MOTOROLA MC14536BF, MC14536BDWR2, MC14536BCP, MC14536BDW, MC14536BFL2 Datasheet

...
Semiconductor Components Industries, LLC, 2000
March, 2000 – Rev. 5
1 Publication Order Number:
MC14536B/D
MC14536B
Programmable Timer
The MC14536B programmable timer is a 24–stage binary ripple counter with 16 stages selectable by a binary code. Provisions for an on–chip RC oscillator or an external clock are provided. An on–chip monostable circuit incorporating a pulse–type output has been included. By selecting the appropriate counter stage in conjunction with the appropriate input clock frequency, a variety of timing can be achieved.
24 Flip–Flop Stages — Will Count From 2
0
to 2
24
Last 16 Stages Selectable By Four–Bit Select Code
8–Bypass Input Allows Bypassing of First Eight Stages
Set and Reset Inputs
Clock Inhibit and Oscillator Inhibit Inputs
On–Chip RC Oscillator Provisions
On–Chip Monostable Output Provisions
Clock Conditioning Circuit Permits Operation With Very Long Rise
and Fall Times
Test Mode Allows Fast Test Sequence
Supply Voltage Range = 3.0 Vdc to 18 Vdc
Capable of Driving Two Low–power TTL Loads or One Low–power
Schottky TTL Load Over the Rated Temperature Range
MAXIMUM RATINGS (Voltages Referenced to V
SS
) (Note 2.)
Symbol
Parameter Value Unit
V
DD
DC Supply Voltage Range –0.5 to +18.0 V
Vin, V
out
Input or Output Voltage Range
(DC or Transient)
–0.5 to VDD + 0.5 V
Iin, I
out
Input or Output Current
(DC or Transient) per Pin
±10 mA
P
D
Power Dissipation,
per Package (Note 3.)
500 mW
T
A
Operating Temperature Range –55 to +125 °C
T
stg
Storage Temperature Range –65 to +150 °C
T
L
Lead Temperature
(8–Second Soldering)
260 °C
2. Maximum Ratings are those values beyond which damage to the device
may occur.
3. Temperature Derating:
Plastic “P and D/DW” Packages: – 7.0 mW/_C From 65_C T o 125_C
This device contains protection circuitry to guard against damage due to high static voltages or electric fields. However, precautions must be taken to avoid applications of any voltage higher than maximum rated voltages to this high–impedance circuit. For proper operation, V
in
and V
out
should be constrained
to the range V
SS
v (Vin or V
out
) v VDD.
Unused inputs must always be tied to an appropriate logic voltage level (e.g., either V
SS
or VDD). Unused outputs must be left open.
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A = Assembly Location WL or L = Wafer Lot YY or Y = Year WW or W = Work Week
Device Package Shipping
ORDERING INFORMATION
MC14536BCP PDIP–16 2000/Box MC14536BDW SOIC–16 47/Rail
MARKING
DIAGRAMS
1
16
PDIP–16
P SUFFIX
CASE 648
MC14536BCP
AWLYYWW
MC14536BDWR2 SOIC–16 1000/Tape & Reel
SOIC–16 DW SUFFIX CASE 751G
1
16
14536B
AWLYYWW
1. For ordering information on the EIAJ version of the SOIC packages, please contact your local ON Semiconductor representative.
SOEIAJ–16
F SUFFIX
CASE 966
1
16
MC14536B
AWLYWW
MC14536BF SOEIAJ–16 See Note 1.
MC14536B
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2
BLOCK DIAGRAM
STAGES 9 THRU 24
Q24Q23Q22Q21Q20Q19Q18Q17Q16Q15Q14Q13Q12Q11Q10Q
9
DECODER
MONOSTABLE
MULTIVIBRATOR
DECODE
OUT
13MONO–IN 15
D12
C11
B10
A9
V
DD
= PIN 16
V
SS
= PIN 8
STAGES
1 THRU 8
8 BYPASSSETRESETCLOCK INH.
7216
5
OUT
2
4
OUT
1
3
IN
1
OSC. INHIBIT 14
PIN ASSIGNMENT
13
14
15
16
9
10
11
125
4
3
2
1
8
7
6
D
DECODE
OSC INH
MONO IN
V
DD
A
B
C
OUT 1
IN 1
RESET
SET
V
SS
CLOCK INH
8–BYPASS
OUT 2
MC14536B
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3
ELECTRICAL CHARACTERISTICS (Voltages Referenced to V
SS
)
V
– 55_C 25_C 125_C
Characteristic Symbol
V
DD
Vdc
Min Max Min Typ
(4.)
Max Min Max
Unit
Output Voltage “0” Level
V
in
= VDD or 0
V
OL
5.0 10 15
— — —
0.05
0.05
0.05
— — —
0 0 0
0.05
0.05
0.05
— — —
0.05
0.05
0.05
Vdc
“1” Level
V
in
= 0 or V
DD
V
OH
5.0 10 15
4.95
9.95
14.95
— — —
4.95
9.95
14.95
5.0 10 15
— — —
4.95
9.95
14.95
— — —
Vdc
Input Voltage “0” Level
(V
O
= 4.5 or 0.5 Vdc)
(V
O
= 9.0 or 1.0 Vdc)
(V
O
= 13.5 or 1.5 Vdc)
V
IL
5.0 10 15
— — —
1.5
3.0
4.0
— — —
2.25
4.50
6.75
1.5
3.0
4.0
— — —
1.5
3.0
4.0
Vdc
“1” Level
(V
O
= 0.5 or 4.5 Vdc)
(V
O
= 1.0 or 9.0 Vdc)
(V
O
= 1.5 or 13.5 Vdc)
V
IH
5.0 10 15
3.5
7.0 11
— — —
3.5
7.0 11
2.75
5.50
8.25
— — —
3.5
7.0 11
— — —
Vdc
Output Drive Current
(V
OH
= 2.5 Vdc) Source
(V
OH
= 4.6 Vdc) Pins 4 & 5
(V
OH
= 9.5 Vdc)
(V
OH
= 13.5 Vdc)
I
OH
5.0
5.0 10 15
– 1.2 – 0.25 – 0.62
– 1.8
— — — —
– 1.0
– 0.25
– 0.5 – 1.5
– 1.7
– 0.36
– 0.9 – 3.5
— — — —
– 0.7 – 0.14 – 0.35
– 1.1
— — — —
mAdc
(VOH = 2.5 Vdc) Source (V
OH
= 4.6 Vdc) Pin 13
(V
OH
= 9.5 Vdc)
(V
OH
= 13.5 Vdc)
5.0
5.0 10 15
– 3.0
– 0.64
– 1.6 – 4.2
— — — —
– 2.4
– 0.51
– 1.3 – 3.4
– 4.2 – 0.88 – 2.25
– 8.8
— — — —
– 1.7
– 0.36
– 0.9 – 2.4
— — — —
mAdc
(VOL = 0.4 Vdc) Sink (V
OL
= 0.5 Vdc)
(V
OL
= 1.5 Vdc)
I
OL
5.0 10 15
0.64
1.6
4.2
— — —
0.51
1.3
3.4
0.88
2.25
8.8
— — —
0.36
0.9
2.4
— — —
mAdc
Input Current I
in
15 ±0.1 ±0.00001 ±0.1 ±1.0 µAdc
Input Capacitance
(V
in
= 0)
C
in
5.0 7.5 pF
Quiescent Current
(Per Package)
I
DD
5.0 10 15
— — —
5.0 10 20
— — —
0.010
0.020
0.030
5.0 10 20
— — —
150 300 600
µAdc
Total Supply Current
(5.) (6.)
(Dynamic plus Quiescent, Per Package) (C
L
= 50 pF on all outputs, all
buffers switching)
I
T
5.0 10 15
IT = (1.50 µA/kHz) f + I
DD
IT = (2.30 µA/kHz) f + I
DD
IT = (3.55 µA/kHz) f + I
DD
µAdc
4. Data labelled “Typ” is not to be used for design purposes but is intended as an indication of the IC’s potential performance.
5. The formulas given are for the typical characteristics only at 25_C.
6. To calculate total supply current at loads other than 50 pF: I
T(CL
) = IT(50 pF) + (CL – 50) Vfk
where: I
T
is in µA (per package), CL in pF, V = (VDD – VSS) in volts, f in kHz is input frequency, and k = 0.003.
MC14536B
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4
SWITCHING CHARACTERISTICS
(7.)
(C
L
= 50 pF, T
A
= 25_C)
Characteristic
Symbol V
DD
Min Typ
(8.)
Max Unit
Output Rise and Fall Time (Pin 13)
t
TLH
, t
THL
= (1.5 ns/pF) CL + 25 ns
t
TLH
, t
THL
= (0.75 ns/pF) CL + 12.5 ns
t
TLH
, t
THL
= (0.55 ns/pF) CL + 9.5 ns
t
TLH
,
t
THL
5.0 10 15
— — —
100
50 40
200 100
80
ns
Propagation Delay Time
Clock to Q1, 8–Bypass (Pin 6) High
t
PLH
, t
PHL
= (1.7 ns/pF) CL + 1715 ns
t
PLH
, t
PHL
= (0.66 ns/pF) CL + 617 ns
t
PLH
, t
PHL
= (0.5 ns/pF) CL + 425 ns
t
PLH
,
t
PHL
5.0 10 15
— — —
1800
650 450
3600 1300 1000
ns
Clock to Q1, 8–Bypass (Pin 6) Low
t
PLH
, t
PHL
= (1.7 ns/pF) CL + 3715 ns
t
PLH
, t
PHL
= (0.66 ns/pF) CL + 1467 ns
t
PLH
, t
PHL
= (0.5 ns/pF) CL + 1075 ns
t
PLH
,
t
PHL
5.0 10 15
— — —
3.8
1.5
1.1
7.6
3.0
2.3
µs
Clock to Q16
t
PHL
, t
PLH
= (1.7 ns/pF) CL + 6915 ns
t
PHL
, t
PLH
= (0.66 ns/pF) CL + 2967 ns
t
PHL
, t
PLH
= (0.5 ns/pF) CL + 2175 ns
t
PLH
,
t
PHL
5.0 10 15
— — —
7.0
3.0
2.2
14
6.0
4.5
µs
Reset to Q
n
t
PHL
= (1.7 ns/pF) CL + 1415 ns
t
PHL
= (0.66 ns/pF) CL + 567 ns
t
PHL
= (0.5 ns/pF) CL + 425 ns
t
PHL
5.0 10 15
— — —
1500
600 450
3000 1200
900
ns
Clock Pulse Width t
WH
5.0 10 15
600 200 170
300 100
85
— — —
ns
Clock Pulse Frequency
(50% Duty Cycle)
f
cl
5.0 10 15
— — —
1.2
3.0
5.0
0.4
1.5
2.0
MHz
Clock Rise and Fall Time t
TLH
,
t
THL
5.0 10 15
No Limit
Reset Pulse Width t
WH
5.0 10 15
1000
400 300
500 200 150
— — —
ns
7. The formulas given are for the typical characteristics only at 25_C.
8. Data labelled “Typ” is not to be used for design purposes but is intended as an indication of the IC’s potential performance.
MC14536B
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5
PIN DESCRIPTIONS
INPUTS
SET (Pin 1) A high on Set asynchronously forces
Decode Out to a high level. This is accomplished by setting an output conditioning latch to a high level while at the same time resetting the 24 flip–flop stages. After Set goes low (inactive), the occurrence of the first negative clock transition on IN
1
causes Decode Out to go low. The counter’s flip–flop stages begin counting on the second negative clock transition of IN
1
. When Set is high, the on–chip RC oscillator is disabled. This allows for very low–power standby operation.
RESET (Pin 2) A high on Reset asynchronously
forces Decode Out to a low level; all 24 flip–flop stages are also reset to a low level. Like the Set input, Reset disables the on–chip RC oscillator for standby operation.
IN
1
(Pin 3) — The device’ s internal counters advance on
the negative–going edge of this input. IN1 may be used as an external clock input or used in conjunction with OUT1 and OUT
2
to form an RC oscillator. When an external clock is used, both OUT1 and OUT2 may be left unconnected or used to drive 1 LSTTL or several CMOS loads.
8–BYP ASS (Pin 6) A high on this input causes the first
8 flip–flop stages to be bypassed. This device essentially becomes a 16–stage counter with all 16 stages selectable. Selection is accomplished by the A, B, C, and D inputs. (See the truth tables.)
CLOCK INHIBIT (Pin 7) A high on this input
disconnects the first counter stage from the clocking source. This holds the present count and inhibits further counting. However, the clocking source may continue to run. Therefore, when Clock Inhibit is brought low, no oscillator start–up time is required. When Clock Inhibit is low, the counter will start counting on the occurrence of the first negative edge of the clocking source at IN
1
.
OSC INHIBIT (Pin 14) A high level on this pin stops
the RC oscillator which allows for very low–power standby operation. May also be used, in conjunction with an external clock, with essentially the same results as the Clock Inhibit input.
MONO–IN (Pin 15) Used as the timing pin for the
on–chip monostable multivibrator. If the Mono–In input is connected to V
SS
, the monostable circuit is disabled, and Decode Out is directly connected to the selected Q output. The monostable circuit is enabled if a resistor is connected between Mono–In and V
DD
. This resistor and the device’s internal capacitance will determine the minimum output pulse widths. With the addition of an external capacitor to VSS, the pulse width range may be extended. For reliable operation the resistor value should be limited to the range of 5 kΩ to 100 kΩ and the capacitor value should be limited to a maximum of 1000 pf. (See figures 3, 4, 5, and 10).
A, B, C, D (Pins 9, 10, 11, 12) These inputs select the
flip–flop stage to be connected to Decode Out. (See the truth tables.)
OUTPUTS
OUT1, OUT2 (Pin 4, 5) Outputs used in conjunction
with IN1 to form an RC oscillator. These outputs are buffered and may be used for 20 frequency division of an external clock.
DECODE OUT (Pin 13) Output function depends on
configuration. When the monostable circuit is disabled, this output is a 50% duty cycle square wave during free run.
TEST MODE
The test mode configuration divides the 24 flip–flop stages into three 8–stage sections to facilitate a fast test sequence. The test mode is enabled when 8–Bypass, Set and Reset are at a high level. (See Figure 8.)
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