R
Roger Dewhurst
Guest
I read somewhere that the #5 pin can be used to vary the oscillation
rate. How please?
R
rate. How please?
R
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E
Electronworks.co.uk
Guest
"Roger Dewhurst" <dewhurst@wave.co.nz> wrote in message
news:h1mv76$hnc$1@lust.ihug.co.nz...
Inside the 555 you have 3 resistors from Vcc to Ground, all of equal value
(5k) giving thresholds of 0.66Vcc and 0.33 Vcc.
In astable mode, the capacitor charges until it reaches 0.66Vcc (at this
time the output is high) the output toggles low and the capacitor discharges
until it reaches 0.33Vcc. The output then goes high again...
Pin 5 is connected to the 0.66Vcc point, so increasing the voltage on this
pin increases the 0.66Vcc threshold thus making the output stay on for
longer (capacitor needs longer to charge before the output trips). Vice
verca with a decreasing voltage on pin 5.
Without this pin, if you want to change the frequency of operation, you
would have to insert a potentiometer in the place of one of the frequency
control resistors. If this is remote from the 555 timer (mounted on the side
panel), noise can get coupled into the connecting wires and accidentally
trip the internal comparators, giving spurious pulses.
If you add a control pin, you can decouple this point to remove noise
pickup.
Hope this helps
Rgds
--
Bill Naylor
www.electronworks.co.uk
Electronic Kits for Education and Fun
news:h1mv76$hnc$1@lust.ihug.co.nz...
Hi RogerI read somewhere that the #5 pin can be used to vary the oscillation rate.
How please?
R
Inside the 555 you have 3 resistors from Vcc to Ground, all of equal value
(5k) giving thresholds of 0.66Vcc and 0.33 Vcc.
In astable mode, the capacitor charges until it reaches 0.66Vcc (at this
time the output is high) the output toggles low and the capacitor discharges
until it reaches 0.33Vcc. The output then goes high again...
Pin 5 is connected to the 0.66Vcc point, so increasing the voltage on this
pin increases the 0.66Vcc threshold thus making the output stay on for
longer (capacitor needs longer to charge before the output trips). Vice
verca with a decreasing voltage on pin 5.
Without this pin, if you want to change the frequency of operation, you
would have to insert a potentiometer in the place of one of the frequency
control resistors. If this is remote from the 555 timer (mounted on the side
panel), noise can get coupled into the connecting wires and accidentally
trip the internal comparators, giving spurious pulses.
If you add a control pin, you can decouple this point to remove noise
pickup.
Hope this helps
Rgds
--
Bill Naylor
www.electronworks.co.uk
Electronic Kits for Education and Fun
C
Chris
Guest
On Jun 22, 4:07 am, "Electronworks.co.uk"
<newsgro...@electronworks.co.uk> wrote:
http://www.fairchildsemi.com/ds/LM/LM555.pdf
he will see how to vary the 555 output for both astable (one-shot) and
multistable (oscillator) operation like Bill says. See "Pulse Width
Modulation" and "Pulse Position Modulation" on pages 8 and 9.
You also might add a few precautions to Bill's response here. The 555
was crafted back when the earth's crust was cooling, and "rail-to-
rail" inputs were no more than a twinkle in the eye of aspiring
engineers. The differential pair comparator input of the standard 555
does not work properly if it's more than about 1.5V below Vcc. Also,
the comparator offset and other imperfections of the circuit become
more pronounced as the upper and lower limits (set by the three 5K
resistors) become smaller and closer together. Lowering the control
voltage on pin 5 below about 1/4 * Vcc means less control.
So for a Vcc of 5V, the control pin can range between about 1.25V and
3.5V. For a Vcc of 12V, control coltage can range between 3V and
10.5V. This will provide a good range of oscillator frequencies.
Cheers
Chris
<newsgro...@electronworks.co.uk> wrote:
If Roger takes a look at the Fairchild data sheet for the 555"Roger Dewhurst" <dewhu...@wave.co.nz> wrote in message
news:h1mv76$hnc$1@lust.ihug.co.nz...
I read somewhere that the #5 pin can be used to vary the oscillation rate.
How please?
R
Hi Roger
Inside the 555 you have 3 resistors from Vcc to Ground, all of equal value
(5k) giving thresholds of 0.66Vcc and 0.33 Vcc.
In astable mode, the capacitor charges until it reaches 0.66Vcc (at this
time the output is high) the output toggles low and the capacitor discharges
until it reaches 0.33Vcc. The output then goes high again...
Pin 5 is connected to the 0.66Vcc point, so increasing the voltage on this
pin increases the 0.66Vcc threshold thus making the output stay on for
longer (capacitor needs longer to charge before the output trips). Vice
verca with a decreasing voltage on pin 5.
Without this pin, if you want to change the frequency of operation, you
would have to insert a potentiometer in the place of one of the frequency
control resistors. If this is remote from the 555 timer (mounted on the side
panel), noise can get coupled into the connecting wires and accidentally
trip the internal comparators, giving spurious pulses.
If you add a control pin, you can decouple this point to remove noise
pickup.
Hope this helps
Rgds
--
Bill Naylorwww.electronworks.co.uk
Electronic Kits for Education and Fun
http://www.fairchildsemi.com/ds/LM/LM555.pdf
he will see how to vary the 555 output for both astable (one-shot) and
multistable (oscillator) operation like Bill says. See "Pulse Width
Modulation" and "Pulse Position Modulation" on pages 8 and 9.
You also might add a few precautions to Bill's response here. The 555
was crafted back when the earth's crust was cooling, and "rail-to-
rail" inputs were no more than a twinkle in the eye of aspiring
engineers. The differential pair comparator input of the standard 555
does not work properly if it's more than about 1.5V below Vcc. Also,
the comparator offset and other imperfections of the circuit become
more pronounced as the upper and lower limits (set by the three 5K
resistors) become smaller and closer together. Lowering the control
voltage on pin 5 below about 1/4 * Vcc means less control.
So for a Vcc of 5V, the control pin can range between about 1.25V and
3.5V. For a Vcc of 12V, control coltage can range between 3V and
10.5V. This will provide a good range of oscillator frequencies.
Cheers
Chris