HITACHI HD74HC4538

HD74HC4538
Dual Precision Retriggerable/Resettable Monostable
Multivibrators
Description
Each multivibrator features both a negative, A, and a positive, B, transition triggered input, either of which
can be used as an inhibit input. Also included is a clear input that when taken low resets the one short. The
HD74HC4538 is retriggerable. That is, it may be triggered repeatedly while their outputs are generating a
pulse and the pulse will be extended.
Pulse width stability over a wide range of temperature. The output pulse equation is simply: tw = 0.7 (R)
(C).
Features
•
•
•
•
•
High Speed Operation: tpd (A or B to Y) = 22 ns typ (CL = 50 pF)
High Output Current: Fanout of 10 LSTTL Loads
Wide Operating Voltage: VCC = 2 to 6 V
Low Input Current: 1 µA max
Low Quiescent Supply Current
Function Table
Inputs
Outputs
CD
A
B
Q
Q
L
X
X
L
H
H
L
H
H
H
H
H
X :
Not triggered
L
Irrelevant
Not triggered
HD74HC4538
Pin Arrangement
T1A
1
16 VCC
T2A
2
T1
T2
T1
15 T1B
CDA
3
CD
T2
14 T2B
AA
4
A
CD
13 CDB
BA
5
B
A
12 AB
QA
6
Q
B
11 BB
QA
7
Q
Q
10 QB
GND
8
Q
9
(Top view)
2
QB
HD74HC4538
Block Diagram
CX
RX
VCC
T1A
T2A
QA
AA
BA
QA
CDA
CX
RX
VCC
T1B
T2B
QB
AB
BB
QB
CDB
RX and CX are external components
3
HD74HC4538
Absolute Maximum Ratings
Item
Symbol
Rating
Unit
Supply voltage range
VCC
–0.5 to +7.0
V
Input voltage
Vin
–0.5 to VCC + 0.5
V
Output voltage
Vout
–0.5 to VCC + 0.5
V
DC input diode current
I IK
±20
mA
DC input diode current pin 2, 14
I IK
±30
mA
DC output diode current
I OK
±20
mA
DC current drain per pin
Iout
±25
mA
DC current drain per VCC, GND
I CC, I GND
±50
mA
Power dissipation per package
PT
500
mW
Storage temperature
Tstg
–65 to +150
°C
4
HD74HC4538
DC Characteristics
Ta = –40 to
+85°C
Ta = 25°C
Item
Symbol
VCC (V) Min Typ Max Min
Max
Unit
Input voltage
VIH
2.0
1.5 —
—
1.5
—
V
4.5
3.15 —
—
3.15
—
6.0
4.2 —
—
4.2
—
2.0
—
—
0.5
—
0.5
4.5
—
—
1.35 —
1.35
6.0
—
—
1.8
—
1.8
2.0
1.9 2.0 —
1.9
—
4.5
4.4 4.5 —
4.4
—
6.0
5.9 6.0 —
5.9
—
4.5
4.18 —
—
4.13
—
I OH = –4 mA
6.0
5.68 —
—
5.63
—
I OH = –5.2 mA
2.0
—
0.0 0.1
—
0.1
4.5
—
0.0 0.1
—
0.1
6.0
—
0.0 0.1
—
0.1
4.5
—
—
0.26 —
0.33
I OL = 4 mA
6.0
—
—
0.26 —
0.33
I OL = 5.2 mA
VIL
Output voltage
VOH
VOL
Test Conditions
V
V
V
Vin = VIH or VIL I OH = –20 µA
Vin = VIH or VIL I OL = 20 µA
Input current
Iin
6.0
—
—
±0.1 —
±1.0
µA
Vin = VCC or GND
Quiescent supply
current
(standby state)
I CC
6.0
—
—
130 —
220
µA
Vin = VCC or GND,
QA = QB = GND, Iout = 0 µA
Current drain
(active state)
I CC
6.0
—
—
130 —
220
µA
Vin = VCC or GND,
QA = QB = VCC
Pin 2, 14 = 0.5 VCC
5
HD74HC4538
AC Characteristics (CL = 50 pF, Input tr = tf = 6 ns)
Ta = –40 to
+85°C
Ta = 25°C
VCC (V) Min Typ Max Min
Max
Unit
Test Conditions
Propagation delay t PLH
2.0
—
—
235 —
295
ns
A or B to Q
time
4.5
—
22
47
—
59
6.0
—
—
40
—
50
2.0
—
—
260 —
325
ns
A or B to Q
4.5
—
23
52
—
65
6.0
—
—
44
—
55
2.0
—
—
235 —
295
ns
CD to Q
4.5
—
17
47
—
59
6.0
—
—
40
—
50
2.0
—
—
235 —
295
ns
CD to Q
4.5
—
—
47
—
59
6.0
—
—
40
—
50
2.0
80
—
—
100
—
ns
A, B, C D
4.5
16
—
—
20
—
6.0
14
—
—
17
—
3.0
—
150 —
—
—
ns
RX = 1 kΩ, CX = 12 pF
5.0
—
100 —
—
—
3.0
—
—
—
—
—
µs
RX = 10 kΩ, CX = 100 pF
5.0
—
1.3 —
—
—
3.0
—
—
—
—
—
µs
RX = 10 kΩ, CX = 1000 pF
5.0
—
9
—
—
—
3.0
—
—
—
—
—
µs
RX = 10 kΩ, CX = 10000 pF
5.0
—
70
—
—
—
5.0
—
±0.1 —
—
—
%
RX = 10 kΩ, CX = 1000 pF
Item
Symbol
t PHL
t PHL
t PLH
Pulse width
tw
Output pulse width t WQ
Pulse width match ∆tWQ
between circuits in
the same package
Caution in use: In order to prevent any malfunctions due to noise, connect a high frequency performance
capacitor between V CC and GND, and keep the wiring between the External components and
Cext, Rext/Cext pins as short as possible.
6
HD74HC4538
Circuit Operation
Fig. 3 shows the HC4538 configured in the retriggerable mode. Briefly, the device operates as follows
(refer to Fig. 1): In the quiescent state, the external timing capacitor, CX, is charged to V CC. When a trigger
occurs, the Q output goes high and CX discharges quickly to the lower references voltage (Vref Lower 1/3
V CC). CX then charges, through RX, back up to the upper reference voltage (Vref Upper 2/3 V CC), at
which point the one-shot has timed out and the Q output goes low.
The following, more detailed description of the circuit operation refers to both the function diagram (Fig. 1)
and the timing diagram (Fig. 2)
Quiescent State
In the quiescent state, before an input trigger appears; the output latch is high and the reset latch is high (1
in Fig. 2). Thus the Q output (pin 6 or 10) of the monostable multivibrator is low (2 Fig. 2).
The output of the trigger-control circuit is low (3), and transistors M1, M2, and M3 are turned off. The
external timing capacitor, CX, is charged to VCC (4), and the upper reference circuit has a low output (5).
Transistor M4 is turned on and analog switch S1 is turned off. Thus the lower reference circuit has V CC at
the noninverting input and a resulting low output (6).
In addition, the output of the trigger-control reset circuit is low.
Trigger Operation
The HC4538 is triggered by either a rising-edge signal as input A (7) or a falling-edge signal at input B (8),
with the unused trigger input and the Reset input held at the voltage levels shown in the Function Table.
Either trigger signal will cause the output of the trigger-control circuit to go high (9). The trigger-control
circuit going high simultaneously initiates three events. First, the output latch goes low, thus taking the Q
output of the HC4538 to a high state (10). Second, transistor M3 is turned on, which allows the external
timing capacitor, CX, to rapidly discharge toward ground (11). (Note that the voltage across CX appears at
the input of the upper reference circuit comparator). Third, transistor M4 is turned off and analog switch
S1 is turned on, thus allowing the voltage across C X to also appear at the input of the lower reference circuit
comparator.
When CX discharges to the reference voltage of the lower reference circuit (12), the outputs of both
reference circuits will be high (13). The trigger-control circuit flip-flop to a low state (14). This turns
transistor M3 off again, allowing CX to begin to charge back up toward VCC, with a time constant t = RXCX
(15). In addition, transistor M4 is turned on and analog switch S1 is turned off. Thus a high voltage level
is applied to the input of the lower reference circuit comparator, causing its output to go low (16). The
monostable multivibrator may be retriggered at any time after the trigger-control circuit goes low.
When CX charges up to the reference voltage of the upper reference circuit (17), the output of the upper
reference circuit goes low (18). This causes the output latch to toggle, taking the Q output of the HC4538
to a low state (19), and completing the time-out cycle.
7
HD74HC4538
Reset Operation
A low voltage applied to the Reset pin always forces the Q output of the HC4538 to a low state.
The timing diagram illustrates the case in which reset occurs (20) while C X is charging up toward the
reference voltage of the upper reference circuit (21). When a reset occurs, the output of the reset latch goes
low (22), turning on transistor M1. Thus CX is allowed to quickly charge up to VCC (23) to await the next
trigger signal.
Retrigger Operation
When used in the retriggerable mode (Fig. 3), the HC4538 may be retriggered during timing out of the
output pulse at any time after the trigger-control circuit flip-flopw has been reset (24). Because the triggercontrol circuit flip-flop resets shortly after CX has discharged to the reference voltage of the lower reference
circuit (25), the minimum retrigger time, trr (Switching Waveform 1) is a function of internal propagation
delays and the discharge time of CX:
Fig. 4 shows the device configured in the non-retriggerable mode.
Power-Down Considerations
Large values of CX may cause problems when powering down the HC4538 because of the amount of
energy stored in the capacitor. When a system containing this device is powered down, the capacitor may
discharge from VCC through the input protection diodes at pin 2 or pin 14. Current through the protection
diodes must be limited to 30 mA; therefore, the turn-off time of the V CC power supply must not be faster
than t = VCC•CX/(30 mA). For example, if VCC = 5 V and CX = 15 µF, the VCC supply must turn off no
faster than t = (5 V)•(15 µF)/30 mA = 2.5 ms. This is usually not a problem because power supplies are
heavily filtered and cannot discharge at this rate.
When a more rapid decrease of VCC to zero voltage occurs, the HC4538 may sustain damage. To avoid this
possibility, use an external clamping diode.
8
HD74HC4538
VCC
RX
2, 14
T2
CX
VCC
M1
M2
Upper Reference
Circuit
2kΩ
Output Latch
+
–
M3
Vref Upper
6, 10
S1
M4
7, 9
Q
+
–
4, 12
Trigger-Control Circuit
A
Q
Lower Reference
Circuit
VCC
Vref Lower
C Q
B
CR
5, 11
Trigger-Control
Reset Circuit
3, 13
CD
Reset Latch
Fig. 1 Function Diagram
9
HD74HC4538
Quiescent
State
Trigger Cycle (A Input)
Trigger Cycle (B Input)
Reset
Retrigger
trr
7
Trigger Input A
(Pin 4 or 12)
Trigger Input B
(Pin 5 or 11)
8
Reset Input CD
(Pin 3 or 13)
21
24
9
14
3
Trigger-Control
Circuit Output
11
4
T2 Input
(Pin 2 or 14)
15
20 23
17
12
Vref Upper
Vref Lower 13
Upper Reference
Circuit Output
5
Lower Reference
Circuit Output
6
Reset Latch
Output
1
25
13
16
22
10
Q Output
(Pin 6 or 10)
19
2
tWQ
tWQ
tWQ+trr
tW (H)
50%
A
tW (L)
B
50%
tWQ
tPLH
Q
tPLH
50%
tPHL
Q
tPHL
50%
A
trr
B
50%
tf
tr
50%
CD
tW (L)
tPHL
50%
tTLH
90%
10%
Q
tTHL
Q
90%
10%
90%
10%
tWQ+trr
50%
(Retriggered Pulse)
tPLH
50%
Fig. 2 Timing Diagram
10
HD74HC4538
CX
RX
VCC
T1
T2
Q
A
Rising-Edge
Trigger
B
Q
CD
CX
RX
VCC
T1
T2
Q
A
B
Q
Rising-Edge
Trigger
CD
Fig. 3 Retriggerable Monostable Circuitry
11
HD74HC4538
CX
RX
VCC
T1
T2
Q
A
Falling-Edge
Trigger
B
Q
CD
CX
RX
VCC
T1
T2
Q
A
B
Q
Falling-Edge
Trigger
CD
Fig. 4 Nonritriggerable Monostable Circuitry
12
Unit: mm
19.20
20.00 Max
1
7.40 Max
9
6.30
16
8
1.3
0.48 ± 0.10
2.54 Min 5.06 Max
2.54 ± 0.25
0.51 Min
1.11 Max
7.62
+ 0.13
0.25 – 0.05
0° – 15°
Hitachi Code
JEDEC
EIAJ
Weight (reference value)
DP-16
Conforms
Conforms
1.07 g
Unit: mm
10.06
10.5 Max
9
1
8
1.27
*0.42 ± 0.08
0.40 ± 0.06
0.10 ± 0.10
0.80 Max
*0.22 ± 0.05
0.20 ± 0.04
2.20 Max
5.5
16
0.20
7.80 +– 0.30
1.15
0° – 8°
0.70 ± 0.20
0.15
0.12 M
*Dimension including the plating thickness
Base material dimension
Hitachi Code
JEDEC
EIAJ
Weight (reference value)
FP-16DA
—
Conforms
0.24 g
Unit: mm
9.9
10.3 Max
9
1
8
0.635 Max
*0.42 ± 0.08
0.40 ± 0.06
0.15
*0.22 ± 0.03
0.20 ± 0.03
1.27
0.11
0.14 +– 0.04
1.75 Max
3.95
16
0.10
6.10 +– 0.30
1.08
0° – 8°
0.67
0.60 +– 0.20
0.25 M
*Dimension including the plating thickness
Base material dimension
Hitachi Code
JEDEC
EIAJ
Weight (reference value)
FP-16DN
Conforms
Conforms
0.15 g
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contact Hitachi’s sales office before using the product in an application that demands especially high
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4. Design your application so that the product is used within the ranges guaranteed by Hitachi particularly
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conditions and other characteristics. Hitachi bears no responsibility for failure or damage when used
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failure rates or failure modes in semiconductor devices and employ systemic measures such as failsafes, so that the equipment incorporating Hitachi product does not cause bodily injury, fire or other
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