that's so cool

Thats awesome

They have something like this at Jodrell Bank a large astrophysics centre in the UK, I went there on a school trip many many years back and it's pretty much the same setup, except this is outside and the distance between the two dishes is maybe 200 meters, so cool!

The Oval Office of the White House actually is elliptical, and sounds made at one focus are clearly audible at the other focus. This is clearly intentional, although I'm not entirely sure what purpose it was intended to serve other than being impressive in the days before amplification.

@@mal2ksc You think that would be intentional? Seems a bit of a security risk. *Whispers quietly to veep. Guy on other end: "I can hear you..."

I don't know why but your comment made me laugh really hard brah

I'm now going to call curved brackets as "parenthesis".

@@onepunchman1953 lmao

Hark, what men are these, that wear their legs in parentheses. 🙂

Antennae are for animals, antennas are for communication

Only if the feeder is omnidirectional :) If the feeder is directional and pointed towards the parabolic reflector, all the energy goes reflected to destination. That's why in some broadcast dishes, you find a small reflector in front of the feeder antenna, so to reflect all the signal to the main dish

I thought the same one 👍

@@MatteoGalet except that has nothing to do with what the op was commenting about. this was not a demonstration of the situation you described. and so it did infact demonstrate the signal loss.

@@darkracer1252 what he wrote is applicable both in case of the emitted signal (which I commented on), and the received signal. But in the latter, there is HUGE percentage of signal not bouncing off the antenna reflector... Much more than shown in the video

That was the part that interested me the most. I can easily visualize the focusing effect, but seeing how clutter repeatedly interrupted, distorted, and weakened the core signal was fascinating!

It looks like a little ray gun shooting a beam directly at the foci

See how the primary "flat" wave from the antenna on the left winds up hitting the little dot on the right all at once after it's reflected? That dot's the receiver, meaning it got a vastly more powerful signal than if the transmitter (left dot) had sent the wave in free space without the reflectors. That way transmissions can be sent and received from much greater distances.

Bro easily I can beat you in a foot race to 20 yards.

@André Bartels You are clearly educated enough to recognize the limits of your knowledge. With a mind open enough to assimilate new information. Congratulations 🎊 👏

@@ToastyMozart this is also how brittain made theyre first Way of detecting german bombers

@@fregtz735 those big ass antenas that would pick up the sound of i coming bombers?? Is that what you meant

Thanks, I'll have to see if I can find parameter values allowing to demonstrate that...

@@NilsBerglund That'd be awesome

@@NilsBerglund It would be awesome

In 2D a circle analogue would just be a line segment blocking the wave. I'm not sure, but I think the center spot would be brighter in 3D than 2D because in 3D the wave would have the entire circumference of the circle to diffract around compared to just the two ends of the line segment in 2D.

You notice that if you have more than 2iq

you know those are different waves, right? Those filters deal with waves as a signal, not as physical waves.

@@atirutwattanamongkol8806 signal waves are physical waves.

@@MrMegaMetroid No? Physical waves travel through the air in 3d but signal waves are just fluctuations in the current

@@atirutwattanamongkol8806 Signal waves you mean electrical signals? - If so then they are also waves, electromagnetic waves - either in medium or on surface of conductors...

Are there physical filters? Or do you mean the ones we do with electronic components?

That part of the wave would be received as a fainter and unfocused version of the signal. The longer the distance between the parabolic reflectors, the fainter this part would be. Real dishes use a directional emitter, to avoid this part of the wave altogether.

​@@NilsBerglundthank you so much for the reply. That's extremely helpful. I really enjoyed your video. Have a great day!

Aw the old pringle can days.

( )

My thoughts exactly lmao

Same lol

YES me too

Idk there is something so iconic on Bill wurtz style

Kind of like power being generated by the relative motion of conductors and fluxes, produced by the modial interaction of magneto-reluctance and capacitive diractance.

@@Synthwave89 Exactly! Gotta be careful though to prevent side-fumbling of the unsynchronised gramm-meter..

@@silas0403 moreover whenever fluorescence score motion is required it may also be employed in conjunction with a drawn reciprocation Dingle arm to reduce sinusoidal deplanaration. Which, goes without saying, is vital in the operation of Milford trunnions.

@@zombieregime you forgot about the malleable logarithmic casing Because without it the two main spurving bearings wouldn't be in a direct line with the panametric fan.

Ya what he said in ten years when I understand it

Messy but also controlled and predictable

Thanks! You also have that in some old buildings, such as the dome of St-Paul's cathedral in London, UK.

There's a theme park I used to go to as a kid that has those on either side of this huge hall. You could easily talk to a mate over all the other noise going on, they're proper trippy.

There is a set of parabolic acoustic reflectors on the side of a large hill at the space museum in Alamogordo NM. Surprisingly effective.

They are a lot of fun. I've never seen a good visualization of it before!

Science works melbourne has this very cool you can almost whisper into the dish and you mate on the other side hears it clear as a bell

Wow yes

Is that actual interference pattern or an artifact of the simulation?

The human brain loves fractal patterns. Clouds, trees, water, moiré, doesn’t matter where it comes from. Fractals are brain food. Or at least yummy spice.

​@@AlessioSangalli I would say it's somewhere in between, but mostly due to the size of the mirror and the fact that they diffract the wavefront. 1) There are some artifacts visible, for instance if you look at 0:13 you see that after the reflection on the left parabolic mirror, there are multiple dim circles present. This looks like it's coming from the sharp edges of the pixelated mirror, reflections coming from those should look like light emerging from point sources. It reminds me of the huygens principle stating that any wavefront can be described as the sum of distributed point sources. In our case the distribution is not 100% optimal, otherwise you wouldn't even see any residual circles. 2) The shape you are asking about looks to me like it's the resulting diffraction pattern of the mirror itself. The mirror is finite and the wavefront "sees" this a diffracting object (like an aperture/slit). In the simulation if the size of the mirror was much bigger but with the same curvature you would surely an interference pattern that is a lot less complex. In optics we have to think about this when using a lens to focus a beam. If the lens is too small compared to the beam, the lens will diffract the beam you will not obtain a nice focal spot.

At the two minute mark It kind of looks like the interference pattern seen in the double slit experiment.

I think the colors cover about 40 to 50 dB. In a couple days there will be a simulation showing a log plot of the energy along a color plot like here, for a different geometry.

I wouldn't be surprised to see the effects shown when the antennae are this close?

@@SimonBuchanNz They're not close !! Based on ~46s travel time at 'c', they're almost 14 million km apart. Of course this implies that they're each about 7 million km in diameter... ;-) !!

@@NilsBerglund Hmmmm... The colour starts out red, and strangely stays red - even as the initial circular wavefront from the feed point spreads out. Just spreading loss alone should have the wavefront changing colour in the first 10s of the video. Perhaps the colour scale has a flat-top section where it's constant colour over at least a magnitude of dynamic range. If the present colour is not log, then it's linear? If it was linear, then it would even more so fade away if the colour scale was distributed linearly. Beware Radio Communications vice Physics (especially Optics), as there can sometimes be confusion and/or miscommunication between 10*Log... and 20*Log... (power density vice field amplitude); almost if they're sometimes speaking a different language. :-)

You're right, I feed the energy into a flattening tanh() function because I don't know the range beforehand. Maybe I should decrease the contrast to get more range, or use a log scale. There will be a log plot for a different geometry in a couple of days.

Thank you very much! You may want to check out the new version kzbin.info/www/bejne/hqGuooGhlKxlftk as well

Yay! Thank you!

I never heard brackets being called something as fancy as parentheses

@@lucasc5622 I never heard curve bois be called anything as fancy as brackets.

@@WiseMasterNinja sideway eyebrows

@@WiseMasterNinja I never heard lines be called as fancy as curvy bois.

@@WiseMasterNinja I've never heard "c" be called something as fancy as curved bois.

what power

@@mistathenicepersonthatwont2546 received power in milliwatts or dBm. Basically the strength of your signal, think of it like how many "bars" your cell phone has to a tower. Those bars on your phone translate to rssi or rsrq or received signal strength. This visualization shows color range, red meaning strong signal, to green to blue weak signal. The red strength could be something like -50 or better dBM, where the green in the -60's, and blue in the -80's. Closer to 0 is stronger, further from 0 is weaker. Not all wireless is same range. LTE or cell phones, -80 dBm is good, and -120 dBm is poor.

@@Wadmd bro its me downloading 1 megabyte of big chungus meme

@@mistathenicepersonthatwont2546 lmfao

@@Wadmd I work with satellite communication and in our feild -120 is like the silence of space lol. -80 is hardly anything at all if there's something we work within an acceptable range of like -60 up to -5 or -4 depending on whats being measured. Edited for spelling error

I think so, yes. There should be some diffraction on any edge, but it will depend on the angle at the edge. Also, I lowered the contrast a bit compared to some previous simulations.

Radio engineers sometimes use the edge effect to diffract radio signals to the other side of mountains.

Maybe one day!

No you dont

and in phase too!

It can be several kinds of medium, but is most realistic for sound (pressure) waves in air.

I think so, although I'm not completely sure. I'm using here a simple discretization on a square grid, which does not fit the parabolas. It would probably be better to use a finite elements discretization adapted to the parabolas, but that would be harder to code...

@@NilsBerglund i actually thought this was a finite element simulation, although the straigt line formed after the first bounce made me doubt it for a bit. This is great!! Thanks a lot!

This video needs 5x to 10x speed.

@@Linuxdirk you can go up to 16x on KZbin.

@@islandcave8738 It shows 2x as maximum speed here.

You're welcome! Keep in mind I used the simplest possible algorithm, so depending on what you want to simulate, it may be necessary to use an improved version.

@@NilsBerglund Yes, I will probably have to stare blankly at it for some time to even have a faint idea what its doing. Then figure out how to make a rough approximation of a driver...

you actually can speed any youtube video to any value up to 16, if you are on computer type Ctrl + Shift + J, in the tab that opened copy and paste document.getElementsByTagName("video")[0].playbackRate = x where x is the speed you want, for example 3, then press enter, you can close the tab and play the video

@@Rafael-pi4md *cries in mobile app*

@@LonnyH just press the 3 dots

See my reply to Kram1032.

Is there a suggestion that they couldn't or don't already?

@@lolerskatez My photographic eye is always looking for simmetries and reflections or for any geometric patterns and textures that can be spotted in natural or less natural landscapes. This is what motivated my comment. I love the human ability of generating works of art, either on purpose or not.

Then the wave should keep alternating between planar and circular. It could be fun to try it, thanks!

@@NilsBerglund This sounds like an example of an optical resonator. Lots of interesting math and physics to be visualized there with different configurations and stability conditions!

If the wave origin was also the focal point would it not have destructive interference with itself after the first reflection?

Thanks! Feel free to recommend this channel to any math/physics teachers/professors you think may be interested... 1. Solving real 3d wave equations would take too long at this point, roughly 1000 times longer to compute. What seems possible is to do 3d plots of the 2d wave equation, that is, the wave height z as a function of x and y. I'll have to refresh my knowledge of 3d OpenGL, though. 2. I'll have to look into what could be interesting and possible to do with polarization. I assume it would require a vectorial, 2d wave equation, e.g. a version of Maxwell's equations.

@@NilsBerglund I was thinking abbout that 3d thing. I'm no quantum scientist, nor programmer. BUT I was thinking about making two separate animations one for vertical axis, and one for horizontal. It seems like you could "hide" some of the data in the colour values, and maybe it would be possible to make the whole thing using just two separate animations... you would have to have some kind of dedicated compiler of some sorts to transpose the data to 3d... It propabbly would work if you would stick to "simple shapes" like well parabolic mirrors for example :x ... spheres, walls, cubes etc... like I said I'm no computer scientist but maybe some kind of X-Y axis shenanigans is possible if you could menage to use the colour values as some kind of medium, and since you already use it to represent the strength, phases, and other values... maybe that ain't that far off... dunno just thinking out loud :) Have a nice day and please do continue your good work

@@NilsBerglund Oh and also, a "time took to render" could be a nice touch for US THE INTERNET NERDS 🤓

Okay, I'll try doing it in future simulations!

lol

Indeed it is

it's saturday

It's Sunday

2024 on a Wednesday

It is not that easy to get absorbing boundary conditions right. If you just set the wave equal to zero outside the simulated domain, the waves will get fully reflected on the boundaries. Thus you need a form of what is called perfectly matched layer boundary conditions. This is a rather old video. I later managed to improve the plm boundary conditions, see for instance kzbin.info/www/bejne/hqGuooGhlKxlftk

@@NilsBerglund Awesome. That was what my intuition was telling me. Thanks for the insight. To handle the boundary condition in the case of EM waves then, is the technique similar to impedance matching? I realized after it was an older video. 😄

I'm no expert on impedance matching, but there may be some similarity. What you basically try is to predict what the derivative of the wave will look like at the boundary, based on its value, and use that as a type of mixed ("Robin") boundary condition.

Yes, this is most likely due to the relatively low resolution of the simulation mesh. I later improved the resolution, see for instance kzbin.info/www/bejne/hqGuooGhlKxlftk

There are many more like this in the playlist kzbin.info/aero/PLAZp3rbgWLo3VO2rqVKyL1T6DUmnDAaEN

I'm using a form of absorbing (perfectly matched layer) boundary condition, but in this simulation the resolution is probably too low. Later versions such as kzbin.info/www/bejne/hqGuooGhlKxlftk use a higher resolution, and the reflections are reduced.

@@NilsBerglund thanks, subscribed !

Glad it helped!

Thanks! While I have not simulated microwave cavities as such, I have several sims of "parabolic resonators" that may interest you, they are in the playlist kzbin.info/aero/PLAZp3rbgWLo3VO2rqVKyL1T6DUmnDAaEN

This particular point is known as the focal point, or focus of the parabola.

Indeed. In practice, small errors in alignment and imperfections in the parabolic shapes will degrade the signal, but it remains much better than without the dishes.

Thx!

The question is how to simulate the amplifier. One would have to add some active wave sources, that react to incoming waves.

The initial state is radial, with a radial dependence given by a Gaussian times a cosine. I have not tried using a Hanning pulse.