HDSP-210X_08 Datasheet, PDF(14/16 Page) AVAGO TECHNOLOGIES LIMITED – Eight Character 5 mm and 7 mm Smart Alphanumeric Displays

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HDSP-210X_08 Datasheet, PDF (14/16 Pages) AVAGO TECHNOLOGIES LIMITED – Eight Character 5 mm and 7 mm Smart Alphanumeric Displays

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Self Test Function (Bits 5, 6)

Bit 6 of the Control Word RegisÂter is used to initiate the

self test function. Results of the internal self test are

stored in bit 5 of the Control Word. Bit 5 is a read only bit

where bit 5 = â1â indicates a passed self test and bit 5 =

â0â indicates a failed self test.

Setting bit 6 to a logic 1 will start the self test function.

The built-in self test function of the IC consists of two

internal rouÂtines which exercise major portions of the

IC and illuminÂate all of the LEDs. The first routine cycles

the ASCII decoder ROM through all states and performs

a checkÂsum on the output. If the checksum agrees

with the correct value, bit 5 is set to â1.â The second

rouÂtine provides a visual test of the LEDs using the drive

circuitry. This is accomplished by writing checkered and

inverse checkered patterns to the display. Each pattern is

displayed for approxiÂmately 2 seconds.

During the self test function the display must not be

accessed. The time needed to execute the self test

function is calculated by multiplying the clock period

by 262,144. For example, assume a clock frequency of

58 KHz, then the time to execute the self test function

frequency is equal to (262,144/58,000) = 4.5 second

duration.

At the end of the self test funcÂtion, the Character RAM

is loaded with blanks, the Control Word Register is set to

zeros except for bit 5, the Flash RAM is cleared, and the

UDC Address Register is set to all ones.

Clear Function (Bit 7)

Bit 7 of the Control Word will clear the Character RAM

and the Flash RAM. Setting bit 7 to a â1â will start the

clear funcÂtion. Three clock cycles (110 ms minimum using

the internal refresh clock) are required to complete the

clear function. The display must not be accessed while

the display is being cleared. When the clear function

has been comÂpleted, bit 7 will be reset to a â0.â The ASCII

charÂacter code for a space (20H) will be loaded into the

Character RAM to blank the display and the Flash RAM

will be loaded with â0âs. The UDC RAM, UDC Address

unaffected.

RST CE WR RD

01XX

FL A4 -A0 D7 -D0

XX X

0 = LOGIC 0; 1 = LOGIC 1; X = DO NOT CARE

NOTE:

IF RST, CE, AND WR ARE LOW, UNKNOWN

DATA MAY BE WRITTEN INTO THE DISPLAY.

Figure 7. Logic levels to reset the display.

Display Reset

Figure 7 shows the logic levels needed to Reset the

display. The display should be Reset on Power-up. The

external Reset clears the Character RAM, Flash RAM,

Control Word and resets the internal counters. After the

rising edge of the Reset signal, three clock cycles (110 Âµs

minimum using the internal refresh clock) are required

to complete the reset sequence. The display must not

be accessed while the display is being reset. The ASCII

Character code for a space (20H) will be loaded into

the Character RAM to blank the display. The Flash RAM

and Control Word Register are loaded with all â0âs. The

UDC RAM and UDC Address RegisÂter are unaffected. All

displays which operate with the same clock source must

be simulÂtaÂneÂously reset to synchronize the Flashing and

Blinking functions.

Mechanical and ElecÂtrical Considerations

The HDSP-210X/-211X/â250X are 28 pin dual-in-line

packages with 26 external pins. The devices can be

stacked horizontally and vertiÂcally to create arrays of any

size. The HDSP-210X/-211X/-250X are designed to operate

continuÂously from -45Â°C to +85Â°C with a maxiÂmum of 20

dots on per character at 5.25 V. Illuminating all thirty-five

dots at full brightÂness is not recommended.

The HDSP-210X/-211X/â250X are assembled by die

attaching and wire bonding 280 LED chips and a CMOS

IC to a thermally conductive printed circuit board. A poly-

carbonate lens is placed over the PC board creating an air

gap over the LED wire bonds. A protective cap creates an

air gap over the CMOS IC. Backfill epoxy environmentÂally

seals the display package. This package construction

makes the display highly tolerant to temÂperÂature cycling

and allows wave soldering.

The inputs to the IC are proÂtected against static discharge

and input current latchup. HowÂever, for best results

standard CMOS handling precautions should be used.

Prior to use, the HDSP-210X/-211X/-250X should be

stored in antistatic tubes or in conductive material.

During assembly, a grounded conducÂtive work area

should be used, and assembly personnel should wear

conductive wrist straps. Lab coats made of synthetic

maÂterial should be avoided since they are prone to static

buildup. Input current latchup is caused when the CMOS

inputs are subÂjected to either a voltage below ground

(VIN < ground) or to a voltage higher than VDD (VIN >

VDD) and when a high current is forced into the input. To

prevent input current latchup and ESD damage, unÂused

inputs should be conÂnected either to ground or to VDD.

VoltÂages should not be applied to the inputs until VDD

has been applied to the display.

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