Lead (Pb) Free Product - RoHS Compliant
Red SCE5780
Yellow SCE5781
Super-red SCE5782
Green SCE5783
High Efficiency Green SCE5784
Soft Orange SCE5785
InGaAlP Red SCE5786
0.180" 8-Character 5 x 7 Dot Matrix
Serial Input Dot Addressable Intelligent Display® Devices
2006-01-23 1
DESCRIPTION
The SCE5780 (red), SCE5781 (yellow), SCE5782
(HER), SCE5783 (green), SCE5784 (HEG), SCE5785
(orange), and SCE5786 (I nGaAlP red) a re eight d igit, dot
addressable 5 x 7 dot matrix, serial input, Intelligent Dis-
play devices. The eight 4.57 mm ( 0.180") high digits are
packaged in a rugged, hig h quality, optically transparent,
plastic 26 pin DIP with 7.62 mm (0.3") pin spacing.
The on-board CMOS has a 280 bit RAM, one bit associ-
ated with one LED, each to generate User Defined Char-
acters.
The SCE578X is designed to work with the serial port of
most common microprocessors. Data is transferred into
the displa y throu gh the Serial Data Input ( DATA), clock ed
by the Serial Data Clock (SDCLK), and enabled by the
Load Input (LOAD).
The Clock I/O (CLK I /O) and Clock Select (CLKSEL) pi ns
off er the user the capability to supply a high speed exter-
nal multiplex clock. This feature can minimize audio
in-band interference for portable communicati on equip-
ment or eliminate the visual synchronizatio n effects f ound
in high vibration environments such as avionic equipment.
The prescaler function allo ws for a higher spee d e x ternal
multiplex clock when set to divide by 16.
FEATURES
Eight 4.57 mm (0.180") 5 x 7 Dot Matrix
Characters in Red, Yellow, Super-red, Green, High
Efficiency Gr een , So ft Orange, or InGaAlP Red
ROMless Serial Input, Dot Addressable Display
Ideal for User Defined Characters
Built-in Decoders, Multiplexers and LED Drivers
Readable from 2.5 meters (8 Feet)
Programmable Features:
– Clear Function
Eight Dimming Levels
Peak Current Select
(12.5% or Full Peak Current)
– Prescaler Function
(External Oscillator Divided by 16 or 1)
Internal or External Clock
2006-01-23 2
SCE5780
Package Outlines Dimensions in mm (inch)
Ordering Information
Type Color of Emission Character Height
mm (inch) Ordering Code
SCE5780 red
4.57 (0.180)
Q68000A9100
SCE5781 yellow Q68000A9101
SCE5782 super-red Q68000A9102
SCE5783 green Q68000A9103
SCE5784 high efficiency green Q68000A9104
SCE5785 soft orange on request
SCE5786 InGaAlP Red Q68000A1435
IDOD5216
2.54 (0.100) 2.68 (0.105)
42.93 (1.690) max. 5.36 (0.211)
4.57 (0.180)
2.29 (0.090)
11.43 (0.450) max.
C
L
L
C
SCE578X Z
OSRAM YYWW V
L
C
0.51 (0.020)
0.46 (0.018) typ.
Pin 1 Pin 13
2.54 (0.100) typ.
±0.13 (0.005)
10.16 (0.400)
(Tol. non accum.)
Pin 1
Identifier
Date Code Intensity Code
0.25 (0.010)
0.3 (0.012) typ.
7.62 (0.300)
5.71 (0.225)
Pin 14
Tolerance: ±0.25 (0.010)
0213
5467
5.33 (0.210)
4.01 (0.158) typ.
Pin 1
Identifier C
L
unless otherwise specified
SCE5780
2006-01-23 3
Maximum Ratings
Parameter Symbol Value Unit
Operating temperature range1) Top – 40 … + 85 °C
Storage temperature range Tstg – 40 … + 100 °C
VCC, Logic Supply Voltage (non-operating) VCC -0.5 to + 7.0 V
Input Voltage Levels Relative to GND -0.5 to VCC +0.5 V
VLL, LED Supply Voltage (non-operating) VCOL -0.5 to + 5.5 V
Solder temperature
1.59 mm (0.063“) below seating plane, t < 5.0 s TS260 °C
Relative Humidity at 85°C 85 %
Power Dissipation at 70°C 1.7 W
Power Dissipation at 85°C 1.25 W
ESD (100 pF, 1.5 k)2.0 kV
Input Current 100 mA
1) For operation at high temperatur e, see Thermal Considerations (page 10)
Optical Characteristics at 25°C
(VLL=VCC=5.0 V at 100% brightness leve l, viewing angle: X axis ± 55°, Y axis ± 65 °)
Description Symbol Values Unit
Red
SCE5780
Yellow
SCE5781
Super-red
SCE5782
Green
SCE5783
High Efficiency Green
SCE5784
Soft Orange
SCE5785
InGaAlP Red
SCE5786
Luminous Intensity (min.)
(typ.) IV37.5
90.0 75
110 75
190 75
150 120
215 120
150 375
950 µcd/dot
µcd/dot
Peak Wavelength (typ.) λpeak 660 585 630 565 568 610 645 nm
Dominant Wavelength (typ.) λdom 639 583 626 570 574 605 632 nm
Notes:
1. Dot to dot intensity matching at 100% brightness is 1.8:1.
2. Display are binned for hue at 2.0 nm intervals for yellow, green, and high efficiency green.
3. Displays within a given intensity category have an intensity matching of 1.5:1 (max.)
2006-01-23 4
SCE5780
Timing Diagram—Data Write Cycle
Timing Diagram—Instruction Cycle
Switching Specificatio ns
(over operating temperature range and VCC=4.5 V to 5.5 V)
Symbol Description Min. Units
TRC Reset Ac tive Time 600 ns
TLDS Load Setup Time 50 ns
TDS Data Setup Time 50 ns
TSDCLK Clock Period 200 ns
TSDCW Clock Width 70 ns
TLDH Load Hold Time 0ns
TDH Data Hold Time 25 ns
TWR Total Write Time 2.2 µs
TBL Time Between Loads 600 ns
Note:
TSDCW is the minimum time the SDCLK may be low or high.
The SDCLK period must be a minimum of 200 ns.
SDCLK
SDCLK
T
SDCW
T
DATA
LOAD
D0
DS
T
LDS
T
TDH
D7
LDH
T
LOAD
LOAD
DATA
DATA
SDCLK
SDCLK
D0 D1 D2 D3 D4 D5 D6 D7
D0 D1 D2 D3 D4 D5 D6 D7
D0
D0
BL
T
WR
T
OR
SCE5780
2006-01-23 5
Input/Output Circuits
The follo wing tw o figures sho w the input and outp ut resis-
tor/diode networks used for ESD protection and to elimi-
nate substrate latch-up caused by input voltage
over/under shoot.
Inputs Clock I/O
Electrical Characteristics (over operating temperature)
Parameter Min. Typ. Max. Units Conditions
VCC 4.5 5.0 5.5 V
VLL 3.0 5.5 V
ICC (PWR DWN) 4) 100 µA VCC=VLL=5.0 V, all inputs=0 V or VCC
ILL (PWR DWN) 4) 50 µA
ICC 2.0 mA VCC=5.0 V
ILL (20 dots/char) 1) 2) 240 345 mA VCC=VLL=5.0 V, “#” displayed in 8 digits,
brightness=100%, IP=100% at 25°C
IIL –10 µA VCC=5.0 V, all inpu ts=0 V
IIH 10 µA VCC=VIN=5.0 V (all inputs)
VIH 3.5 V VCC=4.5 V to 5.5 V
VIL 1.5 VVCC=4.5 V to 5.5 V
IOH (CLK I/O) –8.9 mA VCC=4.5 V, VOH=2.4 V
IOL (CLK I/O) 1.6 mA VCC=4.5 V, VOH=0.4 V
θJC-pin 34 °C/W
Internal OSC Frequency 120 347 kHz VCC=5.0 V, CLKSEL=1, Prescale= ÷1
External OSC Frequency 120 347 kHz VCC=5.0 V, CLKSEL=0, Prescale= ÷1
External OSC Frequency with Prescale 1.92 5.55 MHz VCC=5.0 V, CLKSEL=0, Prescale= ÷16
Mux Frequency 3) 375 768 1086 Hz
Notes:
1) Peak current =1 .87 x ILL x ILL varies with VLL Normalized curve, Figure „ILL Variance (page 11).
2) Unused inputs must be tied high.
3) Mux rate=[OSC Frequency/ (64 x 7)].
4) External oscillator must be stopped during power down mode for minimum current.
IDCD5021
GND
1 k
Input
CC
V
IDCD5026
GND
1 k
Input/Output
CC
V
SCE5780
2006-01-23 6
Top View
Dot Matrix Format
Pin Assignment
Pin Function Pin Function
1CLKSEL 14 Serial Data
2VCC (Logic) 15 No connect
3VLL (LED) 16 Serial CLK
4No pin 17 No pin
5No pin 18 No pin
6No pin 19 No pin
7No pin 20 No pin
8No pin 21 No pin
9No pin 22 No pin
10 No pin 23 No pin
11 Load 24 Reset
12 GND 25 CLK I/O
13 GND 26 No connect
IDPA5120
0123
4567
IDOD5217
2.54 (0.100)
0.72 (0.028) typ.
0.57 (0.022) typ.
4.57 (0.180)
C0 C1 C2 C3 C4R0
R1
R2
R3
R4
R5
R6
Pin Definitions
Pin Function Definitions
1CLKSEL H=internal clock, L=external clock
2VCC (Logic) Logic power supply
3VLL (LED) LED power supply
4–10 No pin No pins in these positions
11 Load Low input enab les data clocking into the 8-bit
serial shift register. When Load goes high, the
contents of the 8-bit serial shift register will be
decoded.
12,13 GND Power supply ground
14 Serial Data Serial data input
15 No connect Pin has no function
16 Serial CLK For loadi ng data into th e 8-bit serial regis ter on
a low to high transition
17–23 No pin No pins in these positions
24 Reset Asynchronous input, when low will clear the
Multiple x Counte r, User RAM, and Data Regis-
ter. Control Word Register is set to 100%
brightness, maximum peak current, and oscil-
lator divided by 1. The display blanked.
25 CLK I/O Outputs master clock or input external clock for
display multiplexing.
26 No connect Pin has no function
Display Column and Row Format
C0 C1 C2 C3 C4
Row 0 11111
Row 1 00100
Row 2 00100
Row 3 00100
Row 4 00100
Row 5 00100
Row 6 00100
1=Display dot “On” /// 0=Display dot “Off”
Column Data Ranges
Row 0 00H to 1FH
Row 1 00H to 1FH
Row 2 00H to 1FH
Row 3 00H to 1FH
Row 4 00H to 1FH
Row 5 00H to 1FH
Row 6 00H to 1FH
SCE5780
2006-01-23 7
Block Diagram
Operation of the SCE578X
The SCE578X display consists of two CMOS ICs containing con-
trol logic and drivers for eight 5 x 7 characters . The first IC controls
characters 0 through 3 and the second IC controls characters 4
through 7. Th ese co m pon en ts a r e a ssem bled in a compact plasti c
package.
Individual LED dot addressability al lows the user great freedo m in
creating special characters or mini-icons.
The serial data interface p rovides a highly efficient inte r conn ecti o n
between th e d ispl ay and th e m o the r boa r d. Th e S C E57 8X re qu i res
a minimum three input l ines as compare d to fourteen for an equ i va-
lent eight character parallel input part.
The on-board C MOS IC is the ele c troni c h ea rt of the displ ay. Each
IC accepts serially formatted data, which is store d in the inte rnal
RAM. The IC accepts d ata ba sed on th e ch aracter address
selected. The fir st IC is selecte d wh en addressing ch aracters 0
through 3, the se con d IC is s electe d w h en ad dressi n g ch aracters 4
though 7, and both ICs are selected when the Control Word is
addressed.
Asynchronously the RAM is read by the character multiplexer at a
strobe rate that results in a flicker free display. The Block Diagram
shows the thre e functional area s of the IC. The se include: the inpu t
serial data register and control logic, a 140 bit two po rt RAM, and
an internal multiplexer/display driver. The second IC is identical
except characters 4 though 7 are driven.
The following explains how to format the serial data to be loaded
into the display. The user supplies a string of bit mapped decoded
characters. The contents of this string is shown in Figure „Loading
Serial Character Data“ a (page 8). Figure „Loading Serial Charac-
ter Data“ b (page 8) show s that each character consist of eight 8
bit words. The first word encodes the displa y character location and
the succeeding seven b ytes are row data. The row data represents
the status (On, Off) of individual column LEDs. Figure „Loading
Serial Character Data“ c (page 8) shows that each 8 bit w ord is f or-
matted to represent Character Address, or Column Data.
Figure „Loading Serial Character Data“ d (page 8) shows the
sequence for loading the bytes of data. Bringing the LOAD line low
enables the serial register to accept data. The shift action occurs
on the low to high transition of the serial data clock (SDCLK). The
least significa nt bi t (D 0 ) is loaded first. After eight clock pulses the
LOAD line is brought high. With this transition the OPCODE is
decoded. The decoded OPCODE directs D4–D0 to be latched in
the Characte r Address regis ter, stored in the RAM as Column
data, or latched in the Control Word register. The control IC
requires a minimum 600 ns delay between successive byte loads.
As indicated in Figure „Loading Serial Character Data“ a (page 8),
a total of 512 bits of data are required to load all eight characters
into the display.
The Character Address Register selects the character address that
the row and column data will be written to. See Table „Load Char-
acter Adress“ (page 9) for opcode an d chara cter ad dress ing. Af ter
loading the Character Address Register, the next seven bytes load
the column data, one row at a time, starting with row 0 (top row)
and ending with row 6 (bottom row). Each character address has a
7 x 5 bit User RAM formatted as seven rows, each containing five
IDBD5071
LOAD
SDATA
SD CLK
Register
Data
140 bit RAM
Read 7 x 20
Write 28 x 5
Y Address Decode
0 1 2 3
X Address Decode
3-bit Address
Register
6-bit Control
Word Register
Control Word Logic
Column
Digits
Drivers
0 to 3
Counter Chain
& Timing Logic
RESET
Oscillator
CLKSEL
CLK I/O
4 - 5 x 7
Characters
4 - 5 x 7
Characters
4567
VDIM Controls
Display Multiplexer
& Driver
Row Decoder
MUX
Rate
The second IC has the same
IC 2 controls characters 4 to 7
Function diagram as IC 1
Serial
IC 1
IC 2
SCE5780
2006-01-23 8
column data bits. The three most significant bits, D7–D5 represent
the opcode for the row data and the least significant five bits, D4–
D0 represent the column dat a. See Table „Load Column Data“
(page 9) for the column data format. If an address is loaded before
all seven rows are written, the next column data will be loaded into
Row 0 of the new address. The remaining rows of the old address
are not changed.
Table Charcater „D“ (page 8) shows the Row Address for the
example character, “D.” Column data is written and read asynchro-
nously from the 280 bit RAM. Once loaded, the internal oscillator
and character multiplexer reads the data from the RAM. These
characters are row strobed with column data as shown in Figur es
„Row and Column Locations for a Character ’D’“ (page 9) and
„Row Strobing“ (page 10). The character strobe rate is determined
by the internal or user supplied external MUX Clock and the
ICs ÷ 32 0 counter.
Loading Serial Character Data
Character „D“
Row Op code
D 7 D 6 D 5 Column Data
D4 D3 D2 D1 D0
C0 C1 C2 C3 C4
Hex
000 0 11 1 1 01E
100 0 10 0 0 111
200 0 10 0 0 111
300 0 10 0 0 111
400 0 10 0 0 111
500 0 10 0 0 111
600 0 11 1 1 01E
Character 0 Character 1 Character 2 Character 3 Character 4 Character 5 Character 6 Character 7
Example: Serial Clock=5.0 MHz, Clock Period=200 ns
Time between LOADS
LOAD
Serial
Clock
DATA
Clock
Period
t0
D0 D1 D2 D3 D4 D5 D6 D7
11 Clock Cycles, 2.2 µs
Time
Between
Loads
600 ns(min)
Character Address OPCODEOPCODE Column Data
D0
D D1
D D2
D D3
D D4
D
11 Clock Cycles, 2.2 µs
Character 0
Address Row 0 Column
Data
88 Clock Cycles, 17.6 µs
704 Clock Cycles, 140.8 µs
Row 1 Column
Data Row 2 Column
Data Row 3 Column
Data Row 4 Column
Data
D0
0 D1
0 D2
0 D3
0 D4
0 D5
1 D6
0 D7
1
a.
b.
c.
d.
Row 5 Column
Data Row 6 Column
Data
D5
0D6
0 D7
0
Time
Between
Loads
600 ns(min)
OPCODE
SCE5780
2006-01-23 9
The user can activate four Control functions. These include: LED
Brightness Level, IC Power Down, Prescaler, or Display Clear.
OPCODEs and six bit words are used to initiate these functions.
The OPCODEs and Control Words for the Character Address and
Loading Column Data are shown in Tables „Load Character
Address“ and „Load Column Data“.
The user can select eight specific LED brightness levels, Tables
„Display Brightness“. Depending on how D3 is selected either one
(1) for maximum peak current or zero (0) for 12.5% of maximum
peak current in the con trol wo rd per Table „ Displa y Brig htness“, the
user can select 16 specific LED brightness levels. These bright-
ness levels (in percentages of full brightness of the display)
depending on how the user selects D3 can be one (1) or zero (0)
are as fo llows: 100% ( E0HEX or E8HEX), 53% (E1HEX or E9HEX), 40%
(E2HEX or EAHEX), 27% (E3HEX or EBHEX), 20% (E4HEX or ECHEX),
13% (E5HEX or EDHEX), and 6.6% (E6HEX or EEHEX), 0.0% (E7HEX or
EFHEX). The brightness levels are controlled by changing the duty
factor of the row strobe pulse.
The SCE578X offers a unique Display Power Down feature which
reduces ICC to less than 150 mA total. When EFHEX is loaded
(Table „Po wer Down“) the display is set to 0% brightness. When in
the Power Down mode data may still be written into the RAM. The
display is reactivated by loading a new brightness Level Control
Word into the display.
Row and Column Locations for a Character “D”
Load Character Address
Op code
D7 D6 D5 Character Address
D4 D3 D2 D1 D0 Hex Operation
Load
101 00000A0 Character 0
101 00001A1 Character 1
101 00010A2 Character 2
101 00011A3 Character 3
101 00100A4 Character 4
101 00101A5 Character 5
101 00110A6 Character 6
101 00111A7 Character 7
Load Column Data
Op code
D7 D6 D5 Column Data
D4 D3 D2 D1 D0 Operation
Load
000 C0 C1 C2 C3 C4 Row 0
000 C0 C1 C2 C3 C4 Row 1
000 C0 C1 C2 C3 C4 Row 2
000 C0 C1 C2 C3 C4 Row 3
000 C0 C1 C2 C3 C4 Row 4
000 C0 C1 C2 C3 C4 Row 5
000 C0 C1 C2 C3 C4 Row 6
Display Brightness
Op code
D7 D6 D5 Control Word
D4 D3 D2 D1 D0 Hex Operation
Level
111 00000E0 100%
111 00001E1 53%
111 00010E2 40%
111 00011E3 27%
111 00100E4 20%
111 00101E5 13%
111 00110E6 6.6%
111 00111E7 0.0%
Display Brightness
Op code
D7 D6 D5 Control Word
D4 D3 D2 D1 D0 Hex Operation
Level
111 01000E8 100%
111 01001E9 53%
111 01010EA 40%
111 01011EB 27%
111 01100EC 20%
111 01101ED 13%
111 01110EE 6.6%
111 01111EF 0.0%
Power Down
Op code
D7 D6 D5 Control Word
D4 D3 D2 D1 D0 Hex Operation
Level
111 01111EF 0%
brightness
IDXX5191
Row 2
Row 3
Row 4
Row 5
Row 6 01234
Previously "on" LED
On LED
Off LED
Columns
Row 0
Row 1
SCE5780
2006-01-23 10
Row Strobing
The SCE578X allows a high f req uen cy exter na l osc ill ator so ur ce
to drive the display. Data bit, D4, in the control word format con-
trols the prescaler function. The pr escale r all ows the oscillator
source to be divided by 16 by setting D4=1. However, the pres-
caler should not be used, i.e., when using the internal oscillator
source.
The Software Clear (C0HEX), given in Table „Software Clear“,
clears the Address Register and the RAM. The display is blanked
and the Char acter Address Reg ister will be se t to Chara cter 0. The
internal counter and the Control Word Register are unaffected.
The Software Clear will remain activ e until the next d ata input cycle
is initiated.
Multiplexer and Displ ay Driver
The eight characters are row multiplexed with RAM resident col-
umn data. The stro be ra te is estab lish ed b y the in ternal or e xternal
MUX Clock rate. The MUX Clock frequency is divided by a 320
counter chain. This results in a typical strobe rate of 768 Hz. By
pulling the Cl ock SEL l ine low, the displa y can be operate d from an
external MUX Cloc k. The e xte rnal cloc k is a tta che d to the CL K I /O
connection.
An asynchronous hardware Reset (pin 24) is also provided. Bring-
ing this pin low will clear the Character Address Register, Control
Wor d Register , RAM, and blanks t he displa y. This action lea ves t he
displa y set at Char acter Address 0, and the Bright ness Le v el set at
100%, prescaler ÷1.
Electrical and Mechanical Considerations
Thermal Considerations
The display’s power usag e may n eed to be reduced t o o pe ra t e at
high ambient temperatures. The power may be reduced by lower-
ing the brightness level, reducing the total number of LEDs illumi-
nated, or lowering VLED. The VCC supply, relative to the VLED
supply, has little effect on the power dissi pation of the displa y and
is not considered when determining the power dissipation.
To determine the power deration with a given ambient tempera-
ture, use the following formula:
where: Tjmax=maximum IC junction temperature
PD=power dissipated by the ICs
θja=thermal resistance, junction to ambient
To determine the pow er dis sipation of the displa y, use the follo wing
formula:
where: N=number of LEDs on
ILL/140=average current for a single LED
RB=relative brightness level
A typical thermal resistance value (θja) for this display is 50 °C/W
when mounted in a socket solde re d on a 1.57 mm (0 .06 2" ) thic k
PCB with 0.5 mm (0.020"), 1 ounce copper traces and the display
covered by a plastic filter. The display’s maximum IC junction tem-
perature i s 125°C . Power Deration Curve is ba sed on these typ ical
values.
Power Deration Curve (θja=50°C/W)
VCC and VLL are two separate power supplies sharing a common
ground. VCC supplies power for all the display logic. VLL supplies
the power for the LEDs. By separating the two supplies, VCC and
VLL can be varied independently and keeps the logic supply clean.
0
4
5
6
Columns
1234
Load
Row Load Row 0
1
2
3
0
Columns
01234 Columns
01234
Load Row 1 Load Row 2 Load Row 5
Columns
Columns
012340
Columns
1234 01
Load Row 4Load Row 3
Columns
IDXX5192
234 01234
Load Row 6
6
5
3
4
2
0
1
6
5
3
4
2
0
1
6
5
3
4
2
0
1
6
5
3
4
2
0
1
6
5
3
4
2
0
1
6
5
3
4
2
0
1
Software Clear
Op code
D7 D6 Control Word
D5 D4 D3 D2 D1 D0 Hex Operation
11 000000 C0 CLEAR
Tjmax TAPDθja
+=
PD N ILL 140 RB=
IDDG5333
-40
0
P
W
-20 0 20 40 60 ˚C 100
0.5
1.0
1.5
2.0
2.5
T
SCE5780
2006-01-23 11
VLL can be varied between 3.0 V and 5.5 V. The LED drive cur-
rent will vary with changes in VLL. See Figure „ILL varianc e“:
ILL Variance
VCC can vary between 4.5 V and 5.5 V. Operation below 4.5 V will
change the timing and switching levels of the inputs.
Interconnect Considerations
Optimum product performance can be had when the following
electrical and mechanical recommendations are adopted. The
SCE578X’s IC is constructed in a high speed CMOS process; con-
sequent l y high speed noise on the SERIAL DATA, SERIAL DATA
CLOCK, LOAD and RESET lines may cause incorrect data to be
written into the serial shift register. Adhere to transmission line ter-
mination procedures when using fast line drivers and long cables
(> 10 cm).
Good ground and power supply decoup ling will insure th at
ICC (< 800 mA peak) switching currents do not generate localized
ground bounce. Therefore it is recommended that each display
package use a 0.1 µF and 20 µF tantulum capacitor between VCC
and ground.
When the internal MUX Clock is being used connect the CLKSEL
pin to VCC. In those applications where RESET will not be con-
nected to the system’s reset control, it is recommended that this
pin be connect ed to the center no de of a se ries 0.1 µF a nd 100 k
RC network. Thus upon initi al power up the RESET will be held
low for 10 ms allowing adequate time for the system power supply
to stabilize.
ESD Protection
The input protection structure of th e SCE578X pro vides signi ficant
protection against ESD damage. It is capable of withstanding dis-
charges greater than 2.0 kV. Take all the stan dard precautions,
normal for CMOS components. These include properly grounding
personnel, tools, tables, and transport carriers that come in con-
tact with unshi elded parts. If these condi tions are not, or cannot be
met, keep the leads of the device shorted together or the parts in
antistatic pac kaging.
Soldering Considerations
The SCE578X can be hand soldered with SN63 solder using a
grounded iron set to 260°C.
Wave soldering is also possible following these conditions: Pre-
heat that does n ot e xceed 93°C on the sol der side of th e PC bo ard
or a package surface temperature of 85°C. Water soluble organic
acid flux (except carboxylic acid) or resin-based RMA flux without
alcohol can be used.
Wa ve temperature of 245°C ± C with a dwell between 1.5 sec.
to 3.0 sec. Exposure to the wave should not exceed tempera-
tures above 260°C for five seconds at 1.59 mm (0.063") below
the seating plane. The packages should not be immersed in the
wave.
Post Solder Cleaning Procedures
The least offensive cleaning solution is hot D.I. water (60°C) for
less than 15 minutes. Addition of mild saponifiers is acceptable. Do
not use commercial dishwasher detergents.
For faster cleaning, solvents may be used. Exercise care in choos-
ing solvents as some may chemically attack the nylon package.
For further information refer to Appnotes 18 and 19.
An alternative to soldering and cleaning the display modules is to
use sockets. Naturally, 14 pin DIP sockets 7.62 mm (0.300") wide
with 2.54 mm (0.100") centers work well for single displays. Multi-
ple display assemblies are best handled by longer SIP sockets or
DIP sock ets whe n av ailab le f or uni fo rm package al ignment. So ck et
manufacturers are A ries Elec tronics, Inc., Frenchtown, NJ; Garry
Manufacturing, New Brunswick, NJ; Robinson-Nugent, New
Albany, IN; and Samtec Electronic Hardward, New Albany, IN.
For further information refer to Appnote 22.
Optical Considerations
The 4.57 m m (0 .180" ) high cha rac ter o f the SC E578 X gi v es read -
ability up to five feet. Proper filter selection enhances readability
over this distance.
Using filters emphasizes the contrast ratio between a lit LED and
the character background. This will increase the discrimination of
different characters. The only limitation is cost. Take into consider-
ation the ambient lighting environment for the best cost/benefit
ratio for filters.
Incandescent (wit h almost no g reen) or fluorescent (w ith almost no
red) lights do not have the flat spectral response of sunlight. Plas-
tic band-pass filter s are an in expen sive and effect ive way to
strengthen contrast ratios. The SCE5780 is a red display and
should be used with long wavelength pass filter having a sharp
cut-off in the 600 nm to 620 nm range. The SCE5782 is a
super-red display and should be used with long wavelength pass
filter having a sharp cut-off in the 570 nm to 600 nm range. The
SCE5784 is a high efficiency green display and should be u sed
with long wavelength pass filter that peaks at 565 nm. The
SCE5785 is a soft orange display and should be used with long
wavelength pass filter that peaks at 610 nm. The SCE5786 is an
InGaAlP red display and should be used wit h long wavelength
pass filter that peaks at 645 nm.
Additional contrast enhancement is gained by shading the dis-
plays. Plastic band-pass filters with built-in louvers offer the next
step up in contrast improvement. Plastic filters can be improved
further with anti-refle ctive coatings to re duce glare . The trad e-off is
fuzzy characters. Mounting the filters close to the display reduces
this effect. Take care not to overheat the plastic filter by allowing f or
proper air flow.
Optimal filter enhancements are gained by using circular polar-
IDDG5334
3
0
LL
V
LL
I
3.5 4 4.5 5 V 5.5
0.2
0.4
0.6
0.8
1.0
1.2
1.4
A
SCE5780
2006-01-23 12
ized, anti-re flec ti ve, band-pas s f ilter s. The c ircu lar po larizing fu r-
ther enhances contrast by reducing the light that travels through
the filter and reflects back off the display to less than 1.0%.
Seve ral filter manufacturers supply quality filter materials. Some of
them are: Panelgraphic Corporation, W. Caldwell, NJ; SGL Homa-
lite, Wilmington, DE; 3M Company, Visual Products Division, St.
Paul, MN; Polaroid Corporation, St. Paul, MN; Polaroid Corpora-
tion, Polarizer Division, Cambridge, MA; Marks Polarized Corpora-
tion, Deer Park, NY, Hoya Optics, Inc., Fremont, CA.
One last note on mounting filters: recessing displays and bezel
assemblies is an inexpensive way to provide a shading effect in
overhead lighting sit uat io ns. Several Bezel manufacturers are :
R.M.F. Products, Batavia, IL; Nobex Components, Griffith Plastic
Corp., Burlingame, CA; Photo Chem ical Produ cts of Californi a,
Santa Monica, CA; I.E.E.-Atlas, Van Nuys, CA.
Microprocessor Interface
The microproces sor interface is through the serial po rt, SPI port or
one out of ei ght d ata b its on the eight b it pa r allel p ort and also con-
trol lines SDCLK and LOAD.
Power Up Sequence
Upon power up display will come on at random. Thus the display
should be reset at power-up. The reset will set the Address Regis-
ter to Digit 0, User RAM is se t to 0 (displa y blank) t he Contro l W ord
is set to 0 (100% brightness) and the internal counters are reset.
Loading Data into the Display
Use following procedure to load data into the display:
1. Power up the display.
2. Bring RST low (600 ns duration minimum) to clear the Multi-
plex C oun ter, Address Register, Control Word Reg i ster, User
Ram and Data Register. The display will be blank. Display
brigh tness is set to 100%.
3. If a different brightness is desired, load the proper brightness
opcode into the Control Word Register.
4. Load the Digit Address into the display.
5. Load display row and column data for the selected digit.
6. Repeat steps 4 and 5 for all digits.
Data Contents for the Word „ABCDEFGH“
Step D7 D6 D5 D4 D3 D2 D1 D0 Function
A
B 1 1 0
1 1 1 0000 0
0000 0 CLEAR
100% BRIGHT-
NESS
1
2
3
4
5
6
7
8
1 0 1
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
0000 0
00100
0101 0
1000 1
1111 1
10001
10001
1000 1
DIGIT D0 SELECT
ROW 0 (A)
ROW 1 (A)
ROW 2 (A)
ROW 3 (A)
ROW 4 (A)
ROW 5 (A)
ROW 6 (A)
9
10
11
12
13
14
15
16
1 0 1
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
00001
11111
10001
1000 1
1111 0
1000 1
1000 1
1111 1
DIGIT D1 SELECT
ROW 0 (B)
ROW 1 (B)
ROW 2 (B)
ROW 3 (B)
ROW 4 (B)
ROW 5 (B)
ROW 6 (B)
17
18
19
20
21
22
23
24
1 0 1
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
0001 0
00111
01000
1000 0
1000 0
10000
0100 0
0011 1
DIGIT D2 SELECT
ROW 0 (C)
ROW 1 (C)
ROW 2 (C)
ROW 3 (C)
ROW 4 (C)
ROW 5 (C)
ROW 6 (C)
25
26
27
28
29
30
31
32
1 0 1
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
00011
1111 0
1000 1
10001
1000 1
1000 1
10001
11110
DIGIT D3 SELECT
ROW 0 (D)
ROW 1 (D)
ROW 2 (D)
ROW 3 (D)
ROW 4 (D)
ROW 5 (D)
ROW 6 (D)
33
34
35
36
37
38
39
40
1 0 1
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
00100
1111 1
1000 0
10000
1111 0
1000 0
10000
11111
DIGIT D4 SELECT
ROW 0 (E)
ROW 1 (E)
ROW 2 (E)
ROW 3 (E)
ROW 4 (E)
ROW 5 (E)
ROW 6 (E)
41
42
43
44
45
46
47
48
1 0 1
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
00101
1111 1
1000 0
10000
1111 0
1000 0
10000
10000
DIGIT D5 SELECT
ROW 0 (F)
ROW 1 (F)
ROW 2 (F)
ROW 3 (F)
ROW 4 (F)
ROW 5 (F)
ROW 6 (F)
49
50
51
52
53
54
55
56
1 0 1
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
00110
0111 0
1000 1
10000
1000 0
1001 1
10001
01110
DIGIT D6 SELECT
ROW 0 (G)
ROW 1 (G)
ROW 2 (G)
ROW 3 (G)
ROW 4 (G)
ROW 5 (G)
ROW 6 (G)
57
58
59
60
61
61
62
63
1 0 1
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
0 0 0
00111
1000 1
1000 1
10001
1111 1
1000 1
10001
10001
DIGIT D7 SELECT
ROW 0 (H)
ROW 1 (H)
ROW 2 (H)
ROW 3 (H)
ROW 4 (H)
ROW 5 (H)
ROW 6 (H)
SCE5780
2006-01-23 13
Display Interface to Siemens/Intel 8031
Microprocessor (using serial port in mode 0)
Display Interface to Siemens/Intel 8031
Microprocessor (using one bit of parallel port as serial
port)
Display Interface with Motoro la 68HC05C4
Microprocessor (using SPI port)
Cascading Multiple Displays
Multiple displays can be cascaded using the CLKSEL and C LK I/O
pins (Figure „Ca scading Mult iple Displa y “). The displa y desi gnated
as the MasterClock source should have its CLKSEL pin tied high
and the sla ve s should h av e thei r CLKSEL pins tied lo w . All CLK I/O
pins should be tied together. One display CLK I/O can drive 15
slave CLK I/Os. Use RST to synchronize all display counters.
IDCD5227
XTAL2 RxD
18 10
19 XTAL1
RST
917
P3.7
13
P3.3
P3.4 14
8031
U1
TxD 11 SDCLK
RST
LD
GND CLKSEL
CLK I/O
CC
V
DATA
GND
CC
V
40
ID
+
0.01 µF
TAN
22 µF
CC
V
V
CC
IDCD5228
XTAL2 P3.0
18 10
19 XTAL1
RST
1
8031
U1 SDCLK
RST
LD
GND CLKSEL
CLK I/O
CC
V
DATA
GND
CC
V
40
ID
+
0.01 µF
TAN
22 µF
CC
V
V
CC
P1.0
9
20
P3.1 11
P3.6 16
P0.0 39
IDCD5229
OSC1 PA0
38 11
39 OSC2
RST
1
68HC05C4
U1 SDCLK
RST
LD
GND CS
CLK I/O
CC
V
DATA
GND
CC
V
40
ID
+
0.01 µF
TAN
22 µF
CC
V
V
CC
PA2
9
20
PA1 10
SCLK 33
MOSI 32
IDCD5030
RST CLK SEL
Intelligent Display
CC
V
DATA SDCLK LOAD
14 more displays
in between
DATA
SDCLK
Decoder
Address Address Decode 1-14
A0
A1
A3
RST
CLK I/O
Intelligent Display
DATA
RST
SDCLK
CLK I/O
LOAD
CLK SEL
Chip
0
15
A2
LD CE
2006-01-23 14
SCE5780
Character Set
IDCS5095
CODE
HEX
0E
06
0E
1E
02
02
06
0E
04
14
04
00
01
00
00
00
00
00
00
00
00
11
19
11
0E
13
15
0E
11
17
10
0E
17
15
0E
11
10
10
10
11
1E
1E
0C
00
00
00
08
04
0C
00
19
16
10
1E
11
00
HEX
CODE
11
11
0E
08
04
04
00
00
04
15
15
0E
04
0E
04
00
04
04
04
04
04
04
04
0E
04
04
04
0C
0E
11
1F
11
11
11
11
15
12
0D
11
11
11
0E
12
0D
12
12
00
00
0E
00
01
13
0D
0F
11
00
HEX
CODE HEX
CODE HEX
CODE HEX
CODE HEX
CODE HEX
CODE
11
0A
11
0A
04
00
1F
11
11
1B
0A
11
11
0E
11
19
11
13
15
00
1F
0E
11
11
11
1F
00
04
00
00
00
00
00
0A
0A
1F
0A
0A
0A
1F
0A
0A
01
06
1F
10
08
11
0E
01
0E
0E
11
01
11
0E
11
1E
1E
11
11
11
1E
10
10
0E
11
10
11
0E
11
1E
11
12
14
11
1E
10
0E
0E
11
01
11
0E
10
16
1E
11
19
10
10
0B
0C
08
08
08
00
00
0E
10
0E
11
10
00
00
0E
10
1E
01
0E
00
00
1C
08
04
0A
08
08
08
11
11
0D
13
11
00
00
0E
11
0E
10
1E
00
00
01
0D
0F
11
13
01
01
04
04
04
04
04
04
1F
11
11
0E
11
11
11
11
11
11
1E
11
11
11
1E
10
1E
1F
10
10
10
1F
0A
12
02
02
1F
06
02
1E
01
1E
01
01
10
1F
14
0E
04
1E
05
0F
04
02
04
03
13
08
19
18
0E
12
0D
12
12
00
04
0E
11
11
11
1F
00
0A
0D
12
0D
12
12
00
00
16
19
11
11
11
00
1F
12
16
10
16
11
12
0C
0E
12
0D
12
12
00
0A
04
0E
0E
11
11
08
06
11
11
0E
11
11
0E
0A
14
08
0D
12
15
14
08
04
08
00
00
00
0C
0C
10
1E
0E
11
11
08
06
02
04
08
08
08
01
1F
10
1E
10
10
10
10
1F
10
10
0E
11
13
11
0E
11
0A
04
04
0A
11
11
11
15
11
1B
15
11
11
08
1C
08
08
08
0A
04
0F
11
06
01
0F
00
00
11
11
04
0A
11
00
00
11
11
0A
15
15
00
00
11
1F
0A
00
04
00
00
02
01
12
10
12
1C
00
11
0E
11
11
1F
11
0E
11
11
0A
10
04
08
00
0E
10
09
00
09
09
00
0A
0A
0A
01
1A
0E
00
11
0E
11
00
11
0E
0A
11
0E
11
00
11
11
0A
11
0E
11
0A
11
00
00
04
00
02
04
1F
02
00
18
08
08
0F
08
08
00
00
00
1E
12
08
04
0C
12
0C
12
00
12
0F
00
08
1F
04
08
02
04
1F
08
1F
08
09
1C
08
06
04
04
0E
0A
04
04
11
04
02
04
04
04
04
02
04
08
04
04
04
04
08
0A
00
04
0A
1F
04
00
04
00
04
04
1F
04
00
08
10
18
00
18
00
00
00
00
00
00
1F
00
00
0C
0C
00
00
00
00
00
10
00
08
01
04
02
00
11
0E
11
11
0E
11
0E
02
0C
01
11
0F
11
0E
0C
00
0C
0C
00
0C
00
04
08
0C
0C
0C
00
0C
02
01
04
02
08
04
01
00
00
1F
00
00
1F
00
08
10
04
08
02
04
10
00
04
04
11
02
01
0E
11
11
11
11
1F
11
11
04
07
04
04
04
04
07
11
0E
01
01
01
01
01
12
11
14
12
18
14
11
10
1F
10
10
10
10
10
11
11
11
1B
15
15
11
11
11
13
11
15
19
11
11
0E
11
11
11
11
0E
11
11
0A
11
04
0A
11
04
04
04
11
04
0A
11
08
1F
10
02
04
1F
01
04
07
04
04
04
07
04
02
00
01
08
04
00
10
04
1C
04
04
04
1C
04
04
04
04
15
04
04
0E
00
1F
00
00
00
00
00
11
11
11
16
19
10
10
04
11
0A
11
0A
00
00
04
0E
04
00
0C
00
04
04
08
04
11
0A
00
00
02
0C
12
06
02
02
00
04
1F
08
1F
02
00
00
18
12
14
12
14
10
10
04
02
04
04
08
02
04
04
0E
04
04
04
0C
04
04
04
04
04
00
04
04
11
11
11
0A
15
00
00
04
08
04
04
02
08
04
11
11
11
16
19
00
00
11
0E
11
0E
11
00
00
02
00
00
08
05
00
00
0A
0A
15
0A
15
0A
15
SCE5780
2006-01-23 15
Published by
OSRAM Opto Semiconductors GmbH
Wernerwerkstrasse 2, D-93049 Regensburg
www.osram-os.com
© All Rights Reserved.
Attention please!
The information describes the type of component and shall not be considered as assured characteristics.
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 late st version in the Inter net.
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
components1) may only be used in life-support devices or systems2) with the express written approval of OSRAM OS.
1) 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.
2) Life support devices or systems are intended (a) to be implanted in the human body, or (b) to support and/or maintain and sustain
human life. If they fail, it is reasonable to assume that the health and the life of the user may be endangered.
Revision History: 2006-01-23
Previous Version: 2005-01-10
Page Subjects (major changes since last revision) Date of change
all Lead free device 2006-01-23