Cavity Filter Basics
HTML-код
- Опубликовано: 10 фев 2025
- #227 In this video I look at another constructive type of filters that moves from the world of lumped elements to the world of distributed elements, what I'm referring to is cavity filters. I look at some of the basic operating principles as well as some constructive types and next time I will be performing some measurements on a set of practical devices.
Filter series:
Ep1 - Intro : • Intro to Filters
Ep2 - Passive RC Filters: • Passive RC Filters
Ep3 - Active RC Filters: • Active RC-filter Basics
Ep4 - More Active RC Filters: • MORE Active RC Filters
Ep5 - Introduction to LC Filters: • Introduction to LC Fil...
Ep6 - LC filter limitations: • Limitations of LC Filters
Ep7 - Piezo-Electric Filters: • Piezo-Electric Filters
Ep8 - Crystal Filter Measurements and Design: • Crystal Filter Experim...
Ep9 - Cavity filter Basics: • Cavity Filter Basics
Ep10 - Cavity filter Experiments: • Cavity filter Experiments
Ep11 - Stub filters: • Coax Stub Filters
Further reading:
w6nbc.com/arti...
lea.hamradio.s...
k5tra.net/tech...
Special Thanks to all my supporters on Patreon!
If you liked this video be sure to check out my other videos and you can also subscribe to be up to date with all the new ones!
If you want to support the creation of more and better videos please consider checking out: / feszelectronics
The dark magic of electronics
Rather the CURSED! area of the Dark Magic Electronics XD
University Inquisition was alread noticed.
And the area where you find surprising results every time you try replicating the exact same physical experiment!
Excellent and elegant as always. This exemplifies the artiness of electronics!
Can’t wait for the practical measurements! 👍
I have been waiting for a clear and concise video on cavity filters forever! Thank you so much!!!
having seen this some time ago in one or some of Curious Marc's vids, this is finally building the missing link to this dark art of trolling the rest of electronics!
Good explanation! Thanks for sharing! 👍
Excellent video ! I appreciate your clear and thorough approach. This technology cannot be replaced by SDR when power is involved eg. in a transmitter. Keep up the good work !
"I signed up to a degree in electronic engineering, NOT plumbing!"
Thanks for explaining Cavity filters.. Very black magic 😛
great video many thanks... talking about amateur radio "abuse" of these things I have heard of aluminium beer kegs successfully being used as the conductive "cavity" for a VHF filter but the best one was a April fools joke about a 30' shipping container for a 7MHz (40 metre) cavity filter.
I bet a shipping container wouldn't be big enough for 7mhz. 14mhz though 🤔
@@Dazzwidd standard length 40 & 45 foot shipping containers should easily contain a 33 foot 7MHz quarter wave resonator.. but I do agree that finding a "dunk tank" big enough to silver plate it might prove a little difficult 🤪.... I just don't know how I'm going to find a suitable filter for my stacked & bayed rotatable rhombic antenna farm.
Great topic 👍
thank you, beyond my brain to absorb all of it ... right now. but gets me thinking. -
Analog is king. 🙂
Amazing, thank you
I am a hobbyist and I experiment with RF, my mathematical knowledge is poor. I have a quartz oscillator ICD6233 programmed for 100MHz, but there are multiple harmonics and I need to boost the 400MHz while filtering out the rest. I need to also narrow the slopes of the frequency (in hobbyist terms) I need to suppress -filter out (attenuate) the grass (notch) before 400MHz and after it. Is it possible by using a cavity filter? I did experiment with LC Band pass filters shunt and series but I couldn't get the results I wanted. Can you suggest a solution? Thanks a lot.
I would have liked to see the design of those two sample filters you created. Design, construction, and testing. That would make a interesting video. For instance how did you spec out the size, positioning of the internal components & how to make any adjustments (presuming its possible with the construction method used.
How is it response against temperature? In case the filter is in a cabinet expose to direct sun, external temperature could range 20° differential in a night-day cicle. Is the resonant frequency affected and how much? Thanks.
Super interesting as always. Question: the 50 ohm source impedance in the models should be in series no? Or what is the effect of having this resistor in parallel with the voltage source?
When modeling a voltage source, this is comprised of an ideal voltage source with a series resistor; when modeling a current source, its comprised of a ideal current source with a parallel resistor. If you add the resistor in parallel with an ideal voltage source it will have no effect (same for a resistor in series with the current source); from the "outside", an ideal voltage source, or an ideal voltage source with a parallel resistor behave in exactly the same way.
@@FesZElectronics Yes, yes! But at 5:30 you are using voltage sources. Therefore my comment . Thanks for this quick answer, and for your excellent videos!
With voltage sources, if you right click on them directly, or going to "advanced", you have the option of defining the parasitics - series resistance and parallel capacitance; in the simulation, you can see under the "AC 1" parameter definition, the text "Rser=50" which is part of the voltage source definition -so the 50ohm series resistance is included into the voltage source, it does not have to be a dedicated external resistance.
@@FesZElectronics Oh I see. So the external resistor is just an adapted load resistor? this makes sense.
It iš source output resistane from signal , other----output- loud resistane.You must conect 50 om resistor ir you measure with big resistance voltmetr( and not conected any loud with 50 om input )
And I still don't understand what's going on with the last filter I build. It was meant to be for 149 MHz but has a second dip at 137 MHz. Nice 2 meter bandpass, but that's not what I wanted.😅
Any chance for FEM of these filters? Like, what's an optimal coupling loop shape / position? Some coupling loops use flat wire instead of round. Why?
Can we see one of those nifty copper boxes on a VNA? 🙂
Of course! I test all the filters I've built in the next episode.
The electric field is perpendicular to equipotentials (i.e. conductors). At 3:00, the electric field is radial rather than longitudinal.
In the case of the resonator, the structure (at resonance) has opposing charges at the ends - when the top is positively charged, the bottom is negative; that is why the lines seem to go perpendicular. Even though its one piece of conductor, at high frequency it is not a equipotential - local bits are at different values.
Thanks.
I wish these videos better explained the design. I cannot tell what is grounded and what is not. Where does the center conductor and shield of my coax connect??
"The way how Machine God speaks with you depends on size of scented candles and distance between them during the ritual."
- Tech-priest of Adeptus Mechanicus
Isn't this what Tesla was doing with wireless power and Wardenclyff?
gibberish. Sounds like a chipmonk
nah chipmunks have voices sped up and are very high pitched.
"Aaaaaalvinnnnnn!"
Shut up angloid moron