English
Language : 

ICM7245_14 Datasheet, PDF (11/13 Pages) Intersil Corporation – 8-Character, 16-Segment, Microprocessor Compatible,LED Display Decoder Driver
ICM7245
Display Font and Segment Assignments (Continued)
VDD
SEGMENT
DRIVER
VLED = 2V
RTYPICAL =136Ω
R
SEG x DISPLAY
CHARACTER
DRIVER
CHAR N
rDS(ON) ~ 7.4Ω
VSS
SEGMENT LEDs
FIGURE 10. SEGMENT AND CHARACTER DRIVERS OUTPUT CIRCUIT
Detailed Description
WR, CS
These pins are immediately functionally ANDed, so all actions
described as occurring on an edge of WR, with CS enabled, will
occur on the equivalent (last) enabling or (first) disabling edge
of any of these inputs. The delays from CS pins are slightly
(about 5ns) greater than from WR due to the additional
inverter required on the former.
MODE
The MODE pin input is latched on the falling edge of WR (or its
equivalent, see WR description). The location (in Data
Memory) where incoming data will be placed is determined
either from the Address pins or the Sequential Address
Counter. This is controlled by MODE input. MODE also controls
the function of A0/SEN, A1/CLR, and A2/DlSPlay FULL lines.
Random Access Mode
When the internal mode latch is set for Random Access (RA)
(MODE latched low), the Address input on A0, A1 and A2 will
be latched by the falling edge of WR (or its equivalent).
Subsequent changes on the Address lines will not affect device
operation. This allows use of a multiplexed 6-bit bus controlling
both address and data, with timing controlled by WR.
Sequential Access Mode
If the internal latch is set for Sequential Access (SA), (MODE
latched high), the Serial ENable input or SEN will be latched on
the falling edge of WR (or its equivalent). The CLR input is
asynchronous, and will force-clear the Sequential Address
Counter to address 000 (CHARacter 1), and set all Data
Memory contents to 100000 (blank) at any time. The DISPlay
FULL output will be active in SA mode to indicate the overflow
status of the Sequential Address Counter. If this output is low,
and SEN is (latched) high, the contents of the Counter will be
used to establish the Data Memory location for the Data input.
The Counter is then incremented on the rising edge of WR. If
SEN is low, or DISPlay FULL is high, no action will occur. This
allows easy “daisy-chaining” of display drivers for multiple
character displays in a Sequential Access mode.
Changing Modes
Care must be exercised in any application involving changing
from one mode to another. The change will occur only on a
falling edge of WR (or its equivalent). When changing mode
from Sequential Access to Random Access, note that
A2/DlSPlay FULL will be an output until WR has fallen low, and
an Address drive here could cause a conflict. When changing
from Random Access to Sequential Access, A1/CLR should be
high to avoid inadvertent clearing of the Data Memory and
Sequential Address Counter. DISPlay FULL will become active
immediately after the rising edge of WR.
Data Entry
The input Data is latched on the rising edge of WR (or its
equivalent) and then stored in the Data Memory location
determined as described above. The six Data bits can be
multiplexed with the Address information on the same lines in
Random Access mode. Timing is controlled by the WR input.
OSC/OFF
The device includes a relaxation oscillator with an internal
capacitor and a nominal frequency of 200kHz. By adding
external capacitance to VDD at the OSC/OFF pin, this
frequency can be reduced as far as desired. Alternatively, an
external signal can be injected on this pin. The oscillator (or
external) frequency is pre-divided by 64, and then further
divided by 8 in the Multiplex Counter, to drive the CHARacter
drive lines (Figure 3). An inter-character blanking signal is
derived from the pre-divider. An additional comparator on the
OSC/OFF input detects a level lower than the relaxation
oscillator's range, and blanks the display, disables the DISPlay
FULL output (if active), and clears the pre-divider and Multiplex
Counter. This puts the circuit in a low-power-dissipation mode
11
FN8587.0
October 29, 2013