ISD2013 - OSRAM OPTO SEMICONDUCTORS

4-Character 5 x 7 Dot Matrix / RoHS Compliant - By Exemption (see page 1)

Serial Input Alphanumeric Industrial Display

Sunlight Viewable: ISD235X

2006-04-04 1

ISD201X, ISD231X, ISD235X

ISD201X ISD231X ISD235X

RoHS Compliant - By ExemptionDESCRIPTION

The ISD201 X/231X/235X are four digit 5 x 7 dot matrix serial input

alphanumeric displays. The displays are available in red, yellow,

high efficiency red, or high efficiency green. The package is a

standard tw elve-pin he rmetic DIP wit h glass len s. The displa y can

be stacked horizontally or vertically to form messages of any

length.

These displays have two fourteen-bit CMOS shift registers with

built-in row drivers. These shift registers drive twenty-eight rows

and enable the design of customized fonts. Cascading multiple

displays is possibl e because of the Data In and Data O ut pins. Data

In and Out are easily input with the clock signal and displayed in

parallel on the row drivers. Data Out represents the output of the

7th bit of d igit number f our shift re gister. The sh ift register is level

triggered. The like columns of each character in a display cluster

are tied to a single pin (see Block Diagram). High true data in the

shift register enables the output current mirror driver stage

associated with each row of LEDs in the 5 x 7 diode array.

The TTL compatible VB input may either be tied to VCC for ma ximum

display intensity or pulse width modulated to achieve intensity

control and r educe power consumption.

In the normal mod e of operation, input dat a for digit four, column

one is loaded into the seven on-board shift register locations one

through seven. Column one data for di g i ts 3, 2 an d 1 i s sh if ted into

the display shift register locations. Then column one input is

enabled for an appropriate period of time, T. A similar process is

repeated for columns 2, 3, 4 and 5. If the decode time and load data

time into the shift register is t, then with five columns, each column

of the display is operating at a duty factor of:

T+t, allotted to each display column, is generally chosen to provide

the maxim um dut y f act o r co nsis te nt wi th th e m ini mum re f resh r ate

necessary to achieve a flicker free display. For most strobed

display systems, each column of the display should be refreshed

(turned on) at a minimum rate of 100 times per second.

With columns to be addressed, this refresh rate then gives a value

for the time T+t of: 1⁄ [5 x (100)]=2.0 msec. If the device is operated

at 5.0 MHz clock rate maximum, it is possible to maintain t<T. For

short display strings, the duty factor will then approach 20%.

See Appnote 44 for application information and Appnotes 18, 19,

22, 23 at www.osram-os.com

DF T

5T 1+()

---------------------=

FEATURES

• Four Dot Matrix Characters

• Character Height

ISD201X— 3.81 mm (0.150")

ISD231X— 5.08 mm (0.200")

ISD235X— 5.08 mm (0.200")

• Built-in CMOS Shift Registers with Constant Current

LED Row Drivers

• Wide Viewing Angle

• Shift Registers Allow Custom Fonts

• Easily Cascaded for Multiple Displays

• TTL Compatible

• End Stackable

• Operating Temperature Range:

–55°C to +100°C

• Categorized for Luminous Intensity

• Ceramic Package, Hermetically Sealed Flat Glass

Window

RoHS Compliance

The ISD201X, ISD231X, ISD235X Intelligent DisplaysTM are her-

metically sealed displays using a ceramic and glass construction.

These compone nts are n ot lead (Pb) free but are RoHS C omplia nt

based on the RoHS Compliance Directive's Annex, paragraphs 5

and 7. These exemption s all ow for lea d (Pb) in glass and cerami c

electronic components. Refer to the following excerpts from the

RoHS Compliance Directive Annex:

Applications of lead, mercury, cadmium and hexavalent chromium,

which are ex empted from the require m ents of Arti cle 4(1)

5. Lead in glass of cathode ray tubes, electronic components and

fluorescent tubes.

7. Lead in electronic cer amic parts (e.g. piezoelec tronic devices). .

2006-04-04 2

ISD201X, ISD231X, ISD235X

Ordering Information

Type Color of Emission Character Height

mm (inch) Ordering Code

ISD2351

ISD2352

ISD2353

yellow

high efficiency red

high efficiency green

5.08

(0.200)

Q68000A8142

Q68000A8143

Q68000A8144

ISD2010

ISD2011

ISD2012

ISD2013

red

yellow

high efficiency red

high efficiency green

3.81

(0.150)

Q68000A8134

Q68000A8135

Q68000A8136

Q68000A8137

ISD2310

ISD2311

ISD2312

ISD2313

red

yellow

high efficiency red

high efficiency green

5.08

(0.200)

Q68000A8138

Q68000A8139

Q68000A8140

Q68000A8141

Maximum Ratings

Parameter Symbol Value Unit

Operating temperature range1) Top -55 to +100 °C

Storage temperature range Tstg -65 to +125 °C

Supply voltage VCC to GND VCC -0.5 to 7.0 V

Inputs, data out and VB-0.5 to VCC +0.5 V

Column input voltage VCOL -0.5 to 6.0 V

Solder temperature

1.59 mm (0.063“) below seating plane, t < 5.0 s Ts260 °C

Allowable power dissipation, TA=25°C2)

ISD2010

ISD2011 / ISD2012 / ISD2013

ISD231X

ISD235X

Ptot

0.91

0.86

1.10

1.35

ISD201X, ISD231X, ISD235X

2006-04-04 3

Timing Characteristics4)

AC Electrical Characteristics

(VCC= 4.75 to 5.25 V, TA= –55°C to 100°C)

Symbol Description Min. Typ. Max.5) Units

TSETUP Setup Time 50 10 —ns

THOLD Hold Time 25 20 —ns

TWL Clock Width Low 75 45 —ns

TWH Clock Width High 75 45 —ns

F(CLK) Clock

Frequency ——5 MHz

TTHL

TTLH

Clock

Transition Time —75 200 ns

TPHL

TPLH

Propagation

Delay Clock to

Data Out

—50 125 ns

TWL

l/fCLOCK

TPLH, TPHL

TTHL

CLOCK

DATA IN

DATA OUT

THOLD

TSETUP

TWH

TON

TOFF

2.4 V

0.4 V

2.0 V

0.8 V

2.0 V

0.8 V

2.0 V

0.8 V

VIH

VIL

VIH

VIL

VIH

VIL

VOH

VOL

DISPLAY ON (illuminated)

OFF (not illuminated)

90%

10%

2006-04-04 4

ISD201X, ISD231X, ISD235X

ISD201X3)

Package Outlines Dimensions in mm (inch)

IDOD5004

YYWW

2.11 (0.083)

4.44 (0.175)

±0.13 (0.005)

17.75 (0.699) max.

3.7 (0.146)

7.87 (0.310)

7.37 (0.290)

marked by dot on back of package

Pin 1

5.08 (0.200)

2.54 (0.100)

6.85 (0.270)

1.27 (0.050)

12 pl. 0.51 (0.020)

±0.08 (0.003)

1.27 (0.050)

±0.13 (0.005)

2.54 (0.100) typ.

10 pl., non cum.

Hue Code

Luminous

Intensity Code

ISD201X

Part Number OSRAM

Pin 1

Indicator

Year

Work Week

0.25 (0.010) typ.

±0.05 (0.002)

7.62 (0.300)

Plane

Seating

ISD201X, ISD231X, ISD235X

2006-04-04 5

ISD231X / ISD235X3)

Package Outlines: Dimensions in mm (inch)

IDOD5005

YYWW

5.08 (0.200)

2.54 (0.100)

6.86 (0.270)

1.27 (0.050)

12 pl. 0.51 (0.020)±0.08 (0.003)

±0.13 (0.005)

2.54 (0.100)

10 pl., non cum.

Hue Code

Luminous

Intensity Code

ISD231X

Part No. OSRAM

Pin 1 indicators

dot and notch on

Year

Work Week

0.25 (0.010)±0.05 (0.002)

6.35 (0.250)

package underside

±0.25 (0.010)

Pin Function Pin Function

1 7 Data OutColumn 1 82 Column 2 B

93 Column 3

104 Column 4 Clock

115 Column 5 Ground

126 No Connection Data In

20.07 (0.790) max.

8.43 (0.332)

2.51 (0.099)

±0.13 (0.005)

32 4 5 6

±0.13 (0.005)

5 (0.197)

2.84 (0.112)

11 9 87

4.88 (0.192)

Tolerance: ±0.30 (0.015)

ISD201X, ISD231X, ISD235X

2006-04-04 6

Maximum Allowable Power Dissipation vs.

Temperature, ISD201X

Maximum Allowable Power Dissipation

vs. Temperature, ISD231X

Maximum Allowable Power Dissipation

vs. Temperature, ISD235X

IDDG5121

-60

˚C

-40 -20 0 20 40 60 80 120

jmax

= 125 ˚C

0.2

0.4

0.6

0.8

1.0

= 35 ˚C/W

= 55 ˚C/W

thJA

IDDG5122

-60

˚C

-40 -20 0 20 40 60 80 120

0.2

0.4

0.6

0.8

1.0

1.2

jmax

= 125 ˚C

thJA

= 35 ˚C/W

= 55 ˚C/W

thJA

IDDG5123

-60

˚C

-40 -20 0 20 40 60 80 120

jmax

= 125 ˚C

thJA

= 35 ˚C/W

= 55 ˚C/W

thJA

0.5

1.0

1.5

ISD201X, ISD231X, ISD235X

2006-04-04 7

Optical Characterist ics

Red ISD2010 / ISD2310

Description Symbol Min. Typ.9) Units Test Conditions

Peak Luminous Intensity per LED6) 7)

(Character Average) ISD2010 IVpeak 105 200 µcd VCC=5.0 V,

VCOL=3.5 V,

TJ=25°C 10),

VB=2.4 V

ISD2310 220 370

Peak Wavelength λVpeak —660 nm —

Dominant Wavelength 8) λdom —639 nm —

Yellow ISD2011 / ISD2311 / ISD2351

Description Symbol Min. Typ.9) Units Test Conditions

Peak Luminous Intensity per LED6) 7)

(Character Average) ISD2011 IVpeak 400 750 µcd VCC=5.0 V,

VCOL=3.5 V,

TJ=25°C 10),

VB=2.4 V

ISD2311 650 1140

ISD2351 2400 3400

Peak Wavelength λVpeak —583 nm —

Dominant Wavelength 8) λdom —585 nm —

High Efficiency Red ISD2012 / ISD2312 / IS D2352

Description Symbol Min. Typ.9) Units Test Conditions

Peak Luminous Intensity per LED6) 7)

(Character Average) ISD2012 IVpeak 400 1430 µcd VCC=5.0 V,

VCOL=3.5 V,

TJ=25°C 10),

VB=2.4 V

ISD2312 650 1430

ISD2352 853 2500

Peak Wavelength λVpeak —630 nm —

Dominant Wavelength 8) λdom —626 nm —

High Efficiency Green ISD2013 / ISD2 313 / ISD2353

Description Symbol Min. Typ.9) Units Test Conditions

Peak Luminous Intensity per LED6) 7)

(Character Average) ISD2013 IVpeak 850 1550 µcd VCC=5.0 V,

VCOL=3.5 V,

TJ=25°C 10),

VB=2.4 V

ISD2313 1280 2410

ISD2353 2400 3000

Peak Wavelength λVpeak —568 nm —

Dominant Wavelength 8) λdom —574 nm —

ISD201X, ISD231X, ISD235X

2006-04-04 8

Peak Column Current vs. Column

Voltage, ISD201X

Recommended Operating

Conditions

(Guaranteed over operating

temperatur e range)

Parameter Symbol Min. Nom. Max. Units

Supply Voltage VCC 4.75 5.0 5.25 V

Data Out Curren t, Low S tate IOL ———mA

Data Out Curren t, Hig h St a te IOH ———mA

Column Input Voltage, Column On*VCOL 2.75 —3.5 V

Setup Time TSETUP 70 45 —ns

Hold Time THOLD 30 ——ns

Width of Clock TW(CLK) 75 ——ns

Clock Frequency TCLK — — 5.0 MHz

Clock Transition Time TTHL — — 200 ns

Free Air Operating Temperature Range TA–55 —+100 °C

* See Figures „Peak Column Current vs. Column Voltage“

IDDG5124

COL

123456V

100

200

300

400

500

600

2010

2011/2012/2013

Peak Column Current vs. Column

Voltage, ISD231X

IDDG5125

COL

123456V

100

200

300

400

500

600

ISD2310

ISD2311/2/3

Peak Column Current vs. Column

Voltage, ISD235X

IDDG5126

COL

123456V

100

200

300

400

500

600

ISD201X, ISD231X, ISD235X

2006-04-04 9

Electrical Characteristics

(–55°C to +100°C, unless otherwise specified)

Description Symbol Min. Typ.9) Max. Units Test Conditions

Supply Current (quiescent) ICC ——5.0 mA VB=0.4 V VCC=5.25 V

VCLK=VDATA=2.4V

All SR

Stages=Logical 1

——5.0 VB=2.4 V

Supply Current (operating) ICC ——10 mA FCLK=5.0 MHz

Column Current at Any Column Input* ICOL ——10 µA VB=0.4 V VCC=5.25 V

VCOL=3.5 V

All SR

Stages=Logical 1

Column Current at Any Column Input*

ISD2010 red

ISD2011/2/3: yellow, HER, green

ISD231X: red, yellow, HER, green

ISD235X: yellow, HER, green

ICOL —350

335

380

550

435

410

520

650

mA —

VB, Clock or Data Input Threshold Low VIL ——0.8 VVCC=4.75 V–5.25 V

VB, Clock or Data Input Threshold High VIH 2.0 ——V

Data Out Voltage VOH 2.4 3.6 — V IOH=0.5 mA VCC=5.25 V

ICOL=0 mA

VOL ————IOL=1.6 mA

Input Current Logical 0, VB only IIL –30 –110 –300 µA VCC=4.75 V–5.25 V,

VIL=0.8 V

Input Current Logical 0, Data, Clock IIL ————

Power Dissipation per Package

ISD201X

ISD231X

ISD235X

PD0.44

0.52

0.74

——WVCC=5.0 V, VCOL=3.5 V,

17.5% DF

15 LEDs on per character,

VB=2.4 V

Thermal Resistance IC, Junction-to-Pin

ISD201X

ISD231X

ISD235X

RqJ-PIN —

— °C/W —

* See Figures „Peak Column Current vs. Column Voltage“ (page 8)

2006-04-04 10

ISD201X, ISD231X, ISD235X

Block Diagram

Contrast Enhancement Filters for Sunlight Readability

Display Color Filter Color Marks Polarized Corp.* Optical Characteristics of Filter

Red, HER Red MPC 20-15C 25% at 635 nm, Circular Polarizer

Yellow Amber MPC 30-25C 25% at 583 nm, Circular Polarizer

Green Yellow/Green MPC 50-122C 22% at 568 nm, Circular Polarizer

Multiple Colors

High Ambient Light Neutral Gray MPC 80-10C 10% Neutral, Circular Polarizer

Multiple Colors Neutral Gray MPC 80-37C 37% Neutral, Circular Polarizer

* Marks Polarized Corp.

25-B Jefryn Blvd. W.

Deer Park, NY 11729

516 /242-1300

FAX 516 /242-1347

Marks Polarized Corp. manufactures to MIL-1-45208 inspection system.

IDBD5062

LED

Matrix

LED

Matrix

LED

Matrix

Rows 1-7 Rows 1-7 Rows 1-7

Constant Current Sinking LED Drivers

28-bit SIPO Shift Register

Rows 8-14 Rows 15-21 Rows 22-28 Serial

Data

Output

1234567

Serial

Input

Data

Control,

Blanking

Clock

Rows

12345

Column Drive Inputs

Columns

ISD201X, ISD231X, ISD235X

2006-04-04 11

The small alphanumeric displays are hybrid LED and CMOS

assemblies that are designed for reliable operation in commercial

and industrial environments. Optimum reliability and optical

performance will result when th e junction temperat ure of the L EDs

and CMOS ICs are kept as low as possible.

Thermal Modeling

ISD displays consist of two driver ICs an d fo ur 5 x 7 LED matrixes.

A thermal model of the display is shown in Figure „Thermal Model“.

It illustrates that the junction temperature of the semiconductor =

junction self heating + the case temperature rise + the ambient

temperature.

Equation 1 shows this relationship.

Thermal Model

See Equation 1 below.

The junction rise within the LED is the product of the thermal

impedance of an individual LED (37°C/W, DF=20%, F=200 Hz),

times the forward voltage, VF(LED), and forward current IF(LED), of

13 – 14.5 mA. This rise averages TJ(LED)=1°C. The Table below

shows the VF(LED) for the respective displays.

The junction rise within the LED driver IC is the combination of the

power dissipa ted by the IC quiescen t cur ren t an d th e 2 8 r o w d r ive r

current sinks. The IC junction rise is given in Equation 2.

A thermal resistance of 28°C/W results in a typical junction rise of

6°C.

See Equation 2 below.

For ease of calculations the maximum allowable electrical operat-

ing condition is dependent upon the aggregate thermal resistance

of the LED matrixes and the two driver ICs. All of the thermal man-

agement calculations are based upon the parallel combination of

these two networks which is 15°C/W. Maximum allowable power

dissipation is given in Equation 3.

Equation 3.

For further reference see Figures „Maximum Allowable Power Dis-

sipation vs. Temperature“ (page 6) and Figures from page 12 on.

Key to equation symbols

DF Duty factor

ICC Quiescent IC current

ICOL Column current

n Number of LEDs on in a 5 x 7 array

PCASE Package power dissipation excluding LED

under consideration

PCOL Power dissipati on of a column

PDISPLAY Power dissipation of t he display

PLED Power dissipation of a LED

RqCA Thermal resistance case to ambient

RqJC Thermal resistance junction to case

TAAmbient temperature

TJ(IC) Junction temperature of an IC

TJ(LED) Junction temperature of a LED

TJ(MAX) Maximum junction temperature

VCC IC voltage

VCOL Column voltage

VF(LED) Forward voltage of LED

ZqJC Thermal impedance junction to case

Optical Considerations

The light output of the LED s is in v ersely re lated to the LED di ode’s

junction temperature as shown in „Normalized Luminous Intensity

vs. Junction Temperature“ (page 12). For optimum light output,

keep the thermal resistance of the socket or PC board as low as

possible.

Equation 1.

Equation 2.

Model Number VF

Min. Typ. Max.

ISD2010

ISD2310 1.6 1.7 2.0

ISD2011/2/3

ISD2311/2/3

ISD2351/2/3

1.9 2.2 3.0

IDDG5321

LED Power

LED

IC Power

θ2

LED Power

θ1

LED

LED Power

LED

IC Power

LED Power

1θ

LED

PDISPLAY

TJMAX()

–

RθJC RθCA

----------------------------------------=

PDISPLAY 5VCOL ICOL n35⁄()DF VCC ICC

TJ LED()

PLED ZθJC PCASE RθJC RθCA

+()TA

++=

TJ LED()ICOL 28⁄()VF LED()

ZθJC

[]n35⁄()ICOL DF 5VCOL

()VCC ICC

+[]RθJC RθCA

+[]TA

+⋅+=

TJIC() PCOL RθJC RθCA

+()TA

TJIC() 5V

COL VF LED()

–()ICOL 2⁄()n35⁄()DF⋅⋅ VCC ICC

⋅+[]RθJC RθCA

+[]⋅TA

ISD201X, ISD231X, ISD235X

2006-04-04 12

Normalized Luminous Intensity vs. Junction Temperature

When mounted in a 10°C/W socket and operated at Absolute

Maximum Electrical conditions, the display will show an LED

junction rise of 17°C. If TA=40°C, then the LED’s TJ will be 57°C.

Under these conditions the following Figure „Max. LED Junction

Temperature vs. Socket Thermal Resistance“ shows that the lV will

be 75% of its 25°C value.

Max. LED Junction Temperature vs. Socket Thermal

Resistance

Max. Package Power Dissipation, ISD201X

Max. Package Power Dissipation, ISD231X

Max. Package Power Dissipation, ISD235X

IDDG5127

-60

Normalized

Liminous Intensity

-40 -20 0 20 40 60 80 100 ˚C 140

-1

= 25 ˚C

Normalized to:

IDDG5128

Socket Thermal

n = 20 LEDs, DF = 20%

COL

= 3.5, COL

= 410 mA

= 5.25 V,

= 10 mA

∆

˚C

510 15 20 25 30 35 ˚C/W 50

Resistance

= 0.87 W

IDDG5129

= 25 ˚C

LEDs on per Character

510 15 20 25 30 35 40

DF = 20%,

COL

= 3.5 V, COL

= 410 mA

= 5.25 V,

= 10 mA

Dmax

0.5

1.0

1.5

IDDG5130

= 25 ˚C

LEDs on per Character

510 15 20 25 30 35 40

0.5

1.0

1.5

2.0

DF = 20%,

COL

= 3.5 V,

COL

= 520 mA

= 5.25 V,

= 10 mA

Dmax

IDDG5131

= 25 ˚C

LEDs on per Character

5 10152025303540

DF = 20%,

COL

= 3.5 V,

COL

= 600 mA

= 5.25 V,

= 10 mA

Dmax

0.5

1.0

1.5

2.0

2.5

3.0

ISD201X, ISD231X, ISD235X

2006-04-04 13

Package Power Dissipation, ISD201X

Package Power Dissipation, ISD231X

Package Power Dissipation, ISD235X

Max. Character Power Dissipation, ISD201X

Max. Character Power Dissipation, ISD231X

Max. Character Power Dissipation, ISD235X

IDDG5132

= 25 ˚C

LEDs on per Character

5 10152025303540

DF = 20%,

COL

= 3.5 V, COL

= 335 mA

= 5 V,

= 5 mA

0.5

1.0

1.5

IDDG5134

= 25 ˚C

LEDs on per Character

5 10152025303540

DF = 20%,

COL

= 3.5 V,

COL

= 380 mA

= 5 V,

= 5 mA

0.5

1.0

1.5

IDDG5136

LEDs on per Character

5 10152025303540

DF = 20%

COL

= 3.5 V, COL

= 450 mA

= 5 V,

= 5 mA

0.5

1.0

1.5

2.0

IDDG5133

LEDs on per Character

5 10152025303540

COL

= 3.5 V,

COL

= 410 mA

= 5.25 V,

= 10 mA

0.1

0.2

0.3

0.4

0.5

Duty Factor = 20%

17%

10%

IDDG5135

LEDs on per Character

5 10152025303540

COL

= 3.5 V,

COL

= 380 mA

= 5.25 V,

= 10 mA

0.1

0.2

0.3

0.4

0.5

Duty Factor = 20%

17%

10%

IDDG5137

LEDs on per Character

5 10152025303540

DF = 20%

COL

= 3.5 V,

COL

= 450 mA

= 5 V,

= 5 mA

0.5

1.0

1.5

2.0

ISD201X, ISD231X, ISD235X

2006-04-04 14

Character Power Dissipation, ISD201X

Character Power Dissipation, ISD231X

Character Power Dissipation, ISD235X

IDDG5138

LEDs on per Character

5 10152025303540

Duty Factor = 20%

COL

= 3.5 V, COL

= 335 mA

= 5 V,

= 5 mA

0.1

0.2

0.3

0.4

17%

10%

IDDG5139

LEDs on per Character

5 10152025303540

COL

= 3.5 V,

COL

= 380 mA

= 5 V,

= 5 mA

0.1

0.2

0.3

0.4

0.5

Duty Factor = 20%

17%

10%

IDDG5140

LEDs on per Character

5 10152025303540

COL

= 3.5 V,

COL

= 450 mA

= 5 V,

= 5 mA

0.1

0.2

0.3

0.4

0.5

Duty Factor = 20%

17%

10%

ISD201X, ISD231X, ISD235X

2006-04-04 15

Attention please!

The information describes the type of component and shall not be considered as assured charact eristics.

Terms of delivery and rights to change design reserved. Due to technical requirements components may contain

dangerous substances. For information on the types in question please contact our Sales Organization .

If printed or downloaded, please find the latest version in the Internet.

Packing

Please use the recycling operators known to you. We can also help you – get in touch with your nearest sales office.

By agreement we will take packing material back, if it is sorted. You must bear the costs of transport. For packing

material that is retu rned to us unsorted or which we are not obliged to a ccept, we shall have t o invoice you for any costs

incurred.

Components used in life-support devices or systems must be expressly authorized for such purpose! Critical

components11) page 16 may only be used in life-support devices or systems12) page 16 with the express written approval of

OSRAM OS.

Revision History: 2006-04-04

Previous Version: 2004-12-09

Page Subjects (major changes since last revision) Date of change

all RoHS Compliant - By Exemption 2006-03-03

2006-04-04 16

ISD201X, ISD231X, ISD235X

Remarks:

1) Operation above +100°C ambient is possible if t he following conditions are met.

The junction should not e xceed TJ=125°C and the case temper ature (as measured at pin 1 or the bac k of the display)

should not exceed TC=100°C.

2) Maximum allowable dissipation is deriv ed from:

VCC=5.25 V, VB=2.4 V, VCOL=3.5 V 20 LEDs on per character, 20% DF.

3) Dimensions are specified as follows: inch (mm)

4) VB Pulse Width Frequency—50 kHz (max.)

5) All typical values specified at VCC=5.0 V and TA=25°C unless otherwise noted.

6) The displays are categorized for luminous intensity with the intensity category designated by a letter code on the

bottom of the package.

7) The luminous sterance of the LED may be calculated using the following relationships:

LV (cd/m2) = lV (Candela)/A (Meter)2

LV (Footlamberts) = p lv (Candela)/A (Foot)2

A=5.3 x 10–8 m2 = 5.8 x 10–7 (Foot)2

8) Dominant wavelength (ldom) is derived from the CIE chromaticity diagram and represents the single wavelength

which defines the color of the device.

9) All typical values specified at VCC=5.0 V and TA=25°C unless otherwise noted.

10) The luminous intensity is measured at TA=TJ=25°C. No time is allowed for the device to warm up prior to

measurement.

11) A critical component is a component used in a life-support device or system whose failure can reasonably be

expected to cause the failure of that life-support device or system, or to affect its safety or the effectiveness of that

device or system.

12) Life support devices or systems are intended

(a) to be implanted in the human bod y,

(b) to support and/or maintain and sustain human life.

If they fail, it is reasonable to assume that the health or the life of the user may be endangered.

Published by

OSRAM Opto Semiconductors GmbH

Wernerwerkstrasse 2, D-93049 Regensburg