HLCP-J100 [AGILENT]
10-Element Bar Graph Array; 10元条形图阵列
| 型号: | HLCP-J100 |
| 厂家: | 
AGILENT TECHNOLOGIES, LTD. |
| 描述: | 10-Element Bar Graph Array |
| 文件: | 总8页 (文件大小:183K) |
| 中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
10-Element Bar Graph Array
Technical Data
HLCP-J100
HDSP-4820
HDSP-4830
HDSP-4832
Features
• Custom Multicolor Array
Capability
• Matched LEDs for Uniform
Appearance
• End Stackable
• Package Interlock Ensures
Correct Alignment
• Low Profile Package
• Rugged Construction
• Large, Easily Recognizable
Segments
• High ON-OFF Contrast,
Segment to Segment
• Wide Viewing Angle
• Categorized for Luminous
Intensity
• HDSP-4832/4836/4840/4850
Categorized for Dominant
Wavelength
Description
These 10-element LED arrays are
designed to display information
in easily recognizable bar graph
form. The packages are end
stackable and therefore capable
of displaying long strings of
information. Use of these bar
graph arrays eliminates the
alignment, intensity, and color
matching problems associated
with discrete LEDs. The HDSP-
4820/4830/4840/4850 and HLCP-
J100 each contain LEDs of one
color. The HDSP-4832/4836 are
multicolor arrays with High
Efficiency Red, Yellow, and High
Performance Green LEDs in a
single package.
CUSTOM MULTICOLOR ARRAYS
ARE AVAILABLE WITH
MINIMUM DELIVERY REQUIRE-
MENTS. CONTACT YOUR LOCAL
DISTRIBUTOR OR AGILENT
SALES OFFICE FOR DETAILS.
Package Dimensions
• HLCP-J100 Operates at Low
Current
Typical Intensity of 1.0 mcd at
1 mA Drive Current
25.40 (1.000) MAX.
0.38
(0.015)
1. DIMENSIONS IN MILLIMETERS (INCHES).
2. ALL UNTOLERANCED DIMEMSIONS FOR
REFERENCE ONLY.
3. HDSP-4832/-4836/-4840/-4850 ONLY.
10.16
(0.400)
5.08 (0.200)
MAX.
Applications
• Industrial Controls
• Instrumentation
• Office Equipment
• Computer Peripherals
• Consumer Products
2.54
(0.100)
1.52
(0.060)
6.10 ± 0.25
(0.240 ± 0.010)
LUMINOUS
INTENSITY
CATEGORY
COLOR BIN
(NOTE 3)
DATE CODE
PIN ONE
MARKING
HDSP XXXX
5.08 (0.200)
XYY
ZW
0.38
(0.015)
4.06
(0.160)
MIN.
2.54 ± 0.25
(0.100 ± 0.010)
7.62 ± 0.38
0.61
(0.024)
(0.300 ± 0.015)
2
Absolute Maximum Ratings[7]
Red
HDSP-4820
AlGaAs Red
HLCP-J100
HER
HDSP-4830
Yellow
HDSP-4840
Green
HDSP-4850
Parameter
Average Power
Dissipation per LED
(TA = 25°C)
63 mW
37 mW
87 mW
50 mW
105 mW
Peak Forward Current
per LED
DC Forward Current
per LED
150 mA[1]
30 mA[4]
45 mA[2]
15 mA[4]
90 mA[3]
30 mA[5]
60 mA[3]
20 mA[5]
90 mA[3]
30 mA[5]
Operating
Temperature Range
Storage Temperature -40°C to +85°C -55°C to +100°C
-40°C to +85°C -20°C to +100°C
-40°C to +85°C
-40°C to +85°C
-20°C to +85°C
Range
Reverse Voltage per
LED
3.0 V
5.0 V
3.0 V
Lead Soldering
Temperature
260°C for 3 seconds[8]
(1.59 mm
(1/16 inch) below
seating plane)[6]
Notes:
1. See Figure 1 to establish pulsed operating conditions. Maximum pulse width is 1.5 ms.
2. See Figure 2 to establish pulsed operating conditions. Maximum pulse width is 1.5 ms.
3. See Figure 8 to establish pulsed operating conditions. Maximum pulse width is 2 ms.
4. Derate maximum DC current for Red above T = 62°C at 0.79 mA/°C, and AlGaAs Red above T = 91°C at 0.8 mA/°C. See Figure 3.
A
A
5. Derate maximum DC current for HER above T = 48°C at 0.58 mA/°C, Yellow above TA = 70°C at 0.66 mA/°C, and Green above
A
T = 37°C at 0.48 mA/°C. See Figure 9.
A
6. Clean only in water, isopropanol, ethanol, Freon TF or TE (or equivalent), or Genesolve DI-15 (or equivalent).
7. Absolute maximum ratings for HER, Yellow, and Green elements of the multicolor arrays are identical to the HDSP-4830/4840/
4850 maximum ratings.
8. Maximum tolerable component side temperature is 134°C during solder process.
Internal Circuit Diagram
a
Pin Function
Pin
Function
1
2
20
19
18
17
16
15
14
13
12
11
b
c
d
e
1
2
Anode a
Anode b
Anode c
Anode d
Anode e
Anode f
Anode g
Anode h
Anode i
Anode j
11
12
13
14
15
16
17
18
19
20
Cathode j
Cathode i
Cathode h
Cathode g
Cathode f
Cathode e
Cathode d
Cathode c
Cathode b
Cathode a
3
3
4
5
6
4
5
f
6
g
7
7
8
h
8
i
j
9
9
10
10
3
Multicolor Array Segment Colors
HDSP-4832
HDSP-4836
Segment
Segment Color
Segment Color
a
b
c
d
e
f
g
h
i
HER
HER
HER
Yellow
Yellow
Yellow
Yellow
Green
Green
Green
HER
HER
Yellow
Yellow
Green
Green
Yellow
Yellow
HER
j
HER
Electrical/Optical Characteristics at TA = 25°C[4]
Red HDSP-4820
Parameter
Symbol Min. Typ. Max. Units
Test Conditions
Luminous Intensity per LED
(Unit Average)[1]
IV
610 1250
µcd
IF = 20 mA
Peak Wavelength
Dominant Wavelength[2]
λPEAK
λd
655
645
1.6
nm
nm
V
Forward Voltage per LED
VF
2.0
IF = 20 mA
IR = 100 µA
Reverse Voltage per LED[5]
Temperature Coefficient VF per LED
Thermal Resistance LED Junction-to-Pin
VR
∆VF/°C
RθJ-PIN
3
12
-2.0
300
V
mV/°C
°C/W/LED
AlGaAs Red HLCP-J100
Parameter
Symbol Min. Typ. Max. Units
Test Conditions
Luminous Intensity per LED
(Unit Average)[1]
IV
600 1000
µcd
IF = 1 mA
5200
IF = 20 mA Pk;
1of 4 Duty Factor
Peak Wavelength
Dominant Wavelength[2]
λPEAK
λd
645
637
1.6
nm
nm
V
Forward Voltage per LED
VF
IF = 1 mA
1.8
15
2.2
IF = 20 mA
IR = 100 µA
Reverse Voltage per LED[5]
VR
5
V
Temperature Coefficient VF per LED
Thermal Resistance LED Junction-to-Pin
∆VF/°C
RθJ-PIN
-2.0
300
mV/°C
°C/W/LED
4
High Efficiency Red HDSP-4830
Parameter
Symbol Min. Typ. Max. Units
Test Conditions
Luminous Intensity per LED
(Unit Average)[1,4]
IV
900 3500
µcd
IF = 10 mA
Peak Wavelength
Dominant Wavelength[2]
λPEAK
λd
635
626
2.1
nm
nm
V
Forward Voltage per LED
VF
2.5
IF = 20 mA
IR = 100 µA
Reverse Voltage per LED[5]
Temperature Coefficient VF per LED
Thermal Resistance LED Junction-to-Pin
VR
∆VF/°C
RθJ-PIN
3
30
-2.0
300
V
mV/°C
°C/W/LED
Yellow HDSP-4840
Parameter
Symbol Min. Typ. Max. Units
Test Conditions
Luminous Intensity per LED
(Unit Average)[1,4]
IV
600 1900
µcd
IF = 10 mA
Peak Wavelength
Dominant Wavelength[2,3]
Forward Voltage per LED
Reverse Voltage per LED[5]
Temperature Coefficient VF per LED
Thermal Resistance LED Junction-to-Pin
λPEAK
λd
583
nm
581
3
585
2.2
40
-2.0
300
592
2.5
nm
V
VF
IF = 20 mA
VR
∆VF/°C
RθJ-PIN
V
IR = 100 µA
mV/ °C
°C/W/LED
Green HDSP-4850
Parameter
Symbol Min. Typ. Max. Units
Test Conditions
Luminous Intensity per LED
(Unit Average)[1,4]
IV
600 1900
µcd
IF = 10 mA
Peak Wavelength
Dominant Wavelength[2,3]
λPEAK
λd
566
571
2.1
nm
nm
V
577
2.5
Forward Voltage per LED
VF
IF = 10 mA
IR = 100 µA
Reverse Voltage per LED[5]
Temperature Coefficient VF per LED
Thermal Resistance LED Junction-to-Pin
VR
3
50
V
∆VF/°C
RθJ-PIN
-2.0
300
mV/°C
°C/W/LED
Notes:
1. The bar graph arrays are categorized for luminous intensity. The category is designated by a letter located on the side of the
package.
2. The dominant wavelength, λd, is derived from the CIE chromaticity diagram and is that single wavelength which defines the color of
the device.
3. The HDSP-4832/-4836/-4840/-4850 bar graph arrays are categorized by dominant wavelength with the category designated by a
number adjacent to the intensity category letter. Only the yellow elements of the HDSP-4832/-4836 are categorized for color.
4. Electrical/optical characteristics of the High-Efficiency Red elements of the HDSP-4832/-4836 are identical to the HDSP-4830
characteristics. Characteristics of Yellow elements of the HDSP-4832/-4836 are identical to the HDSP-4840. Characteristics of
Green elements of the HDSP-4832/-4836 are identical to the HDSP-4850.
5. Reverse voltage per LED should be limited to 3.0 V max. for the HDSP-4820/-4830/-4840/-4850/-4832/-4836 and 5.0 V max. for
the HLCP-J100.
5
Red, AlGaAs Red
20
10
9
8
15
7
6
12.5
10 KHz
3KHz
1
KHz
300 Hz
10
OPERATION IN THIS
REGION REQUIRES
TEMPERATURE
1
KHz
5
4
OPERATION IN THIS
REGION REQUIRES
TEMPERATURE
8
6
5
DERATING OF I
MAX
DC
DERATING OF I
MAX
DC
4
3
2
3
2
1.5
1
1
DC OPERATION
DC OPERATION
1
10
100
1000
10000
1
10
100
1000
10000
t
– PULSE DURATION – µSEC
t
– PULSE DURATION – µs
P
P
Figure 1. Maximum Tolerable Peak Current vs. Pulse
Duration – Red.
Figure 2. Maximum Tolerable Peak Current vs. Pulse
Duration – AlGaAs Red.
40
160
1.2
R
= 600°C/W
θ
J-A
AlGaAs RED
RED
35
30
25
20
15
10
140
1.1
1.0
0.9
RED
RED
120
100
80
0.8
0.7
0.6
0.5
0.4
AlGaAs RED
60
40
AlGaAs RED
5
0
20
0
25 35 45 55 65 75 85 95 105
0
0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0
– FORWARD VOLTAGE – V
0
20 40 60 80 100 120 140 160
– PEAK SEGMENT CURRENT – mA
V
T
– AMBIENT TEMPERATURE – °C
I
PEAK
F
A
Figure 3. Maximum Allowable DC
Current vs. Ambient Temperature.
TJMAX = 100°C for Red and
Figure 4. Relative Efficiency
(Luminous Intensity per Unit
Current) vs. Peak Current.
Figure 5. Forward Current vs.
Forward Voltage.
TJMAX = 110°C for AlGaAs Red.
1.4
1.2
1.0
0.8
0.6
0.4
20
10
5
2
1
0.2
0
0.1
0.1 0.2
0.5
1
5
10 20
0
5
10
15
20
25
I
– FORWARD CURRENT PER SEGMENT
F
I
– FORWARD CURRENT PER SEGMENT – mA
F
Figure 6. Relative Luminous Intensity
vs. DC Forward Current – Red.
Figure 7. Relative Luminous Intensity
vs. DC Forward Current – AlGaAs.
For a Detailed Explanation on the Use of Data Sheet Information and Recommended Soldering Procedures,
See Application Note 1005.
6
HER, Yellow, Green
20
15
GREEN
12
10
OPERATION IN
THIS REGION
REQUIRES
TEMPERATURE
DERATING OF
HER
8
f - REFRESH RATE
6
YELLOW
4
I
MAX
DC
3
100 Hz
2
1.5
1
DC OPERATION
1
10
100
1000
10000
t
– PULSE DURATION – µSEC
P
Figure 8. Maximum Tolerable Peak Current vs. Pulse Duration –
HER/Yellow/Green.
1.6
40
35
30
25
R
= 600°C/W
θ
J-A
1.5
1.4
YELLOW SERIES
HER SERIES
GREEN/HER
GREEN
1.3
1.2
1.1
1.0
HER
GREEN SERIES
YELLOW
20
15
10
5
YELLOW
0.9
0.8
0.7
0.6
0
0
10 20 30 40 50 60 70 80 90 100
– PEAK SEGMENT CURRENT – mA
15 25 35 45 55 65 75 85 95
I
T
– AMBIENT TEMPERATURE – °C
PEAK
A
Figure 9. Maximum Allowable DC
Current vs. Ambient Temperature.
TJMAX = 100°C.
Figure 10. Relative Efficiency
(Luminous Intensity per Unit
Current) vs. Peak Current.
90
4.0
3.5
GREEN SERIES
80
70
3.0
2.5
2.0
1.5
60
YELLOW SERIES
50
40
HER
SERIES
30
1.0
0.5
0
20
10
0
1.0
2.0
3.0
4.0
5.0
0
5
10 15 20 25 30 35 40
V
– FORWARD VOLTAGE – V
I
– FORWARD CURRENT PER SEGMENT – mA
F
F
Figure 11. Forward Current vs.
Forward Voltage.
Figure 12. Relative Luminous
Intensity vs. DC Forward Current.
For a Detailed Explanation on the Use of Data Sheet Information and Recommended Soldering Procedures,
See Application Note 1005.
7
Electrical/Optical
Standard Red HDSP-4820 series
VFMAX = 1.8 V + IPeak (10 Ω)
For: IPeak ≥ 5 mA
Where:
IVAVG is the calculated time
averaged luminous intensity
resulting from IFAVG.
IFAVG is the desired time
averaged LED current.
IFAVG DATA SHEET is the data
sheet test current for IVDATA
SHEET.
ηpeak is the relative efficiency at
the peak current, scaled from
Figure 4 or 10.
IV DATA SHEET is the data sheet
luminous intensity, resulting
from IFAVG DATA SHEET.
These versatile bar graph arrays
are composed of ten light emit-
ting diodes. The light from each
LED is optically stretched to form
individual elements. The Red
(HDSP-4820) bar graph array
LEDs use a p-n junction diffused
into a GaAsP epitaxial layer on a
GaAs substrate. The AlGaAs Red
(HLCP-J100) bar graph array
LEDs use double heterojunction
AlGaAs on a GaAs substrate. HER
(HDSP-4830) and Yellow (HDSP-
4840) bar graph array LEDs use
a GaAsP epitaxial layer on a GaP
substrate. Green (HDSP-4850)
bar graph array LEDs use liquid
phase GaP epitaxial layer on a
GaP substrate. The multicolor bar
graph arrays (HDSP-4832/4836)
have HER, Yellow, and Green
LEDs in one package.
AlGaAs Red HLCP-J100 series
VFMAX = 1.8 V + IPeak (20 Ω)
For: IPeak ≤ 20 mA
VFMAX = 2.0 V + IPeak (10 Ω)
For: IPeak ≥ 20 mA
HER (HDSP-4830) and Yellow
(HDSP-4840) series
VFMAX = 1.6 + IPeak (45 Ω)
For: 5 mA ≤ IPeak ≤ 20 mA
VFMAX = 1.75 + IPeak (38 Ω)
For: IPeak ≥ 20 mA
For example, what is the
luminous intensity of an HDSP-
4830 driven at 50 mA peak 1/5
duty factor?
Green (HDSP-4850) series
VFMAX = 2.0 + IPeak (50 Ω)
For: IPeak > 5 mA
Figures 4 and 10 allow the
designer to calculate the
IFAVG = (50 mA)(0.2) = 10 mA
luminous intensity at different
peak and average currents. The
following equation calculates
intensity at different peak and
average currents:
IFAVG DATA SHEET = 10 mA
ηpeak = 1.3
IV DATA SHEET = 3500 µcd
These displays are designed for
strobed operation. The typical
forward voltage values can be
scaled from Figures 5 and 11.
These values should be used to
calculate the current limiting
resistor value and typical power
consumption. Expected maxi-
mum VF values for driver circuit
design and maximum power
dissipation may be calculated
using the VFMAX models:
Therefore
IVAVG = (IFAVG/IFAVG DATA
SHEET)ηpeak)(IVDATA
SHEET)
IVAVG = (10 mA/10 mA)
(1.3)(3500 µcd)
= 4550 µcd
www.semiconductor.agilent.com
Data subject to change.
Copyright © 1999 Agilent Technologies, Inc.
Obsoletes 5954-0869, 5954-8465
5963-7037E (11/99)
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