FAQ and corrections in this comment! (video Q&A will be on the second channel!) 1) This is the first time I'm using the A/B split thumbnail tool. because I was kinda lost - I just think waves on strings are really cool. If anybody has good title/thumbnail ideas, I'm all ears lol. 2) Real Q&A coming soon - after there are Qs to A...
@@GabeSullice It already does if you count IR. If you mean visible light - No, it would melt way before that. And probably lose resonance way before melting because of softening.
@@AlphaPhoenixChannel Thumbnail idea: INFINITE WAVES??? In red with you (just your head) doing a click bait face on the bottom right confused looking up trying to find the top and a wave dwarfing you in the background. There is a red arrow pointing off screen to the top of the wave. Directs the viewers eyes to the wave, and makes them wonder what's so special at the top.
I wouldn't necessarily say it's "overused." In fact, I think the opposite is true. People think superposition is magic because it's only really used in the context of quantum weirdness, but many different things in physics obey the superposition principle. Waves, forces, fields.
Superposition itself is just a boring, but useful tool. The WHY (why can you just add two waves?) is way more interesting because it leads you to the simplifying assumptions discussed in this video.
For my entire life this was known as "linearity". A more precise: passing something through linear function does not change how things are added. In Math language f(A + B) = f(A) + f(B). I do not understand why we need another term (and I know this property holds for some definitely not linear functions, so I guess "linear" might be misleading), but what is crazy, is how simple this property is and how often explanation of superposition is made so complicated, that you have no idea what people are talking about.
@IlluminatiBG linearity and superposition are not quite the same thing. As you said, linearity can be described as f(a) + f(b) = f(a+b). That's not what superposition is. If you wanted to put it into mathematical notation that way, superposition would be much more akin to h(a) = f(a) + g(a). The superposition principle says that for certain quantities if there are two (or more) sources of that quantity at the same position the value you get when you measure that quantity at that location is the sum of the values for all sources. The big difference between the two is that the measured function (h in my example) *need not be the same* as either of the original source functions (f and g). This is why two traveling waves can add together to form a superposition which is a standing wave.
As an instrument maker this is super cool. One thing I would add is there are two types of nodes. Really, a node just means a spot where a certain property is zero or minimal, so there are many depending on what property you are interested in but two are usually important. The node you mention at 4:18 is a velocity node where the movement or velocity is zero. However this spot also represents a stress/pressure anti-node, where the internal tension in the string is maximal. This is similar to pressure anti-nodes in a woodwind instrument where the air isn't moving because it is being squished from both sides evenly, but the pressure changes are highest.
in transmission lines, an electrical node is a currents antinode... with a standing wave induced, the electric node can reach potentials so high the insulation breaks down. and 1/4 wave from there, the current so high the conductor fuses and melts...
That part near the end where you mentioned "Knowing when your model is about to break" is a whole entire video (or series) in itself. I'd love to deep dive that point applied to models of the universe or climate or even traffic or holiday shopping. A lot of people distrust scientific models because they have a limit where the model breaks down, but the accuracy of a model up to that limit isn't linear, and it's that accuracy and knowing those limits that allows us to do things like predict the future (e.g. meteorology) with astounding precision.
Yes! This is why statistics is so important. The models predict things with infinite precision, so you need statistical analysis of real-world data to assess how valid the model is under given parameters.
@@BracaPhoto They are using the word infinite correctly here. You can't "see" infinity - it's a mathematical concept that means that, for any number, there is always a number bigger than it. In the case of a mathematical model, you can always keep calculating more digits of precision. As an example, say you calculate the model out to 10 digits. That's just when you choose to stop. You can continue to 11 digits, 12, 13, and so on. There is never a number of digits N for which there isn't another number N+1 that you could continue to. That's the definition of infinite. Keep in mind that they are also using the word "precision" for it's mathematical meaning. Precision simply means the number of digits we have in the number - how little we leave out. That doesn't mean the model is perfectly "accurate" - the value calculated need not match the value you would observe in the real world. People often use these words interchangeably without realizing they mean two distinctly different things. Like it or not, statistics is how we summarize our knowledge of the world. We can't see everything happening for all of eternity. We can't measure it to infinite precision. We only have moments in time measured to some fixed precision. These are representations of the real world (think Plato's shadows on the cave wall), but they nonetheless are a result of the things that happen in the real world. Without a way to know exactly how the real things come to be, we can only create models - ideas - of what's happening based on our observations. This is statistics - combining all of the discrete observations we have to form an idea that could explain what we have observed. The insight that is gained is that we move from individual observations to an overall understanding of the whole by combining those observations and finding the set of possible relationships that would agree with those observations. The more observations we have, the fewer models we are left with that agree, bringing us ever closer to the true behaviour. It has nothing to do with pictures or shapes. Please understand that without a thorough understanding of what statistics is and how it's used, you can't make a fair judgment of it. Just like you said, you are making a stereotype out of statistics - you think of it based on your own observations while not seeing the whole picture. Those who work with statistics every day have many more observations and as a result have a much better picture of what it is. Keep an open mind and keep learning - don't assume that you know all there is to know about a subject, whether that's about life or just about statistics. Otherwise, you make the same error that you are telling others to avoid.
Excellent video! Another fun example: the change in resonant frequency as tension increases is easily observed with a guitar string which is strummed too aggressively, especially the lower-pitched strings. Playing a string too hard results in its pitch going sharp and then returning to its proper pitch as the amplitude decays.
@@AlphaPhoenixChannelanother music related phenomenon - the harmonics of a plucked string are not quite integer multiples. The higher harmonics are sharp because of the stiffness of the string. This is especially noticeable in the thick bass strings of a piano. This also affects that way that pianos are tuned, which is as much an art as a science.
How glad are you that Mythbusters is finally available on TH-cam? Personally, I would even pay money to buy a complete series on dvd's. I'm just glad it's finally available!
@@runforitman I've seen a few episodes of "mythbusters abridged" on youtube. (although they might have been taken down by now) and after taking out the fluff, those episodes are like 5 minutes, lol. I don't blame @BeefIngot for not being able to watch em anymore.
It hasn't happened too often and only in buildings with the right construction, usually older wooden dance halls, but during some gigs where my bass is locked in with the drums and put through a decent PA system, I've sometimes felt the stage resonate beneath my feet. And the stage is attached is attached to the floor and of course the walls so you can actually get the whole building throbbing. It's an extremely visceral feeling with the shifting volume of air but also little puffs of dust coming of the tops of rafters provide visual evidence. Also I'm totally putting a slo-mo camera on my bottom B string now. Great video, cheers.
This made me realise that's probably the awe-inspiring effect they go for with those building-spanning pipe organs, having that happen back before electricity was widespread and buildings just didn't move without wind or calamity would have been quite something. Now I wanna try amped up drone music in a cathedral...
I was playing drums, near the bass rig, last week. The bassist was using a 1000w amp, with the preamp turned down, and 2 15" + 2 12" cabinets (yeah...overkill). He began to play and I felt a literal "gut wrenching", sickening, pressure through my whole body. I asked him to stop and change something (anything) on his settings because I assumed I was in exactly the wrong spot in a "standing wave". He did and the effect disappeared. Now I wonder where I was in that wave...a node, crest, mid-rise/fall....??? It felt as if my body was resonating with the wave and soaking up too much energy from the amp.
As an electrical engineer, I'm accustomed to thinking of resonant electrical circuits. I was happy to learn about these details that explain the deviation of physical string vibrations from the simple models, which I had never heard before. The other comments explaining how this affects musical instruments (especially guitars) are also delightfully informative. I was not expecting to have a phenomenon confirmed that I puzzled me since I was a child.
One of the best teachers I've ever had was great at gradually introducing new clues to a problem, meaning that the solution will click for different people at different times. I think this video manages to do the same and it's one of the biggest compliments I can think of. Thank you for the time and effort you put into your videos
For my applied physics bachelor, we did string resonance experiments as well. We would put alternating current on a tensioned copper wire and make it vibrate by placing a magnet next to the wire
I was actually surprised regarding the derivation of Einstein field equtions. Lots of dancing around with the geometry on a sphere. Nothing complicated, easy to mess up due to a blunder in basic geometry. What I love about physics: no politics envolved (unlike hystory or gender studies). Physisists find a way to say "we can bring politics in the field, but then your nuke fails to launch your tank wouldn't start moving". Good job, physisists. Keep politics away from the field.
That's so cool. I have a degree in Music Technology which includes a lot of sound wave theory, but to see things like the nodes appearing as you tune into a harmonic frequency is so cool! I should also say that harmonics are not always exact multiples of the fundamental frequency with regard to standing waves on a string, as it depends on the medium. e.g. harmonic intervals can stretch with stiff strings, meaning length and other related properties can also affect harmonic intervals.
I've always been curious about the behavior of standing waves inside a curved conical tube (french horn). Does each node travelling along the tube have a different amplitude? How would this affect the summed (overtones) and differential tones? What does articulation 'look like' in the wave form? A hard attack vs legato playing?
@@jamesgage5418 I thought I replied to this, I think they removed it because I added a link to a paper. Anyway, most of the French horn is actually cylindrical, which is where the natural resonance creates the sympathetic standing waves, so the anti-node amplitudes would be roughly uniform for a given excitement level. I'm not sure how the tube (body) curvature affects this, though - I don't actually know much about the physics of the French horn - I know a bell-shape is an interesting shape for natural resonance, as the fundamental is not the dominant harmonic (I think it's the second, usually). So I'm guessing the bell-shaped end has a similar effect in that it amplifies certain low-mid tone harmonics, thus increasing the peak of the audible range. You'd have to check on that, though. Attack and legato are simply effects of sympathetic response over time. So the basic tonality and timbre would be the same, really, just rapid changes over time with standing waves appearing and disappearing and thus maybe even nodes travelling back and forth at different frequency-dependant rates. The paper I linked about French horn harmonics seems fascinating, I'll try to post it again in another reply.
@WindsorMason It's called _A Study of French Horn Harmonics_ by Andy Thompson hosted on tnt-audio. I did reply like I said, and it wasn't removed right away, so I thought it was safe 🙄
It's crazy how quickly and clearly the fundamentals of calculus show up in this. I could very easily see the adding up of forces in a string canceling each other out in a textbook.
a single pendulum driven with a motor is a classic physics lab demonstration for a reason, it's so well behaved and lets you play with resonance and nonlinearity without needing special equipment and without having to go into waves immediately
I never had this happen, it's always struggling to understand something, I manage to grasp it and then someone posts a video clearly explaining the basics of it that weren't explained at all that I had to spend hours looking for
@@AmorDeae Same 😅. This video was actually not perfectly timed for me either. I actually learned about resonance in strings 2 months ago, but since my final exam in roughly 45 days will most likely include resonance, I think it still counts 🤓. The video did add something new that our teacher didn't mention though, the struggles of trying to match the theory with reality 👀. And I have to agree, I've found so many videos after learning about a subject in school (college), barely passing the subject and perfectly understanding the subject with a 20-40 minutes video by a "random" guy on youtube 😅.
To add a bit more rigor to the calculation of the limit on how much it can resonate: Let's say an individual wave has an initial amplitude of A, and each time a wave makes a round trip to end up back at the motor, it loses energy and has its amplitude reduced by a factor of B. With that, when the motor emits a wave, that will have an amplitude of A, while the previous wave that arrives at the same spot has an effective amplitude of AB, and the one before that is AB², continuing with AB³, AB^4, AB^5, etc. When you continue this infinitely, you get the sum over A×B^k, with k going from 0 to infinity. This sum is known as a geometric sum, and evaluates to A × 1/(1-B). This means that the overall amplitude will just be proportional to the strength of a single wave that is emitted by the motor, since B, i.e. the amount of a wave preserved by the bridge carrying it, is constant. By that logic, it makes perfect sense that a weak motor would have noticeable limitations, but it stays plausible that a stronger motor would have much stronger effects.
@@arthurmoore9488 The proof is actually pretty simple. First consider a finite sum, for example: x = 1 + B + B² then, multiply the equation by (1 - B) on both sides. As a result, you get: x (1 - B) = (1 + B + B²)(1 - B) = (1 + B + B²) * 1 - (1 + B + B²) * B = 1 + B + B² - B + B² - B³ = 1 - B³ Then, you can divide by (1 - B) on both sides, and get: x = (1 - B³)/(1 - B) You can do an analogous calculation for any arbitrary sum size. As a result, you get: 1 + B + B² + ... + B^n = (1 - B^(n+1)) / (1 - B) In this, the only part where n appears (which is what you want to be infinite) is in B^(n+1), but because the wave always loses a bit of energy instead of gaining or staying the same, you have 0
This video is incredible. So many brilliant camera techniques used to explain such a broad variety of concepts. 15:38 is such an effective way of visualizing exponential decay; I've never seen something like that done before.
A description about Q factor would be good, how quickly the amplitude drops off as the freq +/-'s from the resonant freq. And when you described the energy been used up in heat, sound, etc and the rate the amplitude drops away, this is called 'damping'. The Thiele/Small Parameters for loud speakers are calculated by all the fundamental physics of resonance.
He mentioned avoiding getting deep into the math for the sake of the video. Counter-intuitively, if you introduce too much complexity, people learn less, not more. I think his broad explanation and demonstration that the amplitude depends on a very narrow range of frequencies is enough for most people to get the general idea without having to know the technical terms we use in industry.
Not only the content is perfectly explained, but also the editing that demonstrates all these concepts must have taken a lot of work and the result is 10/10
This is really exceptionally well done! Bravo. The ARRL and anyone interested in antennas or traveling wave theory should watch and share this episode.
This reminded me of showing my son this idea with the antenna on my car. Once he got it then we spent a few minutes working to get the frequency right on an apartment carport. We nearly took the carport down with 30-40 pound shoves at the right time. It was a good teaching moment.
Always love the questions you ask and consequent explanations. As a fun adjacent experiment to explain the boundary conditions, you could try and build an oscillator into a string loop launcher ^^
I had an instructional guitar book called "How to Become Dangerous on Rock Guitar" when i was a kid. It was an awesome book and i did indeed become quite dangerous, not only on rock guitar but a number of different genres. Anyway, one of the things that made it such an awesome book was the amount of depth and detail it went into. It started with a thorough explanation of how a guitar string vibrates and how these vibrations result in the fundamental tone and subsequent harmonics (overtones) that make up each note. It was quite mind blowing to learn how a single string could vibrate simultaneously in halfs, thirds, fourths, etc. and that each of these different vibrations produced its own harmonic that was higher in pitch and lower in volume all making up what is heard as one note. In fact you can see this happening if you look at a plucked guitar string in a certain light along with the nodes at certain intervals. You can actually isolate different harmonics by touching the string lightly over a node.
I was about to comment on how this is the first resonance video I watch in a long while that DOESN'T mentions the Takoma bridge, but he came in clutch at the last minute. It's a fascinating case and I love to hear about it every time.
Great video, thoroughly researched with accurate demonstrations, nice wrap-up. As a mechanical engineer for 45 years, I could simplify most problems to keep the analysis down to a reasonable size job, but the key was to understand what I could simplify without invalidating that analysis. If I failed to that properly, my hardware would fail in vibration test...or worse, in service, thereby validating the most important rule, "Good judgement comes from experience; experience comes from bad judgement!"
Now try your string wave in a vacuum to exclude the dampening of the wave due to wind resistance at the high velocity points...If you plot your amplitude vs. frequency and drive power experiment it should get more linear. Or repeat your experiments with "less stretchy" materials like steel cable or as we did in school a glass rod. Maybe you can even destroy a glass rod like in the resonance experiments we did with a speaker and wine glass.
not the same problem exactly, the millennium bridge did not suffer from the wind, it suffered from the pedestrians walking in sync. the answer was simple add dampeners to absorb and dissipate that frequency and you are good to go. it was a different lesson that the millennium bridge taught us
@@nilsdock Fair point but in both cases, the cause was still resonance that the engineers hadn't planned for 🤷♂️. Also my comment was mostly a joke 😅.
I mean, this has been an issue with structural engineering for a long time. I forget which one it was, but I seem to recall there was a skyscraper where the engineers had tuned its twisting resonance to be outside the normal range that weather events could amplify. But when the synchronized steps of an aerobics class on the 13th floor happened to hit that exact frequency, it triggered an earthquake panic on the upper floors. Stuff like this can be VERY difficult to foresee, even WITH computer simulations.
Good demo. These effects happen in speaker cones too. I wonder if some of your fine-tuning problem is due to the delay of the actuator. The motor arm itself also has resonance. These things might be skewing results a bit at the really fine detail level.
At one point I had a really long motor arm - it let me put a really big initial wave in, but the reflections got wacky. I’d get a reflection off the interface between the plastic arm and the string, then another reflection from back near the stand. The final design was a compromise
You could greatly improve your string driving mechanism by using a 10” or 12” woofer with a vertical rod attached to the cone and a 100-200 watt audio amp. That would also allow you to use more than one signal generator (summing to mono) to create multiple simultaneous waves on the string. Your visualizations of the physics are among the best I’ve EVER SEEN on TH-cam. Great Work! 👍🏼🤓👍🏼
I love the pace and depth of your videos! I feel like no other science youtuber gets it right. Any time a question builds up in my head while watching (string stretching) you address exactly that later, it's fantastic!
I'm surprised you aren't talking about stringed musical instruments because that is where this is all studied most for hundreds of years, albeit often in more intuitive non-scientific ways (aka by ear) Ears are very accurate. When I was studying piano string tuning, we learned that all the resonant harmonics go higher up in pitch vs the fundamental. This is because string is not perfectly ideal and has a stiffness to it. That that looks like is the section at the node(s) that is flat and doesn't bend due to the material stiffness of the string. I had never heard about the idea that the string became longer when it has waves in it, though graphically that looks true. But the important point is that the harmonics all go to higher pitch because the more nodes you have in the string the shorter the string is, hence more tension/higher pitch. Interesting meandering video. Thank you.
I have no idea whether this can be done, but I know that Heisenbergs uncertainty principe is a property of waves in gemeral and was already known before quantum physics. Could a setup like this demonstrate the principle?
You can see it in this video. In terms of waves, the uncertainty principle means there is a maximum amount of knowledge we can have about the position of a wave along the string and its frequency. In order to know the position of the wave precisely it needs to be just a single pulse. But a single pulse doesn't have a frequency so there is a lot of uncertainty about the frequency of the wave. To reduce the uncertainty about the frequency we need multiple pulses together, but doing that spreads out the wave along the string (increasing the uncertainty in the position of the wave).
Oh this brings back memories of physics labs of days past, with one of those oscillation machines (probably made by Pasco or another "educational lab warehouses" that supplies stuff to schools at prices that seem way to expensive), and me and a couple guys stretched a string across the entire lab, and managed to get 13 or 14 nodes to a standing wave, and they were so tiny but we felt like we accomplished something. In reality, as a teacher of physics myself, I now realize internally the teacher was probably thinking "can you guys finish, I want to go home already". P.S. I love the "as an exercise for the viewer" bit, had me cracking up.
I personally have a hard time believing that the harmonic oscillator the MythBusters put on that bridge was totally harmless to it. I feel like it must at the very least put a lot of stress and wear on the joints and structural elements in the bridge and reduce its overall lifespan somewhat
Steel is awfully elastic, that bridge could probably move 1m at it's centre without reaching any plastic deformation, and as for joints/rivets, they wouldn't of shifted in that test, remember the bridge is moving constantly anyway, through wind and just general use.
@ yes I understand that the bridge is moving constantly due to a variety of factors, however, the lifespan of anything is pretty much always going to be some kind of function of the energy that has been put into it, and we’re talking about a device that’s literally tuned to add energy to the system as efficiently as possible. This is not in any manner comparable to the normal stresses that the bridge experiences on a regular basis. Please keep in mind that bridges, especially ones that carry cars, tend to last a very long time, and the kind of damage I’m talking about could mean the difference between the bridge lasting 99 years versus 100 (these aren’t real numbers, obviously) not necessarily it collapsing anytime in the near future
Eventually yes low amplitude repeated loading could cause fatigue, but if they were below the plastic deformation limit then they wouldn’t do anything at all. In reality this limit is fuzzy, so maybe a LITTLE? But the total energy in was not much compared to regular operation - they compared the feeling to a truck driving by. Wind provides massively stronger forces, but at very low dosing frequencies unless you get flutter like tacoma
@@AlphaPhoenixChannel thanks for the response! I loved your video by the way. This is basically my thinking for the record. I certainly don’t think the MythBusters did something wrong or anything haha. But I think people tend to forget that this stuff really does add up over very long timescales, I mean, put another way we’re saying that a 6 pound weight was able to re-create the stress of an entire bridges worth of trucks constantly rolling across it the entire time! (remember they said that they were able to feel the vibrations throughout the entire structure!)
@@jarlsparkleySteel is one of the only materials that has a threshold for fatigue buildup. Meaning, if the load is low enough it doesn't matter how many cycles you apply, you can't cause a fatigue failure. That threshold is pretty high and additionally structures are massively overbuilt, so you are never even close to working in that range for a bridge. That's why you don't typically deal with fatigue issues in bridges, and other factors play far bigger roles, like corrosion and extreme loads such as high wind or earthquakes.
Before watching this I thought I had a pretty good grasp on resonance but this video really makes the "why" much clearer, indeed almost obvious at points. I wasn't previously aware that the resonant frequency changes when waves are present but the diagram makes it pretty obvious and I thought "the string is longer" before you said it 😊. But I didnt spot that the effect of this was opposite and the whole tension making the wave travel faster thing.
The thing I love about discussing has tension is you can imagine yourself as a person in a string of people linked hand to hand. And as you imagine that you can actually feel the tension in your arms as the mote wave passes by.
Even when the answer to the thesis question seems intuitive to me, the journey from A to B always includes a wealth of detail I never considered. I love this channel more with every new video. And so help me if you ever say the words "this video is brought to you by raid shadow legends" I will explode into pink mist.
Please please please do a video explaining tesla coils in an intuitive way. I've always had a hard time understanding whats going on, but the way you present has helped get a lot of complicated subjects to finally sink in for me.
How did this pop up literally the day I watched the mythbusters bridge episode, I just found out that so many mythbusters episodes are on youtube from them so I've been watching through them recently as comfort watching as I do other things. It's bittersweet to see Grant always being the person that made people love and respect him and then realizing he isn't around in the world anymore, that's why it's called loss, and accepting that is just the way of the world.
Great video, was just having a buddy create standing wave animations for our chemistry section of our physics site. That slow mow standing wave on the reflection was so pleasing to see!
You can see this take place in a coaxial cable system. Troubleshoot standing waves in a coaxial cable system can be complex if you don't have the right tools and the right mindset. Thank you for this video.
Nice demos of single sine waveforms, TFS. As you likely know, in actual complex physical acoustical environments, the reflections and minute pressure interactions of sound fields still have many behaviours similar to simple sine reactions, but the math is quite exponentially more complex (still, super computers can generate IMO some fascinating visual depictions of sound “snapshots”). I’d like to see you also demo how sound behaves in rooms with flat vs. curved panels, and to hear/see Lissajous figures and how they “feel”, because resonance isn’t too different from reverb/echo in a scientific sense. (I also caution against using the verb “amplify” unless you literally [externally] track and expand the waveforms in perfect sync to increase their amplitudes, which, like acoustics in general, seems like an imperfect task to depict by its complex nature.) What about depicting how our brains “interpret” transients and collisions of more complex sound fields to give us meaningful, usable information?
My point at the end of my long initial comment was that, like the tiny ‘barbs’ in serif text fonts give us almost subconscious cues about characters being used, so transients and other “anomalies” can have the effect of implying other “expected causal phenomena”, maybe akin to a hologram being at essence an “interference pattern”, which is an oft-used “explanation of reality” that I personally find uselessly imprecise.
Honestly, the minute I saw the simulated demo of a wave on a bent rope it started to make sense. You aren't adding more energy into a single wave, but rather layering waves on top of each other. And as you demonstrated, a wave will eventually decay. So you get to this point where even though you are adding more waves onto the layer, the first ones are dropping out in a sort of FIFO stack.
I like your explanations. My Dad did a lot of the Resonance Frequency Analysis on Skylab and the Space Shuttles in building 49 at nasa jsc and I remember him showing me all the exaggerated flexing of the Shuttle's wings during re-entry. At some speeds they flapped like a bird but other speeds caused multiple waves to appear. Cool stuff to see.
Great demonstration of resonance. The main setup of the experiment is satisfyingly low tech but very effective with the high-speed camera and signal generator input.
Noise cancellation, surprised nobody has mentioned yet this is why it's so important your speakers are correctly wired. Between two with mono (same) sound on each, there is silence in the middle, it's amazing to experience. This is key to how active noise cancelling works, how audio sound extraction works, etc.
Just realizing this now, but I would _LOVE_ a collab between you and Grady from Practical Engineering! You guys are both great explainers with a knack for demonstration through experimental results. It would be a real power duo!
The one side fixed string is the best live demo of what superposition and linearity is. It visualises the math concepts very well. You can calculate lots of stuff and test it in real world.
Yup, this was very cool. I had never really thought through why resonance doesn't build forever... this was a beautiful explanation... and, the idea of superposition of repeated waves instead of just amplitude building is the key to understanding this. Great job. I thought for sure that you'd show how you can add different frequencies (and phase offsets) to create a monster peak anywhere along the string (in the world of ocean navigation it's called the "rogue wave"). It requires using Fourier series with D/As instead of just simple frequency generators... but a great way to show how these waves add together in some pretty magical ways.
The tacoma bridge is the largest widely-known example of the same phenomenon that causes ratchet straps to 'hum' when driving down the highway while carrying a load. Much larger scale, much more inertia, much slower oscillation, but still the same thing.
Beautiful video, and beautiful experiment. I've always been fascinated about waves, and this experiment is just perfect to introduce kids and students to it. Thank you!!!
The final observation about how the equations physicists like to use are all wrong was actually kinda crushing for me to learn (but it was a sow realization so I got to distribute the disappointment over time lol) after leaving school. When I learned this, and I still do wish, that my teachers had made it more clear that the things we learned were simplifications and idealized models that don't represent the real world. I'm not mad that I wasn't made to do *actual* optical calculations for physically accurate lenses in physics, but I *am* mad that I spent a significant amount of time thinking that paparabolic lenses were actually perfectly physically ideal in the real world. I felt lied to, or at the very least I felt like an assumption was made that I would not have been able to understand the reason that things were being simplified. Videos like this are awesome, and should be required viewing when learning a subject. It would have been intensely helpful in school to have something that explains "This is why everything you are about to learn is technically wrong, and *this* is why you should be happy not to have to do it the hard way, because shit is complicated" lol. I consider myself lucky that I did not end up going into any of the hard sciences, because If I had learned this stuff after making a more serious commitment I'm not sure what I would have done. It's like the education equivalent of scope creep. In other industries if you sign up for a job with a certain scope and then the scope gets increased out from under you we usually consider that to be bad and hopefully not allowed by the contract if you have one. It's weird to me that school effectively just does that repeatedly and seemingly no one cares.
Anyone else wish he would have tuned the length so it would resonate at a whole number frequency (4hz) so the trickiness of the 2 super imposed waves was easier to "see" in the non-integer multiple of the required frequency? Great video - love your stuff!
I love that waves deflect upside down because, assuming my thought process is correct, it models one of Newton's laws perfectly. The wave hits the wall, pulling it in one direction, we'll say contacting it a little, and the wall expands back to its original size, but not perfectly, expanding just a little too much and exerting that extra force used to expand it as a wave with lower amplitude in the opposite direction to conserve momentum. Of course this deformation of the wall in incredibly tiny with rigid structures, but the heat lost in this compression/expansion is part of the reason the wave bounces back with a noticable amount less amplitude.
I knew that losses were the reason for the loss of wave energy, but I hadn’t ever thought of the energy being lost to breaking bonds in the metal which makes a ton of sense. There’s also the idea that the bridge doesn't have just one resonant frequency. All the individual parts still have other resonances. It also made me realize that even if you put a much larger driving mass on a bridge, it still likely wouldn’t come down because even if you managed to crack a beam or blow out enough rivets, you still would have to account for the sudden and complete change in resonance from such a large structural change.
Dude, this is AWESOME! I always thought about how exactly do radio antennas form and emit electromagnetic waves and you just visualized it using a cord. Different medium but everything else is the same
I loved this part of my calculus classes. It was amazing to model the harmonics and see how they would sync and amplify. More fascinating to me was offsetting them slightly and watching the patterns that emerged with the period slightly off the harmonics frequency. A tuning parameter which allowed slowly passing the wave through harmonics and anharmonics was cool to suddenly see the wave snap into harmony and then almost resist leaving that harmony back into disordered frequencies.
Nice! One point about the exponential decay you show: The first initial decay seem to have a much faster decay that the rest of the curve, I think that is an indication of a non-linear decay that you get when your string is already oscillating at amplitudes where the nonlinear terms in the wave-equation are no longer negligible. Also, nice to see a video of the Tacoma bridge, and the man walking off it was very very calm, much calmer than I'd be...
wahoo, another video from my favorite creator! This is also an example of why the coil frequency calculators and an approximation. You always have to add or remove loops of wire on the coil to come close to the predicted oscillation. There are so many factors like insulation thickness, wire thickness, air gaps between windings. Even if you created a perfect math calculation to predict it, you would still only get close because some adjacent turns may be stretched or closer together than others on the same coil. I always wanted a better calculation but I think there are just too many tiny unmeasurable things in real life that would determine the actual frequency. Great video as always by the way. You are one of the few creators that has a broad and deep stroke of education broken down into simple concepts. Thank you for all the videos you create! I wonder what the minimum power to break a wine glass from a speaker is. I have seen it done many times, but there has to be some minimum power to make it happen. Great demo and animations as always. I really appreciate your videos.
wow... i cant believe i found this interesting. I mean it isnt exciting by nature lol, but i couldnt help but keep watching. Somehow watching a string vibrate and all the stuff i cant understand that went into it was somehow mesmerizing. the subtle nuances of each factor going into it was somehow interesting.... Cool man, right on. Thanks
I'd love to see the resonance of brass instruments modeled and explained on this channel if you can ever get to it! The point about harmonics not being exactly integer multiples in the real world made me think about the way brass instruments work. On a brass instrument, you can get multiple notes on the same length of tubing by going through the harmonics (called "partials" in this context). However, they end up not all being in tune, meaning you sometimes need to pitch a particular partial up or down. This is usually done by adjusting the input frequency to get the partial back in tune, and experienced musicians have these tunings memorized so they can hit the right pitch immediately. It's also not as simple of a relationship as on the string model, because the tubes on brass instrument loop around and change diameter. Depending on where the nodes end up in the tube, you could get different interactions with the bends in the pipe (or even with any dents that might be there). Another interesting interaction on brass instruments is that the partials actually influence the player's input frequency, nudging it towards that partial's resonant frequency like a ball rolling into a valley. It's a neat effect that I don't think can be represented with your string model, but I'd love to understand it better.
I love how the history of physics is basically summed up with "Wow, that problem is difficult! I wish it was easier. So lets find an easier problem and solve that instead. If we dial in the assumptions close enough, it will be effectively the same" It's not about being right, it's about being as not wrong as you can be. Though obviously sometimes we end up with epicycles because of that
I almost headed to the comments before the video was over to mention the Tacoma Narrows bridge, but thankfully I waited until the end lol. Also, sticking your tongue out while trying to get the two waves to work was very funny and cute.
These videos are better than every EE class I've taken lol. A cool way to build up to Tesla coils (or just more nonlinear electrical fun) would be to look more at the coil used here and explain why a flyback diode or some snubber is needed to prevent kickback from the inductance (which could lead to a deeper look at inductance and capacitance as a continuation of transmission line concepts, or even RF, or just pure Tesla madness haha).
Before watching the PS section, I wasn’t planning to destroy a bridge using resonance. Now, I’m going to do it because a guy on TH-cam assured me the bridge would be fine. Wish me luck!
We had a professor nicely show us his example of why linearity and describing formulas break down: He just used a large resistive heating-element. Simple "V=IR" would tell us that doubling the voltage would also double the current and 4x the power - and as we have measured the resistance we can predict that ... yeah and then it starts glowing and the resistance goes up until it finally breaks apart.
I like to imagine the string model as a series of points elastically connected to each other, and then I am able to visualize how they interact with each other. This then tells me that the wave we are seeing is a product of particles moving up and down. So, the answer to how the wave is being reflected at the end of the string is: When the final few points get stretched, they apply a force to the "immovable object", since it can't be moved all of the energy gets stored elastically in the fabric of the string stretching even further before returning and sending the wave backwards with some energy loss
FAQ and corrections in this comment! (video Q&A will be on the second channel!)
1) This is the first time I'm using the A/B split thumbnail tool. because I was kinda lost - I just think waves on strings are really cool. If anybody has good title/thumbnail ideas, I'm all ears lol.
2) Real Q&A coming soon - after there are Qs to A...
Could you get the string to glow/radiate if you placed the whole apparatus inside a vacuum?
@@GabeSullice It already does if you count IR. If you mean visible light - No, it would melt way before that. And probably lose resonance way before melting because of softening.
@@AlphaPhoenixChannel Thumbnail idea: INFINITE WAVES??? In red with you (just your head) doing a click bait face on the bottom right confused looking up trying to find the top and a wave dwarfing you in the background.
There is a red arrow pointing off screen to the top of the wave.
Directs the viewers eyes to the wave, and makes them wonder what's so special at the top.
Correction: At the end you accidentally left out the "dis" part of "disheartening."
Next up Fourier transformation for dummies
25:40 Did he say "I hope you enjoyed this Fourier into resonance today?" :)
No but now I wish I had
I said it in my head.
@@UncleKennysPlace
I’m only saying it now, don’t give me away 🤭
I like how this video seems to answer the questions that pop into my head almost right after they appear, extremely intuitive structure
😁
exactly! I was literally reading about standing waves before I clicked on the video!
smart people tend to think in similar ways.
In my case, he is about 37 years late.
I literally Just posed the same question in my head and found this video 2 mins after a little scrolling lol
THANK YOU for finally saying that "superposition" = "adding things together". Its probably the most overused term for something very lame lol
I wouldn't necessarily say it's "overused." In fact, I think the opposite is true. People think superposition is magic because it's only really used in the context of quantum weirdness, but many different things in physics obey the superposition principle. Waves, forces, fields.
Superposition itself is just a boring, but useful tool. The WHY (why can you just add two waves?) is way more interesting because it leads you to the simplifying assumptions discussed in this video.
For my entire life this was known as "linearity". A more precise: passing something through linear function does not change how things are added. In Math language f(A + B) = f(A) + f(B). I do not understand why we need another term (and I know this property holds for some definitely not linear functions, so I guess "linear" might be misleading), but what is crazy, is how simple this property is and how often explanation of superposition is made so complicated, that you have no idea what people are talking about.
@IlluminatiBG linearity and superposition are not quite the same thing. As you said, linearity can be described as f(a) + f(b) = f(a+b). That's not what superposition is. If you wanted to put it into mathematical notation that way, superposition would be much more akin to h(a) = f(a) + g(a). The superposition principle says that for certain quantities if there are two (or more) sources of that quantity at the same position the value you get when you measure that quantity at that location is the sum of the values for all sources.
The big difference between the two is that the measured function (h in my example) *need not be the same* as either of the original source functions (f and g). This is why two traveling waves can add together to form a superposition which is a standing wave.
There are a lot of terms that people don't understand and use all the time.
As an instrument maker this is super cool. One thing I would add is there are two types of nodes. Really, a node just means a spot where a certain property is zero or minimal, so there are many depending on what property you are interested in but two are usually important. The node you mention at 4:18 is a velocity node where the movement or velocity is zero. However this spot also represents a stress/pressure anti-node, where the internal tension in the string is maximal. This is similar to pressure anti-nodes in a woodwind instrument where the air isn't moving because it is being squished from both sides evenly, but the pressure changes are highest.
in transmission lines, an electrical node is a currents antinode...
with a standing wave induced, the electric node can reach potentials so high the insulation breaks down.
and 1/4 wave from there, the current so high the conductor fuses and melts...
@@paradiselost9946 wow! I understood very little of what you described , but it sounds incredibly interesting! Tell us more please?
That part near the end where you mentioned "Knowing when your model is about to break" is a whole entire video (or series) in itself. I'd love to deep dive that point applied to models of the universe or climate or even traffic or holiday shopping.
A lot of people distrust scientific models because they have a limit where the model breaks down, but the accuracy of a model up to that limit isn't linear, and it's that accuracy and knowing those limits that allows us to do things like predict the future (e.g. meteorology) with astounding precision.
Yes! This is why statistics is so important. The models predict things with infinite precision, so you need statistical analysis of real-world data to assess how valid the model is under given parameters.
@@BracaPhoto They are using the word infinite correctly here. You can't "see" infinity - it's a mathematical concept that means that, for any number, there is always a number bigger than it. In the case of a mathematical model, you can always keep calculating more digits of precision. As an example, say you calculate the model out to 10 digits. That's just when you choose to stop. You can continue to 11 digits, 12, 13, and so on. There is never a number of digits N for which there isn't another number N+1 that you could continue to. That's the definition of infinite.
Keep in mind that they are also using the word "precision" for it's mathematical meaning. Precision simply means the number of digits we have in the number - how little we leave out. That doesn't mean the model is perfectly "accurate" - the value calculated need not match the value you would observe in the real world. People often use these words interchangeably without realizing they mean two distinctly different things.
Like it or not, statistics is how we summarize our knowledge of the world. We can't see everything happening for all of eternity. We can't measure it to infinite precision. We only have moments in time measured to some fixed precision. These are representations of the real world (think Plato's shadows on the cave wall), but they nonetheless are a result of the things that happen in the real world. Without a way to know exactly how the real things come to be, we can only create models - ideas - of what's happening based on our observations. This is statistics - combining all of the discrete observations we have to form an idea that could explain what we have observed. The insight that is gained is that we move from individual observations to an overall understanding of the whole by combining those observations and finding the set of possible relationships that would agree with those observations. The more observations we have, the fewer models we are left with that agree, bringing us ever closer to the true behaviour. It has nothing to do with pictures or shapes.
Please understand that without a thorough understanding of what statistics is and how it's used, you can't make a fair judgment of it. Just like you said, you are making a stereotype out of statistics - you think of it based on your own observations while not seeing the whole picture. Those who work with statistics every day have many more observations and as a result have a much better picture of what it is. Keep an open mind and keep learning - don't assume that you know all there is to know about a subject, whether that's about life or just about statistics. Otherwise, you make the same error that you are telling others to avoid.
Excellent video! Another fun example: the change in resonant frequency as tension increases is easily observed with a guitar string which is strummed too aggressively, especially the lower-pitched strings. Playing a string too hard results in its pitch going sharp and then returning to its proper pitch as the amplitude decays.
That’s fascinating! Makes sense!
The whole metal music style was born above this phenomena. Called "Jent".
@@Ma_X64Djent?
Was just about to say the same! Well known effect
@@AlphaPhoenixChannelanother music related phenomenon - the harmonics of a plucked string are not quite integer multiples. The higher harmonics are sharp because of the stiffness of the string. This is especially noticeable in the thick bass strings of a piano. This also affects that way that pianos are tuned, which is as much an art as a science.
How glad are you that Mythbusters is finally available on TH-cam?
Personally, I would even pay money to buy a complete series on dvd's. I'm just glad it's finally available!
I remember it so fondly, but I find it so unbearably unwatchable now with the way tv used to be at the time with all the recaps and breaks.
@@BeefIngotneed mythbusters abridged
@@runforitman I've seen a few episodes of "mythbusters abridged" on youtube. (although they might have been taken down by now) and after taking out the fluff, those episodes are like 5 minutes, lol. I don't blame @BeefIngot for not being able to watch em anymore.
@@BeefIngot Get yourself SponsorBlock, it has options to skip those sections.
You have Allan Pan to thank for it.
It hasn't happened too often and only in buildings with the right construction, usually older wooden dance halls, but during some gigs where my bass is locked in with the drums and put through a decent PA system, I've sometimes felt the stage resonate beneath my feet. And the stage is attached is attached to the floor and of course the walls so you can actually get the whole building throbbing. It's an extremely visceral feeling with the shifting volume of air but also little puffs of dust coming of the tops of rafters provide visual evidence. Also I'm totally putting a slo-mo camera on my bottom B string now. Great video, cheers.
This made me realise that's probably the awe-inspiring effect they go for with those building-spanning pipe organs, having that happen back before electricity was widespread and buildings just didn't move without wind or calamity would have been quite something.
Now I wanna try amped up drone music in a cathedral...
the story regarding tesla and resonance did involve a building, and not a bridge.
I was playing drums, near the bass rig, last week. The bassist was using a 1000w amp, with the preamp turned down, and 2 15" + 2 12" cabinets (yeah...overkill). He began to play and I felt a literal "gut wrenching", sickening, pressure through my whole body. I asked him to stop and change something (anything) on his settings because I assumed I was in exactly the wrong spot in a "standing wave". He did and the effect disappeared. Now I wonder where I was in that wave...a node, crest, mid-rise/fall....??? It felt as if my body was resonating with the wave and soaking up too much energy from the amp.
I think Mr Phoenix should get a Moog Minitaur and start cracking bricks 😂
@@oleran4569 Cool
As an electrical engineer, I'm accustomed to thinking of resonant electrical circuits. I was happy to learn about these details that explain the deviation of physical string vibrations from the simple models, which I had never heard before. The other comments explaining how this affects musical instruments (especially guitars) are also delightfully informative. I was not expecting to have a phenomenon confirmed that I puzzled me since I was a child.
Totally agree !
One of the best teachers I've ever had was great at gradually introducing new clues to a problem, meaning that the solution will click for different people at different times. I think this video manages to do the same and it's one of the biggest compliments I can think of. Thank you for the time and effort you put into your videos
For my applied physics bachelor, we did string resonance experiments as well. We would put alternating current on a tensioned copper wire and make it vibrate by placing a magnet next to the wire
I was actually surprised regarding the derivation of Einstein field equtions. Lots of dancing around with the geometry on a sphere. Nothing complicated, easy to mess up due to a blunder in basic geometry.
What I love about physics: no politics envolved (unlike hystory or gender studies). Physisists find a way to say "we can bring politics in the field, but then your nuke fails to launch your tank wouldn't start moving".
Good job, physisists. Keep politics away from the field.
That's so cool. I have a degree in Music Technology which includes a lot of sound wave theory, but to see things like the nodes appearing as you tune into a harmonic frequency is so cool! I should also say that harmonics are not always exact multiples of the fundamental frequency with regard to standing waves on a string, as it depends on the medium. e.g. harmonic intervals can stretch with stiff strings, meaning length and other related properties can also affect harmonic intervals.
I've always been curious about the behavior of standing waves inside a curved conical tube (french horn). Does each node travelling along the tube have a different amplitude? How would this affect the summed (overtones) and differential tones? What does articulation 'look like' in the wave form? A hard attack vs legato playing?
@@jamesgage5418 I thought I replied to this, I think they removed it because I added a link to a paper. Anyway, most of the French horn is actually cylindrical, which is where the natural resonance creates the sympathetic standing waves, so the anti-node amplitudes would be roughly uniform for a given excitement level. I'm not sure how the tube (body) curvature affects this, though - I don't actually know much about the physics of the French horn - I know a bell-shape is an interesting shape for natural resonance, as the fundamental is not the dominant harmonic (I think it's the second, usually). So I'm guessing the bell-shaped end has a similar effect in that it amplifies certain low-mid tone harmonics, thus increasing the peak of the audible range. You'd have to check on that, though. Attack and legato are simply effects of sympathetic response over time. So the basic tonality and timbre would be the same, really, just rapid changes over time with standing waves appearing and disappearing and thus maybe even nodes travelling back and forth at different frequency-dependant rates. The paper I linked about French horn harmonics seems fascinating, I'll try to post it again in another reply.
@@GetMoGaming try giving just the title of it :)
@WindsorMason It's called _A Study of French Horn Harmonics_ by Andy Thompson hosted on tnt-audio. I did reply like I said, and it wasn't removed right away, so I thought it was safe 🙄
It's crazy how quickly and clearly the fundamentals of calculus show up in this. I could very easily see the adding up of forces in a string canceling each other out in a textbook.
It's also crazy that the word fundament once referred to ones butthole. Sorry my wife says I am an encyclopedia of useless knowledge.
I love the way these second-order effects make so much sense with just a little thought
a single pendulum driven with a motor is a classic physics lab demonstration for a reason, it's so well behaved and lets you play with resonance and nonlinearity without needing special equipment and without having to go into waves immediately
But his demo really shows you how wave resonace works. It is a bit of a leap for beginners to go from pendulums to standing waves.
What I love about your videos - except of course from the great content, demos and animations - is the enthusiasm you radiate when explaining stuff.
I love it when youtubers just happen to post stuff related to what I'm currently learning about 😂. Makes things so much easier 😁.
I don't think I would have graduated if it wasn't for mathematicians on TH-cam. Thanks old Indian guys!
It makes things more interesting for me
I never had this happen, it's always struggling to understand something, I manage to grasp it and then someone posts a video clearly explaining the basics of it that weren't explained at all that I had to spend hours looking for
@@AmorDeae Same 😅. This video was actually not perfectly timed for me either. I actually learned about resonance in strings 2 months ago, but since my final exam in roughly 45 days will most likely include resonance, I think it still counts 🤓. The video did add something new that our teacher didn't mention though, the struggles of trying to match the theory with reality 👀. And I have to agree, I've found so many videos after learning about a subject in school (college), barely passing the subject and perfectly understanding the subject with a 20-40 minutes video by a "random" guy on youtube 😅.
Yah, just a coincidence...not that all your apps have permission to listen to you
There cannot be an educational lesson about resonance without that bridge.
A nod to the footfalls of marching legions of Roman soldiers would have been kinda cool, too... Jus' sayin'...
Our physics teacher surmised the walls of Jericho may have come tumbling down due to resonance induced by the trumpet! 😅
No frickin way, I was just googling this exact question last night!
Perfect timing man :D
To add a bit more rigor to the calculation of the limit on how much it can resonate:
Let's say an individual wave has an initial amplitude of A, and each time a wave makes a round trip to end up back at the motor, it loses energy and has its amplitude reduced by a factor of B.
With that, when the motor emits a wave, that will have an amplitude of A, while the previous wave that arrives at the same spot has an effective amplitude of AB, and the one before that is AB², continuing with AB³, AB^4, AB^5, etc.
When you continue this infinitely, you get the sum over A×B^k, with k going from 0 to infinity. This sum is known as a geometric sum, and evaluates to A × 1/(1-B).
This means that the overall amplitude will just be proportional to the strength of a single wave that is emitted by the motor, since B, i.e. the amount of a wave preserved by the bridge carrying it, is constant.
By that logic, it makes perfect sense that a weak motor would have noticeable limitations, but it stays plausible that a stronger motor would have much stronger effects.
To infinity you say? Sounds like calculus magic to me. :D Especially when I dont remember the identity and transformation equations.
@@arthurmoore9488 The proof is actually pretty simple. First consider a finite sum, for example:
x = 1 + B + B²
then, multiply the equation by (1 - B) on both sides. As a result, you get:
x (1 - B) = (1 + B + B²)(1 - B)
= (1 + B + B²) * 1 - (1 + B + B²) * B
= 1 + B + B² - B + B² - B³
= 1 - B³
Then, you can divide by (1 - B) on both sides, and get:
x = (1 - B³)/(1 - B)
You can do an analogous calculation for any arbitrary sum size. As a result, you get:
1 + B + B² + ... + B^n
= (1 - B^(n+1)) / (1 - B)
In this, the only part where n appears (which is what you want to be infinite) is in B^(n+1), but because the wave always loses a bit of energy instead of gaining or staying the same, you have 0
This video is incredible. So many brilliant camera techniques used to explain such a broad variety of concepts.
15:38 is such an effective way of visualizing exponential decay; I've never seen something like that done before.
A description about Q factor would be good, how quickly the amplitude drops off as the freq +/-'s from the resonant freq. And when you described the energy been used up in heat, sound, etc and the rate the amplitude drops away, this is called 'damping'. The Thiele/Small Parameters for loud speakers are calculated by all the fundamental physics of resonance.
He mentioned avoiding getting deep into the math for the sake of the video. Counter-intuitively, if you introduce too much complexity, people learn less, not more. I think his broad explanation and demonstration that the amplitude depends on a very narrow range of frequencies is enough for most people to get the general idea without having to know the technical terms we use in industry.
Not only the content is perfectly explained, but also the editing that demonstrates all these concepts must have taken a lot of work and the result is 10/10
This is really exceptionally well done! Bravo. The ARRL and anyone interested in antennas or traveling wave theory should watch and share this episode.
G1MNB In an antenna the electrons are doing the motion loosing energy as electromagnetic radio wave.
This reminded me of showing my son this idea with the antenna on my car. Once he got it then we spent a few minutes working to get the frequency right on an apartment carport. We nearly took the carport down with 30-40 pound shoves at the right time. It was a good teaching moment.
Always love the questions you ask and consequent explanations. As a fun adjacent experiment to explain the boundary conditions, you could try and build an oscillator into a string loop launcher ^^
I had an instructional guitar book called "How to Become Dangerous on Rock Guitar" when i was a kid. It was an awesome book and i did indeed become quite dangerous, not only on rock guitar but a number of different genres. Anyway, one of the things that made it such an awesome book was the amount of depth and detail it went into. It started with a thorough explanation of how a guitar string vibrates and how these vibrations result in the fundamental tone and subsequent harmonics (overtones) that make up each note. It was quite mind blowing to learn how a single string could vibrate simultaneously in halfs, thirds, fourths, etc. and that each of these different vibrations produced its own harmonic that was higher in pitch and lower in volume all making up what is heard as one note. In fact you can see this happening if you look at a plucked guitar string in a certain light along with the nodes at certain intervals. You can actually isolate different harmonics by touching the string lightly over a node.
I was about to comment on how this is the first resonance video I watch in a long while that DOESN'T mentions the Takoma bridge, but he came in clutch at the last minute. It's a fascinating case and I love to hear about it every time.
Great video, thoroughly researched with accurate demonstrations, nice wrap-up. As a mechanical engineer for 45 years, I could simplify most problems to keep the analysis down to a reasonable size job, but the key was to understand what I could simplify without invalidating that analysis. If I failed to that properly, my hardware would fail in vibration test...or worse, in service, thereby validating the most important rule, "Good judgement comes from experience; experience comes from bad judgement!"
Now try your string wave in a vacuum to exclude the dampening of the wave due to wind resistance at the high velocity points...If you plot your amplitude vs. frequency and drive power experiment it should get more linear.
Or repeat your experiments with "less stretchy" materials like steel cable or as we did in school a glass rod. Maybe you can even destroy a glass rod like in the resonance experiments we did with a speaker and wine glass.
Onl yone minute passed, and you already explained resonance better than any other teacher in my life.
27:20 Engineers learned from this event, so they repeated the same mistake with the Millenium bridge 😂.
not the same problem exactly, the millennium bridge did not suffer from the wind, it suffered from the pedestrians walking in sync. the answer was simple add dampeners to absorb and dissipate that frequency and you are good to go. it was a different lesson that the millennium bridge taught us
@@nilsdock This is why we now prefer Engineers learn their lessons in simulations before we use these items as human test dummys
@@BeefIngot I'm pretty sure accurate enough simulations didn't exist back when that bridge was built 🤔…
@@nilsdock Fair point but in both cases, the cause was still resonance that the engineers hadn't planned for 🤷♂️. Also my comment was mostly a joke 😅.
I mean, this has been an issue with structural engineering for a long time. I forget which one it was, but I seem to recall there was a skyscraper where the engineers had tuned its twisting resonance to be outside the normal range that weather events could amplify. But when the synchronized steps of an aerobics class on the 13th floor happened to hit that exact frequency, it triggered an earthquake panic on the upper floors. Stuff like this can be VERY difficult to foresee, even WITH computer simulations.
You just snuck up and ambushed us with the knowledge of exactly how tesla coils work.
Wonderful job. Excellent illustrations.
I do not really often comment, but I just wanted to say that I really appreciate your content! Have been for 3+ years now!
Good demo. These effects happen in speaker cones too. I wonder if some of your fine-tuning problem is due to the delay of the actuator. The motor arm itself also has resonance. These things might be skewing results a bit at the really fine detail level.
At one point I had a really long motor arm - it let me put a really big initial wave in, but the reflections got wacky. I’d get a reflection off the interface between the plastic arm and the string, then another reflection from back near the stand. The final design was a compromise
You could greatly improve your string driving mechanism by using a 10” or 12” woofer with a vertical rod attached to the cone and a 100-200 watt audio amp. That would also allow you to use more than one signal generator (summing to mono) to create multiple simultaneous waves on the string. Your visualizations of the physics are among the best I’ve EVER SEEN on TH-cam. Great Work! 👍🏼🤓👍🏼
0:35 ksp soundtrack?
Yes it is
I love the pace and depth of your videos! I feel like no other science youtuber gets it right. Any time a question builds up in my head while watching (string stretching) you address exactly that later, it's fantastic!
All of the sudden I had to check if I left KSP running in the background
I'm surprised you aren't talking about stringed musical instruments because that is where this is all studied most for hundreds of years, albeit often in more intuitive non-scientific ways (aka by ear)
Ears are very accurate.
When I was studying piano string tuning, we learned that all the resonant harmonics go higher up in pitch vs the fundamental. This is because string is not perfectly ideal and has a stiffness to it. That that looks like is the section at the node(s) that is flat and doesn't bend due to the material stiffness of the string. I had never heard about the idea that the string became longer when it has waves in it, though graphically that looks true. But the important point is that the harmonics all go to higher pitch because the more nodes you have in the string the shorter the string is, hence more tension/higher pitch.
Interesting meandering video. Thank you.
I have no idea whether this can be done, but I know that Heisenbergs uncertainty principe is a property of waves in gemeral and was already known before quantum physics. Could a setup like this demonstrate the principle?
You can see it in this video. In terms of waves, the uncertainty principle means there is a maximum amount of knowledge we can have about the position of a wave along the string and its frequency.
In order to know the position of the wave precisely it needs to be just a single pulse. But a single pulse doesn't have a frequency so there is a lot of uncertainty about the frequency of the wave. To reduce the uncertainty about the frequency we need multiple pulses together, but doing that spreads out the wave along the string (increasing the uncertainty in the position of the wave).
Oh this brings back memories of physics labs of days past, with one of those oscillation machines (probably made by Pasco or another "educational lab warehouses" that supplies stuff to schools at prices that seem way to expensive), and me and a couple guys stretched a string across the entire lab, and managed to get 13 or 14 nodes to a standing wave, and they were so tiny but we felt like we accomplished something. In reality, as a teacher of physics myself, I now realize internally the teacher was probably thinking "can you guys finish, I want to go home already".
P.S. I love the "as an exercise for the viewer" bit, had me cracking up.
Great video!
Could you include measurement error into your graphs?
Yeah, but sometimes it's hard to estimate the error properly
@@tbird-z1r why so much anger?
And yes, I do that in my graphs.
I appreciate how this video's incredibly intuitive structure seems to address my questions almost immediately after they arise.
posted 10sec ago :D
The number of ‘oh but of course’ moments in this video is 🎉 it’s fun when it all comes together so beautifully!
I personally have a hard time believing that the harmonic oscillator the MythBusters put on that bridge was totally harmless to it. I feel like it must at the very least put a lot of stress and wear on the joints and structural elements in the bridge and reduce its overall lifespan somewhat
Steel is awfully elastic, that bridge could probably move 1m at it's centre without reaching any plastic deformation, and as for joints/rivets, they wouldn't of shifted in that test, remember the bridge is moving constantly anyway, through wind and just general use.
@ yes I understand that the bridge is moving constantly due to a variety of factors, however, the lifespan of anything is pretty much always going to be some kind of function of the energy that has been put into it, and we’re talking about a device that’s literally tuned to add energy to the system as efficiently as possible. This is not in any manner comparable to the normal stresses that the bridge experiences on a regular basis. Please keep in mind that bridges, especially ones that carry cars, tend to last a very long time, and the kind of damage I’m talking about could mean the difference between the bridge lasting 99 years versus 100 (these aren’t real numbers, obviously) not necessarily it collapsing anytime in the near future
Eventually yes low amplitude repeated loading could cause fatigue, but if they were below the plastic deformation limit then they wouldn’t do anything at all. In reality this limit is fuzzy, so maybe a LITTLE? But the total energy in was not much compared to regular operation - they compared the feeling to a truck driving by. Wind provides massively stronger forces, but at very low dosing frequencies unless you get flutter like tacoma
@@AlphaPhoenixChannel thanks for the response! I loved your video by the way. This is basically my thinking for the record. I certainly don’t think the MythBusters did something wrong or anything haha. But I think people tend to forget that this stuff really does add up over very long timescales, I mean, put another way we’re saying that a 6 pound weight was able to re-create the stress of an entire bridges worth of trucks constantly rolling across it the entire time! (remember they said that they were able to feel the vibrations throughout the entire structure!)
@@jarlsparkleySteel is one of the only materials that has a threshold for fatigue buildup. Meaning, if the load is low enough it doesn't matter how many cycles you apply, you can't cause a fatigue failure. That threshold is pretty high and additionally structures are massively overbuilt, so you are never even close to working in that range for a bridge. That's why you don't typically deal with fatigue issues in bridges, and other factors play far bigger roles, like corrosion and extreme loads such as high wind or earthquakes.
Watching the last demonstration of the mode frequency shift, I finally understood how the LIGO interferometer works.
Great content!
Non-linearities
That's my ancient Greek name. (Technically it's Nonlinearites but English speakers get it wrong all the time.)
"ites".... Hmm......
It's fun seeing that the math holds up for antenna design as well. Especially low frequency long wire applications. Resonance is your friend !!
Before watching this I thought I had a pretty good grasp on resonance but this video really makes the "why" much clearer, indeed almost obvious at points.
I wasn't previously aware that the resonant frequency changes when waves are present but the diagram makes it pretty obvious and I thought "the string is longer" before you said it 😊. But I didnt spot that the effect of this was opposite and the whole tension making the wave travel faster thing.
very good, very well produced video
The thing I love about discussing has tension is you can imagine yourself as a person in a string of people linked hand to hand. And as you imagine that you can actually feel the tension in your arms as the mote wave passes by.
24:07 that extended tongue showcase was absolutely necessary for understanding.
Good video mate, very fascinating!
Even when the answer to the thesis question seems intuitive to me, the journey from A to B always includes a wealth of detail I never considered. I love this channel more with every new video.
And so help me if you ever say the words "this video is brought to you by raid shadow legends" I will explode into pink mist.
Please please please do a video explaining tesla coils in an intuitive way. I've always had a hard time understanding whats going on, but the way you present has helped get a lot of complicated subjects to finally sink in for me.
This is completely unrelated to your video, but I absolutely love the way you did your intro at one minute and 10 seconds.
YES! Do a video on the Tesla coil. There are many but your way of explaining things is unique and useful.
Thanks!
How did this pop up literally the day I watched the mythbusters bridge episode, I just found out that so many mythbusters episodes are on youtube from them so I've been watching through them recently as comfort watching as I do other things. It's bittersweet to see Grant always being the person that made people love and respect him and then realizing he isn't around in the world anymore, that's why it's called loss, and accepting that is just the way of the world.
Great video, was just having a buddy create standing wave animations for our chemistry section of our physics site. That slow mow standing wave on the reflection was so pleasing to see!
You can see this take place in a coaxial cable system. Troubleshoot standing waves in a coaxial cable system can be complex if you don't have the right tools and the right mindset. Thank you for this video.
Nice demos of single sine waveforms, TFS. As you likely know, in actual complex physical acoustical environments, the reflections and minute pressure interactions of sound fields still have many behaviours similar to simple sine reactions, but the math is quite exponentially more complex (still, super computers can generate IMO some fascinating visual depictions of sound “snapshots”).
I’d like to see you also demo how sound behaves in rooms with flat vs. curved panels, and to hear/see Lissajous figures and how they “feel”, because resonance isn’t too different from reverb/echo in a scientific sense.
(I also caution against using the verb “amplify” unless you literally [externally] track and expand the waveforms in perfect sync to increase their amplitudes, which, like acoustics in general, seems like an imperfect task to depict by its complex nature.)
What about depicting how our brains “interpret” transients and collisions of more complex sound fields to give us meaningful, usable information?
I agree that seeing standing and travelling waves form and affect others is very impressive. 😊
My point at the end of my long initial comment was that, like the tiny ‘barbs’ in serif text fonts give us almost subconscious cues about characters being used, so transients and other “anomalies” can have the effect of implying other “expected causal phenomena”, maybe akin to a hologram being at essence an “interference pattern”, which is an oft-used “explanation of reality” that I personally find uselessly imprecise.
Honestly, the minute I saw the simulated demo of a wave on a bent rope it started to make sense. You aren't adding more energy into a single wave, but rather layering waves on top of each other. And as you demonstrated, a wave will eventually decay. So you get to this point where even though you are adding more waves onto the layer, the first ones are dropping out in a sort of FIFO stack.
I like your explanations. My Dad did a lot of the Resonance Frequency Analysis on Skylab and the Space Shuttles in building 49 at nasa jsc and I remember him showing me all the exaggerated flexing of the Shuttle's wings during re-entry. At some speeds they flapped like a bird but other speeds caused multiple waves to appear. Cool stuff to see.
Great demonstration of resonance. The main setup of the experiment is satisfyingly low tech but very effective with the high-speed camera and signal generator input.
Noise cancellation, surprised nobody has mentioned yet this is why it's so important your speakers are correctly wired. Between two with mono (same) sound on each, there is silence in the middle, it's amazing to experience. This is key to how active noise cancelling works, how audio sound extraction works, etc.
Just realizing this now, but I would _LOVE_ a collab between you and Grady from Practical Engineering! You guys are both great explainers with a knack for demonstration through experimental results. It would be a real power duo!
The one side fixed string is the best live demo of what superposition and linearity is. It visualises the math concepts very well. You can calculate lots of stuff and test it in real world.
Your mix of explanation and demonstration is the best!
Yup, this was very cool. I had never really thought through why resonance doesn't build forever... this was a beautiful explanation... and, the idea of superposition of repeated waves instead of just amplitude building is the key to understanding this. Great job. I thought for sure that you'd show how you can add different frequencies (and phase offsets) to create a monster peak anywhere along the string (in the world of ocean navigation it's called the "rogue wave"). It requires using Fourier series with D/As instead of just simple frequency generators... but a great way to show how these waves add together in some pretty magical ways.
The tacoma bridge is the largest widely-known example of the same phenomenon that causes ratchet straps to 'hum' when driving down the highway while carrying a load. Much larger scale, much more inertia, much slower oscillation, but still the same thing.
Beautiful demonstration and such a thorough explanation to support it.
Thank you 😊
Beautiful video, and beautiful experiment. I've always been fascinated about waves, and this experiment is just perfect to introduce kids and students to it. Thank you!!!
You're video is so interesting!I was captivated from the beginning to the end. Thanks for this huge work of vulgarisation!
The final observation about how the equations physicists like to use are all wrong was actually kinda crushing for me to learn (but it was a sow realization so I got to distribute the disappointment over time lol) after leaving school. When I learned this, and I still do wish, that my teachers had made it more clear that the things we learned were simplifications and idealized models that don't represent the real world. I'm not mad that I wasn't made to do *actual* optical calculations for physically accurate lenses in physics, but I *am* mad that I spent a significant amount of time thinking that paparabolic lenses were actually perfectly physically ideal in the real world. I felt lied to, or at the very least I felt like an assumption was made that I would not have been able to understand the reason that things were being simplified.
Videos like this are awesome, and should be required viewing when learning a subject. It would have been intensely helpful in school to have something that explains "This is why everything you are about to learn is technically wrong, and *this* is why you should be happy not to have to do it the hard way, because shit is complicated" lol.
I consider myself lucky that I did not end up going into any of the hard sciences, because If I had learned this stuff after making a more serious commitment I'm not sure what I would have done. It's like the education equivalent of scope creep. In other industries if you sign up for a job with a certain scope and then the scope gets increased out from under you we usually consider that to be bad and hopefully not allowed by the contract if you have one. It's weird to me that school effectively just does that repeatedly and seemingly no one cares.
This is could be a fantastic way to demonstrate the intuition behind multiple calculus principles
Anyone else wish he would have tuned the length so it would resonate at a whole number frequency (4hz) so the trickiness of the 2 super imposed waves was easier to "see" in the non-integer multiple of the required frequency? Great video - love your stuff!
I love that waves deflect upside down because, assuming my thought process is correct, it models one of Newton's laws perfectly. The wave hits the wall, pulling it in one direction, we'll say contacting it a little, and the wall expands back to its original size, but not perfectly, expanding just a little too much and exerting that extra force used to expand it as a wave with lower amplitude in the opposite direction to conserve momentum. Of course this deformation of the wall in incredibly tiny with rigid structures, but the heat lost in this compression/expansion is part of the reason the wave bounces back with a noticable amount less amplitude.
Super Informative Creative Video!!! Thanks for Sharing!!! 👍😎
I would love to see an exploration of acoustics and room modes extrapolated from this. This was enlightening!
I knew that losses were the reason for the loss of wave energy, but I hadn’t ever thought of the energy being lost to breaking bonds in the metal which makes a ton of sense. There’s also the idea that the bridge doesn't have just one resonant frequency. All the individual parts still have other resonances.
It also made me realize that even if you put a much larger driving mass on a bridge, it still likely wouldn’t come down because even if you managed to crack a beam or blow out enough rivets, you still would have to account for the sudden and complete change in resonance from such a large structural change.
Dude, this is AWESOME! I always thought about how exactly do radio antennas form and emit electromagnetic waves and you just visualized it using a cord. Different medium but everything else is the same
I loved this part of my calculus classes. It was amazing to model the harmonics and see how they would sync and amplify. More fascinating to me was offsetting them slightly and watching the patterns that emerged with the period slightly off the harmonics frequency. A tuning parameter which allowed slowly passing the wave through harmonics and anharmonics was cool to suddenly see the wave snap into harmony and then almost resist leaving that harmony back into disordered frequencies.
What really fascinates me about these experiments is that they must absolutely apply 100% but in 3D waves to all quantum mechanics. Great demo!
Thanks
Nice! One point about the exponential decay you show: The first initial decay seem to have a much faster decay that the rest of the curve, I think that is an indication of a non-linear decay that you get when your string is already oscillating at amplitudes where the nonlinear terms in the wave-equation are no longer negligible.
Also, nice to see a video of the Tacoma bridge, and the man walking off it was very very calm, much calmer than I'd be...
Man this is Awesome!... Love your videos. Thanks for all the hard work and dedication you are putting in... Thank you Professor! I'm listening
wahoo, another video from my favorite creator! This is also an example of why the coil frequency calculators and an approximation. You always have to add or remove loops of wire on the coil to come close to the predicted oscillation. There are so many factors like insulation thickness, wire thickness, air gaps between windings. Even if you created a perfect math calculation to predict it, you would still only get close because some adjacent turns may be stretched or closer together than others on the same coil. I always wanted a better calculation but I think there are just too many tiny unmeasurable things in real life that would determine the actual frequency. Great video as always by the way. You are one of the few creators that has a broad and deep stroke of education broken down into simple concepts. Thank you for all the videos you create! I wonder what the minimum power to break a wine glass from a speaker is. I have seen it done many times, but there has to be some minimum power to make it happen. Great demo and animations as always. I really appreciate your videos.
wow... i cant believe i found this interesting. I mean it isnt exciting by nature lol, but i couldnt help but keep watching. Somehow watching a string vibrate and all the stuff i cant understand that went into it was somehow mesmerizing. the subtle nuances of each factor going into it was somehow interesting.... Cool man, right on. Thanks
I'd love to see the resonance of brass instruments modeled and explained on this channel if you can ever get to it!
The point about harmonics not being exactly integer multiples in the real world made me think about the way brass instruments work. On a brass instrument, you can get multiple notes on the same length of tubing by going through the harmonics (called "partials" in this context). However, they end up not all being in tune, meaning you sometimes need to pitch a particular partial up or down. This is usually done by adjusting the input frequency to get the partial back in tune, and experienced musicians have these tunings memorized so they can hit the right pitch immediately. It's also not as simple of a relationship as on the string model, because the tubes on brass instrument loop around and change diameter. Depending on where the nodes end up in the tube, you could get different interactions with the bends in the pipe (or even with any dents that might be there).
Another interesting interaction on brass instruments is that the partials actually influence the player's input frequency, nudging it towards that partial's resonant frequency like a ball rolling into a valley. It's a neat effect that I don't think can be represented with your string model, but I'd love to understand it better.
I love how the history of physics is basically summed up with "Wow, that problem is difficult! I wish it was easier. So lets find an easier problem and solve that instead. If we dial in the assumptions close enough, it will be effectively the same"
It's not about being right, it's about being as not wrong as you can be.
Though obviously sometimes we end up with epicycles because of that
I almost headed to the comments before the video was over to mention the Tacoma Narrows bridge, but thankfully I waited until the end lol.
Also, sticking your tongue out while trying to get the two waves to work was very funny and cute.
These videos are better than every EE class I've taken lol. A cool way to build up to Tesla coils (or just more nonlinear electrical fun) would be to look more at the coil used here and explain why a flyback diode or some snubber is needed to prevent kickback from the inductance (which could lead to a deeper look at inductance and capacitance as a continuation of transmission line concepts, or even RF, or just pure Tesla madness haha).
Before watching the PS section, I wasn’t planning to destroy a bridge using resonance. Now, I’m going to do it because a guy on TH-cam assured me the bridge would be fine.
Wish me luck!
We had a professor nicely show us his example of why linearity and describing formulas break down:
He just used a large resistive heating-element. Simple "V=IR" would tell us that doubling the voltage would also double the current and 4x the power - and as we have measured the resistance we can predict that ... yeah and then it starts glowing and the resistance goes up until it finally breaks apart.
I like to imagine the string model as a series of points elastically connected to each other, and then I am able to visualize how they interact with each other. This then tells me that the wave we are seeing is a product of particles moving up and down.
So, the answer to how the wave is being reflected at the end of the string is: When the final few points get stretched, they apply a force to the "immovable object", since it can't be moved all of the energy gets stored elastically in the fabric of the string stretching even further before returning and sending the wave backwards with some energy loss
Excellent…….its helped me visualise a transmitter antenna resonating at a particular frequency.