow (HLMP-2400/2700/2900)
and Green (HLMP-2500/2800/
2900) series
VFMAX = 1.6 + IPeak (50 Ω)
For: 5 mA ≤ IPeak ≤ 20 mA
VFMAX = 1.8 + IPeak (40 Ω)
For: IPeak ≥ 20 mA
The maximum power dissipation
can be calculated for any pulsed
or DC drive condition. For DC
operation, the maximum power
Optical
IAVG
Size of Light
Emitting
Area
Surface Area
Iv TIME AVG
where:
=
(ηIPEAK) (Iv Data Sheet)
[ ]
ITEST
Sq. Metres
67.74 x 10–6
33.87 x 10–6
Sq. Feet
729.16 x 10–6
364.58 x 10–6
8.89 mm x 8.89 mm
8.89 mm x 3.81 mm
ITEST = 3 mA for AlGaAs Red
(HLMP-X000 series)
20 mA for HER,
8.89 mm x 19.05 mm 135.48 x 10–6 1458.32 x 10–6
3.81 mm x 19.05 mm 72.85 x 10–6
781.25 x 10–6
Yellow and Green
(HLMP-2XXX series)
The radiation pattern for these
light bar devices is approximately
Lambertian. The luminous
sterance may be calculated using
one of the two following formulas:
Refresh rates of 1 kHz or faster
provide the most efficient
operation resulting in the maxi-
mum possible time average
luminous intensity.
Example:
For HLMP-2735 series
ηIPEAK = 1.18 at IPEAK = 48 mA
Iv (cd)
Lv (cd/m2) =
A (m2)
The time average luminous
intensity may be calculated using
the relative efficiency character-
istic of Figure 3 or 8, ηIPEAK, and
adjusted for operating ambient
temperature. The time average
luminous intensity at TA = 25°C is
calculated as follows:
12 mA
(1.18) (35 mcd)
Iv TIME AVG
=
[ ]
20 mA
π Iv (cd)
Lv (footlamberts) =
A (ft2)
= 25 mcd
The time average luminous
intensity may be adjusted for
operating ambient temperature by
the following exponential
equation:
immersion time in the vapors of
less than two (2) minutes
Mechanical
These light bar devices may be
operated in ambient temperatures
above +60°C without derating
when installed in a PC board
configuration that provides a
thermal resistance pin to ambient
value less than 280°C/W/LED. See
Figure 2 or 7 to determine the
maximum allowed thermal
resistance for the PC board,
RθPC-A, which will permit
maximum. Some suggested vapor
cleaning solvents are Freon TE,
Genesolv DES, Arklone A or K. A
60°C (140°F) water cleaning
process may also be used, which
includes a neutralizer rinse (3%
ammonia solution or equivalent),
a surfactant rinse (1% detergent
solution or equivalent), a hot
water rinse and a thorough air
dry. Room temperature cleaning
may be accomplished with Freon
T-E35 or T-P35, Ethanol,
Iv (TA) = IV (25°C)e[K (T –25°C)]
A
Color
AlGaAs Red
HER
K
–0.0095/°C
–0.0131/°C
–0.0112/°C
–0.0104/°C
nonderated operation in a given
ambient temperature.
Yellow
Green
Isopropanol or water with a mild
detergent.
To optimize device optical
performance, specially developed
plastics are used which restrict
the solvents that may be used for
cleaning. It is recommended that
only mixtures of Freon (F113)
and alcohol be used for vapor
cleaning processes, with an
Example:
Iv (80°C) = (25 mcd)e[-0.0112 (80-25)]
For further information on
soldering LEDs please refer to
Application Note 1027.
= 14 mcd.
www.semiconductor.agilent.com
Data subject to change.
Copyright © 2001 Agilent Technologies, Inc.
August 20, 2001
Obsoletes 5962-7197E (11/99)
5988-2221EN
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