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HCMS-29X5 Datasheet, PDF (15/16 Pages) Agilent(Hewlett-Packard) – High Performance CMOS 5 x 7 Alphanumeric Displays
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be varied between 4.0 to 5.5 V
without any noticeable variation
in light output. However, operat-
ing VLED below 4.0 V may cause
objectionable mismatch between
the pixels and 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 affecting either the
displayed message or the display
intensity. However, operation
below 4.5 V will change the
timing and logic levels and
operation below 3 V may cause
the Dot and Control Registers to
be altered.
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 then 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. The
LED ground for the LED drivers
can be routed separately from the
logic ground until an appropriate
ground plane is available. On long
interconnections between the
display and the host system,
voltage drops on the analog
ground can be kept from affecting
the display logic levels by
isolating the two grounds.
Electrostatic Discharge
The inputs to the ICs are pro-
tected against static discharge
and input current latchup. How-
ever, for best results, standard
CMOS handling precautions
should be used. Before use, the
HCMS-29XX 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
latchup is caused when the CMOS
inputs are subjected to either a
voltage below ground (VIN <
ground) or to a voltage higher
then VLOGIC (VIN > VLOGIC) and
when a high current is forced into
the input. To prevent input
current latchup and ESD damage,
unused inputs should be con-
nected to either ground or VLOGIC.
Voltages should not be applied to
the inputs until VLOGIC has been
applied to the display.
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 flicker-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
briefly 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.
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