HP HDSP-M103-EF000 Large 5 x 7 dot matrix alphanumeric displays 17.3/26.5 mm character height Datasheet

Large 5 X 7 Dot Matrix
Alphanumeric Displays
17.3/26.5 mm Character Heights
Technical Data
Features
• Multiple Colors Available
• Large Character Height
• 5 X 7 Dot Matrix Font
• Viewable Up to 18 Meters
(26.5 mm Display)
• X-Y Stackable
• Ideal for Graphics Panels
• Available in Common Row
Anode and Common Row
Cathode Configurations
• AlGaAs Displays Suitable for
Low Power or Bright
Ambients
Typical Intensity 1650 mcd
at 2 mA Average Drive
Current
HDSP-450x Series
HDSP-510x Series
HDSP-M10x Series
• Categorized for Intensity
• Mechanically Rugged
• Green Categorized for Color
Description
The large 5 X 7 dot matrix alphanumeric display family consists of
26.5 mm (1.04 inch) and 17.3
mm (0.68 inch) character height
packages. These devices have
excellent viewability; the 26.5
mm character can be read at up
to 18 meters (12 meters for the
0.68 inch part).
The 26.5 mm font has a 10.2 mm
(0.4 inch) dual-in-line (DIP) configuration, while the 17.3 mm font
has an industry standard 7.6 mm
(0.3 inch) DIP configuration.
Applications include electronic
instrumentation, computer
peripherals, point of sale terminals, weighing scales, and industrial electronics.
Devices
AlGaAs
Red
High
Efficiency
Red
High
Performance
Green
HDSP-M101
HDSP-4501
HDSP-5101
26.5 mm Common Row Anode
HDSP-M103
HDSP-4503
HDSP-5103
26.5 mm Common Row Cathode
Description
2
Part Numbering System
HDSP - X X X X
Device Configuration/Color[1]
1: Common Row Anode
3: Common Row Cathode
Character Height/Device Configuration[1]
Refer to Respective Datasheet
Package Configuration[1]
1: 1.04 inch Character Height (for HDSP-5xxx only)
4: 0.68 inch Character Height (for HDSP-5xxx only)
5: 5 x 7 Dot Matrix
Package Type/Color[1]
5: 5 x 7 Dot Matrix
L: 17.3 mm (0.68 inch) 5 x 7 Dot Matrix
M: 26.5 mm (1.04 inch) 5 x 7 Dot Matrix
Notes:
1. For codes not listed in the figure above, please refer to the respective datasheet 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 datasheet for specific bin limit information.
3
Package Dimensions
HDSP-M10x/450x/510x Series
FUNCTION
PIN
HDSP-M101/
-4501/-5101
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
COLUMN 1 CATHODE
NO PIN
ROW 3 ANODE
COLUMN 2 CATHODE
NO PIN
ROW 5 ANODE
NO PIN
ROW 6 ANODE
ROW 7 ANODE
COLUMN 3 CATHODE
COLUMN 5 CATHODE
NO PIN
ROW 4 ANODE
NO PIN
COLUMN 4 CATHODE
ROW 2 ANODE
NO PIN
ROW 1 ANODE
HDSP-M103/
-4503/-5103
ROW 1 CATHODE
NO PIN
COLUMN 3 ANODE
ROW 3 CATHODE
NO PIN
COLUMN 1 ANODE
NO PIN
COLUMN 2 ANODE
ROW 7 CATHODE
ROW 6 CATHODE
COLUMN 4 ANODE
NO PIN
ROW 5 CATHODE
NO PIN
ROW 4 CATHODE
ROW 2 CATHODE
NO PIN
COLUMN 5 ANODE
4
Internal Circuit Diagrams
HDSP-M101/4501/5101
COMMON ANODE ROW
HDSP-M103/4503/5103
COMMON CATHODE ROW
Absolute Maximum Ratings at 25°C
Description
HDSP-M10X Series
Average Power per Dot
(TA = 25°C)[1]
HDSP-450X Series
HDSP-510X Series
75 mW
Peak Forward Current per Dot
(TA = 25°C) [1,2]
125 mA
90 mA
90 mA
Average Forward Current per Dot
(TA = 25°C) [1,3]
23 mA
15 mA
15 mA
–20°C to +85°C
–40°C to +85°C
–20°C to +85°C
Operating Temperature Range
Storage Temperature Range
Wave Soldering Temperature
(1.59 mm [0.062 in.] below Body)
–40°C to +85°C
250°C for 3 s
Notes:
1. Average power is based on 20 dots per character. Total package power dissipation should not exceed 1.5 W.
2. Do not exceed maximum average current per dot.
3. For the HDSP-L10X/M10X series displays, derate maximum average current above 35°C at 0.31 mA/°C. For the HDSP-L20X/450X
series and HDSP-540X/510X series displays, derate maximum average current above 35°C at 0.2 mA/°C. This derating is based on a
device mounted in a socket having a thermal resistance junction to ambient of 50°C/W per package.
5
Electrical/Optical Characteristics at TA = 25°C
AlGaAs Red HDSP-M10x Series
Description
Symbol
Test Conditions
Min.
Typ.
Luminous Intensity/Dot[4]
(Digit Average)
HDSP-L10x (17.3 mm)
HDSP-M10x (26.5 mm)
IV
10 mA pk: 1 of 5
Duty Factor (2 mA Avg.)
Luminous Intensity/Dot[4]
(Digit Average)
HDSP-L10x
HDSP-M10x
IV
730
760
1650
1850
µcd
1750
1980
µcd
λPEAK
645
nm
Dominant Wavelength[5]
λd
637
nm
Forward Voltage
VF
IF = 10 mA
Reverse Voltage[6]
VR
IR = 100 µA
Peak Wavelength
Temperature Coefficient of VF
Thermal Resistance LED
Junction-to-Pin per package
HDSP-L10x
HDSP-M10x
Max.
Units
30 mA pk: 1 of 14
Duty Factor (2.1 mA Avg.)
1.7
3.0
2.1
V
15.0
V
∆VF /°C
-2.0
mV/°C
RθJ-PIN
20
18
°C/W/
PACK
High Efficiency Red HDSP-450x Series
Description
Symbol
Test Conditions
Min.
Typ.
IV
50 mA pk: 1 of 5
Duty Factor (10 mA Avg.)
1150
1400
2800
3500
µcd
740
930
µcd
λPEAK
635
nm
Dominant Wavelength[5]
λd
626
nm
Forward Voltage
VF
IF = 50 mA
Reverse Voltage[6]
VR
IR = 100 µA
Intensity/Dot[4]
Luminous
(Digit Average)
HDSP-L20x (17.3 mm)
HDSP-450x (26.5 mm)
Luminous Intensity/Dot[4]
(Digit Average)
HDSP-L20x
HDSP-450x
Peak Wavelength
Temperature Coefficient of VF
Thermal Resistance LED
Junction-to-Pin per package
HDSP-L20x
HDSP-450x
IV
Max.
Units
30 mA pk: 1 of 14
Duty Factor (2.1 mA Avg.)
2.6
3.0
3.5
V
25.0
V
∆VF /°C
-2.0
mV/°C
RθJ-PIN
15
13
°C/W/
PACK
6
High Performance Green HDSP-510x Series
Description
Symbol
Test Conditions
Min.
Typ.
Luminous Intensity/Dot[4]
(Digit Average)
HDSP-540x (17.3 mm)
HDSP-510x (26.5 mm)
IV
50 mA pk: 1 of 5
Duty Factor (10 mA Avg.)
Luminous Intensity/Dot[4]
(Digit Average)
HDSP-540x
HDSP-510x
IV
1290
1540
4000
4500
µcd
570
630
µcd
λPEAK
566
nm
Dominant Wavelength[5,7]
λd
571
nm
Forward Voltage
VF
IF = 50 mA
Reverse Voltage[6]
VR
IR = 100 µA
Peak Wavelength
Temperature Coefficient of VF
Thermal Resistance LED
Junction-to-Pin per package
HDSP-540x
HDSP-510x
Max.
Units
30 mA pk: 1 of 14
Duty Factor (2.1 mA Avg.)
2.6
3.0
3.5
V
25.0
V
∆VF /°C
-2.0
mV/°C
RθJ-PIN
15
13
°C/W/
PACK
40
30
AlGaAs RED
20
HER/GREEN
10
140
1.4
120
1.2
PEAK – RELATIVE EFFICIENCY
RθJ-A = 50°C/W/PACK
100
AlGaAs RED
80
60
40
HER/GREEN
η
50
IF – FORWARD CURRENT PER DOT – mA
IF AVG. – MAXIMUM AVERAGE CURRENT – mA
Notes:
4. The displays are categorized for luminous intensity with the intensity category designated by a letter on the left hand side of the
package. The luminous intensity minimum and categories are determined by computing the numerical average of the individual dot
intensities.
5. The dominant wavelength is derived from the C.I.E. Chromaticity diagram and is that single wavelength which defines the color of the
device.
6. Typical specification for reference only. Do not exceed absolute maximum ratings.
7. The displays are categorized for dominant wavelength with the category designated by a number adjacent to the intensity category
letter.
20
0
0
-5
15
35
55
75
95
TA – AMBIENT TEMPERATURE – °C
Figure 1. Maximum Allowable Average
Current Per Dot as a Function of
Ambient Temperature.
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
VF – FORWARD VOLTAGE – V
Figure 2. Forward Current vs. Forward
Voltage.
1.0
AlGaAs RED
0.8
GREEN
0.6
HER
0.4
0.2
0
20
40
60
80
100
120
IPEAK – PEAK DOT CURRENT – mA
Figure 3. Relative Efficiency
(Luminous Intensity per Unit Dot) vs.
Peak Current per Dot.
7
Intensity Bin Limits (mcd)
IV Bin Category
E
F
G
H
I
HDSP-M10x
Min.
0.810
1.20
1.80
2.73
4.09
HDSP-450x
IV Bin Category
Min.
F
1.37
G
2.05
H
3.08
I
4.62
J
6.93
K
10.39
Max.
1.50
2.20
3.30
5.00
7.50
Max.
2.51
3.76
5.64
8.64
12.70
19.04
HDSP-510x
IV Bin Category
Min.
G
1.03
H
1.54
I
2.31
J
3.46
K
5.18
L
7.78
Max.
1.88
2.82
4.23
6.34
9.50
14.26
Color Categories
Color
Green
Bin
2
3
4
5
Dominant Wavelength (nm)
Min.
Max.
573.00
577.00
570.00
574.00
567.00
571.00
564.00
568.00
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.
Operational Considerations
Electrical Description
These display devices are composed of light emitting diodes, with
the light from each LED optically
stretched to form individual dots.
These display devices are well
suited for strobed operation. The
typical forward voltage values can
be scaled from Figure 2. These
values should be used to calculate
the current limiting resistor value
and the typical power dissipation.
Expected maximum VF values, for
driver circuit design and maximum
power dissipation, may be
calculated using the following
VFMAX models:
IVAVG is the calculated time
averaged luminous intensity
resulting from IFAVG.
For example, what is the luminous
intensity of an AlGaAs Red (HDSPL10X) driven at 50 mA peak 1/5
duty factor?
IFAVG = 50 mA * 0.2 = 10 mA
IFAVG DATA SHEET = 2 mA
ηPEAK = 0.98
IV DATA SHEET = 1650 µcd
Therefore
IVAVG = (10 mA/2 mA)(0.98)
(1650 µcd) = 8085 µcd
Thermal Considerations
AlGaAs Red
(HDSP-M10x):
VFMAX = 1.8 V + IPEAK(20 Ω)
For IPEAK ≤ 20 mA
VFMAX = 2.0 V + IPEAK(10 Ω)
For IPEAK ≥ 20 mA
HER (HDSP-450x):
VFMAX = 1.75 V + IPEAK(35 Ω)
For IPEAK ≥ 5 mA
Green (HDSP-510x):
VFMAX = 1.75 V + IPEAK(38 Ω)
For IPEAK ≥ 5 mA
Figure 3 allows the designer to
calculate the luminous intensity at
different peak and average
currents. The following equation
calculates intensity at different
peak and average currents:
IVAVG = (IFAVG/IFAVG DATA
SHEET)(ηPEAK)(IV DATA SHEET)
Where:
IFAVG is the desired time averaged
LED current.
IFAVG DATA SHEET is the time
averaged data sheet test current
for IVDATA SHEET.
ηPEAK is the relative efficiency at
the peak current, scaled from
Figure 3.
IV DATA SHEET is the time
averaged data sheet luminous
intensity, resulting from IFAVG
DATA SHEET.
The device thermal resistance may
be used to calculate the junction
temperature of the central LED.
The equation below calculates the
junction temperature of the central
(hottest) LED.
TJ = TA + (PD)(RθJ-A)(N)
PD = (VFMAX)(IFAVG)
RθJ-A = RθJ-PIN+ RθPIN-A
TJ is the junction temperature of
the central LED.
TA is the ambient temperature.
PD is the power dissipated by one
LED.
N is the number of LEDs ON per
character.
VFMAX is calculated using the
appropriate VF model.
RθJ-A is the package thermal
resistance from the central LED
to the ambient.
RθJ-PIN is the package thermal
resistance from the central LED
to pin.
RθPIN-A is the package thermal
resistance from the pin to the
ambient.
For example, what is the maximum
ambient temperature an HDSPL10X can operate with the
following conditions:
IPEAK = 125 mA
IFAVG = 10 mA
RθJ-A = 50°C/W
N = 35
TJMAX = 110°C
VFMAX = 2.0 V + (0.125 A)(10)
= 3.25 V
PD = (3.25 V)(0.01 A)
= 0.0325 W
TA = 110°C –
(50°C/W)(0.0325 W)(35)
= 53°C
The maximum number of dots ON
for the ASCII character set is 20.
What is the maximum ambient
temperature an HDSP-L10X can
operate with the following
conditions:
IPEAK = 125 mA
IFAVG = 10 mA
RθJ-A = 50°C/W
N = 20
TJMAX = 110°C
VFMAX = 3.25 V
PD = 0.0325 W
TA = 110°C –
(50°C/W)(0.0325 W)(20)
= 77°C
Therefore, the maximum ambient
temperature can be increased by
reducing the average number of
dots ON from 35 to 20 dots ON per
display.
Contrast Enhancement
For information on contrast
enhancement, please see
Application Note 1015.
Soldering/Cleaning
For Soldering/Cleaning information
on soldering LEDs, please refer to
Application Note 1027.
For product information and a complete list of
Agilent contacts and distributors, please go to
our web site.
www.agilent.com/semiconductors
E-mail: [email protected]
Data subject to change.
Copyright © 2004 Agilent Technologies, Inc.
Obsoletes 5988-2224EN
July 8, 2004
5988-5215EN
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