NEC UPC1555G2

DATA SHEET
MOS INTEGRATED CIRCUIT
Bipolar Analog Integrated Circuit
µPC1555
TIMER CIRCUIT
The µPC1555 is a powerful integrated circuit. Adding a few external parts to it can turn it into various types of
timing signal generators, such as monostable and astable multivibrators. It has trigger, threshold, and control pins.
Inputting a signal to the reset pin can stop the circuit operation easily. In addition, the output can sink current as high
as 200 mA (maximum). So, it can be used to drive relays and lamps.
TYPICAL CHARACTERISTICS
• Supply voltage
FEATURES
: 4.5 to 16 V
• Monostable and astable oscillation
• Circuit current (VCC = 5 V) : 3 mA
• Interfacing directly with TTL-level signals
• Output current capacity
: 200 mA
• Variable duty cycle
• Temperature stability
: 0.005%/°C
• Rising and falling time
: 100 ns
ORDERING INFORMATION
Part number
µPC1555C
PIN CONFIGURATION (TOP VIEW)
Package
8 VCC
GND 1
8-pin plastic DIP (300 mil)
µPC1555G2 8-pin plastic SOP (225 mil)
Trigger 2
R
COMP
Flip-flop
Output 3
7 Discharge
R
Output
stage
6 Threshold
COMP
R
5 Control voltage
Reset 4
VREF
EQUIVALENT CIRCUIT
8
R2
1 kΩ
VCC
Q6 Q5
6
Q1
Threshold 2 Q2 Q3
5 (3VCC)
Control
1
Q11
R3
5 kΩ
Q21
R1
10 kΩ
5 kΩ
Q8
4
Q25
Q28
R12
3.9
kΩ
R4
Q15
Trigger
Q27
R6
7.5kΩ
Q4
GND
2
Reset
7
Discharge
R11
Q22 6.2
kΩ
Q7
Q9
3
Q17
Q24
R7
4.7 kΩ
Q16
Q10
Q19
Q20
R10
Q23 120
Q18
Q12
Q13
R5
5 kΩ
Output
R8
100
Ω
Q26
R9
3.3kΩ
Q14
Document No. G10649EJ6V0DS00 (6th edition)
(Previous No. IC-1979)
Date Published November 1995 P
Printed in Japan
©
1986
µPC1555
ABSOLUTE MAXIMUM RATINGS (TA = 25°C)
Rated value
Parameter
Symbol
µPC1555C
µPC1555G
Unit
Supply voltage
VCC
–0.3 to +18
–0.3 to +18
V
Input voltage
(trigger, threshold, reset, control)
VIN
–0.3 to VCC + 0.3
–0.3 to VCC + 0.3
V
Applicable output voltageNote 4
VO
–0.3 to VCC + 0.3
–0.3 to VCC + 0.3
V
Output current
IO
200Note 1
200Note 1
mA
Power dissipation
PT
600Note 2
440Note 3
mW
Operating temperature
TA
–20 to +80
–20 to +80
°C
Storage temperature
Tstg
–55 to +125
–55 to +125
°C
(output and discharge)
Notes 1. Be sure to use the product within the Power dissipation.
2. For TA ≥ 25°C, the total loss is derated at TJ
MAX
= 125°C and –6 mW/°C.
MAX
= 125°C and –4.4 mW/°C.
(See the PT-TA characteristic curve.)
3. For TA ≥ 25°C, the total loss is derated at TJ
(See the PT-TA characteristic curve.)
4. This is an external voltage that can be applied to the output pin without deteriorating the quality of the
product or causing damage to the product.
Be sure to use the product within the rated value under any conditions where coils are inserted or power
is turned on or off. The output voltage that can be obtained during normal operation is within the output
saturation voltage range.
RECOMMENDED OPERATING CONDITIONS (TA = 25°C)
Parameter
Symbol
Conditions
MIN.
MAX.
Unit
4.5
16
V
Supply voltage
VCC
Oscillation frequency
f
VCC = 5 to 15 V
0.1
100 k
Hz
Output pulse width
tW (OUT)
VCC = 5 to 15 V
10 µ
10
Sec
Input voltage (trigger, threshold)
VIN
0
VCC
V
Input voltageNote 5 (control)
VIN
3.0
VCC • 1.5
V
Reset voltage (high level)
Vreset H
VCC = 5 to 15 V
1.0
VCC
V
Reset voltage (low level)
Vreset L
VCC = 5 to 15 V
0
0.4
V
Note 5.
This parameter defines the voltage that can be applied when a PWM mode application circuit is
configured by applying an external voltage to the control pin. Usually, a capacitance of 0.01 µF is
connected as shown in the application circuit.
2
µPC1555
ELECTRICAL CHARACTERISTICS (TA = 25°C, VCC = 5 to 15 V)
Parameter
Symbol
Supply voltage
VCC
Supply current
ICC
Conditions
MIN.
TYP.
4.5
MAX.
Unit
16
V
VCC = 5 V, RL = ∞, VO = “L”Note 6
0
3
6
mA
VCC = 15 V, RL = ∞, VO = “L”Note 6
0
10
15
mA
Threshold voltage
Vth
Threshold current
Ith
Note 7
Trigger voltage
Vtr
VCC = 15 V
5
V
VCC = 5 V
1.67
V
0.5
µA
Trigger current
Itr
Reset voltage
Vreset
Reset current
Ireset
Control voltage
Vcont
Output saturation voltage “L”
VOL
2/3 VCC
Note 8
0
0.4
1.0
µA
V
mA
VCC = 15 V
9.0
10
11
V
VCC = 5 V
2.6
3.33
4
V
VCC = 15 V, ISINK = 10 mA
0
0.1
0.25
V
VCC = 15 V, ISINK = 50 mA
0
0.4
0.75
V
VCC = 15 V, ISINK = 100 mA
0
2.0
2.5
V
VCC = 5 V, ISINK = 5 mA
VOH
0.7
0.25
0.1
VCC = 15 V, ISINK = 200 mA
Output saturation voltage “H”
0.1
V
2.5
0
VCC = 15 V, ISOURCE = 200 mA
0.1
V
0.35
12.5
V
V
VCC = 15 V, ISOURCE = 100 mA
12.75
13.3
15.0
V
VCC = 5 V, ISOURCE = 100 mA
2.75
3.3
5.0
V
Propagation delay (L → H)
tPLH
200
ns
Propagation delay (H → L)
tPHL
200
ns
Minimum trigger pulse width
tW (tr)
VCC = 15 V, Vtr min. = 2.5 V
25
ns
Minimum output pulse width
tW (OUT)
VCC = 15 V, Vtr min. = 2.5 V
tW (tr) = 3 µs
6
µs
Minimum reset pulse width
tw (reset)
VCC = 15 V, Vtr min. = 0 V
900
ns
Timing error
Astable multivibrator
Initial accuracy
RA, RB = 1 to 100 kΩ
1
%
Temperature drift
C = 0.1 µF
50
ppm/°C
0.01
%/V
Supply voltage drift
Notes 6. When the output is “H”, the circuit current decreases by approximately 1 mA (when VCC = 5 V).
7. The maximum allowable value for RA + RB is determined for a supply voltage of 15 V. The maximum
value is 20 MΩ.
8. When the reset pin is driven to a low level, discharge TrQ14 is turned on, stopping oscillation (the output
state is undefined).
3
µPC1555
CHARACTERISTIC CURVES (TA = 25°C, TYP.)
ICC-VCC characteristic
1.2
12
VCC = 15 V
1.0
10
Circuit current ICC (mA)
0.8
0.6
TJ = 125°C
0.4
TI = 25°C
0.2
0
1
2
3
4
5
–20°C
8
TA = 25°C
6
70°C
4
2
0
5
6
10
Minimum trigger pulse voltage Vtr min. (V)
ISINK-VOUT characteristic
10
1
3
5
10
1
0.1
0.01
1.0
30 50 100
Output source current ISOURCE (mA)
10
30 50 100
ISINK-VOUT characteristic
10
10
VCC = 10 V
–20°C
1
25°C
70°C
TA = 25°C
0.1
0.01
1.0
C
70°
°C
–20
3.0 5.0
10
30 50 100
Output sink current ISINK (mA)
Output saturation voltage VOUT (V)
Output saturation voltage VOUT (V)
3.0 5.0
Output sink current ISINK (mA)
ISINK-VOUT characteristic
4
70°C
70°C TA = 25°C
1
20°C
–20°C
VCC = 5 V
TA = –
Output saturation voltage VOUT (V)
Output saturation voltage VCC-VOUT (V)
ISOURCE-(VCC-VOUT) characteristic
2
0
15
Supply voltage VCC (V)
25°C
Minimum trigger pulse width tW (tr) (µs)
Minimum trigger pulse width characteristic
VCC = 10 V
–20°C
1
TA = 25°C
0.1
0.01
1.0
70°
C
3.0 5.0
°C
–20
10
30 50 100
Output sink current ISINK (mA)
µPC1555
Propagation delay characteristic
Discharge pin saturation voltage VSAT (mV)
1.2
Propagation delay (µs)
TA = 25°C
1.0
0.8
VCC = 5 V
0.6
0.4
VCC = 10 V,15 V
0.2
0
0.1
0.2
Discharge pin ISINK-VSAT characteristic
0.3
1000
Minimum trigger pulse voltage (×VCC)
VCC = 5 V
–20°C
1.0
0.01
1
10
100
▲ tW-tW (tr) characteristic
5
VCC = 15 V
Vtr min = 2.5 V
C
Minimum output pulse width trigger pulse width ▲tW (µ s)
Total loss PT (mW)
0.1
Discharge pin (pin 7) sink current ISINK (mA)
700
500
G
400
300
200
100
10
25°C
10
PT-TA characteristic
600
TA = 70°C
100
4
3
2
1
0
20
40
60
80
100
2
4
6
8
10
Trigger pulse width tW (tr) (µ s)
Ambient temperature TA (°C)
▲ tW-ttr min. characteristic
7
VCC = 15 V
tW(tr) = 5 sµ
Minimum output pulse width trigger pulse width ▲tW (µ s)
6
5
4
3
2
1
0
1
2
3
4
5
Minimum trigger pulse voltage Vtr min. (V)
5
µPC1555
PIN FUNCTIONS
1. Trigger pin (pin 2)
: Supplying one-third of VCC to the trigger pin triggers the circuit, changing the output
voltage from low to high.
2. Output pin (pin 3)
: The maximum output current is 200 mA. Be careful not to exceed the total loss (see
the PT-TA characteristic curve).
3. Reset pin (pin 4)
: Supplying 0.4 V or less to the reset pin stops the circuit operation (such as monostable
or astable multivibrator operation).
When not used, the reset pin should be clamped at 1 V to VCC.
4. Control voltage (pin 5) : This voltage determines the threshold level of the comparator. It is set to two-thirds
of VCC. It is possible to configure a PWM (pulse width modulation) or PPM (pulse
position modulation) mode application circuit by supplying a control voltage from the
outside. When this pin is not in use, it should be bypassed using a capacitor of
approximately 0.01 µF for more table circuit operation.
5. Threshold pin (pin 6)
: The values of an external capacitor (C) and resistor (R) connected to this pin determine
the width of the output pulse.
6. Discharge pin (pin 7)
: This pin is used to discharge an external capacitor (if connected). It operates, when
the internal flip-flop circuit is turned on, or a reset signal is applied.
6
µPC1555
APPLICATION CIRCUITS
(1) Monostable multivibrator
Fig. a Monostable Multivibrator Example
Fig. b Monostable Response Waveform
t = 0.1 ms/DIV
VCC = 5 to 15 V
Trigger input voltage: 5 V/DIV
Note 10
RL
R1
4
TRIGGER
8
7
2
µ PC1555
3
OUTPUT
6
Output voltage: 5 V/DIV
"H"
"H"
C1
"L"
5
1
"L"
Capacitor (C1) voltage: 2 V/DIV
Control voltage
0.01 µ F
When the µPC1555 is configured as shown in
(R1 = 9.1 kΩ, C1 = 0.01 µ F, RL = 1 kΩ)
Fig. a, it functions as a monostable multivibrator.
Applying a voltage one-third as high as VCC or less
Fig. c Interrelationships among Output
(trigger pulseNote 9) to pin 2 (trigger pin) drives the
Pulse Width, R1, and C1 (approxi-
output to a high level. Under this condition, capacitor
mate value obtained by calculation)
C1 starts charging through resistor R1. When C1 is
100
charged up to two-thirds as high as VCC, pin 6 (threshold
control voltage. If pin 4 (reset pin) is connected to 1 V
or higher (for example, by being connected to VCC), the
circuit operation can be stopped by switching it from 2
V or higher to a GND level.
Ω
M
Ω
10
M
1
kΩ
kΩ
0
10
10
connected to pin 5 functions as a nose filter for the
(R1)
kΩ
repeated. Fig. b shows this operation. A capacitor
1.0
0
pulse is applied to pin 2 again, the same operation is
10
1.
C1 starts discharging through pin 7. When a trigger
t = 1.1 C1 R1
Capacitor C1 capacitance (µF)
pin) is turned on and inverted to a low level. At this point,
0.1
0.01
0.001
10
µs
100 1.0
µ s ms
The output pulse width (delay) is determined theoretically by (see Fig. c):
10 100 1.0
ms
ms
s
10
s
Output pulse width t
t = 1.1 • C1 • R1
The value obtained by this equation is only an approximate value, however. If it is necessary to obtain an accurate
output pulse width, determine R1 and C1 through actual measurement and confirmation; a trimmer should be used
as required. Moreover, R1 should be 300 Ω or higher.
Notes
9. Keep the trigger pulse width smaller than the output pulse width.
10. If the load is connected across the output and GND pins, a “staircase” occurs in the output waveform.
The application circuits and their parameters are for references only and are not intended for use in actual
design-in's.
7
µPC1555
(2) Astable multivibrator example
Fig. d Astable Multivibrator Example
Fig. e Astable Multivibrator Response Waveform
t = 0.5 ms/DIV
VCC = 5 to 15 V
Note 10
Output voltage: 5 V/DIV
RL
R1
4
"H"
"H"
8
"L"
"L"
7
3
OUTPUT
"H"
µ PC1555
5
Capacitor (C1) voltage: 1.7 V/DIV
R2
6
1
2
Control voltage
0.01 µ F
C1
(R1 = R2 = 4.8 kΩ, C1 = 0.1 µ F, RL = 1 kΩ)
When the µPC1555 is used in a circuit configuration
Fig. f Interrelationships among Oscillation
shown in Fig. d, the circuit is triggered by itself to
Frequency, R1, R2, and C1
operate as an astable multivibrator, because pin 2
(approximate value obtained by
(trigger pin) and pin 6 (threshold pin) are connected to
calculation)
each other. When the output voltage is high, capacitor
100
C1 is charged through R1 and R2. When C1 is charged
Capacitor C1 capacitance (µ F)
up to a voltage two-thirds as high as VCC, the threshold
pin is turned on, and the output pin becomes low. At
this point C1 starts discharging through R2. When C1
10
10
0
kΩ
kΩ
kΩ
Ω
(R1 + 2R2)
0.01
0.001
0.1
VCC and two-thirds as high as VCC, the oscillation
10
0.1
M
Ω
This operation is shown in Fig. e. Because C1 repeats
charging and discharging between one-third as high as
0
charge current to flow into C1 through R1 and R2 again.
M
on, and the output voltage becomes high, causing the
1.
voltage one-third as high as VCC, the trigger pin is turned
1.0
10
discharges, and the voltage across C1 decreases to a
10
1.0
10
100 1.0 k 10 k 100 k
Oscillation frequency f (Hz)
(Free running frequency)
frequency is not affected by the supply voltage.
Oscillation is represented theoretically using the
following expressions.
When the output voltage is high, the charge time is
: t1 = 0.693 (R1 + R2) C1 .......................................... (1)
When the output voltage is low, the discharge time is : t2 = 0.693 • R2 • C1 ................................................. (2)
Adding expressions (1) and (2) determines period T
: T = t1 + t2 = 0.693 (R1 + 2R2) C1 .......................... (3)
Therefore, the oscillation frequency is
(see Fig. f for reference)
The duty cycle is determined by the equation (5)
: f=
: D=
1
T
=
1.44
(R1 + 2R2) C1
R2
R1 + 2R2
...................................... (4)
........................................................ (5)
The values obtained this way are approximate values, however. If it is necessary to obtain an accurate oscillation
frequency, determine R1, R2, and C1 through actual measurement and confirmation; a trimmer should be used as
required. Moreover, R1 and R2 should be 300 Ω or higher.
Note 10. If the load is connected across the output and GND pins, a “staircase” occurs in the output waveform.
8
µPC1555
8PIN PLASTIC DIP (300 mil)
8
5
1
4
A
K
I
L
P
J
C
H
G
B
M
R
F
D
N
M
NOTES
1) Each lead centerline is located within 0.25 mm (0.01 inch) of
its true position (T.P.) at maximum material condition.
2) ltem "K" to center of leads when formed parallel.
ITEM
MILLIMETERS
INCHES
A
B
10.16 MAX.
1.27 MAX.
0.400 MAX.
0.050 MAX.
C
2.54 (T.P.)
0.100 (T.P.)
D
0.50±0.10
0.020 +0.004
–0.005
F
1.4 MIN.
0.055 MIN.
G
H
3.2±0.3
0.51 MIN.
0.126±0.012
0.020 MIN.
I
J
4.31 MAX.
5.08 MAX.
0.170 MAX.
0.200 MAX.
K
7.62 (T.P.)
0.300 (T.P.)
L
6.4
0.252
M
0.25 +0.10
–0.05
0.010 +0.004
–0.003
N
0.25
0.01
P
0.9 MIN.
0.035 MIN.
R
0~15°
0~15°
P8C-100-300B,C-1
9
µPC1555
8 PIN PLASTIC SOP (225 mil)
8
5
P
detail of lead end
4
1
A
H
J
E
K
F
G
I
B
L
N
C
D
M
M
NOTE
Each lead centerline is located within 0.12 mm (0.005 inch) of
its true position (T.P.) at maximum material condition.
ITEM
MILLIMETERS
INCHES
A
5.37 MAX.
0.212 MAX.
B
0.78 MAX.
0.031 MAX.
C
1.27 (T.P.)
0.050 (T.P.)
D
0.40 +0.10
–0.05
0.016 +0.004
–0.003
E
0.1±0.1
0.004±0.004
F
1.8 MAX.
0.071 MAX.
G
1.49
0.059
H
6.5±0.3
0.256±0.012
I
4.4
0.173
J
1.1
0.043
K
0.15 +0.10
–0.05
0.006 +0.004
–0.002
L
0.6±0.2
0.024 +0.008
–0.009
M
0.12
0.005
N
0.10
0.004
P
3° +7°
–3°
3° +7°
–3°
S8GM-50-225B-4
10
µPC1555
RECOMMENDED SOLDERING CONDITIONS
The conditions listed below shall be met when soldering the µPC1555.
Please consult with our sales offices in case any other soldering process is used, or in case soldering is done under
different conditions.
Surface-Mount Devices
For details of the recommended soldering conditions, refer to our document SMD Surface Mount Technology
Manual (IEI-1207).
µPC1555G2
Soldering process
Infrared reflow
Soldering conditions
Peak package’s surface temperature: 230°C
Reflow time: 30 seconds or less (at 210°C or more)
Maximum allowable number of reflow processes: 1
Symbol
IR30-00
Exposure limit: NoneNote
VPS
Peak package’s surface temperature: 215°C
Reflow time: 40 seconds or less (at 200°C or more)
Maximum allowable number of reflow processes: 1
Exposure limit: NoneNote
VP15-00
Wave soldering
Temperature in the soldering vessel: 260°C or less
Soldering time: 10 seconds or less
Maximum allowable number of reflow processes: 1
Exposure limit: NoneNote
WS60-00
Partial heating method
Pin temperature: 300°C or less
Flow time: 10 seconds or less
Exposure limit: NoneNote
Note Exposure limit before soldering after dry-pack package is opened.
Storage conditions: Temperature of 25°C or less and maximum relative humidity of 65% or less
Caution Do not apply more than a single process at once, except for “Partial heating method.”
Through-Hole Mount Devices
µPC1555C
Soldering process
Wave soldering
Soldering conditions
Temperature in the soldering vessel: 260°C or less
Soldering time: 10 seconds or less
REFERENCE
Document name
Document No.
NEC Semiconductor Device Reliability/Quality Control System
IEI-1212
Quality Grade on NEC Semiconductor Devices
IEI-1209
Semiconductor Device Mounting Technology Manual
IEI-1207
Semiconductor Device Package Manual
IEI-1213
Guide to Quality Assurance for Semiconductor Devices
MEI-1202
Semiconductor Selection Guide
MF-1134
11
µPC1555
[MEMO]
No part of this document may be copied or reproduced in any form or by any means without the prior written
consent of NEC Corporation. NEC Corporation assumes no responsibility for any errors which may appear in this
document.
NEC Corporation does not assume any liability for infringement of patents, copyrights or other intellectual
property rights of third parties by or arising from use of a device described herein or any other liability arising
from use of such device. No license, either express, implied or otherwise, is granted under any patents,
copyrights or other intellectual property rights of NEC Corporation or others.
While NEC Corporation has been making continuous effort to enhance the reliability of its semiconductor devices,
the possibility of defects cannot be eliminated entirely. To minimize risks of damage or injury to persons or
property arising from a defect in an NEC semiconductor device, customer must incorporate sufficient safety
measures in its design, such as redundancy, fire-containment, and anti-failure features.
NEC devices are classified into the following three quality grades:
“Standard“, “Special“, and “Specific“. The Specific quality grade applies only to devices developed based on
a customer designated “quality assurance program“ for a specific application. The recommended applications
of a device depend on its quality grade, as indicated below. Customers must check the quality grade of each
device before using it in a particular application.
Standard: Computers, office equipment, communications equipment, test and measurement equipment,
audio and visual equipment, home electronic appliances, machine tools, personal electronic
equipment and industrial robots
Special: Transportation equipment (automobiles, trains, ships, etc.), traffic control systems, anti-disaster
systems, anti-crime systems, safety equipment and medical equipment (not specifically designed
for life support)
Specific: Aircrafts, aerospace equipment, submersible repeaters, nuclear reactor control systems, life
support systems or medical equipment for life support, etc.
The quality grade of NEC devices in “Standard“ unless otherwise specified in NEC's Data Sheets or Data Books.
If customers intend to use NEC devices for applications other than those specified for Standard quality grade,
they should contact NEC Sales Representative in advance.
Anti-radioactive design is not implemented in this product.
M4 94.11