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 ? categorized for intensity ? mechanically rugged ? green categorized for color description the large 5 x 7 dot matrix alpha- numeric 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) con- figuration, while the 17.3 mm font has an industry standard 7.6 mm (0.3 inch) dip configuration. hdsp-440x series hdsp-450x series hdsp-470x series hdsp-510x series hdsp-540x series hdsp-l10x series hdsp-l20x series hdsp-m10x series applications include electronic instrumentation, computer peripherals, point of sale termi- nals, weighing scales, and indus- trial electronics. large 5 x 7 dot matrix alphanumeric displays 17.3/26.5 mm character heights technical data devices high high standard algaas efficiency performance red red red green description hdsp-4701 hdsp-l101 hdsp-l201 hdsp-5401 17.3 mm common row anode hdsp-4703 hdsp-l103 hdsp-l203 hdsp-5403 17.3 mm common row cathode hdsp-4401 hdsp-m101 hdsp-4501 hdsp-5101 26.5 mm common row anode hdsp-4403 hdsp-m103 HDSP-4503 hdsp-5103 26.5 mm common row cathode
2 function pin hdsp-4701/-5401/ hdsp-4703/-5403/ l101/l201 l103/l203 1 column 1 cathode row 1 cathode 2 row 3 anode row 2 cathode 3 column 2 cathode column 2 anode 4 row 5 anode column 1 anode 5 row 6 anode row 6 cathode 6 row 7 anode row 7 cathode 7 column 4 cathode column 3 anode 8 column 5 cathode row 5 cathode 9 row 4 anode column 4 anode 10 column 3 cathode row 4 cathode 11 row 2 anode row 3 cathode 12 row 1 anode column 5 anode function hdsp-4401/-m101/ hdsp-4403/-m103/ pin -4501/-5101 -4503/-5103 1 column 1 cathode row 1 cathode 2 no pin no pin 3 row 3 anode column 3 anode 4 column 2 cathode row 3 cathode 5 no pin no pin 6 row 5 anode column 1 anode 7 no pin no pin 8 row 6 anode column 2 anode 9 row 7 anode row 7 cathode 10 column 3 cathode row 6 cathode 11 column 5 cathode column 4 anode 12 no pin no pin 13 row 4 anode row 5 cathode 14 no pin no pin 15 column 4 cathode row 4 cathode 16 row 2 anode row 2 cathode 17 no pin no pin 18 row 1 anode column 5 anode hdsp-440x/m10x/450x/510x series package dimensions hdsp-470x/l10x/l20x/540x series
3 internal circuit diagrams hdsp-4401/m101/4501/5101 hdsp-4403/m103/4503/5103 hdsp-4701/l101/l201/5401 hdsp-4703/l103/l203/5403 common anode row common cathode row common anode row common cathode row 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-440x/470x series displays, derate maximum average current above 35 c at 0.43 ma/ c. 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. absolute maximum ratings at 25 c hdsp-470x/ hdsp-l10x/ hdsp-l20x/ hdsp-540x/ description 440x series m10x series 450x series 510x series average power per dot 75 mw (t a = 25 c) [1] peak forward current per dot 125 ma 125 ma 90 ma 90 ma (t a = 25 c) [1,2] average forward current per dot 32 ma 23 ma 15 ma 15 ma (t a = 25 c) [1,3] operating temperature range -40 c to +85 c -20 c to +85 c-40 c to +85 c -20 c to +85 c storage temperature range -40 c to +85 c lead solder temperature 260 c for 3 s (1.59 mm [0.062 in.] below seating plane)
4 electrical/optical characteristics at t a = 25 c standard red hdsp-440x/470x series description symbol test conditions min. typ. max. units luminous intensity/dot [4] 100 ma pk: 1 of 5 (digit average) i v duty factor (20 ma avg.) hdsp-470x (17.3 mm) 360 770 hdsp-440x (26.5 mm) 400 800 peak wavelength l peak 655 nm dominant wavelength [5] l d 640 nm forward voltage v f i f = 100 ma 1.8 2.2 v reverse voltage [6] v r i r = 100 m a 3.0 12 v temperature coefficient of v f d v f / c -2.0 mv/ c thermal resistance led junction-to-pin per package hdsp-470x r q j-pin 15 c/w/ hdsp-440x 13 pack algaas red hdsp-l10x/m10x series description symbol test conditions min. typ. max. units luminous intensity/dot [4] 10 ma pk: 1 of 5 (digit average) i v duty factor (2 ma avg.) hdsp-l10x (17.3 mm) 730 1650 hdsp-m10x (26.5 mm) 760 1850 luminous intensity/dot [4] 30 ma pk: 1 of 14 (digit average) i v duty factor (2.1 ma avg.) hdsp-l10x 1750 hdsp-m10x 1980 peak wavelength l peak 645 nm dominant wavelength [5] l d 637 nm forward voltage v f i f = 10 ma 1.7 2.1 v reverse voltage [6] v r i r = 100 m a 3.0 15.0 v temperature coefficient of v f d v f / c -2.0 mv/ c thermal resistance led junction-to-pin per package hdsp-l10x r q j-pin 20 c/w/ hdsp-m10x 18 pack m cd m cd m cd
5 high efficiency red hdsp-450x/l20x series description symbol test conditions min. typ. max. units luminous intensity/dot [4] 50 ma pk: 1 of 5 (digit average) i v duty factor (10 ma avg.) hdsp-l20x (17.3 mm) 1150 2800 hdsp-450x (26.5 mm) 1400 3500 luminous intensity/dot [4] 30 ma pk: 1 of 14 (digit average) i v duty factor (2.1 ma avg.) hdsp-l20x 740 hdsp-450x 930 peak wavelength l peak 635 nm dominant wavelength [5] l d 626 nm forward voltage v f i f = 50 ma 2.6 3.5 v reverse voltage [6] v r i r = 100 m a 3.0 25.0 v temperature coefficient of v f d v f / c -2.0 mv/ c thermal resistance led junction-to-pin per package hdsp-l20x r q j-pin 15 c/w/ hdsp-450x 13 pack high performance green hdsp-540x/510x series description symbol test conditions min. typ. max. units luminous intensity/dot [4] 50 ma pk: 1 of 5 (digit average) i v duty factor (10 ma avg.) hdsp-540x (17.3 mm) 1290 4000 hdsp-510x (26.5 mm) 1540 4500 luminous intensity/dot [4] 30 ma pk: 1 of 14 (digit average) i v duty factor (2.1 ma avg.) hdsp-540x 570 hdsp-510x 630 peak wavelength l peak 566 nm dominant wavelength [5,7] l d 571 nm forward voltage v f i f = 50 ma 2.6 3.5 v reverse voltage [6] v r i r = 100 m a 3.0 25.0 v temperature coefficient of v f d v f / c -2.0 mv/ c thermal resistance led junction-to-pin per package hdsp-540x r q j-pin 15 c/w/ hdsp-510x 13 pack 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. m cd m cd m cd m cd
6 operational considerations electrical description these display devices are com- posed 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 v f values, for driver circuit design and maxi- mum power dissipation, may be calculated using the following v f max models: red (hdsp-440x/470x): v f max = 1.55 v + i peak (6.5 w ) for i peak 3 5 ma algaas red (hdsp-l10x/m10x): v f max = 1.8 v + i peak (20 w ) for i peak 20 ma v f max = 2.0 v + i peak (10 w ) for i peak 3 20 ma her (hdsp-450x/l20x): v f max = 1.75 v + i peak (35 w ) for i peak 3 5 ma green (hdsp-540x/510x): v f max = 1.75 v + i peak (38 w ) for i peak 3 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: i v avg = (i f avg/i f avg data sheet)( h peak )(i v data sheet) where: i f avg is the desired time averaged led current. i f avg data sheet is the time averaged data sheet test current for i v data sheet. h peak is the relative efficiency at the peak current, scaled from figure 3. figure 1. maximum allowable average current per dot as a function of ambient temperature. figure 2. forward current vs. forward voltage. figure 3. relative efficiency (luminous intensity per unit dot) vs. peak current per dot. i v data sheet is the time averaged data sheet luminous intensity, resulting from i f avg data sheet. i v avg is the calculated time averaged luminous intensity resulting from i f avg. for example, what is the luminous intensity of an algaas red (hdsp-l10x) driven at 50 ma peak 1/5 duty factor? i f avg = 50 ma * 0.2 = 10 ma i f avg data sheet = 2 ma h peak = 0.98 i v data sheet = 1650 m cd therefore i v avg = (10 ma/2 ma)(0.98) (1650 m cd) = 8085 m cd
7 i peak = 125 ma i f avg = 10 ma r q j-a = 50 c/w n = 35 t j max = 110 c v f max = 2.0 v + (0.125 a)(10) = 3.25 v p d = (3.25 v)(0.01 a) = 0.0325 w t a = 110 c 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: i peak = 125 ma i f avg = 10 ma r q j-a = 50 c/w n = 20 t j max = 110 c v f max = 3.25 v p d = 0.0325 w t a = 110 c 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. thermal considerations the device thermal resistance may be used to calculate the junction temperature of the central led. the equation below calculates the junction tem- perature of the central (hottest) led. t j =t a + (p d )(r q j-a )(n) p d =(v f max)(i f avg) r q j-a = r q j-pin + r q pin-a t j is the junction temperature of the central led. t a is the ambient temperature. p d is the power dissipated by one led. n is the number of leds on per character. v f max is calculated using the appropriate v f model. r q j-a is the package thermal resistance from the central led to the ambient. r q j-pin is the package thermal resistance from the central led to pin. r q pin-a is the package thermal resistance from the pin to the ambient. for example, what is the maxi- mum ambient temperature an hdsp-l10x can operate with the following conditions: contrast enhancement for information on contrast enhancement please see application note 1015. soldering/cleaning for soldering/cleaning infor- mation on soldering leds please refer to application note 1027.
www.semiconductor.agilent.com data subject to change. copyright ? 1999 agilent technologies, inc. obsoletes 5963-7392e 5964-6373e (11/99)
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