MC14541B
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6
TYPICAL RC OSCILLATOR CHARACTERISTICS
Figure 4. RC Oscillator Stability
Figure 5. RC Oscillator Frequency as a
Function of R
and C
8.0
4.0
0
-4.0
-8.0
-12
-16
1251007550250-25-55
T
A
, AMBIENT TEMPERATURE (°C)
FREQUENCY DEVIATION (%)
V
DD
= 15 V
10 V
5.0 V
R
S
= 0, f = 10.15 kHz @ V
DD
= 10 V, T
A
= 25°C
R
S
= 120 kW, f = 7.8 kHz @ V
DD
= 10 V, T
A
= 25°C
R
TC
= 56 kW,
C = 1000 pF
100
0.1
0.2
0.5
1.0
2.0
5.0
10
20
50
1.0 k 10 k 100 k 1.0 m
f, OSCILLATOR FREQUENCY (kHz)
R
TC
, RESISTANCE (OHMS)
0.0001 0.001 0.01 0.1
C, CAPACITANCE (mF)
V
DD
= 10 V
f AS A FUNCTION
OF R
TC
(C = 1000 pF)
(R
S
≈ 2R
TC
)
f AS A FUNCTION
OF C
(R
TC
= 56 kW)
(R
S
= 120 kW)
OPERATING CHARACTERISTICS
With Auto Reset pin set to a “0” the counter circuit is
initialized by turning on power. Or with power already on,
the counter circuit is reset when the Master Reset pin is set
to a “1”. Both types of reset will result in synchronously
resetting all counter stages independent of counter state.
Auto Reset pin when set to a “1” provides a low power
operation.
The RC oscillator as shown in Figure 3 will oscillate with
a frequency determined by the external RC network i.e.,
if (1 kHz v f v 100 kHz)
2.3 R
tc
C
tc
1
f =
and R
S
≈ 2 R
tc
where R
S
≥ 10 kW
The time select inputs (A and B) provide a two−bit address
to output any one of four counter stages (2
8
, 2
10
, 2
13
and
2
16
). The 2
n
counts as shown in the Frequency Selection
Table represents the Q output of the N
th
stage of the counter.
When A is “1”, 2
16
is selected for both states of B. However,
when B is “0”, normal counting is interrupted and the 9th
counter stage receives its clock directly from the oscillator
(i.e., effectively outputting 2
8
).
The Q/Q
select output control pin provides for a choice of
output level. When the counter is in a reset condition and
Q/Q
select pin is set to a “0” the Q output is a “0”,
correspondingly when Q/Q
select pin is set to a “1” the Q
output is a “1”.
When the mode control pin is set to a “1”, the selected
count is continually transmitted to the output. But, with
mode pin “0” and after a reset condition the R
S
flip−flop (see
Expanded Block Diagram) resets, counting commences,
and after 2
n−1
counts the R
S
flip−flop sets which causes the
output to change state. Hence, after another 2
n−1
counts the
output will not change. Thus, a Master Reset pulse must be
applied or a change in the mode pin level is required to reset
the single cycle operation.
DIGITAL TIMER APPLICATION
R
tc
C
tc
NC
R
S
AR
MR
INPUT
t
MR
V
DD
B
A
N.C.
OUTPUT
V
DD
MODE
Q/Q
t + t
MR
1
2
3
4
5
6
78
9
10
11
12
13
14
When Master Reset (MR) receives a positive pulse, the
internal counters and latch are reset. The Q output goes high
and remains high until the selected (via A and B) number of
clock pulses are counted, the Q output then goes low and
remains low until another input pulse is received.
This “one shot” is fully retriggerable and as accurate as the
input frequency. An external clock can be used (pin 3 is the
clock input, pins 1 and 2 are outputs) if additional accuracy
is needed.
Notice that a setup time equal to the desired pulse width
output is required immediately following initial power up,
during which time Q output will be high.
