You are a great teacher, calm and smooth. Thank you sir, and if it applies as to the patch I've seen in a few of you videos, Thank you for your service.
Paul I've used one of these for Years I use a 10.7 MHz crystal, and have used it for checking out I.F. stages on FM, lovely very stable circuit , every hobbyist should have. Paul de M0BSW
Using a package of CMOS gates such as the 74HCU04 is a nice alternative. use one gate for the oscillator and one gate for a buffer, leaves 4 more gates for whatever. Only requires 1-74HCU04, one 2.2 M resistor, 2 caps and a crystal, with rail to rail swing at very low cost
Its has no modulation. So there is a LOT more circuitry your going to need to get this to work on CB. Its just an oscillator, not an RF Transmitter. It has no modulation and does not output RF.
Im currently trying to measure inductors, since I don have all the lab complete, one way to measure them is to use a very fast signal, I willy try to build this to test them out. Thanks mate!
Great video, but as someone who is trying to learn the design of these oscillators so that I can build one for my desired frequency, it would be helpful if you could include or maybe just add to the description or maybe just add a link to an external doc containing the formulae that relate the various component values to the resonant frequency of the circuit. I am trying to make a 13.56MHz oscillator but I am not sure how to adjust the circuit you have shown for that purpose. Also, slight tangent, but do you have a video that teaches how to find the internal resistance of a given oscillator/signal generator? I am working on a rather niche antenna design for this frequency and I need rather good coupling and as much power transfer as I can get as it will be a fairly powerful antenna and losses from poor impedance matching may be detrimental.
Max, it's been a year since your post, so hope you have succeeded in your design. I used to build circuits and antennas for RFID, operating at 13.56MHz. At that time I used a digital SWR meter from MFJ. It could also measure the complex impedance of circuits, a nice feature you wanna have to make it easier to tune the system to resonance, minimizing reflection, etc. I highly recommend it. Regardng the oscillators, I used to start mine with the 13.56MHz crystal itself. If you are interested in the formulae, my reference for that is Boylestad & Nashelsky, Electronic Devices & Circuit Theory. Good luck!
Hi from Galicia (Spain)!!!I have seen your video of the Colpitts oscillator and was wondering how to make it sound? I have got into my head to make a musical osc with those quartz crystals, but I don't know how to start ... Any recommendation or scheme would be of great help ... I have several CD4060 ic's, if they were of any use ... Greetings 👍💖👋
I'm a total noob, but to share what I've already picked up about oscillators... You would adjust the frequency by changing the value of the capacitors. Larger capacitors would lower the frequency, smaller would increase frequency. For a demonstration of this, take a look at something like a feedback oscillator. Basically a joule thief with a frequency regulated by the value of capacitor as opposed to the value of resistor. Also, at a low voltage (5 volts) you can decide the value of the components for yourself. The relationship to other components being obvious... The two 33k resistors act as a voltage divider, the two capacitors also act as a voltage divider. If they aren't equal, you get the ratio of the voltage you divided. While there doesn't seem to be any upside to dividing the voltage via the capacitors in this circuit, lowering the voltage by using one higher (or lower) value resistor than 33k would change the frequency of oscillator via varying the speed of the capacitors charging. Simple stuff guys, just look at what you can build with the individual components as they sit in that circuit.
How do I do this for a circuit that has to be in a humid environment? I want to switch over to crystal oscillators from capacitance-based timing precisely because humidity affects capacitor values. So I'm trying to get away from anything that has capacitors in it. Any way to do it with inductors or something? Or maybe just the crystal with darlingtons or mosfets or other reactive components? Thank you in advance!
I still don't quite understand how the crystal is able to cause the rest of the circuit to resonate? Does the current draw accross the crystal change depending on the flex of the crystal, like an inductor has a reluctancy to change current? I'm assuming that perhaps the crystal draws a larger current while flexing, and then once saturated the current draw drops off, causing an increase in voltage? I'm just struggling to understand how the rest of the circuit _reads_ what the crystal is doing...
The problem is these circuits work perfectly well when placed on breadboard when i solder the same circuit on a perfboard i dont know what happens the output just disappears. I didnt fry the transistor and i also checked my connections many times i dont know what happened. Please someone help me
Try adding a BJT negative-feedback buffer (or multiple): tinyurl.com/y5ovvjk2 (simulate on max speed until the timestamp in the bottom right is around 350us - the oscillator takes a while to increase the amplitude.) Don't make the coupling capacitors too big (15pF or less) - I tried 30pF but it caused previous stages to collapse owing to the bigger capacitors' relatively low impedance. You can also try increasing the feedback resistors for more amplification. Hopefully, that lets it fit the high/low thresholds of the 74LS14. Good luck with your project :)
Hi Paul, hope you are well! I know it is an old video but I tried to replicate it with a 4 mhz crystal, there was output for a few seconds and then zero; I tried different resistors caps. but same results. Any ideas would be appreciated. John
Keep only one capacitor of 220 pF between the Base and Emitter of the transistor. Remove the other capacitor between Emitter and Ground. Tested and it works OK.
i road some were that i can make an fm reciver circuit with the colpitts oscillator . so how can i turn this oscillator in the simplest way to an fm radio ? thank you so much for these great videos :) .
Try adding a resistor between 1k and 10k from 5V to the oscillator, then putting a 22nF decoupling capacitor from the ground to what used to connect to 5V (ie, the collector). If the frequency of the FM signal is greater or less than the resonance frequency, the oscillator will conduct less, and the voltage at the collector will be higher. If there's not much of an audio signal on the FM station, then the frequency received will be closer to the resonance frequency. Thus the oscillator will conduct more, and pull the collector to a lower voltage. This way, the FM is demodulated. You can couple the oscillator to one or more NPN negative-feedback buffers to increase the output signal, as shown here: tinyurl.com/yxpohc2k - Use smaller coupling capacitors, between 1nF and 10nF, as larger ones can - The amplification is positively correlated with the value of the feedback resistor (in my case 1M) ^^ I got that amplifier design from talkingelectronics.com I'm not sure if that will work because I've never tried such a circuit to make a radio that receives audio (I've only made one that receives digital signals) but you can give it a shot.
I've tried constructing this and i am testing different crystal I have on hand. I bought some awhile back and havent test, or didn't know how to test them. I am seeing the signal but it looks pretty crappy. They're looking more triangle like. Exact values as you have... Wonder if the crystals I have are crappy or if I need to build a different circuit to test these crystals..Any input greatly appreciated. Thanks. Interesting channel
The crystals only have an impact on the frequency, not the quality of the waveform. I would check the circuit for loose or poor connections or something that may be generating noise.
I don't remember the Colpitts originally having the Xtal, is this a modified one?, remember this one and the Hartley back in the day. Anyone know of a Voltage controlled version?, also if we want to go down to say 50Hz, how do we do that with an Xtal?
Thank you for this video. I have a question: this should work with any other NPN transistor or we need absolutly the 2N2222 one? Thank you. I did it with a BC546B but it doesn't work.
You should experiment with your circuits. In theory you circuit should also work because 2n2222 and BC546 are somewhat identical. But practice they're can be very different not only that the crystal can be physically different too because of manufacturing tolerances. But most of the time the gain of the feedback amplifier can make life hard too.
> the basic of its work That part is easy. A crystal (properly speaking, a piezoelectric resonator - both crystal and ceramic resonators work the same way) is a special kind of capacitor. Normally a capacitor passes alternating current and blocks direct current. A resonator also blocks certain resonant frequencies. If you want more math, it's very similar to a resonant tank circuit. The graph of susceptance-vs-frequency crosses zero at resonant frequencies. *You'd choose the frequency by choosing a suitable resonator* - and you can fine-tune it with a capacitor in parallel, often an adjustable one. (A parallel component adds susceptance to the circuit, which allows you to adjust where the total susceptance crosses zero.) So at the resonant frequency, the susceptance of the capacitor-pair cancels the susceptance of the resonator. Let's call the susceptance of both capacitors B. The susceptance of the resonator is -B because they cancel. The susceptance of each capacitor is 2B because susceptance works like conductivity. Now here's the interesting part. The transistor will inject alternating current (small-signal model) at the emitter. I'll assume the base current is small, and so is the current that's passed to the next stage. So the injected current divides into three paths. Some amount goes through the emitter resistor, some through the lower capacitor to ground, some through the upper capacitor. The upper capacitor current is then divided again, some is lost through the bias resistors, some is conducted through the resonator. The emitter-resistor current is lost. That resistor value is going to determine the transistor gain, so I'll assume enough current remains to allow the oscillator to function. Similarly, the loss through the voltage-divider resistors can be neglected for a first estimate of how the circuit works. What is the susceptance of the upper capacitor and the resonator? It's a parallel-sum: 2B||-B = B * (2||-1) = B * (-2/(2-1) = -2B. That's exactly opposite the 2B through the lower capacitor. This zero-susceptance result is a singularity - trying to use it causes division-by-zero problems. The voltage divider formula doesn't have that problem - we can expect the resonator to resonate at twice the output voltage. Current loss will cause some current to flow through the upper-capacitor/resonator loop, and the voltage-divider formula can be applied. That loop has total impedance j/B - j/(2B) = j/B * (1 - 1/2) = j/(2B). So the voltage applied to the resonator is j/B / (j/2B) = 2 ---- twice the output voltage. This means that the output signal has no difficulty stepping up to the higher voltage that's driving the resonator. (Resonance is weird that way.) But if the transistor injects current at a slightly different frequency, it doesn't get the same step-up effect. Non-resonant frequencies are damped out, the resonant frequency (or frequencies) grow until they are limited by parasitic losses. If the self-sustaining oscillation is able to grow too large, it will cause distortion and chaos. Oscillator stability depends on having a small but sufficient amount of loss, just enough to balance gain at the operating signal level. And resonator crystal limits other frequencies to much lower levels, rejecting noise and non-harmonic distortion. It can also improve stability.
@@jordanrodrigues8265 Just wanted you to know, this comment was fascinating. It's always a bit of a bummer when you put together a nice comment like this, it gets overlooked. That said, the reward is mostly in sharing knowledge. Communication really helps me gather my thoughts, and understand what I actually know vs what I "kind of" know. When all is said and done, who really cares? Sometimes you just gotta nerd out :)
You can use a multimeter which can also measure ranges in MHz. They display the frequency and duty cycles. They are affordable for a good price, but don't cheap out on some shoddy knock-off brands.
I'm pretty sure you meant R1 and R2, as C1 and C2 aren't actually configured to divide anything. At any rate, R1 and R2 are every bit as equal as C1 and C2, soooo...
Crystal oscillators are used to provide clock signals for microprocessors and microcontrollers that don't have internal oscillators. It's what allows the CPU to change state millions of times per second.
Does the frequency of crystal affects the overall frequency of the oscillator?? If yes, then if I use a 1Mhz crystal would I get same or different value of frequency..
Rewind the bendix from a Ford starter with much lighter wire. A limiter switch at each end that reverses polarity. Then use a feedback oscillator tuned REALLY slow. The beginning of the stroke would be slow, and the end fast... Like a fish. Reverse polarity, overcome resistance, repeat.
Thank you for the video - great tutorial. Forgive a beginner question though - after wiring in a 26.5810 crystal into the circuit (everything else the same) I can only get it to oscillate at 8.86 Mhz - exactly one third of the printed value. What am I doing wrong?
@caliphaxable, It may be that your tank circuit is not tuned close enough to work with the 26 Mhz crystal. I recommend you check out ua-cam.com/video/I4bAfDu6F1k/v-deo.html (another UA-cam video on the subject that explains the circuit and a good deal of the math. If that doesn't clear it up, study RC reactance, RL reactance, and RCL reactance. I hope this helps....
You might want to check the sampling rate of your oscilloscope. I have a relatively cheap one that has a max sampling rate of 50 MHz. It thinks that a crystal oscillating at 27 MHz is only oscillating at around 9 MHz, and I'm pretty sure that it's because the sampling resolution is just too imprecise to get accurate measurements at such (relatively) high frequencies.
Hi. I built this circuit. I only had 22k resistors. I tried 22k instead of 33k. I also tried 470pf instead of 220pf. the circuit did not work.. I saw a flat dc voltage on the oscilloscope, what is the reason?
You mean capacitors right? Make sure you used capacitors, and if you did, try adjusting the resistor values. Crystals are very temperamental to achieve oscillation. Also, if you didn’t use a 27mHz crystal then you’ll need to adjust the values of both the capacitors and resistors. You can probably look up the data sheets of your crystal or search for example schematics using that frequency crystal. I hope that helps. Cheers!
Getting into building synthesizers and I'm seeing a lot of this stuff for the first time. Very fascinating work. Thanks for making this!
You are a great teacher, calm and smooth. Thank you sir, and if it applies as to the patch I've seen in a few of you videos, Thank you for your service.
Paul I've used one of these for Years I use a 10.7 MHz crystal, and have used it for checking out I.F. stages on FM, lovely very stable circuit , every hobbyist should have.
Paul de M0BSW
Thank you
Thanks for taking the time to make these videos. They are very helpful and interesting.
Using a package of CMOS gates such as the 74HCU04 is a nice alternative. use one gate for the oscillator and one gate for a buffer, leaves 4 more gates for whatever. Only requires 1-74HCU04, one 2.2 M resistor, 2 caps and a crystal, with rail to rail swing at very low cost
Thank you so much sir, you are helping me out every time.
priceless effort!
Thanks. I wired this schematic on a breadboard and it works for me on the 40 meter band.
Next I'll substitute a tuned circuit VFO for the crystal.
Thanks for the video, man! Very helpful!
+MrMyutubechannel Welcome
They are very helpful and interesting.
Thanks a lot for sharing ... keep it up ..
Very nice, thanks a ton. Politely yours
exactly what I was looking for. big like from me
Very,very thanks
The output frequency is a CB radio frequency. Therefore I will give this video a big 10-4 !
Its has no modulation. So there is a LOT more circuitry your going to need to get this to work on CB. Its just an oscillator, not an RF Transmitter. It has no modulation and does not output RF.
Im currently trying to measure inductors, since I don have all the lab complete, one way to measure them is to use a very fast signal, I willy try to build this to test them out. Thanks mate!
Nice video, thanks :)
Thanks For Video
Very helpful thanks
+abu abdulah Thank you
Great video, but as someone who is trying to learn the design of these oscillators so that I can build one for my desired frequency, it would be helpful if you could include or maybe just add to the description or maybe just add a link to an external doc containing the formulae that relate the various component values to the resonant frequency of the circuit. I am trying to make a 13.56MHz oscillator but I am not sure how to adjust the circuit you have shown for that purpose. Also, slight tangent, but do you have a video that teaches how to find the internal resistance of a given oscillator/signal generator? I am working on a rather niche antenna design for this frequency and I need rather good coupling and as much power transfer as I can get as it will be a fairly powerful antenna and losses from poor impedance matching may be detrimental.
Max, it's been a year since your post, so hope you have succeeded in your design. I used to build circuits and antennas for RFID, operating at 13.56MHz. At that time I used a digital SWR meter from MFJ. It could also measure the complex impedance of circuits, a nice feature you wanna have to make it easier to tune the system to resonance, minimizing reflection, etc. I highly recommend it. Regardng the oscillators, I used to start mine with the 13.56MHz crystal itself. If you are interested in the formulae, my reference for that is Boylestad & Nashelsky, Electronic Devices & Circuit Theory. Good luck!
thank you for the video.can you tell me whether i can change the peak-to-peak voltage or not?
very clear & simple. How to generate 50 KHz frequency? what adjustment should we make to this layout?
Hi from Galicia (Spain)!!!I have seen your video of the Colpitts oscillator and was wondering how to make it sound? I have got into my head to make a musical osc with those quartz crystals, but I don't know how to start ... Any recommendation or scheme would be of great help ... I have several CD4060 ic's, if they were of any use ... Greetings 👍💖👋
How did you calculate the components values
will be good to use the MATH or FFT mode in the scope to check the oscillator "purity" looking at the spectrum of it
The Colpitts oscillator is not very pure. 0.1% THD is, probably, the most one can get from it
thanks!
+kazibadema kalim okey dokie
How can we multiply the output frequency to use this oscilator in radiotransmiter? (like 100 MHz FM)
TY
I'm a total noob, but to share what I've already picked up about oscillators...
You would adjust the frequency by changing the value of the capacitors.
Larger capacitors would lower the frequency, smaller would increase frequency.
For a demonstration of this, take a look at something like a feedback oscillator.
Basically a joule thief with a frequency regulated by the value of capacitor as opposed to the value of resistor.
Also, at a low voltage (5 volts) you can decide the value of the components for yourself.
The relationship to other components being obvious...
The two 33k resistors act as a voltage divider, the two capacitors also act as a voltage divider.
If they aren't equal, you get the ratio of the voltage you divided.
While there doesn't seem to be any upside to dividing the voltage via the capacitors in this circuit, lowering the voltage by using one higher (or lower) value resistor than 33k would change the frequency of oscillator via varying the speed of the capacitors charging.
Simple stuff guys, just look at what you can build with the individual components as they sit in that circuit.
Where would I inject an audio signal into the oscillator for a low power transmitter?
What are the values of the capacitors and resistor values if i use a 1Mhz crystal
can we use it with a piezo element to turn water to vapour to control humidity?
Nice!
works perfectly , I use 4 MHz crystal . I need this oscillator for my vacuum tube am transmitter ,thx
+ELECTRONICS thank you for watching and commenting. I'm glad you liked it.
How do I do this for a circuit that has to be in a humid environment? I want to switch over to crystal oscillators from capacitance-based timing precisely because humidity affects capacitor values. So I'm trying to get away from anything that has capacitors in it. Any way to do it with inductors or something? Or maybe just the crystal with darlingtons or mosfets or other reactive components? Thank you in advance!
In which equipments this oscillators are used
I still don't quite understand how the crystal is able to cause the rest of the circuit to resonate?
Does the current draw accross the crystal change depending on the flex of the crystal, like an inductor has a reluctancy to change current?
I'm assuming that perhaps the crystal draws a larger current while flexing, and then once saturated the current draw drops off, causing an increase in voltage?
I'm just struggling to understand how the rest of the circuit _reads_ what the crystal is doing...
Will the frequency change slightly on the crystal if you change the resistor and capacitor values???
شكرا صدقي
The problem is these circuits work perfectly well when placed on breadboard when i solder the same circuit on a perfboard i dont know what happens the output just disappears. I didnt fry the transistor and i also checked my connections many times i dont know what happened. Please someone help me
Great video. Works . How would I modify this oscillator to drive a 74LS14 Schmitt Trigger? Thanks.
Try adding a BJT negative-feedback buffer (or multiple): tinyurl.com/y5ovvjk2 (simulate on max speed until the timestamp in the bottom right is around 350us - the oscillator takes a while to increase the amplitude.)
Don't make the coupling capacitors too big (15pF or less) - I tried 30pF but it caused previous stages to collapse owing to the bigger capacitors' relatively low impedance. You can also try increasing the feedback resistors for more amplification.
Hopefully, that lets it fit the high/low thresholds of the 74LS14. Good luck with your project :)
point is would the 2n2222 drive run a bfg135
Thanks for this gr8 video. Is it also possible to make a variable frequency oscillator using the same crystal oscillator?
You can try frequency divider ICs like CD4060 or use Flip-Flop circuits
I have a raw quartz crystal. Can I make its oscillator too?
hi...how we can produce 100mhz frequence with quartz cristal?
Hi, just subbed, great chanel. How can i use this circut to drive a very small solenoid? Cheers
Is this project for gsm signal amp?
how to modify this for 3 volt
vcc?
Hi Paul, hope you are well! I know it is an old video but I tried to replicate it with a 4 mhz crystal, there was output for a few seconds and then zero; I tried different resistors caps. but same results. Any ideas would be appreciated. John
Keep only one capacitor of 220 pF between the Base and Emitter of the transistor. Remove the other capacitor between Emitter and Ground. Tested and it works OK.
How it works
i road some were that i can make an fm reciver circuit with the colpitts oscillator . so how can i turn this oscillator in the simplest way to an fm radio ?
thank you so much for these great videos :) .
Try adding a resistor between 1k and 10k from 5V to the oscillator, then putting a 22nF decoupling capacitor from the ground to what used to connect to 5V (ie, the collector). If the frequency of the FM signal is greater or less than the resonance frequency, the oscillator will conduct less, and the voltage at the collector will be higher. If there's not much of an audio signal on the FM station, then the frequency received will be closer to the resonance frequency. Thus the oscillator will conduct more, and pull the collector to a lower voltage. This way, the FM is demodulated.
You can couple the oscillator to one or more NPN negative-feedback buffers to increase the output signal, as shown here: tinyurl.com/yxpohc2k
- Use smaller coupling capacitors, between 1nF and 10nF, as larger ones can
- The amplification is positively correlated with the value of the feedback resistor (in my case 1M)
^^ I got that amplifier design from talkingelectronics.com
I'm not sure if that will work because I've never tried such a circuit to make a radio that receives audio (I've only made one that receives digital signals) but you can give it a shot.
Tell please how much hz will be without crystal?
Can a square wave be generated from a crystal? What kind of circuit would I need?
Jon Lorusso a Schmidtt trigger would do the trick
I've tried constructing this and i am testing different crystal I have on hand. I bought some awhile back and havent test, or didn't know how to test them. I am seeing the signal but it looks pretty crappy. They're looking more triangle like. Exact values as you have... Wonder if the crystals I have are crappy or if I need to build a different circuit to test these crystals..Any input greatly appreciated. Thanks. Interesting channel
The crystals only have an impact on the frequency, not the quality of the waveform. I would check the circuit for loose or poor connections or something that may be generating noise.
learnelectronics after some research, I didn't take into account impedances or the state or reaction of the BJT
learnelectronics can we increase frequency of a circuit used crystal?
I don't remember the Colpitts originally having the Xtal, is this a modified one?, remember this one and the Hartley back in the day.
Anyone know of a Voltage controlled version?, also if we want to go down to say 50Hz, how do we do that with an Xtal?
I have used the same components except the transistor. I used bc547. But it does not oscillate. Why it does not oscillate?
Do you have any videos on how to build a Rife frequency oscillator?
What are the element values required to generate a 6 MHz frequency? Would you answer urgently? Thank you.
........................... 3 years Later ............. (Crickets chirping)
LOL
how do i design a 1.35 Mhz oscillator
جميل وبسيطة 👍👍👍
Can I use one of this variabile capacitor used in radio to change the frequency? I Need a 333khz oscillator.
what is frequency coverage of tester?
How can I make this temp stable???
What one would need to do to lock the frequency to 50 or 60 hertz in colpitts oscillator?
Just use elm446 with 4mhz.
Is itnuse in fm transmitter and receiver??
Thank you for this video. I have a question: this should work with any other NPN transistor or we need absolutly the 2N2222 one? Thank you. I did it with a BC546B but it doesn't work.
You should experiment with your circuits. In theory you circuit should also work because 2n2222 and BC546 are somewhat identical. But practice they're can be very different not only that the crystal can be physically different too because of manufacturing tolerances.
But most of the time the gain of the feedback amplifier can make life hard too.
@@DoctorThe113 I will try it with a 2N2222. Thank you and have Nice day.
How do u determine the frequency?
I would like to have a frequency of 50 MHz at the output, which crystal do you recommend? Thank you.
I think it must be 16 MHz.
you did not mention the value of the crystal, as well as the basic of its work, or even how to calculate the frequency
> the basic of its work
That part is easy. A crystal (properly speaking, a piezoelectric resonator - both crystal and ceramic resonators work the same way) is a special kind of capacitor. Normally a capacitor passes alternating current and blocks direct current. A resonator also blocks certain resonant frequencies.
If you want more math, it's very similar to a resonant tank circuit. The graph of susceptance-vs-frequency crosses zero at resonant frequencies. *You'd choose the frequency by choosing a suitable resonator* - and you can fine-tune it with a capacitor in parallel, often an adjustable one. (A parallel component adds susceptance to the circuit, which allows you to adjust where the total susceptance crosses zero.)
So at the resonant frequency, the susceptance of the capacitor-pair cancels the susceptance of the resonator. Let's call the susceptance of both capacitors B. The susceptance of the resonator is -B because they cancel. The susceptance of each capacitor is 2B because susceptance works like conductivity.
Now here's the interesting part. The transistor will inject alternating current (small-signal model) at the emitter. I'll assume the base current is small, and so is the current that's passed to the next stage. So the injected current divides into three paths. Some amount goes through the emitter resistor, some through the lower capacitor to ground, some through the upper capacitor. The upper capacitor current is then divided again, some is lost through the bias resistors, some is conducted through the resonator.
The emitter-resistor current is lost. That resistor value is going to determine the transistor gain, so I'll assume enough current remains to allow the oscillator to function. Similarly, the loss through the voltage-divider resistors can be neglected for a first estimate of how the circuit works. What is the susceptance of the upper capacitor and the resonator? It's a parallel-sum: 2B||-B = B * (2||-1) = B * (-2/(2-1) = -2B. That's exactly opposite the 2B through the lower capacitor.
This zero-susceptance result is a singularity - trying to use it causes division-by-zero problems. The voltage divider formula doesn't have that problem - we can expect the resonator to resonate at twice the output voltage. Current loss will cause some current to flow through the upper-capacitor/resonator loop, and the voltage-divider formula can be applied. That loop has total impedance j/B - j/(2B) = j/B * (1 - 1/2) = j/(2B). So the voltage applied to the resonator is j/B / (j/2B) = 2 ---- twice the output voltage.
This means that the output signal has no difficulty stepping up to the higher voltage that's driving the resonator. (Resonance is weird that way.) But if the transistor injects current at a slightly different frequency, it doesn't get the same step-up effect. Non-resonant frequencies are damped out, the resonant frequency (or frequencies) grow until they are limited by parasitic losses.
If the self-sustaining oscillation is able to grow too large, it will cause distortion and chaos. Oscillator stability depends on having a small but sufficient amount of loss, just enough to balance gain at the operating signal level. And resonator crystal limits other frequencies to much lower levels, rejecting noise and non-harmonic distortion. It can also improve stability.
@@jordanrodrigues8265 Just wanted you to know, this comment was fascinating. It's always a bit of a bummer when you put together a nice comment like this, it gets overlooked. That said, the reward is mostly in sharing knowledge. Communication really helps me gather my thoughts, and understand what I actually know vs what I "kind of" know.
When all is said and done, who really cares? Sometimes you just gotta nerd out :)
@@jordanrodrigues8265but what is the value of the crystal
Is the crystal natural or synthetic? Cool stuff! 1918 wow
Threw together a Ball park version...it Worked...lol
Como se puede modular este oscilador.....guracias
How i can test crystal is working or not. Of course with an oscilloscope, when power is on cirquit, but is there other methods?
You can use a multimeter which can also measure ranges in MHz. They display the frequency and duty cycles. They are affordable for a good price, but don't cheap out on some shoddy knock-off brands.
How did Colpitts do it before the transitor was invented?
probably a vacuum tube, could be wrong though.
Surprised it worked so well on a breadboard. They are notorious for stray capacitance between the pins.
Agreed-- though it may have worked because he kept his wires short and used a fairly low frequency
@@awaismushtaq5719 stan component leads. I also use staples when I'm lazy.
Jumper wires are the definition of overengineered
can someone explain the significance of the frequency written on 2-pin crystal oscillators?
@@awaismushtaq5719 thank you so much! 🙏🏾
only 704mv, I think you need to swap around your C1 and C2 caps to get more gain
I'm pretty sure you meant R1 and R2, as C1 and C2 aren't actually configured to divide anything.
At any rate, R1 and R2 are every bit as equal as C1 and C2, soooo...
Is it used as radio receiver
My question too ! What was the value of the crystal ??
27 MHz or nearest.
Will connecting a potentiometer in a circuit the right way, allow me to change the output frequency?
Yes
What will happen if we apply a higher voltage to the circuit? Will the frequency increase?
Not of course.
Hi It is possible to make Pk Pk voltage = 5V ? without adding extra Transistor ?
can you help me design a a 7.77MHz oscillator???
Hi...just replace 7.77mhz crystal
Can you name this circuit it's testing crystal quartz?
Colpitts Oscillator
so why do some crystal oscillators have 3 or 4 leads coming off them? sometimes out of the top of the casing.
If you are talking about the self contained cans, usually one pin is attached to the case, two are power and the fourth is output.
nice video was wondering how could I sell the colpitts oscillator idea to a younger generation
(Any one )What the purpose of this device where is it used and for what reason
Crystal oscillators are used to provide clock signals for microprocessors and microcontrollers that don't have internal oscillators. It's what allows the CPU to change state millions of times per second.
Crystal resonators are used for adjusting clock signals in microcontrollers. Also they are commonly used for making oscillators
They are less often used in radio transmission. You can usually see them in wireless data transmission modules like that you use with arduino.
Does the frequency of crystal affects the overall frequency of the oscillator?? If yes, then if I use a 1Mhz crystal would I get same or different value of frequency..
yes I think so
i have used a 30MHz crystal instead of 27MHz, but there is no output. What may be the problem?
How do i connect a transformer on the circuit
What is the spec on this crystal? I didn't see that you said
+jack002tuber 27 MHz
do you know how to make an oscillator circuit for a electromagnetic flapping fish tail mechanism?
Could do it a few different ways. The easiest would be an Arduino and a servo.
Rewind the bendix from a Ford starter with much lighter wire.
A limiter switch at each end that reverses polarity.
Then use a feedback oscillator tuned REALLY slow.
The beginning of the stroke would be slow, and the end fast... Like a fish.
Reverse polarity, overcome resistance, repeat.
How do i get 30 mhz instead 0f 26
I do the simulation using multisim but It did not work please help me
Sir transistor ku led ni parallel ga connect chesthe chalu ........
From where we get crystal
amazon ebay etc
I like that circuit, seems so simple, yet stable, does anyone know what the spec is of the 'crystal' please.
It's crystal out of an old Ultrasonic distance sensor...27.835MHz or something very close to that.
Thanks, Learnelectronics, I should be able to get something close (the crystal). Now that I've got a ballpark spec.
Thanks Learnelectronics, gives me a ballpark idea.
David Price you're welcome. I'm always around to answer questions.
Thank you for the video - great tutorial. Forgive a beginner question though - after wiring in a 26.5810 crystal into the circuit (everything else the same) I can only get it to oscillate at 8.86 Mhz - exactly one third of the printed value. What am I doing wrong?
+caliphaxable Hmm, I have no idea why it would do that.
I changed the crystal to a different set of 4, 6 and 12mhz crystals and it functioned fine. Busted 26 Mhz crystal perhaps? Thanks again
@caliphaxable, It may be that your tank circuit is not tuned close enough to work with the 26 Mhz crystal. I recommend you check out ua-cam.com/video/I4bAfDu6F1k/v-deo.html (another UA-cam video on the subject that explains the circuit and a good deal of the math. If that doesn't clear it up, study RC reactance, RL reactance, and RCL reactance. I hope this helps....
You might want to check the sampling rate of your oscilloscope. I have a relatively cheap one that has a max sampling rate of 50 MHz. It thinks that a crystal oscillating at 27 MHz is only oscillating at around 9 MHz, and I'm pretty sure that it's because the sampling resolution is just too imprecise to get accurate measurements at such (relatively) high frequencies.
Thanks for the tips guys I will check both out
Hi. I built this circuit. I only had 22k resistors. I tried 22k instead of 33k. I also tried 470pf instead of 220pf. the circuit did not work.. I saw a flat dc voltage on the oscilloscope, what is the reason?
You mean capacitors right? Make sure you used capacitors, and if you did, try adjusting the resistor values. Crystals are very temperamental to achieve oscillation. Also, if you didn’t use a 27mHz crystal then you’ll need to adjust the values of both the capacitors and resistors. You can probably look up the data sheets of your crystal or search for example schematics using that frequency crystal. I hope that helps. Cheers!
@@hrvstmusic I installed the same circuit. maxed 14 mhz crystal worked
how this circuit work?
Could you just stick an aereal on the output and flip the power on and off to send a morse code radio message?
Hi :D What is the speed of the crystal?
6:11 on the oscilloscope. The frequency of the crystal is 26995khz.