Ramsey Electronics UT5A User manual
UT5A 4
THEORY OF OPERATION
Theory Intro:
The UT5A is made up of many small circuits used to control the 555 timer IC,
which is the heart of the kit. First we’ll cover these circuits individually, then
we’ll place them into the two most basic modes of operation (monostable
and astable) and analyze their operation.
Power Entry:
The UT5A requires an external 5 to 15 VDC DC power supply to operate the
timer circuits. This external DC supply is connected through J1, positive at
pin 1 and negative (GND) at pin 2. J1 pin 3 allows for a separate 3 to 24
VDC supply to be used to set the output signal amplitude parameters or
Output Power. JMP1 allows the Timer Power to be used for Output Power.
Input Circuits:
Triggering the 555 timer IC requires a negative going signal applied to its
input. We have three ways to apply this signal to the IC.
1) NEGATIVE INPUT - If the source signal is negative going it can be
applied to J2 pin3 the boards (-) Input which is attached to C1. For this
option JMP2 (Pull-up Select) may or may not be installed depending on the
source. If installed, it supplies VCC through R1 to C1’s input. J2 pin3 allows
us to bring a negative signal into the timer at C1. With a negative input, D1
is turned off, thus preventing Q1 from effecting the input signal.
2) POSITIVE INPUT - This option requires JMP2 (the Pull-up Select) to be
installed to provide power for Q1. The positive pulse enters through J2 pin 1
(+ Input) current limiting resistor R2 to the base of Q1. The positive signal
turns on Q1. It amplifies and inverts the signal, and now we have a negative
going pulse passed by the steering diode D1 to C1’s input.
INTRODUCTION
The UT5A is most versatile 555 timer kit on the market. The input circuit op-
tions allow for connecting to almost any kind of digital signal. The output driv-
ers allow for connection to digital circuits, relays, indictors, etc... It is designed
to provide the easiest way to apply accurate timing signals to almost any ap-
plication.
The UT5A is also an excellent teaching tool. The detailed theory of operation
will arm you with the knowledge to effectively set up and use the 555 timer.
You will have the chance to experiment with the 555 timer IC, transistor
switches, pull-up resistors, limiter, and differentiator circuits.
In addition, experienced 555 IC users will welcome the practical and truly uni-
versal setup of the PC board.
UT5A 5
3) START SWITCH INPUT - We can also generate a negative signal using
Start switch S1. This final option also requires JMP2 (Pull-Up Select) to be
installed. Pull-up resistor R1 keeps a High (+VCC) at S1/C1 junction with no
input signal applied to J2 pin3. When S1 is pressed it pulls S1/C1 junction
low, giving us a negative pulse at C1’s input.
Differentiator Circuit and Limiter:
If the input pulse has a long negative duration, it can override the 555 timer’s
output. In most cases this is not desirable, however if it is then you can install
JMP3 (Differentiator Select). When JMP3 is not installed, C1 and R3 act as a
differentiator circuit. This circuit will turn an input square wave or long
duration pulse into a negative and positive short duration pulse. Pulse width is
determined by C1’s charge or discharge path. Since R3 is tied to VCC the
junction of C1/R3 will rest at VCC. The short duration pulses will be imposed
on that DC level. The negative short duration pulse will have an amplitude
slightly less than the original pulse. The positive short duration pulse will have
its amplitude limited by D2 to a maximum of VCC + 0.7V. This is to prevent
false operation of the timer IC. JMP2 (Input Select) must be installed for any
circuit requiring an external trigger input.
Charging Network:
R4, R5, R6, R7, and C2 make up the RC network responsible for all timing in
the UT5A. The component values determine the rate at which the capacitor
(C2) charges and discharges. JMP6 controls the way the charging network is
connected to the timer IC. JMP6 also determines the mode of operation,
which we will discuss later.
Timer Pin-out and Function:
The 555 timer IC has 8 pins.
Pin1 provides Ground to all timer functions.
Pin8 is +VCC and provides power for all IC functions.
Pin3 is the Output pin; it will be either High (near +VCC) or a Low
(near 0 VDC) depending on the status of the input pins.
Pin7 is called Discharge, it will provide ground to the charging
network when the Output (Pin3) is Low and an open when the Output
is High.
Pin2 is the Trigger input. When the voltage on this pin falls below the
trigger level (usually 1/3 VCC) it will cause the Output (Pin3) to go
High and remove the ground from Discharge (Pin7).
UT5A 6
Pin6 is called the Threshold input. When the voltage on this pin rises
above the Threshold Level (usually 2/3 VCC) it cause, the Output to
go Low and place, a ground in the charging network through the
Discharge (Pin7).
Pin4 is the Reset. When this pin goes low it will override the other
inputs and force the Output to go Low and the Discharge to provide a
ground to the charging network.
Pin5 is the Control Voltage. This pin allows the Trigger and
Threshold levels to be independent of VCC. When this pin is
connected the Threshold level will be equal to the Control Voltage
pin (J3 pin1) and the Trigger level will be ½ Control Voltage pin.
Reset Circuit:
The Reset circuit consists of R11, C6, J3 pin3 (Reset Input) S2 and U1 pin4.
R11 is a pull-up resistor that keeps the timer’s RESET pin normally High. C6
is a filter capacitor to ensure that noise doesn’t accidently reset the timer IC.
S2 is a normally open push button switch that when closed pulls U3 pin4 low,
resetting the timer IC. J3 allows for an external reset of the timer IC.
Control Voltage Circuit:
The control voltage circuit is used to change the trigger levels of the timer as
mentioned in Timer Pin-out and Function. It also can be used for pulse width
and pulse position modulation. C4 is a filter capacitor that ensures noise does
not effect timer operation. R8 allows the Control Voltage to be set to any
value between 0 and +VCC. JMP5 allows R8’s wiper voltage to be applied to
the timer IC. J3 pin1 allows for an external Control Voltage. This voltage can
be any voltage up to +VCC AC or DC. JMP5 should not be installed if an
external Control Voltage is being used. With JMP5 removed and no input on
J3 pin1, the 555 timers Trigger and Threshold voltages are at their default 1/3
VCC and 2/3 VCC values respectively.
Timer Output Circuits:
The Inverted Timer Output circuit consists of current limiting resistor R9, pull-
up resistor R10, protection diode D3, and transistor Q2. The Non-inverted
Timer Output consists of JMP7 the Non-Invert jumper, R12 pull-up resistor,
protection diode D4, and transistor Q3.
The output of the timer chip U1 pin3 is connected to Q2 through current
limiting resistor R9. If U1’s pin3 output is Low the base of Q2 is Low, which
turns it off. This allows pull-up resistor R10 to pull Q2’s collector High. If
JMP7 is removed this High (approximately +V) is applied to J5 pin2 as the
Inverted Timer Output. If JMP7 is installed this high (approximately +0.7VDC)
is applied to the base of Q3. This causes Q3 to turn on pulling, its collector
UT5A 7
low (approximately 0VDC). The Low appears at J4 pin 1 as the Non-inverted
Timer Output.
If U1’s pin3 output is High, the base of Q2 is High, causing it to be turned on.
This pulls Q2’s collector Low, and this Low (approximately 0VDC) is applied to
J5 pin2 as the Inverted Timer Output. If JMP7 is installed, this Low
(approximately 0VDC) is applied to the base of Q3, turning it off. This allows
pull-up resistor R12 to pull Q3’s collector High (approximately +V). The High
appears at J4 pin 1 as the Non-inverted Timer Output.
The Inverted Timer Output at J5 pin2 and Non-Inverted Timer Output at J4
pin1 can be used as logic level outputs. A Low is less than 200mV and a
High is from +3 to +24V, depending on the supply voltage used for V+. They
also can be used to drive a load of up to 200mA if the load is connected
between +V pin at J4 pin2 and either of the Timer Output pins. To have the
load active when the timer’s output at U1 pin3 is High, connect the load
between J4 pin2 and J5 pin2. To have the load active when the timer’s output
at U1 pin3 is Low connect the load between J4 pin2 and J4 pin1. D3 and D4
protect Q2 and Q3 respectively from inductive kick if an inductive load is used.
MODES OF OPERATION
Note: For these explanations we will assume no Control Voltage input. Only
basic operation is covered here.
Monostabe Mode:
In Monostable mode the timer acts as a “one shot” pulse generator. It has
one Stable and one Unstable state. The pulse begins with a negative input
trigger. This causes the output of the 555 timer to go from low to high starting
the pulse (Unstable). The Pulse Width is determined by the charging
network’s RC time constant. When the circuit times out the output of the 555
timer goes from high to low completing the pulse (Stable). The timer will
remain in this Stable state until it is triggered again.
In Monostable mode the 555 timer requires an external negative pulse or
spike to start its operation. We will be using the pulse provided by the Input,
Differentiator, and Limiter circuit previously described. This means JMP4
(Input Select) must be installed.
JMP6 (Mode Select) set to pins 1 and 2 prepares the Charging Network for
Monostable operation. The C2’s charge path can be traced by starting at
+VCC down through R4, R5, to the pin7 (Discharge) of the timer IC, through
JMP6 pin1 to pin2, to C2. You may notice that R6 and R7 are bypassed in
this mode. C2 is also directly connected to pin6 (Threshold) of the timer IC.
When C2 is charging the Monostable is in its Unstable state. C2 is allowed to
charge when U1 pin3 (Output) is High and pin7 (Discharge) is providing an
UT5A 8
open.
The Monostable mode’s Stable State is defined as U1’s Output at pin3 is Low
and its Discharge pin at U1 pin 7 is held at ground allowing C2 to discharge or
preventing it from charging. The timer will stay in this mode until properly
triggered. The discharge path will be from C2 through JMP6 pin2 to pin 1, U1
pin7, to ground through the 555 timer IC, back to C2.
When the proper trigger appears at U1 pin2 (Trigger) input the Output at pin3
goes High and the ground at pin7 is removed (unstable state). This allows C2
to start to charge through JMP6 pins 1 to 2, R5, and R4 to VCC. When the
charge on C2 reaches the Threshold level (2/3 VCC or Control Voltage if
used) U1 pin6 (Threshold) will cause the 555 timer to change to the stable
state setting the Output pin (pin3) to a Low and applying ground at the
Discharge pin (pin7). The Discharge pin (pin7) being at ground discharges
C2.
The time C2 charges in the Unstable state is the Pulse Width (PW) of the
signal, it can be calculated with the following formula. C2’s discharge path
has no resistance so it is considered to be instantaneous. It is important to
note that the use of a control voltage will change the Threshold level of the IC;
therefore, change the RC timing and the pulse width.
PW = 1.1 * C2 * (R4 +R5)
Astable Mode:
In the Astable (no stable states) mode the timer is free running and acts like a
square wave generator. We will call the High output of the square wave from
the 555 timer Pulse Width (PW) and the Low portion of the square wave Rest
Time (RT). The Pulse width is determined by the RC charge time of the
Charging Network and Rest Time is determined by the discharge time of the
Charging Network.
In Astable mode JMP4 (Input Select) is removed disconnecting the signal
inputs. JMP6 is set connecting pin2 and pin3. This sets up C2 charge and
discharge path and connect both U1 pin2 and pin6 to C2.
Since this mode is free running no input, other than applying power, is needed
to start the circuit. Lets start at the end of rest time with U1 pin3 (Output) Low,
U1 pin7 (Discharge) grounded, and C2 discharging slowly. When the charge
on C2 decreases below the Trigger level (1/3VCC or ½ control voltage if used)
U1 pin2 (Trigger input) causes the start of Pulse Width by setting U1 pin3
(Out) to go High and Discharge (pin7) removes ground. C2 is now allowed to
charge through R7, R6, R5, R4, to VCC. When C2’s charge reaches
Threshold level (2/3 VCC or Control Voltage if used) U1 pin6 (Threshold) ends
UT5A 9
Pulse Width and begins Rest Time by setting Out to Low and grounding
Discharge. C2 now discharges through R7, R6, U1 pin7, to ground in the 555
timer, back to C2. When C2 reaches Trigger level Rest Time comes to an end
and we begin the process over again. Formulas for calculating Pulse Width
(PW) and Rest Time (RT) follow (assuming no control Voltage used):
PW = 0.693 * C2 * (R4 + R5 + R6 + R7)
RT = 0.693 * C2 * (R6 + R7)
Total Time (T) can be calculated as:
T=PW+RT
Or
T = 0.693 * C2 * [(R4 + R5) + 2(R6 + R7)]
Frequency (f) can be calculated as:
1
1 _
f = T = 0.693 * C2 * [(R4 + R5) + 2(R6 + R7)]
Duty cycle is the ratio of Pulse Width to Total Cycle time, it can be calculated
as:
R4 + R5 + R6 + R7
DC = R4 + R5 + 2(R6 + R7) * 100%
UT5A 10
UT5A PARTS LAYOUT DIAGRAM
UT5A 11
UT5A PARTS LIST
Semiconductors
1 555 Timer IC (marked 555) U1)
2 1N4002 (marked 1N4002) (D3,4)
2 1N4148 (marked 1N4148) (D1,2)
3 2N3904 NPN General Purpose transistors (marked 2N3904) (Q1,2,3)
Resistors
4 1k ohm resistors (marked brown-black-red) (R2,5,7,9)
5 10k ohm resistors (marked brown-black-orange) (R1,3,10,11,12)
2 47k ohm resistors (marked Yellow-violet-orange) (R5A,7A)
2 82k ohm resistors (marked grey-red-orange) (R5B,7B)
2 470k ohm resistors (marked yellow-violet-yellow) (R5C,7C)
2 1M ohm resistors (marked brown-black-green) (R5D,7D)
2 50k potentiometer (orange top marked 503) (R4A,6A)
1 100k potentiometer (orange top marked 104) (R8)
2 500k potentiometer (orange top marked 504) (R4,6)
Capacitors
3 0.01uF Ceramic disk (marked 103) (C1,4,6)
1 0.01uF Ceramic disk (marked 104) (C5)
1 0.1uF Mylar (marked 104) (C2A)
2 10uF Electrolytic marked (marked 10uF) (C2,3)
1 1000uF Electrolytic marked (marked 1000uF) (C2B)
Connectors
2 Two terminal, terminal block (J4,5)
3 Three terminal, terminal block (J1,2,3)
6 2 pin header (H1,2,3,4,5,7)
1 3 pin header (H6)
7 Jumper Blocks
Other
2 SPST Push Button switch (S1,2)
1 Circuit Board
UT5A 16
tors have no polarity so they can be installed in either direction.
6. Install C5, a 0.1uF ceramic capacitor (marked 104).
7. Install C4, another 0.01uF ceramic capacitor (marked 103).
8. Install C6, the last 0.01uF ceramic capacitor (marked 103).
9. Install Q1, the transistor marked 2N3904. this part must be mounted
in a specific direction. Match the shape of the transistor to the outline
shown on the parts location diagram or the silkscreen on the circuit board.
Mount it as close to the board as possible
10. Install Q3, another 2N3904 transistor. Follow the same care of instal-
lation as you did with Q1.
11. Install Q2, the last 2N3904 transistor.
12. Install R1, a 10k ohm resistor (marked brown-black-orange). Resis-
tors are like ceramic capacitors they have no polarity. They can be in-
stalled in either direction. All resistors in this kit are stand up resistors.
The pad with the silkscreen circle is the pad that the body of the part sits
on.
13. Install R3, another 10k ohm resistor (marked brown-black-orange).
14. Install R12, yet another 10k ohm resistor (marked brown-black-
orange).
15. Install R10, still another 10k ohm resistor (marked brown-black-
orange).
16. Install R9, a 1k ohm resistor (marked brown-black-red).
17. Install R11, the last 10k ohm resistor (marked brown-black-orange).
18. Install R2, a 1k ohm resistor (marked brown-black-red).
19. Install R8, a 100k ohm variable resistor (marked 104). This part has
three legs and will only fit easily in one direction.
20. Install S1, a SPST Push Button switch. This part will fit in the board in
two different directions, either one will work.
21. Install S2, an other SPST Push Button switch.
22. Install JMP2, a 2 pin header.
23. Install JMP3, another2 pin header.
24. Install JMP4, another2 pin header.
UT5A 17
25. Install JMP1, another2 pin header.
26. Install JMP7, you guessed it another 2 pin header.
27. Install JMP6, a 3 pin header.
28. Install JMP5, finally the last 2 pin header.
28. Install D4, this diode is marked 1N4002. This part has a black body
with one silver or white stripe on one end. It is a stand up diode. Bend
the lead closest to the stripe over so that it comes back across the diode
and is in parallel with the other lead. Match this (stripe end) lead to the
circuit board pad closest to the white stripe on the board’s silkscreen.
The lead attached to the black body goes through the hole with the silk-
screen circle.
30. Install D3, another 1N4002 diode (marked 1N4002). Install this diode
in the same manor as D4.
31. Install C3, a 10uF electrolytic capacitor (marked 10uF). Electrolytic
capacitors have a right and wrong way to be installed. Usually, these ca-
pacitors have a wide stripe which indicates their polarity. Most of the time
this stripe indicates the negative lead. This can be verified by looking for
the (-) sign in the stripe. On rare occasions this stripe with have a (+) sign
indicating a positive polarity. The PC board or Parts Layout Diagram will
show the positive side of the capacitor's installation hole. Be sure to place
the ( + ) capacitor lead into the PC board ( + ) hole and the ( - ) lead into
the ( - ) hole. Observe correct polarity when installing all electrolytic ca-
pacitors.
32. Install J2, a three terminal-terminal block. The wire openings must
face outboard. Make sure the terminal block is square and flush to the
circuit board.
33. Install J1, another three terminal-terminal block. Install it with the
same precautions you did J2.
34. Install J4, a three terminal-terminal block.
35. Install J5, a three terminal-terminal block.
36. Install J3, the last three terminal-terminal block.
You will probably notice five parts are still missing from your board and
you have more than five parts left. A this point you will need to figure out
what part values you need to install for your first application. See the the-
ory of operation section for calculations or the charts that follow at the end
of this section for a component values.
UT5A 18
Two different values potentiometers are provided to allow for better tuning
of your timer. The 50k pot allows for fine tuning when more precise pulse
widths are required. The 500k pot allows for greater time ranges.
The Monostable Pulse Width chart shows the Pulse Widths available with
provided components. The R4 Minimum column shows the minimum (0
ohms) Pulse Width for both provided potentiometers (50K and 500K) and
the capacitor resistor combination shown in the left most column. The R4
= 50k/R4 Maximum column shows the maximum Pulse Width of the 50k
pot and the resistor capacitor combination shown in the left most column.
The R4 = 500k/R4 Maximum column does the same for R4= 500k.
The Astable Timing Chart works the same way as the Monostable Pulse
Width chart in addition to Pulse Width it also provides Rest Time, Total
Time, and Frequency. This chart it assumes that R4 = R6 and R5 = R7
which is not required. You may mix and match the potentiometers and
resistors as you wish.
37. Install R4, either the 50k (marked 503) or 500k (marked 504) potenti-
ometer. Make sure this part is square and flush to the board.
38. Install R6, the other timing potentiometer either the 50k (marked 503)
or 500k (marked 504).
39. Install R5, using the calculations or charts select your part value.
Used the parts list description of color bands (Example 1K marked brown-
black-red) to select the proper resistor.
40. Install R7, for this part follow the instructions for R5 above.
41. Install C2, using the calculations or charts select your part value. If
you select the 0.1uF capacitor (marked 104) polarity is no concern. If you
select the 10uF (marked 10uF) or the 1000uF (marked 1000uF) electro-
lytic capacitor observe correct polarity.
UT5A 19
MONOSTABLE PULSE WIDTH CHART FOR PROVIDED PARTS
R4=50k Pot R 4= 500k Pot
R4 Minimum R4 Maximum R4 Maximum
C2 = 0.1uF
R4 = 1k 110 uS 5.6 mS 55.1mS
R4 = 47k 5.2 mS 10.7 mS 60.2 mS
R4 = 82k 9 mS 14.5 mS 64 mS
R4 = 470k 51.7 mS 106.7 mS 106.7mS
R4 = 1M 110 mS 115.5 mS 165mS
C2 = 10uF
R4 = 1k 11 mS 561 mS 5.5S
R4 = 47k 517 mS 1.1 S 6S
R4 = 82k 902 mS 1.5 S 6.4S
R4 = 470k 5.2S 5.72 S 10.7S
R4 = 1M 11 S 11.6 S 16.5 S
C2 = 1000uF
R4 = 1k 1.1 S 56.1 S 551.1S / 9.2M
R4 = 47k 51.7S 106.7S / 1.8M 602S / 10M
R4 = 82k 90.2 S / 1.5M 145.2S / 2.4M 640S / 10.7M
R4 = 470k 517S / 8.6M 572 S / 9.5 M 1067S / 17.8M
R4 = 1M 1100 S / 18.3 M 1155 S / 19.3 M 1650S / 27.5M
ASTABLE TIMING CHART FOR PROVIDED PARTS
50K Pot 500K Pot
C2 Pots to Minimum Maximum Maximum
0.1uF R5/7 = 1k R4/6 = 51k R4/6 = 501k
PW 139 uS 7.1 mS 69.4 mS
RT 69 uS 3.5 mS 34.7 mS
TT 208 uS 10.6 uS 104.2m S
FREQ 4810 Hz 94.3 Hz 9.6 Hz
0.1 uF R5/7 = 47k R4/6 = 97k R4/6 = 547k
PW 6.5 mS 13.4 mS 75.8 mS
RT 3.3 mS 6.7 mS 37.9 mS
TT 9.8 mS 20.2 mS 113.7 mS
FREQ 102.3 Hz 49.6 Hz 8.8 Hz
UT5A 20
ASTABLE TIMING CHART FOR PROVIDED PARTS CONTINUED
50K Pot 500K Pot
C2 Pots to Minimum Maximum Maximum
0.1 uF R5/7 = 82k R4/6 = 132k R4/6 = 582k
PW 11.4 mS 18.3 mS 80.7 mS
RT 5.7 mS 9.1 mS 40.3 mS
TT 17 mS 27.4 mS 121 mS
FREQ 58.70 Hz 36.4 Hz 8.3 Hz
0.1 uF R5/7 = 470k R4/6 = 520k R4/6 = 970k
PW 65.1 mS 72.1 mS 134.4 mS
RT 32.6 mS 36 mS 67.2 mS
TT 97.7 mS 108.1 mS 201.7 mS
FREQ 10.2 Hz 9.3 Hz 4.9 Hz
0.1 uF R5/7 = 1M R4/6 = 1.05M R4/6 = 1.5M
PW 138.6 mS 145.5 mS 207.9 mS
RT 69.3 mS 72.8 mS 104.0 mS
TT 207.9 mS 218.9 mS 311.9 mS
FREQ 4.8 Hz 4.6 Hz 3.2 Hz
10uF R5/7 = 1k R4/6 = 51k R4/6 = 501k
PW 13.9 mS 706.9 mS 6.9 S
RT 6.9 mS 353.4 mS 3.5 S
TT 20.8 mS 1.06 S 10.4 S
FREQ 48.1 Hz 0.9 Hz 96 mHz
10uF R5/7 = 47k R4/6 = 97k R4/6 = 547k
PW 651.4 mS 1.3 S 7.6 S
RT 325.7 mS 672.2 mS 3.8 S
TT 977.1 mS 2.0 S 11.4 S
FREQ 1.0 Hz 496.0 mH 88 mH
10 uF R5/7 = 82k R4/6 = 132k R4/6 = 582k
PW 1.1 S 1.8 S 8.1 S
RT 568.2 mS 914.8 mS 4.0 S
TT 1.7 S 2.7 S 12.1 S
FREQ 587.0 mHz 364.4 mS 83 Hz
UT5A 21
ASTABLE TIMING CHART FOR PROVIDED PARTS CONTINUED
50K Pot 500K Pot
C2 Pots to Minimum Maximum Maximum
10uF R5/7 = 470k R4/6 = 520k R4/6 = 970k
PW 6.5 S 7.2 S 13.4 S
RT 3.3 S 3.6 S 6.7 S
TT 9.8 S 10.8 S 20.2 S
10 uF R5/7 = 1M R4/6 = 1.05M R4/6 = 1.5M
PW 13.9 S 14.6 S 20.8 S
RT 6.9 S 7.3 S 10.4 S
TT 20.8 S 21.8 S 31.2 S
1000uF R5/7 = 1k R4/6 = 51k R4/6 = 501k
PW 1.4 S 70.7 S 694.4 S / 11.6 M
RT 693 mS 35.3 S 347.2 S / 5.8M
TT 2.1 S 106 S 1041.6 S/ 17.4 M
1000uF R5/7 = 47k R4/6 = 97k R4/6 = 547k
PW 65.1 S / 1 M 134.4S / 2.2M 758.1 S / 13.6 M
RT 32.6 S / .54 M 67.2 S / 1.1 M 379.1 S / 6.3 M
TT 97.7 S / 1.6 M 201.7 S / 3.4M 1137.2 S / 19.0 M
1000uF R5/7 = 82k R4/6 = 132k R4/6 = 582k
PW 113.7 S / 1.9 M 183 S / 3.1 M 806.7 S / 13.4 M
RT 56.8 S / 1.0 M 91.5 S / 1.5 M 403.3 S / 6.7 M
TT 170.5 S / 2.8 M 274.4 S / 4.6 M 1210.0 S / 20.2 M
1000uF R5/7 = 470k R4/6 = 520k R4/6 = 970k
PW 651.4 S / 10.9 M 720.7 S / 12.0 M 1344.4 S / 22.4 M
RT 325.7 S / 5.4 M 360.6 S / 6.0 M 672.2 S / 11.2 M
TT 977.1 S / 16.3 M 1081.1 S / 18.0 M 2016.6 S / 33.6 M
1000uF R5/7 = 1M R4/6 = 1.05M R4/6 = 1.5M
PW1386.0 S / 23.1 M 1455.3 S / 24.3 M 2079.0 S / 34.7 M
RT693.0 S / 11.6 M 727.7 S / 12.1 M 1039.5 S / 17.3 M
TT2079 S / 34.7 M 2183.0 S / 36.4 M 3118.5 S / 52. M
UT5A 22
SETUP
Monostable Mode:
1. Install a Shorting Block across pins 1 & 2 of JMP6.
2. In the Monostable mode the timer needs an input. Install a Shorting
Block across both pins of JMP4.
3. Connect the source circuit to J2. Connect the input to J2 pin 1 if the
signal is a positive going pulse or pin 3 if it is a negative going pulse.
Connect the ground of the source circuit to J2 pin 2. If the input signal is a
square wave or a wide pulse you can select which edge of the waveform
you wish the timer to trigger. If you wish to trigger on the positive going
transition connect to pin 1 if the negative going transition connect to pin 3.
4. Your input circuit may need a pull-up resistor. If the source circuit
provides both a high and low the pull-up will not be needed so remove the
Shorting Block from JMP2. If the input circuit provides a contact closure
or open/closed path for current then you will need the pull-up resistor.
Place a Shorting Block on the pins of JMP2.
5. If the input signal is a square wave or wide duration pulse you will
probably need the signal to be differentiated. This prevent the input signal
from interfering with the timing of the timer. Remove the Shorting Block
from the pins of JMP3 to activate the differentiator circuit. If it is required
that the differentiator be disabled install a Shorting Block across JMP3’s
pins. This Shorting Block will normally not be installed
6. Verify that R4, R5, and C2 are the proper values to give the timing
you require.
Astable Mode:
1. Install a Shorting block across pins 2 & 3 of JMP6.
2. Typically a in the Astable mode an input is not required. Remove the
Shorting Block from JMP4. This removes R3 and R1 from C2’s charge
path with JMP6 jumped pins 2 to 3.
3. Verify that R4, R5, R6, R7 and C2 are the proper values to give the
timing you require for both Pulse Width and Rest Time.
Control Voltage Configuration:
1. For no Control Voltage remove the Shorting Block from JMP5 and
leave J3 pin 1 open.
Table of contents
