PD3535_技术文档

^HERPD2435/PD3535/PD4435

^REDPD2436/PD3536/PD4436

^{BRIGHT GREEN}PD2437/PD3537/PD4437

0.200" Character, PD2435/6/7

0.270" Character, PD3535/6/7

0.45" Character, PD4435/6/7

4-Character 5 x 7 Dot Matrix Alphanumeric

Programmable Display™ with

Built-in CMOS Control Functions

PD243X

PD353X

PD443X

FEATURES

• Internal or External Clock

• Built-in Character Generator ROM

• TTL Compatible

• Four Dot Matrix Characters in High Efﬁciency Red,

Red, and Bright Green

– PD2435/6/7, 0.200" High

– PD3535/6/7, 0.270" High

– PD4435/6/7, 0.45" High

• Easily Cascaded for Multidisplay Operation

• Less CPU Time Required

• Built-in Memory, Decoders, Multiplexer and Drivers

• Wide Viewing Angle, X Axis 55°, Y Axis 65°

• Categorized for Luminous Intensity

• 128 Character ASCII Format (Upper and Lower Case

Characters)

• Software Controlled Features:

– Programmable Highlight Attribute

(Blinking, Non-Blinking)

– Asynchronous Memory Clear Function

– Lamp Test

• 8 Bit Bidirectional Data BUS

– Display Blank Function

• READ/WRITE Capability

– Single or Multiple Character Blinking Function

• Dual In-Line Package Conﬁguration, 0.600" Wide,

0.100" Pin Centers

– Programmable Intensity

Three Brightness Levels

• End-Stackable Package

• Extended Operating Temperature Range:

– PD243X, PD353X: –40°C to +85°C

– PD443X: –40°C to +70°C

2001 OSRAM Opto Semiconductors Inc.• San Jose, CA

www.inﬁneon.com/opto • 408-456-4000

OSRAM Opto Semiconductors GmbH & Co. OHG • Regensburg, Germany

www.osram-os.com • +49-941-202-7178

1

July 5, 2001-14

DESCRIPTION

Dimensions in Inches (mm)

These Programmable Displays are four digit display sys-

tem modules. The characters are 0.20" by 0.14"

(PD243X), 0.27" by 0.20" (PD353X), and 0.45" by 0.27"

(PD443X) 5 x 7 dot matrix arrays constructed with the

latest solid state technology in light emitting diodes.

Driving and controlling the LED arrays is a silicon gate

CMOS integrated circuit. This integrated circuit provides

all necessary LED drivers and complete multiplexing

control logic.

1.000 max.

(25.40)

.200

(5.08)

.140

(3.56)

.125

at seating plane

and centered

on package

(3.18)

.250

(6.35)

.200

(5.08)

.700

(17.78)

.600

(15.24)

Additionally, the IC has the necessary ROM to decode

128 ASCII alphanumeric characters and enough RAM to

store the display’s complete four digit ASCII message

with special attributes. These attributes, all software

programmable at the user’s discretion, include a lamp

test, brightness control, displaying cursors, alternating

cursors and characters, and ﬂashing cursors or charac-

ters.

EIA date code

Luminous

Pin 1

Indicator

.160 ±.020

(4.06 ±.51)

location

Intensity Code

PD243X

OSRAM YYWW

Z

.070 ±.004 typ.

(1.78 ±.10)

.050

(1.27)

.018 x .012 typ.

(.46 x .31)

.100 typ. (2.54)

The CMOS IC also incorporates special interface control

circuitry to allow the user to control the module as a fully

supported microprocessor peripheral. The module,

under internal or external clock control, has asynchro-

nous read, write, and memory clear over an eight bit par-

allel, TTL compatible, bi-directional data bus. Each

module is fully encapsulated within a package 1.0" x 0.7"

x 0.2" (PD253X), 1.4" x 0.72" x 0.285" (PD353X), and 1.5"

x 0.82" x 0.285" (PD443X). The standard 20 pin DIP con-

struction with two rows spaced at 0.6" on 0.1" centers is

wave solderable.

Tolerance: .XXX=0.02 (.51)

1.400 max.

(35.56)

.285

(7.24)

.350

.200

(5.08)

typ.

at seating plane

and centered

on package

.175

(8.89)

typ.

(4.45)

.270 typ.

(6.86)

.720max.

(18.29)

.600 typ.

(15.24)

.450

(11.43)

See the end of this data sheet or refer to Appnotes 18,

19, 22, and 23 for further details on handling and assem-

bling OSRAM Programmable Displays.

Pin 1 Identifier and ESD warning

.160 ±.020

(4.06 ±.51)

Part No.

EIA date code

Luminous

Intensity

PD3537

OSRAM YYWW

Code

Z

.018 x .012 typ.

(.46 x .31)

.250

(6.35)

.100 (2.54) typ.

Tolerance: .XXX=0.010 (.25)

unless max.

1.500 max.

(38.1)

.285

.375

(9.53)

typ.

.050

.270

(6.86)

typ.

at seating plane

and centered

on package

(7.24)

(1.27)

.45 ±.010

(11.43)

.820 max.

(20.83)

.600

(15.24)

.600 typ.

(15.24)

Pin 1 Indicator

Part No.

.160 ±.020

(4.06 ±.51)

EIA date code

Luminous

Intensity Code

PD4437

OSRAM YYWW

Z

.018 x .012 ±.002 typ.

(.46 x .31 ±.05)

.300

(7.62)

.100 (2.54) typ.

Tolerance: .XXX=0.020 (.51)

2001 OSRAM Opto Semiconductors Inc.• San Jose, CA

www.inﬁneon.com/opto • 408-456-4000

OSRAM Opto Semiconductors GmbH & Co. OHG • Regensburg, Germany

www.osram-os.com • +49-941-202-7178

PD2535/6/7, PD3535/6/7, PD4435/6/7

July 5, 2001-14

2

Maximum Ratings

Figure 2. Timing Characteristics—Data “Write” Cycle

DC Supply Voltage.........................................–0.5 V to +7.0 Vdc

Input Voltage Relative

2.0 V

0.8 V

CE0, CE1

*

to GND (all inputs)...............................–0.5 V to V +0.5 Vdc

CC

T

CEH

CES

Operating Temperature

PD243X/353X.................................................–40°C to +85°C

PD443X..........................................................–40°C to +70°C

Storage Temperature....................................... –40°C to +100°C

Maximum Solder Temperature, .063" (1.59 mm)

2.0 V

0.8 V

A0, A1

*

T

AS

AH

2.0 V

0.8 V

below Seating Plane, t<5.0 s........................................ 260°C

D0–D6

T

DS

DH

Optical Characteristics at 25°C

2.0 V

0.8 V

Spectral Peak Wavelength

RD

*

T

RH

RS

HER ..................................................................... 635 nm typ.

Red ...................................................................... 660 nm typ.

Green................................................................... 565 nm typ.

Viewing Angle

WR

2.0 V

0.8 V

T

W

Horizontal

T

ACC

PD243X/353X ................................................................. ±55°

PD443X........................................................................... ±40°

Vertical (off normal axis).................................................. ±65°

Digit Height

Notes:

1. All input voltages are V =0.8 V, V =2.0 V.

IL

IH

2. These waveforms are not edge triggered.

PD243X........................................................0.200" (5.08 mm)

PD353X........................................................0.270" (6.86 mm)

PD443X........................................................0.45" (11.43 mm)

Figure 3. Timing Characteristics—Data “Read” Cycle

(1)

Time Averaged Luminous Intensity

2.0 V

0.8 V

CE0, CE1

Red ...............................................................30 µcd/LED min.

HER/Green....................................................90 µcd/LED min.

LED to LED Intensity Matching...............................1.8:1.0 max.

Device to Device (one bin) ......................................1.5:1.0 max.

Bin to Bin (adjacent bins).........................................1.9:1.0 max.

*

T

CEH

CES

2.0 V

0.8 V

A0–A3

D0–D6

*

T

AH

AS

Note:

1)

Peak luminous intensity values can be calculated by

2.0 V

0.8 V

DATA OUT

multiplying these values by 7.

*

T

DH

T

DD

T

RI

2.0 V

0.8 V

*

WR

RD

T

WS

T

WH

2.0 V

0.8 V

*

T

R

T

RACC

Figure 1. Top View

20

11

20

11

20

11

DIGIT3 DIGIT2 DIGIT1 DIGIT0

DIGIT3

DIGIT2

DIGIT1 DIGIT0

10

1

10

1

10

1

2001 OSRAM Opto Semiconductors Inc.• San Jose, CA

www.inﬁneon.com/opto • 408-456-4000

OSRAM Opto Semiconductors GmbH & Co. OHG • Regensburg, Germany

www.osram-os.com • +49-941-202-7178

PD2535/6/7, PD3535/6/7, PD4435/6/7

July 5, 2001-14

3

Switching Speciﬁcations (V =4.5 V)

CC

Write Cycle Timing

Parameter

Description

Speciﬁcation Minimum

–40°C

1.0

10

0

25°C

1.0

10

0

85°C

1.0

10

0

Units

µs

ns

(1)

T

Clear RAM

CLR

(1)

Clear RAM Disable

Address Setup

Chip Enable Setup

Read Enable Setup

Data Setup

CLRD

T

AS

T

ns

CES

RS

DS

W

T

10

20

60

20

0

10

30

70

30

0

10

50

90

40

0

ns

Write Pulse

ns

T

Address Hold

Data Hold

ns

AH

T

ns

DH

T

Chip Enable Hold

Read Enable Hold

ns

CEH

RH

20

90

30

110

40

140

ns

T

Total Access Time=Setup Time+ Write

Time+Hold Time

ns

ACC

Switching Speciﬁcations (V =4.5 V)

CC

Read Cycle Timing

Parameter

Description

Speciﬁcation Minimum

–40°C

0

25°C

0

85°C

0

Units

ns

T

Address Setup

Chip Enable

AS

T

0

ns

CES

WS

DD

R

Write Enable Setup

Data Delay Time

Read Pulse

20

100

150

0

30

150

175

0

40

175

200

0

ns

T

Address Hold

ns

AH

T

Data Hold

0

ns

DH

T

Time to Tristate (Max. time)

Chip Enable Hold

Write Enable Hold

30

0

40

0

50

0

ns

TRI

ns

CEH

WH

30

200

40

245

50

290

ns

T

Total Access Time=Setup Time+ Read

Time+Time to Tristate

ns

ACC

(1)

T

Wait Time between Reads

0

ns

WAIT

Notes:

1)

Wait 1.0 µs between any Reads or Writes after writing a Control Word with a Clear (D7=1). Wait 1.0 µs

between any Reads or Writes after Clearing a Control Word with a Clear (D7=0). All other Reads and

Writes can be back to back.

2)

3)

All input voltages are (V =0.8 V, V =2.0 V)

IL

IH

Data out voltages are measured with 100 pF on the data bus and the ability to source=–40 µA and

sink=1.6 mA The rise and fall times are 60 ns. V =0.4 V, V =2.4 V.

OL

OH

2001 OSRAM Opto Semiconductors Inc.• San Jose, CA

www.inﬁneon.com/opto • 408-456-4000

OSRAM Opto Semiconductors GmbH & Co. OHG • Regensburg, Germany

www.osram-os.com • +49-941-202-7178

PD2535/6/7, PD3535/6/7, PD4435/6/7

July 5, 2001-14

4

DC Characteristics at 25°C

Parameter

Limits

Min.

4.5

Conditions

Typ.

5.0

Max.

5.5

Units

Volts

mA

V

Nominal

CC

I

(Blank)

—

2.5

3.5

V

=5.0 V, A2=1, all other inputs low.

CC

I

80 LEDs/unit (100% Bright)

—

CC

PD243X

PD353X

PD443X

115

145

150

130

165

170

mA

V

=5.0 V

CC

V

—

0.8

—

Volts

µA

V

=4.5 V to 5.5 V

IL

CC

2.0

25

IH

(1)

I

(except D0 to D7)

100

0.4

—

=4.5 V to 5.5 V, V =0.8 V

IL

IN

V

—

Volts

mA

pF

=4.5 V to 5.5 V

OL

OH

OL

2.4

–8.9

1.6

—

I

—

=4.5 V, V =2.4 V

OH

—

=4.5 V, V =0.4 V

OL

Data I/O Bus Loading

Clock I/O Bus Loading

100

240

—

pF

Note:

1)

D0 to D7 have no pull-up resistors so current is negligible.

Pin Assignments and Deﬁnitions

Pin Assignments and Deﬁnitions (continued)

Function

Deﬁnition

Function

Deﬁnition

1

RD

Active low, will enable a processor to

read all registers in the display.

11

WR

Write. Active low. If the device is

selected, a low on the write input

loads the data into memory.

2

CLK I/O

If CLK SEL (pin 3) is low, then expect

an external clock source into this pin.

If CLK SEL is high, then this pin will

be the master or source into this pin.

If CLK SEL is high, then this pin will

be the master or source for all other

devices which have CLK SEL low.

12

13

14

15

16

17

18

19

20

D7

D6

D5

D4

D3

D2

D1

D0

Data Bus bit 7 (MSB).

Data Bus bit 6.

Data Bus bit 5.

Data Bus bit 4.

Data Bus bit 3.

3

4

CLKSEL

RST

CLOCK SELECT determines the

action of pin 2. CLK I/O, see the sec-

tion on Cascading for an example.

Data Bus bit 2.

Data Bus bit 1.

Reset. Used to synchronize blinking.

Will not clear the display. The reset

pulse should be less than 1 ms

Data Bus bit 0 (LSB).

Positive power pin.

V

CC

5

CE1

CE0

A2

Chip enable (active high).

Chip enable (active low).

Address input (MSB).

Address input.

6

7

8

A1

9

A0

Address input (LSB).

Ground.

10

GND

2001 OSRAM Opto Semiconductors Inc.• San Jose, CA

www.inﬁneon.com/opto • 408-456-4000

OSRAM Opto Semiconductors GmbH & Co. OHG • Regensburg, Germany

www.osram-os.com • +49-941-202-7178

PD2535/6/7, PD3535/6/7, PD4435/6/7

July 5, 2001-14

5

Functional Description

Input Buffering

The block diagram includes 5 major blocks and internal regis-

ters (indicated by dotted lines).

If a cable length of 6 inches or more is used, all inputs to the

display should be buffered with a tri-state non-inverting buffer

mounted as close to the display as conveniently possible. Rec-

ommended buffers are: 74LS245 for the data lines and

74LS244 for the control lines.

Display Memory consists of a 5 x 8 bit RAM block. Each of

the four 8-bit words holds 7-bits of ASCII data (bits D0–D6)

and an attribute select bit (Bit D6). The ﬁfth 8-bit memory

word is used as a control word register. A detailed description

of the control register and its functions can be found in the

Control Word section. Each 8-bit word is addressable and can

be read from or written to.

Figure 4. Block Diagram

14

The Control Logic dictates all of the features of the display

device and is discussed in the Control Word section of this

data sheet.

Display Memory

(RAM) 4x8

Control

Reg

8

D0-D7

128 Char

ROM

1x8

128 x 5

8

The Character Generator converts the 7-bit ASCII data into

the proper dot pattern for the 128 characters shown in the

character set chart.

4

15

Output

Control

Logic

Decode

and

Mux

1

7

CE0,CE1

A0-A2

RD, WR

The Clock Source can originate either from the internal oscilla-

tor clock or from an external source—usually from the output of

another display in a multiple module array.

5

Output

Latch

1

20

The Display Multiplexer controls all display output to the digit

drivers so no additional logic is required for a display system.

3

OSC

Logic

Display

Multiplexer

Column

Drivers

CLK SEL

XCLK

RST

3

The Column Drivers are connected directly to the display.

The Display has four digits. Each of the four digits is com-

prised of 35 LEDs in a 5 x 7 dot array which makes up the

alphanumeric characters.

3

20

Row

Drivers

The intensity of the display can be varied by the Control Word

in steps of 0% (Blank), 25%, 50%, and full brightness.

Display

The Reset pin when activated clears the internal counter. A reset

is usually done after power up and is of very short duration-nano-

seconds or microseconds. If the reset pin is held low for a longer

time (milliseconds) some or all LEDs in the bottom row may light

up. The appearance of lit LEDs during a “reset” is not an indica-

tion of a malfunctioning part. It is advisable to keep the reset

pulse as short as possible to avoid displaying a row of lit LEDs.

Figure 5. Mode Selection

CEO

CE1

1

RD

0

WR

0

Operation

None

0

1

X

None

Microprocessor Interface

0

X

None

The interface to the microprocessor is through the address

lines. (A0–A2), the data bus (D0–D7), two chip select lines

(CE0, CE1), and read (RD) and write (WR) lines.

X

1

None

0=Low logic level, 1=High logic level, X=Don’t care

The CE0 should be held low when executing a read, or write

operation. CE1 must be held high.

The read and write lines are both active low. During a valid read

the data input lines (D0–D7) become outputs. A valid write will

enable the data as input lines.

Data Input Commands

CEO CE1 RD

WR A2

A1

X

0

A0

X

0

D7

X

0

D6

X

0

D5

X

1

D4

X

0

D3

X

0

D2

X

1

D1

X

0

D0

X

0

Operation

1

0

1

X

0

1

X

1

0

X

1

No Change

Read Digit 0 Data to Bus

($) Written to Digit 0

(W) Written to Digit 1

(f) Written to Digit 2

(3) Written to Digit 3

0

1

0

1

0

1

0

1

0

1

0

1

0

1

0

1

0

1

0

1

X

Char. Written to Digit 0

and Cursor Enabled

2001 OSRAM Opto Semiconductors Inc.• San Jose, CA

www.inﬁneon.com/opto • 408-456-4000

OSRAM Opto Semiconductors GmbH & Co. OHG • Regensburg, Germany

www.osram-os.com • +49-941-202-7178

PD2535/6/7, PD3535/6/7, PD4435/6/7

July 5, 2001-14

6

There are ﬁve registers within the display. Four of these regis-

ters are used to hold the ASCII/attribute code of the four dis-

play characters. The ﬁfth register is the Control Word, which is

used to blink, blank, clear, or dim the entire display, or to

change the presentation (attributes) of individual characters.

Control Word

When address bit A2 is taken low, the Control Word is

accessed. The same Control Word appears in all four of the

lower address spaces of the display. Through the Control Word,

the display can be cleared, the lamps can be tested, display

brightness can be selected, and attributes can be set for any

characters which have been loaded with their most signiﬁcant

bit (D7) set high.

Addressing

The addresses within the display device are shown below. Digit

0 is the rightmost digit of the display, while digit 3 is on the left.

Although there is only one Control Word, it is duplicated at the

four address locations 0–3. Data can be read from any of these

locations. When one of these locations is written to, all of them

will change together.

Brightness (D0, D1): The state of the lower two bits of the

Control Word are used to set the brightness of the entire dis-

play, from 0% to 100%. The table below shows the correspon-

dence of these bits to the brightness.

D7 D6 D5 D4 D3 D2 D1 D0 Operation

Address

Contents

0

X

0

1

0

1

0

1

Blank

A2

0

A1

X

A0

X

25% brightness

50% brightness

Full brightness

Control Word

Digit 0 (rightmost)

Digit 1

1

0

1

0

1

X=don't care

1

0

Digit 2

Attributes (D2–D4): Bits D2, D3, and D4 control the visual

attributes (i.e., blinking) of those display digits which have been

written with bit D7 set high. In order to use any of the four

attributes, the Cursor Enable bit (D4 in the Control Word) must

be set. When the Cursor Enable bit is set, and bit D7 in a char-

acter location is set, the character will take on one of the fol-

lowing display attributes.

1

Digit 3 (leftmost)

Bit D7 of any of the display digit locations is used to allow an

attribute to be assigned to that digit. The attributes are dis-

cussed in the next section. If Bit D7 is set to a one, that charac-

ter will be displayed using the attribute. If bit D7 is cleared, the

character will display normally.

Control Word Format

D7

D6

D5

D4

D3

Attributes

D2

D1

Brightness

D1 D0 Brightness

D0

Attribute

enable

Lamp

test

Blink

Clear

0

1

0

1

0

1

0% (blank)

25%

D3 D2 Attributes

50%

100%

0

Display Cursor instead

of Character

0

1

0

Blink Character

Display Blinking Cursor

instead of Character

Alternate Character

with Cursor

1

D4 Attribute enable

0

1

Disable above Attributes

Enable above Attributes

D5 Blink

0

1

Blink Attribute Disabled

Blink Entire Display

D6 Lamp test

0

1

Standard Operation

Display All Dots at 50% Brightness

D7 Clear

0

1

Standard Operation

Clear Entire Display

2001 OSRAM Opto Semiconductors Inc.• San Jose, CA

www.inﬁneon.com/opto • 408-456-4000

OSRAM Opto Semiconductors GmbH & Co. OHG • Regensburg, Germany

www.osram-os.com • +49-941-202-7178

PD2535/6/7, PD3535/6/7, PD4435/6/7

July 5, 2001-14

7

D7 D6 D5 D4 D3 D2 D1 D0 Operation

Blinking display

D7 D6 D5 D4 D3 D2 D1 D0 Operation

0

1

X

B

0

X

B

Disable highlight

attribute

Lamp Test (D6): When the Lamp Test bit is set, all dots in the

entire display are lit at half brightness. When this bit is cleared,

the display returns to the characters that were showing before

the lamp test.

0

1

0

B

Display cursor*

instead of

character

0

1

0

1

0

B

Blink single

character

D7 D6 D5 D4 D3 D2 D1 D0 Operation

0

1

0

X

Lamp test

Display blinking

cursor* instead

of character

Clear Data (D7): When D7 is set (D7=1) in the Control Word, all

(display) memory bits are reset to zero and the display goes blank.

0

1

B

Alternate charac-

ter with cursor*

D7 D6 D5 D4 D3 D2 D1 D0 Operation

*“Cursor”=all dots in a single character space lit to half brightness

X=Don't care

1

0

X

Clear

B=Depends on the selected brightness.

A second control word must be written into the chip with D7

reset (D7=0) to set up attributes and brightness levels.

Attributes are non-destructive. If a character with bit D7 set is

replaced by a cursor (Control Word bit D4 is set, and D3=D2=0)

the character will remain in memory and can be revealed again

by clearing D4 in the Control Word.

The SMC-4740 oscillator is designed to drive up to 16 displays

with input loading of 15 pF each.

The general requirements for cascading 16 displays are:

1. Determine the correct address for each display.

2. Tie CE0 to ground and use CE1 from an address.

Blink (D5): The entire display can be caused to blink at a rate of

approximately 2.0 Hz by setting bit D5 in the Control Word. This

blinking is independent of the state of D7 in all character locations.

To synchronize the blink rate in a bank of these devices, it is

necessary to tie all devices' clocks and resets together as

described in a later section of this data sheet.

3. Select one of the displays to provide the clock for the

other displays.

4. Tie CLKSEL to ground on other displays.

5. Use RST to synchronize the blinking between the displays.

Figure 6. Cascading Diagram

RST

RD

WR

V_CC

RST CLK I/O CLKSEL

Programmable Display

D0-D7 A0-A2 CE0 CE1

WR

RD

WR

RD

Programmable Display

D0-D7 A0-A2 CE0 CE1

RST CLK I/O CLKSEL

14 More Displays

in between

Data I/O

Address

A4

A5

A6

Address

Decoder

Address Decode Chip 1 to 14

2001 OSRAM Opto Semiconductors Inc.• San Jose, CA

www.inﬁneon.com/opto • 408-456-4000

OSRAM Opto Semiconductors GmbH & Co. OHG • Regensburg, Germany

www.osram-os.com • +49-941-202-7178

PD2535/6/7, PD3535/6/7, PD4435/6/7

July 5, 2001-14

8

How to Load Information Into the Display

Information loaded into the display can be either ASCII data or

Control Word data. The following procedure (see also Typical

Loading Sequence) will demonstrate a typical loading sequence

and the resulting visual display. The word STOP is used in all of

the following examples.

Step 7

Step 8

Load enable blinking character into the control

word register. The display should show “STOP”

with a ﬂashing “O”.

Add Another Blinking Character

Into the left hand digit, load the hex code “D3”

which gives an “S” with the D7 bit added as a

control bit. The display should show “STOP”

with ﬂashing “O” and a ﬂashing “S.”

Set Brightness

Step 1

Set the brightness level of the entire display to your

preference (example: 100%)

Load Four Characters

Alternate Character/Cursor Enable

Step 2

Step 3

Step 4

Step 5

Load an “S” in the left hand digit.

Load a “T” in the next digit.

Load an “O” in the next digit.

Load a “P” in the right hand digit.

Step 9

Load enable alternate character/cursor into the

control word register. The display now should show

“STOP” with the “O” and the “S” alternating

between the letter and cursor (all dots lit).

Initiate Four Character Blinking

If you loaded the information correctly, the display

now should show the word “STOP.”

(Regardless of Control Bit setting)

Step 10 Load enable display blinking. The display now

should show the entire word “STOP” blinking.

Blink a Single Character

Step 6

Into the digit, second from the right, load the hex

code “CF,” which is the code for an “O” with the

D7 bit added as a control bit.

Note:

The “O” is the only digit which has the control bit (D7)

added to normal ASCII data.

Typical Loading Sequence

CEO CE1 RD

WR A2

A1

X

A0

X

D7

0

D6

0

D5

0

D4

0

D3

0

D2

0

D1

1

D0

1

Display

1.

2.

3.

4.

5.

6.

7.

8.

9.

10.

L

H

L

H

L

H

L

H

L

0

1

0

1

0

1

S

0

1

0

1

0

1

0

ST

H

L

0

1

0

1

STO

L

0

1

0

1

0

STOP

STO*P

S*TO*P

S†TO†P

S*T*O*P*

L

H

X

1

0

1

X

0

1

0

1

H

L

H

X

H

X

1

0

1

0

1

0

1

L

X

0

1

0

1

* Blinking character

† Character alternating with cursor (all dots lit)

2001 OSRAM Opto Semiconductors Inc.• San Jose, CA

www.inﬁneon.com/opto • 408-456-4000

OSRAM Opto Semiconductors GmbH & Co. OHG • Regensburg, Germany

www.osram-os.com • +49-941-202-7178

PD2535/6/7, PD3535/6/7, PD4435/6/7

July 5, 2001-14

9

Electrical and Mechanical Considerations

Power Down Sequence

The CMOS IC of the display is designed to provide resistance

to both Electrostatic Discharge Damage and Latch Up due to

voltage or current surges. Several precautions are strongly rec-

ommended to avoid overstressing these built-in safeguards.

1. Float all active signals by tri-stating the inputs to the display.

2. Turn off the power to the display.

Soldering Considerations

These displays can be hand soldered with SN63 solder using a

grounded iron set to 260°C.

ESD Protection

Display users should be careful to handle the devices consis-

tent with Standard ESD protection procedures. Operators

should wear appropriate wrist, ankle or feet ground straps and

avoid clothing that collects static charges. Work surfaces, tools

and transport carriers that come into contact with unshielded

devices or assemblies should also be appropriately grounded.

Wave soldering is also possible following these conditions: Pre-

heat that does not exceed 93°C on the solder side of the PC

board or a package surface temperature of 85°C. Water soluble

organic acid ﬂux (except carboxylic acid) or rosin-based RMA

ﬂux without alcohol can be used.

Wave temperature is 245°C ±5°C with a dwell between 1.5

seconds to 3.0 seconds. Exposure to the wave should not

exceed temperatures above 260°C, for 5 seconds at 0.063"

below the seating plane. The packages should not be

immersed in the wave.

Latch up Protection

Latch up is a condition that occurs in CMOS ICs after the input

protection diodes have been broken down. These diodes can

be reversed through several means:

V

<GND, V >V + 0.5 V, or through excessive currents

IN CC

IN

Voltage Transient Suppression

forced on the inputs. When these situations exist, the IC may

It has become common practice to provide 0.01 µF bypass

capacitors liberally in digital systems. Like other CMOS cir-

cuitry, the Intelligent Display controller chip has very low

power consumption and the usual 0.01 µF would be adequate

were it not for the LEDs. To prevent power supply transients,

capacitors with low inductance and high capacitance at high

frequencies are required. This suggests a solid tantalum or

ceramic disc for high frequency bypass. For multiple display

module systems distribute the bypass capacitors evenly, keep-

ing capacitors as close to the power pins as possible. Use a

0.01 µF capacitor for each display module and a 22 µF for

every third display module.

develop the response of an SCR and begin conducting as much

as one amp through the V pin. This destructive condition will

CC

persist (latched) until device failure or the device is turned off.

The Voltage Transient Suppression Techniques and buffer inter-

faces for longer cable runs help considerably to prevent latch

conditions from occurring. Additionally, the following Power Up

and Power Down sequence should be observed.

Power up Sequence

1. Float all active signals by tri-stating inputs to displays.

2. Apply V and GND to the display.

CC

3. Apply active signals to the displays by enabling all input

signals per application.

Figure 7. Character Set

Notes:

D0

D1

D2

D3

0

1

0

1

0

1

0

2

1

0

3

0

1

0

4

1

0

1

0

5

0

1

0

6

1

0

7

0

1

8

1

0

1

9

0

1

0

1

A

1

0

1

B

0

1

C

1

0

1

D

0

1

E

1

F

ASCII

CODE

1. A2 must be held high for ASCII data.

2. Bit D7=1 enables attributes for the

assigned digit.

D6 D5 D4 HEX

0

1

0

1

0

1

0

1

0

1

0

1

0

1

0

1

2

3

4

5

6

7

2001 OSRAM Opto Semiconductors Inc.• San Jose, CA

www.inﬁneon.com/opto • 408-456-4000

PD2535/6/7, PD3535/6/7, PD4435/6/7

OSRAM Opto Semiconductors GmbH & Co. OHG • Regensburg, Germany

www.osram-os.com • +49-941-202-7178

10

July 5, 2001-14

Post Solder Cleaning Procedures

The least offensive cleaning solution is hot D.l. water (60°C) for

less than 15 minutes. Addition of mild saponiﬁers is acceptable.

Do not use commercial dishwasher detergents.

Incandescent (with almost no green) or ﬂuorescent (with

almost no red) lights do not have the ﬂat spectral response of

sunlight. Plastic band-pass ﬁlters are inexpensive and effective

in optimizing contrast ratios. The PD2435/3535/4435 is high

efﬁciency red display and should be matched with a long

wavelength pass ﬁlter in the 570 nm to 590 nm range. The

PD2436/3536/4436 is a standard red display and should be

matched with a long wavelength pass ﬁlter in the 600 nm to

620 nm range. The PD2437/3537/4437 should be matched

with a yellow-green band-pass ﬁlter that peaks at 565 nm. For

displays of multiple colors, neutral density grey ﬁlters offer the

best compromise.

For faster cleaning, solvents may be used. Carefully choose the

solvents as some may chemically attack the package. Maxi-

mum exposure should not exceed two minutes at elevated

temperatures. Acceptable solvents are: TF (trichlorotriﬂuoroet-

(1)

hane), TA, 111 Trichloroethane, and unheated acetone.

Note:

1)

Acceptable commercial solvents are: Basic TF Arklone P.

Genesolv D, Genesolv DA, BlacoTron TF, Blaco-Tron TA and,

Freon TA.

Additional contrast enhancement can be gained through shad-

ing the displays. Plastic band-pass ﬁlters with built-in louvers

offer the “next step up” in contrast improvement. Plastic ﬁlters

can be further improved with anti-reﬂective coatings to reduce

glare. The trade-off is “fuzzy” characters. Mounting the ﬁlters

close to the display reduces this effect. Care should be taken

not to overheat the plastic ﬁlters by allowing for proper air ﬂow.

Do not use solvents containing alcohol, methanol, methylene

chloride, ethanol, TP35, TCM, TMC, TMS+, TE, and TES. Since

many commercial mixtures exist, you should contact your pre-

ferred solvent vendor for chemical composition information.

Some major solvent manufacturers are: Allied Chemical Corpo-

ration, Specialty Chemical Division, Morristown, NJ; Baron-

Blakeslee, Chicago, IL; Dow Chemical, Midland, Ml; E.l. DuPont

de Nemours & Co., Wilmington, DE.

Optimal ﬁlter enhancements for any condition can be gained

through the use of circular polarized, anti-reﬂective, band-pass

ﬁlters. The circular polarizing further enhances contrast by

reducing the light that travels through the ﬁlter and reﬂects back

off the display to less than 1%. Proper intensity selection of the

displays will allow 10,000 foot candle sunlight viewability.

For further information refer to Appnotes 18 and 19.

An alternative to soldering and cleaning the display modules is

to use sockets. Naturally, 20 pin DIP sockets 0.600" wide with

0.100" centers work well for single displays. Multiple display

assemblies are best handled by longer SIP sockets or DIP

sockets when available for uniform package alignment. Socket

manufacturers include: Aries Electronics, Inc., Frenchtown,

NJ; Garry Manufacturing, New Brunswick, NJ; Robinson-

Nugent, New Albany, IN; and Samtec Electronic Hardware,

New Albany, IN.

Several ﬁlter manufacturers supply quality ﬁlter materials.

Some of them are: Panelgraphic Corporation, W. Caldwell, NJ;

SGL Homalite, Wilmington, DE; 3M Company, Visual Products

Division, St. Paul, MN; Polaroid Corporation, Polarizer Division,

Cambridge, MA; Marks Polarized Corporation, Deer Park, NY;

Hoya Optics, Inc., Fremont, CA.

For further information refer to Appnote 22.

One last note on mounting ﬁlters: recessing display and bezel

assemblies is an inexpensive way to provide a shading effect in

overhead lighting situations. Several Bezel manufacturers are:

R.M.F. Products, Batavia, IL; Nobex Components, Grifﬁth Plas-

tic Corp., Burlingame, CA; Photo Chemical Products of Califor-

nia, Santa Monica, CA; I.E.E.Atlas, Van Nuys, CA.

Optical Considerations

The character heights of these displays allows readability up to

eight feet. Proper ﬁlter selection allows the user to build a dis-

play that can be used over this distance.

Filters allow the user to enhance the contrast ratio between a

lit LED and the character background. This will maximize dis-

crimination of different characters as perceived by the display

user. The only limitation is cost. So ﬁrst consider the ambient

lighting environment to maximize the cost beneﬁt ratio for

using ﬁlters.

See Appnote 23.

2001 OSRAM Opto Semiconductors Inc.• San Jose, CA

www.inﬁneon.com/opto • 408-456-4000

OSRAM Opto Semiconductors GmbH & Co. OHG • Regensburg, Germany

www.osram-os.com • +49-941-202-7178

PD2535/6/7, PD3535/6/7, PD4435/6/7

July 5, 2001-14

11


型号：	PD3535
厂家：	OSRAM GMBH
描述：	4-Character 5 x 7 Dot Matrix Alphanumeric Programmable Display⑩ with Built-in CMOS Control Functions 4个字符的5× 7点阵字母数字可编程Display⑩与内置的CMOS控制功能光电静态存储器功效驱动
文件：	总11页 (文件大小：212K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

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