HCMS-3901, HCMS-3902, HCMS-3961, HCMS-3962,
HCMS-3911, HCMS-3912, HCMS-3971, HCMS-3972
HCMS-3903, HCMS-3904, HCMS-3963, HCMS-3964,
HCMS-3913, HCMS-3914, HCMS-3973, HCMS-3974
ESD WARNING: STANDARD CMOS HANDLING PRECAUTIONS SHOULD BE OBSERVED TO AVOID STATIC DISCHARGE
Description
The 3.3 V HCMS-39xx family is similar to the 5.0 V
HCMS-29xx family, except it operates at a lower
operating voltage. Package dimen sions and pin outs
are exactly the same for both families. The product has
been thoroughly characterized and stringent reliability
tested to ensure that the product is of high quality.
Similar to the 5.0 V platform, this family product is
a high per formance, easy to use dot matrix display
driven by on-board CMOS IC. Each display can be
directly interfaced with a micro processor, thus
eliminating the need for cumbersome interface com-
ponents. The serial IC interface allows higher character
count information displays with a minimum of data
lines. The easy to read 5x7 pixel format allows the
display of upper case, lower case, Katakana, and custom
user-dened characters. These displays are stackable
in the x- and y-directions, making them ideal for high
character count displays.
Features
x Easy to use
x Interfaces directly with microprocessors
x 0.15” character height in 4 and 8 character package
x 0.20” character height in 4 and 8 character package
x Rugged X- and Y-stackable package
x Serial input
x Convenient brightness controls
x Wave solderable
x Low power CMOS technology
x TTL compatible
x 3.3 V operating voltage
Applications
x Telecommunications equipment
x Portable data entry devices
x Computer peripherals
x Medical equipment
x Test equipment
x Business machines
x Avionics
x Industrial controls
HCMS-39xx
3.3 V High Performance CMOS
5x7 AlphaNumeric Displays
Data Sheet
2
Package Dimensions
Figure 1. HCMS-390X package dimensions
XZ
COO
2.11 (0.083) TYP.
0.25
(0.010)
7.62
(0.300)
PIN # 1 IDENTIFIER
4321
17.78 (0.700) MAX.
3.71 (0.146) TYP.
4.45 (0.175) TYP.
2.22 (0.087) SYM.
10.16 (0.400) MAX.
PIN # 1
LIGHT INTENSITY CATEGORY
DATE CODE
COLOR BIN
COUNTRY OF ORIGIN
PART NUMBER
5.08
(0.200)
2.54
(0.100)SYM.
TYP.
0.51 ± 0.13
(0.020 ± 0.005)
2.54 ± 0.13
(0.100 ± 0.005)
(NON ACCUM.)
TYP.
4.32
(0.170)TYP.
1.27
(0.050)SYM.
1
12
0.51 (0.020)
DATA OUT
OSC
V LED
DATA IN
RS
CLK
CE
BLANK
GND
SEL
V LOGIC
RESET
PIN FUNCTION
ASSIGNMENT TABLE
1
2
3
4
5
6
7
8
9
10
11
12
PIN # FUNCTION
HCMS-390x
YYWW
2.54 ± 0.13
(0.100 ± 0.005)
(NON ACCUM.)
TYP.
35.56 (1.400) MAX.
76543210
0.25
(0.010)
7.62
(0.300)
PIN # 1 IDENTIFIER
XZ
COO
INTENSITY CATEGORY
DATE CODE (YEAR, WEEK)
COLOR BIN
COUNTRY OF ORIGIN
PART NUMBER
5.08 (0.200)
2.54
(0.100) SYM.
0.51
(0.020)
TYP.
0.51 ± 0.13
(0.020 ± 0.005)
2.22 (0.087) SYM.
10.16 (0.400) MAX.
2.11 (0.083) TYP.
4.32
(0.170)TYP.
1.27
(0.050)SYM.
4.45
(0.175)TYP.
3.71
(0.146)
TYP. NO PIN
NO PIN
V LED
NO PIN
NO PIN
NO PIN
GND LED
NO PIN
NO PIN
V LED
NO PIN
NO PIN
NO PIN
DATA IN
RS
NO PIN
CLOCK
CE
BLANK
GND LOGIC
SEL
V LOGIC
NO PIN
RESET
OSC
DATA OUT
PIN FUNCTION
ASSIGNMENT TABLE
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
PIN # FUNCTION
3
26
HCMS-391x
YYWW
Figure 2. HCMS-391X Package dimensions
NOTES:
1. DIMENSIONS ARE IN mm (INCHES).
2. UNLESS OTHERWISE SPECIFIED, TOLERANCE ON DIMENSIONS IS ± 0.38 mm (0.015 INCH).
3. LEAD MATERIAL: SOLDER PLATED COPPER ALLOY.
3
Figure 3. HCMS-396X Package dimensions
Package Dimensions, continued
3210
PIN # 1 IDENTIFIER
PART NUMBER
5.31
(0.209)
0.169
(4.28) SYM.
TYP.
0.51 ± 0.13
(0.020 ± 0.005)
2.54 ± 0.13
(0.100 ± 0.005)TYP.
2.67 (0.105) SYM.
2.54 (0.100) TYP.
11.43 (0.450) MAX.
5.36 (0.211) TYP.
0.25
(0.010)
7.62
(0.300)
3.71
(0.146)TYP.
0.072
(1.83)SYM.
4.57
(0.180)TYP.
XZ
COO
INTENSITY CATEGORY
DATE CODE (YEAR, WEEK)
COLOR BIN
COUNTRY OF ORIGIN
21.46 (0.845) MAX.
0.50
(0.020)
DATA OUT
OSC
V LED
DATA IN
RS
CLK
CE
BLANK
GND
SEL
V LOGIC
RESET
1
2
3
4
5
6
7
8
9
10
11
12
PIN FUNCTION
ASSIGNMENT TABLE
PIN # FUNCTION
HCMS-396x
YYWW
Figure 4. HCMS-397X Package dimensions
PIN FUNCTION
ASSIGNMENT TABLE
87654321
XZ
COO
PIN # 1 IDENTIFIER
INTENSITY CATEGORY
DATE CODE (YEAR, WEEK)
COLOR BIN
COUNTRY OF ORIGIN
PART NUMBER
5.31
(0.209)
6.22
(0.245) SYM.
0.51
(0.020)
TYP.
0.51 ± 0.13
(0.020 ± 0.005)
2.54 ± 0.13
(0.100 ± 0.005)
(NON ACCUM.)
TYP.
42.93 (1.690) MAX.
2.67 (0.105) SYM.
5.36 (0.211) TYP.
11.43 (0.450) MAX.
2.54 (0.100) TYP.
0.25
(0.010)
7.62
(0.300)
3.71
(0.146)TYP.
1.90
(0.075)SYM.
NO PIN
NO PIN
V LED
NO PIN
NO PIN
NO PIN
GND LED
NO PIN
NO PIN
V LED
NO PIN
NO PIN
NO PIN
DATA IN
RS
NO PIN
CLOCK
CE
BLANK
GND LOGIC
SEL
V LOGIC
NO PIN
RESET
OSC
DATA OUT
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
PIN # FUNCTION
4.57
(0.180)TYP.
3
26
HCMS-397x
YYWW
NOTES:
1. DIMENSIONS ARE IN mm (INCHES).
2. UNLESS OTHERWISE SPECIFIED, TOLERANCE ON DIMENSIONS IS ± 0.38 mm (0.015 INCH).
3. LEAD MATERIAL: SOLDER PLATED COPPER ALLOY.
4
Device Selection Guide
Description Yellow Red Green Orange
1 x 4 0.15” Character HCMS-3901 HCMS-3902 HCMS-3903 HCMS-3904
1 x 8 0.15” Character HCMS-3911 HCMS-3912 HCMS-3913 HCMS-3914
1 x 4 0.20” Character HCMS-3961 HCMS-3962 HCMS-3963 HCMS-3964
1 x 8 0.20” Character HCMS-3971 HCMS-3972 HCMS-3973 HCMS-3974
Absolute Maximum Ratings
Logic Supply Voltage, VLOGIC to GNDLOGIC ..................................... -0.3 V to 7.0 V
LED Supply Voltage, VLED to GNDLED ................................................ -0.3 V to 5.5 V
Input Voltage, Any Pin to GND ........................................................... -0.3 V to VLOGIC +0.3 V
Free Air Operating Temperature Range TA[1] ................................ -40°C to +85°C
Relative Humidity (non-condensing) ................................................ 85%
Storage Temperature, TS . ...................................................................... -55°C to 100°C
Soldering Temperature [1.59 mm (0.063 in.) below body]
Solder Dipping ....................................................................................... 260°C for 5 secs
Wave Soldering ...................................................................................... 250°C for 3 secs
ESD Protection @ 1.5 kΩ, 100 pF (each pin) ................................... Class 1, 0-1999 V
TOTAL Package Power Dissipation at TA = 25°C[1]
4 character ............................................................................................. 0.766 W
8 character .............................................................................................. .1.532 W
16 character . ............................................................................................ 3.064 W
Note:
1. For operation in high ambient temperatures, see Appendix A, Thermal Considerations.
Recommended Operating Conditions over Temperature Range
(-40°C to +85°C)
Parameter Symbol Min. Max. Units
Logic Supply Voltage[1] VLOGIC 3.1 5.5 V
LED Supply Voltage[1] V
LED 3.1 5.5 V
GNDLED to GNDLOGIC[1] – -0.3 +0.3 V
Note:
1. For further description, see Appendix B, Electrical Considerations, VLOGIC and VLED
Considerations”.
5
Electrical Characteristics over Operating Temperature Range (-40°C to +85°C)
TA = 25°C -40°C < TA < 85°C
VLOGIC = 3.3 V 3.0 V < VLOGIC < 5.5 V
Parameter Symbol Typ. Max. Min. Max. Units Test Conditions
Input Leakage Current II
μA VIN = 0 V to VLOGIC
HCMS-390X/396X (4 char) +7.5 -2.5 +50
HCMS-391X/397X (8 char) +15 -5.0 +100
ILOGIC OPERATING ILOGIC (OPT) mA VIN = VLOGIC
HCMS-390X/396X (4 char) 0.4 2.5 5
HCMS-391X/397X (8 char) 0.8 5 10
ILOGIC SLEEP[1] ILOGIC (SLP) μA VIN = VLOGIC
HCMS-390X/396X (4 char) 5 15 25
HCMS-391X/397X (8 char) 10 30 50
ILED BLANK ILED (BL) mA BL = 0 V
HCMS-390X/396X (4 char) 2.0 4.0 4.0
HCMS-391X/397X (8 char) 4.0 8.0 8.0
ILED SLEEP[1]
I
LED (SLP) μA
HCMS-390X/396X (4 char) 7.5 20 50
HCMS-391X/397X (8 char) 15 40 100
Peak Pixel Current[2] I
PIXEL 14.0 15.9 17.1 mA VLED = 5.5 V. All
pixels ON, average
value per pixel
HIGH level input voltage VIH 2.4 V 3.0 V < VLOGIC < 5.5 V
LOW level input voltage VIL 0.4 V 3.0 V < VLOGIC < 5.5 V
HIGH level output voltage VOH 2.4 V 3.0 V < VLOGIC < 5.5 V
LOW level output voltage VOL 0.4 V 3.0 V < VLOGIC < 5.5 V
Thermal Resistance J-P 70 oC/W
Notes:
1. In SLEEP mode, the internal oscillator and reference current for LED drivers are o.
2. Average peak pixel current is measured at the maximum drive current set by Control Register 0. Individual pixels may exceed this value.
Optical Characteristics at 25°C ±1°C[1]
VLED = 3.3 V, 100% Peak Current, 100% Pulse Width[2]
Luminous
Intensity per LED [3] Peak Wavelength Dominant Wavelength
Character Average (μcd) λPeak (nm) λd [4] (nm)
Display Color Minimum Typ. Typ. Typ.
Red 30 128 641 628
Orange 30 128 592 588
Yellow 70 148 583 585
Green 77 252 568 574
Notes:
1. Refers to the initial case temperature of the device immediately prior to measurement.
2. For comparison purpose with existing HCMS-29xx 5 V devices. The Typical and Minimum Luminous Intensity per LED Character Average can be
calculated by dividing the values in the table by two for the test condition 50% Peak Current, 100% Pulse Width and VLED = 3.3 V.
3. Measured with all LEDs illuminated in a digit.
4. Dominant wavelength, λd, is derived from the CIE chromaticity diagram and represents the single wavelength which denes the perceived
LED color.
6
Electrical Description
Pin Function Description
RESET (RST) Sets Control Register bits to logic low. The Dot Register contents are unaected by the
Reset pin. (logic low = reset; logic high = normal operation).
DATA IN (DIN) Serial Data input for Dot or Control Register data. Data is entered on the rising edge of the
Clock input.
DATA OUT (DOUT) Serial Data output for Dot or Control Register data. This pin is used for cascading
multiple displays.
CLOCK (CLK) Clock input for writing Dot or Control Register data. When Chip Enable is logic low, data
is entered on the rising Clock edge.
REGISTER SELECT (RS) Selects Dot Register (RS = logic low) or Control Register (RS = logic high) as the
destination for serial data entry. The logic level of RS is latched on the falling edge of
the Chip Enable input.
CHIP ENABLE (CE) This input must be a logic low to write data to the display. When CE returns to logic
high and CLK is logic low, data is latched to either the LED output drivers or a Control
Register.
OSCILLATOR SELECT Selects either an internal or external display oscillator source. (SEL) (logic low = External
Display Oscillator; logic high = Internal Display Oscillator).
OSCILLATOR (OSC) Output for the Internal Display Oscillator (SEL = logic high) or input for an External
Display Oscillator (SEL = logic low).
BLANK (BL) Blanks the display when logic high. May be modulated for brightness control.
GNDLED Ground for LED drivers.
GNDLOGIC Ground for logic.
VLED Positive supply for LED drivers.
VLOGIC Positive supply for logic.
7
AC Timing Characteristics over Temperature Range (-40 to +85°C)
Timing
Diagram 4.5 V<VLOGIC < 5.5 V VLOGIC = 3 V
Ref. Number Description Symbol Min. Max. Min. Max. Units
1 Register Select Setup Time to Chip Enable trss 10 10 ns
2 Register Select Hold Time to Chip Enable trsh 10 10 ns
3 Rising Clock Edge to Falling Chip Enable Edge tclkce 20 20 ns
4 Chip Enable Setup Time to Rising Clock Edge tces 35 55 ns
5 Chip Enable Hold Time to Rising Clock Edge tceh 20 20 ns
6 Data Setup Time to Rising Clock Edge tds 10 10 ns
7 Data Hold Time after Rising Clock Edge tdh 10 10 ns
8 Rising Clock Edge to DOUT [1] t
dout 10 40 10 65 ns
9 Propagation Delay DIN to DOUT
Simultaneous Mode for one IC[1,2] t
doutp 18 30 ns
10 CE Falling Edge to DOUT Valid tcedo 25 45 ns
11 Clock High Time tclkh 80 100 ns
12 Clock Low Time tclkl 80 100 ns
Reset Low Time trstl 50 50 ns
Clock Frequency Fcyc 5 4 MHz
Internal Display Oscillator Frequency Finosc 80 210 80 210 KHz
Internal Refresh Frequency Frf 150 410 150 410 Hz
External Display Oscillator Frequency Fexosc
Prescaler = 1 51.2 1000 51.2 1000 KHz
Prescaler = 8 410 8000 410 8000 KHz
Notes:
1. Timing specications increase 0.3 ns per pf of capacitive loading above 15 pF.
2. This parameter is valid for Simultaneous Mode data entry of the Control Register.
8
Display Overview
The HCMS-39XX series is a family of LED displays driven
by on-board CMOS ICs. The LEDs are congured as 5x7
font characters and are driven in groups of 4 characters
per IC. Each IC consists of a 160-bit shift register (the Dot
Register), two 7-bit Control Words, and refresh circuitry.
The Dot Register contents are mapped on a one-to-one
basis to the display. Thus, an individual Dot Register bit
uniquely controls a single LED.
Eight-character displays have two ICs that are cascaded.
The Data Out line of the rst IC is internally connected to
the Data In line of the second IC forming a 320-bit Dot
Register. The display’s other control and power lines are
connected directly to both ICs.
Reset
Reset initializes the Control Registers (sets all Control
Register bits to logic low) and places the display in the
sleep mode. The Reset pin should be connected to the
system power on reset circuit. The Dot Registers are not
cleared upon power-on or by Reset. After power-on,
the Dot Register contents are random; however, Reset
will put the display in sleep mode, thereby blanking the
LEDs. The Control Register and the Control Words are
cleared to all zeros by Reset.
To operate the display after being Reset, load the Dot
Register with logic lows. Then load Control Word 0 with
the desired brightness level and set the sleep mode bit
to logic high.
Dot Register
The Dot Register holds the pattern to be displayed by the
LEDs. Data is loaded into the Dot Register according to
the procedure shown in Table 1 and Figure 5.
First RS is brought low, then CE is brought low. Next, each
successive rising CLK edge will shift in the data at the DIN
pin. Loading a logic high will turn the corresponding
LED on; a logic low turns the LED o. When all 160 bits
have been loaded (or 320 bits in an 8-digit display), CE is
brought to logic high.
When CLK is next brought to logic low, new data is
latched into the display dot drivers. Loading data into
the Dot Register takes place while the previous data is
displayed and eliminates the need to blank the display
while loading data.
Table 1. Register Truth Table
Function CLK CE RS
Select Dot Register Not Rising p L
Load Dot Register n L X
D
IN = HIGH LED = “ON”
D
IN = LOW LED = “OFF”
Copy Data from Dot Register to Dot Latch L H X
Select Control Register Not Rising p H
Load Control Register[1,3] n L X
Latch Data to Control Word[2] L H X
Notes:
1. BIT D0 of Control Word 1 must have been previously set to Low for serial mode or High for simultaneous mode.
2. Selection of Control Word 1 or Control Word 0 is set by D7 of the Control Shift Register. The unselected control word retains its previous value.
3. Control Word data is loaded Most Signicant Bit (D7) rst.
9
Figure 5. HCMS-39XX write cycle timing diagram
Pixel Map
In a 4-character display, the 160-bits are arranged as 20
columns by 8 rows. This array can be conceptualized as
four 5 x 8 dot matrix character locations, but only 7 of
the 8 rows have LEDs (see Figures 6 & 7). The bottom
row (row 0) is not used. Thus, latch location 0 is never
displayed. Column 0 controls the left-most column.
Data from Dot Latch locations 0-7 determine whether
or not pixels in Column 0 are turned-on or turned-o.
Therefore, the lower left pixel is turned-on when a logic
high is stored in Dot Latch location 1. Characters are
loaded in serially, with the left-most character being
loaded rst and the right-most character being loaded
last. By loading one character at a time and latching
the data before loading the next character, the gures
will appear to scroll from right to left.
NOTE:
1. DATA IS COPIED TO THE CONTROL REGISTER OR THE DOT LATCH AND LED OUTPUTS WHEN CE IS HIGH AND CLK IS LOW.
T
RSS RSH
T
T
CLKCE CES
T
CLKH
T
CLKL
T
CEH
T
DS
T
DH
T
CEDO
T
DOUT
T
DOUTP
T
PREVIOUS DATA NEW DATA
NEW DATA LATCHED HERE
[1]
CE
RS
CLK
D
IN
LED OUTPUTS,
CONTROL
REGISTERS
D
OUT
S
IMULTANEOUS)
D
OUT
(SERIAL)
34
12
5
12
11
67
10 8
9
10
Figure 6. Block diagram for HCMS-39xx
40 BIT
S.R.
DO
DI
DATA IN
OSCILLATOR
÷8
CLK
CHIP
ENABLE
REGISTER
SELECT
RESET
OSC
OSC
SELECT
BLANK
DATA IN
CLR
DATA
OUT
CONTROL
REGISTER
REFRESH
CONTROL
RST
PRESCALE
VALUE
H
L
H
L
L
H
D Q
RS
(LATCHED)
L
H
CURRENT
REFERENCE
PWM BRIGHTNESS
CONTROL
LH
LH
RS (LATCHED)
SER/PAR
MODE
3:8 DECODER
40 BIT
S.R.
DO
DI
40 BIT
S.R.
DO
DI
40 BIT
S.R.
DO
DI
ANODE CURRENT SOURCES
V LED +
GND (LED)
0
CHAR 0
COLUMN 0 COLUMN 19
CHAR 1 CHAR 2 CHAR 3
ROW 7
DOT
REGISTER
BIT # 159
ROW 1
ROW 0 (NO LEDS)
DOT
REGISTERS
AND
LATCHES
DATA OUT
CATHODE
FIELD DRIVERS
xxxx xxxxx xxxxx xxxxx
11
Figure 7. Pixel map
ROW 0
(NOT USED)
DATA TO
NEXT
CHARACTER
PIXEL
DATA FROM
PREVIOUS
CHARACTER
ROW 7
ROW 6
ROW 5
ROW 4
ROW 3
ROW 2
ROW 1
12
Control Register
The Control Register allows software modication of
the IC’s operation and consists of two independent
7-bit control words. Bit D7 in the shift register selects
one of the two 7-bit control words. Control Word 0
performs pulse width modulation brightness control,
peak pixel current brightness control, and sleep mode.
Control Word 1 sets serial/simultaneous data out
mode, and external oscillator prescaler. Each function is
independent of the others.
Control Register Data Loading
Data is loaded into the Control Register, MSB rst,
according to the procedure shown in Table 1 and Figure
5. First, RS is brought to logic high and then CE is brought
to logic low. Next, each successive rising CLK edge will
shift in the data on the DIN pin. Finally, when 8 bits
have been loaded, the CE line is brought to logic high.
When CLK goes to logic low, new data is copied into the
selected control word. Loading data into the Control
Register takes place while the previous control word
congures the display.
Control Word 0
Loading the Control Register with D7 = Logic low selects
Control Word 0 (see Table 2). Bits D0 -D3 adjust the
display brightness by pulse width modulating the LED
on time, while Bits D4 -D5 adjusts the display brightness
by changing the peak pixel current. Bit D6 selects normal
operation or sleep mode.
Sleep mode (Control Word 0, bit D6 = Low) turns o the
Internal Display Oscillator and the LED pixel drivers. This
mode is used when the IC needs to be powered up, but
does not need to be active. Current draw in sleep mode
is nearly zero. Data in the Dot Register and Control Words
are retained during sleep mode.
Control Word 1
Loading the Control Register with D7 = logic high
selects Control Word 1. This Control Word performs
two functions: serial/simultaneous data out mode and
external oscillator prescale select (see Table 2).
13
Table 2. Control Shift Register.
L D6 D
5 D
4 D
3 D
2 D
1 D
0
Bit D7
Set Low
to Select
Control
Word 0
On-Time Duty Relative
Oscillator Factor Brightness
Cycles (%) (%)
0 0 0
1 0.2 1.7
2 0.4 3.3
3 0.6 5.0
4 0.8 6.7
5 1.0 8.3
7 1.4 11.7
9 1.8 15
11 2.1 18
14 2.7 23
18 3.5 30
22 4.3 37
28 5.5 47
36 7.0 60
48 9.4 80
60 11.7 100
PWM Brightness Control
L L L L
L L L H
L L H L
L L H H
L H L L
L H L H
L H H L
L H H H
H L L L
H L L H
H L H L
H L H H
H H L L
H H L H
H H H L
H H H H
Peak Current Typical Peak Relative Full
Brightness Pixel Current Scale Current
Control (mA) (Relative Brightness, %)
H L 4.0 31
L H 6.4 50
L L 9.3 73 (Default at Power Up)
H H 12.8 100
SLEEP MODE L – DISABLES INTERNAL OSCILLATOR-DISPLAY BLANK
H – NORMAL OPERATION
CONTROL WORD 0
H L L L L L D1 D
0
CONTROL WORD 1
Bit D7
Set High
to Select
Control
Word 1
Reserved for Future
Use (Bits D2-D6 must
be set Low)
Serial/Simultaneous Data Out
L – DOUT holds contents of Bit D7
H – DOUT is functionally tied to Din
External Display Oscillator Pres-
caler
L – Oscillator Freq ÷ 1
H – Oscillator Freq ÷ 8
14
Serial/Simultaneous Data Output D0
Bit D0 of control word 1 is used to switch the mode of
DOUT between serial and simultaneous data entry during
Control Register writes. The default mode (logic low) is
the serial DOUT mode. In serial mode, DOUT is connected
to the last bit (D7) of the Control Shift Register.
Storing logic high to bit D0 changes DOUT to
simultaneous mode, which aects the Control Register
only. In simultaneous mode, DOUT is logically connected
to DIN. This arrange ment allows multiple ICs to have their
Control Registers written to simultaneously. For example,
for n ICs in the serial mode, n * 8 clock pulses are needed
to load the same data in all Control Registers. In the
simultaneous mode, n ICs only need 8 clock pulses to
load the same data in all Control Registers. The propaga-
tion delay from the rst IC to the last is n * tDOUTP
.
External Oscillator Prescaler Bit D1
Bit D1 of Control Word 1 is used to scale the frequency of
an external Display Oscillator. When this bit is logic low,
the external Display Oscillator directly sets the internal
display clock rate. When this bit is logic high, the external
oscillator is divided by 8. This scaled frequency then sets
the internal display clock rate. It takes 512 cycles of the
display clock (or 8 x 512 = 4096 cycles of an external clock
with the divide by 8 prescaler) to completely refresh the
display once. Using the prescaler bit allows the designer
to use a higher external oscillator frequency without
extra circuitry.
This bit has no aect on the internal Display Oscillator
Frequency.
Bits D2 -D6
These bits must always be pro-grammed to logic low.
Cascaded ICs
Figure 8 shows how two ICs are connected within an
HCMS-39XX display. The rst IC controls the four left-
most characters and the second IC controls the four
right-most characters. The Dot Registers are connected
in series to form a 320-bit dot shift register. The location
of pixel 0 has not changed. However, Dot Shift Register
bit 0 of IC2 becomes bit 160 of the 320-bit dot shift
register.
The Control Registers of the two ICs are independent
of each other. This means that to adjust the display
brightness the same control word must be entered
into both ICs, unless the Control Registers are set to
simultaneous mode.
Longer character string systems can be built by cascading
multiple displays together. This is accom plished by
creating a ve-line bus. This bus consists of CE, RS, BL,
Reset, and CLK. The display pins are connected to the
corresponding bus line. Thus, all CE pins are connected
to the CE bus line. Similarly, bus lines for RS, BL, Reset,
and CLK are created. Then DIN is connected to the right-
most display. DOUT from this display is connected to the
next display. The left-most display receives its DIN from
the DOUT of the display to its right. DOUT from the left-
most display is not used.
Each display may be set to use its internal oscillator, or
the displays may be synchronized by setting up one
display as the master and the others as slaves. The slaves
are set to receive their oscillator input from the masters
oscillator output.
15
Figure 8. Cascaded ICs
CE
IC2
BITS 160-319
CHARACTERS 4-7
RS
BL
SEL
OSC
CLK
D
OUT
DIN
IC1
BITS 0-159
CHARACTERS 0-3
DIN
RS
BL
SEL
OSC
CLK
DOUT
CE
RESET
RESET
RS
BL
SEL
OSC
CLK
D
OUT
CE
RESET
DIN
16
Appendix A. Thermal Considerations
The display IC has a maximum junction temperature of
150°C. The IC junction temperature can be calculated
with Equation 1 in Table 3.
A typical value for RθJA is 100°C/W. This value is typical
for a display mounted in a socket and covered with a
plastic lter. The socket is soldered to a .062 inch thick
PCB with .020-inch wide, one ounce copper traces. PD
can be calculated as Equation 2 in Table 3.
Figure 9 shows how to derate the power of one IC
versus ambient temperature. Operation at high ambient
temperatures may require the power per IC to be
reduced. The power consumption can be reduced by
changing the N, IPIXEL , Osc cyc or VLED. Changing VLOGIC
has very little impact on the power consumption.
Figure 9. Maximum power dissipation per IC versus ambient temperature
P MAX – MAXIMUM POWER
DISSIPATION PER IC – W
D
0
25
TA– AMBIENT TEMPERATURE – °C
0.7
0.6
0.5
0.4
0.3
0.2
0.1
60555045403530
0.8
0.9
1.0
1.1
1.2
8580757065
R = 100°C/W
90
1.3
θJ-A
17
Appendix B. Electrical Considerations
Current Calculations
The peak and average display current requirements
have a signicant impact on power supply selection. The
maximum peak current is calculated with Equation 3 in
Table 3.
The average current required by the display can be
calculated with Equation 4 in Table 3.
The power supply has to be able to supply IPEAK
transients and supply ILED (AVG) continuously. The
range on VLED allows noise on this supply without
signi cantly changing the display brightness.
VLOGIC and VLED Considerations
The display uses two independent electrical systems.
One system is used to power the display’s logic and the
other to power the displays LEDs. These two systems
keep the logic supply clean.
Separate electrical systems allow the voltage applied to
VLED and VLOGIC to be varied in dependently. Thus, VLED
can vary from 0 to 5.5 V without aecting either the Dot
or the Control Registers. VLED can be varied between 3.1
to 5.5 V without much noticeable variation in light output
to the human eyes. There is also no pixel mismatch
observed.
The intensity of the light output takes a plunge if
operated less than 3.1 V. There is also no pixel mismatch
observed at voltage as low as 2.6 V. However, operating
below 3.1 V is not recommended. Dimming the display by
pulse width modulating VLED is also not recommended.
VLOGIC can vary from 3.0 to 5.5 V without aecting either
the displayed message or the display intensity. However,
operating below 3 V may change the timing and logic
levels and may cause Dot and Control Registers to be
altered. Thus, operation of the display below 3.0 V is not
recommended.
The logic ground is internally connected to the LED
ground by a substrate diode. This diode becomes
forward biased and conducts when the logic ground
is 0.4 V greater than the LED ground. The LED ground
and the logic ground should be connected to a common
ground, which can withstand the current introduced
by the switching LED drivers. When separate ground
connections are used, the LED ground can vary from
-0.3 V to +0.3 V with respect to the logic ground. Voltages
below -0.3 V can cause all the dots to be ON. Voltage
above +0.3 V can cause dimming and dot mismatch.
Using a decoupling capacitor between the power supply
and ground will help prevent any supply noise in the
frequency range greater than that of the functioning
display from interfering with the display’s internal
circuitry. The value of the capacitor depends on the series
resistance from the ground back to the power supply
and the range of frequencies that need to be suppressed.
It is also advantageous to use the largest ground plane
possible.
Electrostatic Discharge
The inputs to the ICs are protected against static
discharge and input current latch up. However, for best
results, standard CMOS handling precautions should
be used. Before use, the HCMS-39XX should be stored
in antistatic tubes or in conductive material. During
assembly, a grounded conductive work area should be
used and assembly personnel should wear conductive
wrist straps. Lab coats made of synthetic material
should be avoided since they are prone to static
buildup. Input current latch up is caused when the
CMOS inputs are subjected to either a voltage below
ground (VIN < ground) or to a voltage higher than
VLOGIC (VIN > VLOGIC) and when a high current is forced
into the input. To prevent input current latch up and ESD
damage, unused inputs should be connected to either
ground or VLOGIC. Voltages should not be applied to the
inputs until VLOGIC has been applied to the display.
Table 3. Equations.
Equation 1:
TJ MAX = TA + PD * RθJA
Where:
TJ MAX = maximum IC junction temperature
TA = ambient temperature surrounding the display
JA = thermal resistance from the IC junction to ambient
PD
= total power dissipation
Equation 2:
PD = (N * IPIXEL * Duty Factor * VLED) + ILOGIC * VLOGIC
Where:
PD = total power dissipation
N = number of pixels on (maximum 4 char * 5 * 7 = 140)
IPIXEL = peak pixel current.
Duty Factor = 1/8 * Osccyc/64
Osc cyc = number of ON oscillator cycles per row
ILOGIC = IC logic current
VLOGIC = logic supply voltage
Equation 3:
IPEAK = M * 20 * IPIXEL
Where:
IPEAK = maximum instantaneous peak current for the display
M = number of ICs in the system
20 = maximum number of LEDs on per IC
IPIXEL = peak current for one LED
Equation 4:
ILED (AVG) = N * IPIXEL * 1/8 * (oscillator cycles)/64
(See Variable Denitions above)
For product information and a complete list of distributors, please go to our website: www.avagotech.com
Avago, Avago Technologies, and the A logo are trademarks of Avago Technologies in the United States and other countries.
Data subject to change. Copyright © 2005-2010 Avago Technologies. All rights reserved. Obsoletes AV01-0310EN
AV02-0868EN - August 20, 2010
Figure 10. Relative luminous Intensity versus ambient temperature
Appendix F. Reference Material
Application Note 1027: Soldering LED Components
Application Note 1015: Contrast Enhancement Techniques
for LED Displays
Appendix E. Display Brightness
Two ways have been shown to control the brightness
of this LED display: setting the peak current and setting
the duty factor. Both values are set in Control Word 0.
To compute the resulting display brightness when both
PWM and peak current control are used, simply multiply
the two relative brightness factors. For example, if
Control Register 0 holds the word 1001101, the peak
current is 73% of full scale (BIT D5=L, BIT D4 = L) and the
PWM is set to 60% duty factor (BIT D3 = H, BIT D2 = H,
BIT D1 = L, BIT D0 = H). The resulting brightness is 44%
(.73 x .60 = .44) of full scale.
The temperature of the display will also aect the LED
bright ness as shown in Figure 10.
Appendix C. Oscillator
The oscillator provides the internal refresh circuitry
with a signal that is used to synchronize the columns
and rows. This ensures that the right data is in the dot
drivers for that row. This signal can be supplied from
either an external source or the internal source.
A display refresh rate of 100 Hz or faster ensures
icker-free operation. Thus, for an external oscillator the
frequency should be greater than or equal to 512 x 100 Hz
= 51.2 kHz. Operation above 1 MHz without the prescaler
or 8 MHz with the prescaler may cause noticeable pixel-
to-pixel mismatch.
Appendix D. Refresh Circuitry
This display driver consists of 20 one-of-eight column
decoders and 20 constant current sources, 1 one-of-
eight row decoder and eight row sinks, a pulse width
modulation control block, a peak current control
block, and the circuit to refresh the LEDs. The refresh
counters and oscillator are used to synchronize the
columns and rows.
The 160 bits are organized as 20 columns by 8 rows.
The IC illuminates the display by sequentially turning
ON each of the 8 row-drivers. To refresh the display
once takes 512 oscillator cycles. Because there are
eight row drivers, each row driver is selected for 64
(512/8) oscillator cycles. Four cycles are used to briey
blank the display before the following row is switched
on. Thus, each row is ON for 60 oscillator cycles out of a
possible 64. This corresponds to the maximum LED on
time.