Now I can see why I never really "got" concepts like force, but rather memorized the treatment, and pretended to be comfortable with it, as presumably the teacher was also doing. The unsatisfactory feeling that the science was somehow settled and accepted, but I couldn't understand it, is maybe why I pursued mathematics, instead of physics. I'll make sure to teach my kids that it's ok (and desirable) to admit a lack of understanding, even on the most basic and common concepts.

I have not even started watching the video, but I am going to give you a like because of the mere fact that you chose to do a video on such a seemingly basic and simple concept. Topics like these are usually hand-waved away by teachers and professors alike as if they don't warrant a deeper explanation and have already been logically figured out by minds greater than our own. As someone who has always felt dumb for questioning the most basic of concepts, especially in physics, it is very refreshing to see that you have made explainers on these topics and taken them with enough sincerity in an attempt to properly formalise the most fundamental notions

Feel force, feel time, feel space? If you delve on that, you can doubt everything, not just forces. Stay simple. With clocks we measure time intervals. With rules we measure space distances. With springs we measure force differences. In F=ma, we can use clocks and rules to evaluate the acceleration, a spring to evaluate the force, and the thing we really need to assume to exist beyond our measurement instruments is mass.

What's funny about the subject of inertial vs non-inertial reference frames is that there are apparently no inertial frames anywhere in the universe.

Inside the closed room the person is standing and the accelerometer is hanging from the ceiling. That can mean atleast two things: 1. There is a force that is pointing downwards. 2. The person and the ball are arranged inside the room in such a way in free space free from any external force.( let us assume that the only matter left in the universe is the concrete room with the things inside it) In both the situation direction of acceleration can be observed. Situation 1. The person may fall if the acceleration is high enough. Situation 2. In case of an acceleration, the person will move towards a wall if the shoes he's wearing aren't fixed to the floor. If the shoes he is wearing are fixed to the floor , he will rotate and bang his head on a wall or floor.

I have never been taught that forces are “felt”, only that forces act on objects to change their motion.

Being pushed into the seat is not the feeling of your acceleration - rather, it's the feeling of the car's acceleration! If you were made of metal, and both you, and the car were accelerated by a magnet, you would not feel anything at all!

Summary 3: To find out inertial vs non-inertial frames NO REFERNCE TO ANYTHING OUTSIDE THE FRAME IS NECESSARY. Experiments confined within the frame are good enough to tell us if we are in an inertial frame or a non-inertial frame.

Dialect, you got it wrong! Force & Acceleration both exist and are independent of your feelings. And force does not cause acceleration only, instead it could just increase mass or energy of an object without accelerating it!

As regards to "Can we 'feel' force?" No, we can't -- not because how you explained it, but because "feeling" is a biological phenomenon and in Physics we DO NOT FEEL ANYTHING. We measure things. And let me tell you, YES, we can measure real forces by doing experiments. Of course Einstein's General Relativity has been formulated in such a way that the gravitational force has been done away with by redefining the effect of mass & energy on spacetime and vice versa, thereby bringing accelerated frames due to gravity within the realm of inertial frames of reference. But acceleration of a reference frame due to any other of the 3 forces of nature (as discovered till now) are definitely detectable by simple experiments within the frame of reference.

Finally, at this moment, my spring have been awakened. It feels the force. Seriously "Force" does not have be felt. One of the easiest way to "observe" the force is the use of spring as a measure. In my humble opinion, spring does not "feel" anything. It does not have any knowledge about "inertial-ness". It also doesn't observe an acceleration, too. It's just a thing. It's different from me and my cat. But it perfectly & precisely react to the Force. How do you explain this? Quantum mechanics doesn't even bother the force!!??? man, quantum world is FULL of forces. It even tells how different kind of forces are transmitted through the particles. It doesn't covers Einstein's gravity yet but gravity is actually included in the theory as graviton (undiscovered yet, though). Okay, if you think, acceleration is caused by the "transformation of reference frame" you says, what about the "force" caused by the magnetic fields? how it's related to the "reference frame"? there is no acceleration but electron moves! I really liked your clam on "twin paradox" (at least half of it) but this is total nonsense. I agree that there are lots of interpretation of the laws of the physics as long as it consistent with the theory. But if you want to make your point, you should explain why your interpretation is better than the others. For example, Everett introduce his new interpretation for quantum mechanics to eliminate Von Neumann's projection. Because as long as we have it, we can't apply quantum theory to the universe itself where there is no "outside". He did not say, there are thousand of universe correspond to every quantum state...he said this is the reasonable assumption to improve the theory. So what is the point of your interpretation...no offence but seriously you need more research on the topic your interested in!!! Finally, this is the last claim. The reality of the variable in the physics law is actually questionable. In other words, the force may not be the "real thing". It only appears in the theory to clarify the relationship of the variable, that's all. But one thing for sure is, as I stated at the first of this comment, you can measure it actually. Therefore, I think it exists. But this is not a physics, it totally unrelated to the actual theory. It's more like philosophy than the physics.

What I like about your channel, Dialect, is you always provoke thoughts and concepts to make one think again and understand better.

Some broad thoughts im thinking right now: say, 1.) Force concerns how mass/matter reacts to motion. 2.) Matter/mass units can't (in essence) occupy the exact same space. So if you have multiple mass units, they are a distance apart from eachother. 3.) Max speed is C, so it will always take time to move mass across space. So you have a blob of mass spread across space, another mass comes in contact with the blob (there must be motion involved). They can't occupy the same space. 'internal pressure' of a mass or w/e will be in an equilibrium if outside conditions stay the same. Now after the collision, at the point of contact theres a bunch of back and forth of pressure-waves I guess.. It takes time for pressure to spread acros the blob of mass. This squeezing and stretching of the volume units of mass, because of localised pressure changes inside of the blob, are what they mean by 'feeling force'. If you happen to read this and think im an idiot its entirely possible. Got no real physics/math background. Would like to know why this would be wrong so I can see where i'm thinking wrong.

3:06 Mass is not directly observable either. Mass can only defined with respect to an inertial frame. This is easy to fix in Newtonian physics because accelerations are invariant under Galelian transformations. The fix in relativity is more difficult, and leads directly to E=mc^2.

We may miss the feeling of force when a train accelerates smoothly enough....because the acceleration is very small ...and we are often not paying too much attention to it. But that does not mean the feeling is not there. But great video....got me into thinking over the basics again.

Here is simpler one. Two objects in free fall will deduce that they are not acclerating relative to each other. they "feel" they are not accelerating.

Summary 2: An inertial frame is one such that no mechanical and/or optical experiments conducted completely within the frame can ever tell us about the motion of the frame. Whereas, in a non-inertial frame we can easily detect motion without any reference to outside, just by conducting certain experiments confined within the reference frame.

You can simply deduce force by asking 'Am i being detained?'

(7:55) I have always assumed that my grocer has a spring in his scale, so you can only imagine my astonishment when he used the theory of relativity to weight my tomatoes!

omg I was always so confused when my teacher said f = ma was determined "experimentally" and was like "if it's measured in kg.m/s² because of the formula, how would he know before coming up with it how to measure it anyways?"

Fantastic. I hope you will tell us eventually more about the history and resolution of this discrepancy between your vision (Who else shares it? Does it have a name?) and that of the mainstream.

3:30 You talk about a train accelerating "smoothly enough so you don't notice it" but if I had an accelerometer (such as a 2 masses held together by a spring) that could measure to ARBITRARY PRECISION, then you'd always be able to tell whether you're the one accelerating or not, even if it's not noticable enough to feel with the limited human body. In other words, you can always tell whether your frame of reference is inertial or not. Acceleration is objective!

Inertia has nothing to do with "Feeling", it is simply the resistance to change in velocity. Or to put it in better terms it is the resistance to change from an inertial frame of reference. If two objects are accelerating away from each other there would have to be a force involved. This is why you can measure which train is actually accelerating. Since the force is only being applied initially to the train and not the objects inside it, the train will move relative to the objects until the objects come into contact with the train and the force is then applied to them via the wall or seat of the train pushing them forward. This is why if you had two trains in space with a ball inside each of them and only one accelerated away; the ball inside the accelerating train would seem to move relative to its train while the ball in the stationary train would appear to stay still relative to its train. This of course would stop once the acceleration stopped and both trains were moving at a constant velocity relative to each other again. This effect only occurs during the period of acceleration.

In "Spacetime Physics", Taylor and Wheeler define an inertial reference frame as follows: "A reference frame is said to be inertial in a certain region of space and time when, throughout that region of spacetime, and within some specified accuracy, every test particle that is initially at rest remains at rest, and every test particle that is initially in motion continues that motion without change in speed or in direction." According to this definition, inertial frames are always local ones. An accelerating elevator in free fall can be an inertial reference frame.

This is a very interesting video, but I think you are missing one point. No object is really solid. All objects, even the most solid objects behave in a way like a spring. This means that when a force is applied to an object, it is usually not applied homogeneously on all its parts, but mostly on one part. So when a force is applied to an object, the acceleration is not applied instantly to all its parts, but applied first to one part, causing the object to shrink slightly. The shrinking increases the inner tension forces, which causes the rest of the object to accelerate at the same rate. Try imagining accelerating a spring by pushing it, and you will see what I mean. This shrinking is what activates your nerves, but you can technically measure it by other methods. You do not need the surroundings to know that a force is applied to you. In the example of the accelerometer in a closed room, you forgot that the person is going to feel a force due to the non-homogeneous acceleration applied to him. That is, his feet will accelerate before his head. Even if the non-homogeneous acceleration is too slight to detect by human senses, (like the example of the train) it is still measurable by more subtle devices. If you would apply the force homogeneously to all parts of the object, perhaps like with a charged body in an electric or magnetic field, theoretically you can create an accelerating frame of reference with real undetectable force.

We speak of "feeling" a force because we have the acceleration detection machinery built in, so it is something everyone is aware of, but obviously the phenomenon exists absent any knowledge of it. But in the imagined room with suspended ball, the person in the room would also experience the acceleration in other ways than observing the ball. The idea that it's impossible to know if your observer frame is inertial by local tests, as opposed to observation of other objects, is false. There are many reliable "blind" tests for acceleration.

So feeling squished back into my seat isn't feeling a force? I'm lost.

Ok, maybe I'll look like an idiot here, but something is off in the thought experiment. When you're in a free fall, there is a spaghettification effect (your feet are slightly more attracted than your head) and thus, I can tell if there is a gravitational field around. I know that GR speculates that the "free falling object" is a size-less point. But then we cannot apply the reasoning of an apple (which has a size) and say it does not feel the acceleration. In the example of the passenger in a train, why does he feel the acceleration ? Because the train pushes the seat, then the seat pushes on the back of the passenger, etc. That's the equivalent of the spaghettification in acceleration. The reason why we don't feel like the passenger in a train when we are falling is because the gravity field is very smooth (almost continuously spread) and each part of the falling object is accelerating *almost* together at *almost* the same time. But that does not mean that there is not a theoretical/measurable difference.

If you stick a knife in a light socket you're going to feel the electromagnetic force course through your body and give you a jolt.

Pure classic philosophy. Thought-inspiring, but for other purposes it feels quite useless. And I guess the same reasoning can be applied to any physics concept. (What is mass/time/distance “REALLY”?).

AFAIK when you ‘feel’ a force you are feeling compression or decompression. This happens to all objects that are not a single dimensionless point, so therefore all objects. Even in a gravity field some atoms of an object will be closer to the center than others and experience it slightly differently. Of course that would be hard to measure, but that isn’t the point. Our mathematical approximations can’t distinguish which element is moving, but that is only because it is an approximation using dimensionless points that don’t exist. I could be wrong, so I’m curious how compression/decompression fits into this idea. Perhaps you can’t tell which atom is causing the compression, or which proton for that matter, but isn’t the whole body feeling a force if it is compressing?

Tell me please how conservation of linear momentum would work with relative acceleration.

There are some serious flaws and your reasoning here. 1. Not feeling the acceleration when is a vehicle that starts up slowly and smoothly it's simply a result of the acceleration being too small for you to feel. That is it is simply too small to be detected by our senses. That does not mean that the acceleration and the force or not absolute, just if they are too small for you to notice. 2. Your illustration of the accelerometer in a room that most likely is not accelerating is not a problem with being able to measure an actual acceleration, both of the possible causes that you gave are a result of someone applying a force to the pendulum. Hence the problem is, that you do not have it honest accelerometer, the one that has been rigged by someone deliberately trying to trick you. The fundamental flaw in your argument is the simple fact that acceleration is locally measurable. For example, the Earth's rotation can be measured with an interferometer that sends light in two opposite directions, if it is big enough. Basically what you were doing in this video is, relying on an acceleration that is below perceptibility, and someone trying to trick you by applying a force to the pendulum. Neither of these, actually indicates that acceleration is not absolute. However, the fact that we can feel it when acceleration is high enough, and the fact that acceleration can be measured, when the device is functioning properly, shows that acceleration can be locally measured without any reference to the outside universe.

This is a truly physical channel. Thanks, Dialect. In my opinion, an observer doesn't have mass, so no "feeling".

You can always deduce if you are in a accelerating train with a ball, if it was at rest and stays at rest it is not an accelerating train but if it doesn't stay at rest it is an accelerating train.

Just wanted to say that I love your videos. We need more of these!! :)

If one imagines that to any single atom of your body is connected a infinitely thin and massles string and each string in turn is hooked, on the other edge, to an object that may accelerate, then your body will never experience the feeling of acceleration, because all atoms behave like a single object. That's in my opinion, how fields work.

You've come up with lots of reasons why the question of acceleration can be problematic. To go from that and say it's RELATIVE is specious. An electrically neutral ball in a non-accelerating spacecraft floats freely. Then the engine is switched on and the ball is forced against the bulkhead in the direction of the engine and opposite the direction of acceleration. That is force and acceleration, absolutely, pure and simple. Feeling and coordinates have nothing to do with it.

Having watched the entire video, I think your point is just: "Force and acceleration cannot be defined without outside information." But we can define: "If light always travels in a straight line in this frame of reference, then the frame of reference is inertial." There is nothing wrong with this definition. If anyone has a different thought, rebuttals are welcome.

From the beginning I was skeptical that if velocities are relative so should be acceleration. So am I feeling the force or the reference frame. is force even real?

Given the example of the twins in space with no reference. If one did accelerate away from the other, wouldn't they be able to deduce who is the one that accelerated? Let us assume that Alice accelerated away from Bob and both of them had a frictionless surface with a ball on it. Alice would see the ball move to the back of the plane whereas Bob would not. Given that there is no other information in the universe, then we can demonstrate that Alice is indeed accelerating and Bob is not. In the video, the explanation (5:00) would be that there is no way to tell if your refrence frame is accelerating because it can be due to some other mechanism that is moving it. Is it reasonable to state that there is no mechanism in this situation or would that count as measurement information?

This video is great and make a very compelling argument, but there is still one thing that confuse me. Let's say there is 2 boxes each with measuring instruments and one person inside in an otherwise empty universe, the boxes start next to one another with no speed relative to each other, then, the distance between the boxes start increasing faster and faster, let's say it increase like d(t) = t². In this situation as you point out, each of the boxes' passengers has an equal right to say that they are static while the other is accelerating or vice-versa, but! Let's now say that in one of the boxes, the passenger experience a constant push in the direction of the other box and the instruments on board read an "acceleration" a(t) = 2, meanwhile, in the other box, the passenger doesn't feel anything and the onboard instruments read 0. My question is, since acceleration is relative and each passenger has an equal right to claim that it is the other that is accelerating, where does the first box's passenger's experience and instrument's reading come from? How do we explain them? Does it have to do with space-time curvature?

Acceleration is simply a change in your worldline vector. The change requires energy. The force we feel is nerve endings in the mass of our bodies sensing is moving from our initial state, sending signals to the brain. We can also see water in a bucket, or changes on an accelerometer.

Forces exist whether we feel them or not. Can you feel the magnetic lines of force acting on iron filings around a magnet or on a compass needle? Nevertheless, the force is empirically evident. No feelings required.

"Feeling" is a perfectly valid scientific measurement. The only problem is that it's much less reliable than most technical measurement apparatuses.

When reading about General Relativity, one claim I encountered frequently was the justification for gravity not being a force. It goes like this: Imagine you are in freefall. You won't feel a force acting on you, even though you're being accelerated by gravity. On the other hand, if you're in a car that's accelerating, you will feel it. Therefore, gravity is not a force but a warping of spacetime. Took me a long time to see that this is nonsense.

I think one can tell if it is on an inertial frame of reference or not by checking homogeneity and isotropy of space and homogeneity of time, rather than in a "feel force" argument. I belive the first method is really clear and unambiguous and the fact that we see objects accelerate is a consequence of interaction. From and accelerating object due to interaction one can check that objects which don't interact (this may be where the argument may be weaker) break this frame of reference spacetime symmetry properties.

Yes, acceleration is one potential result of a force, but it can be resisted by a counteracting static force due to molecular forces causing friction and strain in the mass. So force is measurable. Force will change the velocity of mass if it is no restrained by an opposing force so again you can measure it my measuring the force required to prevent a change in velocity of the mass.

A single particle doesn't "feel" force, but multiparticle systems do. Same with entropy. It's an interesting perspective, but it seems to show we don't fully understand the physical world. Our best theories are know to be wrong, good mathematical models for our context, but still wrong.

If you see waves on an ocean are you not seeing a force? The water itself only moves up and down but the waves move

"feeling" and "seeing" aside, surely by one pressing the throttle pedal you know you are mechanically applying "force" and causing accelerating and the other who is doing nothing is not given all else equal ... how would one translate this to absolute acceleration? ...

I find it interesting that you decided to draw in a midnight dump in the middle of the field 0:25

Force is derived from mass and acceleration. But how is mass determined except by testing it with forces?

The train example that you give is floored. It just shows the fallible human sensors are. If you asked a accelerometer what was happening it would tell you.

The very same kind of problem exists with mass actually, as you could always rescale it. In fact, in a world with only electric fields/interactions, there is no way to discriminate the (absolute) motions of similar q/m physical objects. This excess "freedom" should convince you that there is some kind of redundancy in these charges, or that there has to exist another fundamental interaction that would "split" those (as in, there should exist a physical experiment involving other interactions that are able to discriminate the motion of two similar q/m physical objects)

IN A AUTO DEATH ACCIDENT WHEN YOUR BRAIN GETS COMPLETELY FORCED TO ONE SIDE OF YOUR SKILL.......OH NO THAT WASN'T A FORCE !

Isn't my stationary body an inertial frame by which I can feel whatever force that acts upon it?

I am enjoying your videos. Keep up the great work.

There's are increase of internal stresses when accelerating. Which will not happened under other circumstances

I'm half joking but seriously,the primatologist name them according to distinctive traits,scars and whatever. It's just impossible for them to look so alike that you can't tell them apart.

idk what about a *roller coaster?* like yeah i know that i am in it an can see stuff moving around me going faster, but I can feel being pushed into the back of my seat as it speeds up, or being pulled out of it from the centrifugal force when it spins.

Acceleration is the change of velocity so increases and decreases of speed are both considered acceleration.

Man, I came here for answers and I am leaving with even more questions. Kudos.

I love your video on the metric tensor so I arrived here. Quick side note: the fact that a force causes an acceleration is not metaphysics, that is physics as defined by Newton. 'Feel' is associated with the biological conception of sensation and perception. Biological organisms can 'feel' forces, but does an electron 'feel' the electromagnetic force from other charged objects? That is metaphysics. We know things 'experience' forces, thus things move.

From what I understand proper acceleration is simply a mechanical force applied on the object, it may not even have a coordinate component. Just stress on the mass. Say in the context of general relativity when a vessel accelerates just to stay in one position in an orbital free fall.

Great video!! Continue doing them please. Just one question: if I am in a closed room and attach an accelerometer to the wall, that says 9.8m/S2, can I ensure that I am not in an inertial frame of reference?

Profound stuff - sure to piss off the Star Wars fans! But seriously, you’re onto something here. Make some more videos, soon. All the best. A fellow astute thinker. 😊

If your accelerometer is faulty, you will have faulty understandings... if the accelerometer is accurate, you will determine that the room is undergoing acceleration, even if you think it implausible.

Does not a glass of water provide an observable change in motion? F=m×a is not just an illusion.

"Well, the Force is what gives a Jedi his power. It's an energy field created by all living things. It surrounds us and penetrates us. It binds the galaxy together." I find your lack of faith... disturbing!

Tbh it seems kind of weird to kill force and then wonder about causes of acceleration. That’s exactly what force is supposed to explain. Even if, coming down to it, you couldn’t find a totally proper way to measure it, it doesn’t mean one couldn’t make an argument for their real existence. Second, I think there should’ve been more argument on why biological feeling isn’t sufficient. Why would a Newtonian have to find a proper criterion of how matter feels things if the bodily feeling we have when accelerating is enough to show there has to be real acceleration and therefore real force?

You cannot directly measure Time either. What you measure is a constant velocity over a constant distance. This is true with a classic clock whose hand moves around a circle off a given size at a constant velocity. This is also true with more sophisticated clocks, but the distance is a wave-length and the velocity is C.

I will stop you right here in the first 33 seconds. Often in physics classes a lecture will describe the force of say accelerate in an example of accelerate is the force you feel when you get pushed to the back of you seat in a car while speeding up. That is simply to give students an understanding of what a force is. When describing a force in a situation they might say this impact exerts a force of 100 Newtons on impact with an object.

I am struggling to see the issue with thinking of acceleration as absolute. I don't think relative comparisons really need to come into it. It is a concept that stands on its own. You can add another object to your thought experiment if you like, and then see the implication for relative motion/position but it seems entirely optional and unnecessary for having a conception of acceleration. In my understanding acceleration is fundamental to the definition of mass. I define mass as energy that resists acceleration. Anything with mass, even the most fundamental things, are composite entities that involve interactions between parts such as the Higs field or the quarks and gluons in hadrons. Without such interactions, the unencumbered energy would travel at c and have no mass. In the photon box analogy, there is a pressure on the back side of the box when a force accelerates the object, which could just as well be a neutron, a quark, a person or a cheese burger. In all cases where there is mass there is something confining energy, preventing it from traveling at c creating an asymmetry in pressure when it is accelerated that resists said acceleration. I could be wrong but I have listened to your arguments multiple times and I have failed to be convinced that we need to think of acceleration as a purely relative phenomenon.

2:46 I feel like this part needs to be elaborated more because it was confusing to me. To my understanding, you need force in order to measure inertial mass and passive gravitational mass (fictitious force for the latter perhaps). I can see that force is not needed for active gravitational mass, and if we can treat active gravitational mass and inertial mass as equivalents (because there's no evidence of deviation so far), then that part made sense. Though, I'm still unsure if that's what you were arguing.

So would be lagrangian and hamiltonian mechanics more consistent because we don't use the concept of force?

Wouldn't this make gravity and acceleration the same? Since gravity is the amount of energy which creates the force and accelerating is adding energy to move an object therefore making it the same as gravity but with a different kind of energy?

I did not quite get why the accelerometer does not solve this? In another video you mention that it must be calibrated relative to something, which is true. But this is why we rely on fundamental constants to calibrate our SI base units to and assume these quantities stay constant as time progresses. Physics has to be useful for predicting outcomes of experiments, enabling technologies. It is not concerned with the "true" nature of reality as long as it is not measurable. For all we know we could as well just be a boltzmann brain. Philosophy is an interesting field in and of itself, concerned with questions like "the ship of theseus" and the like. It has been helpful to physics and technology by posing new questions to ask. But you'll have to remind yourself that physics is mostly just concerned with frameworks for technologically useful predictions, everything else is "extra". As Descartes once said "I think therefore I am" we have to make reasonable assumptions from which we can build our frameworks upon. There has to be some sort of value proposition to change views, albeit just an exploration out of curiosity.

Force should be the first derivative of momentum, not simply acceleration, which does have an observable component namely it's conservation. This is to say inertia, or mass, itself. Inertia is the thing we 'feel' as we accelerate. For example when a proton colides with an object the majority of its mass is do to the internal 'collisions' of its quarks or rather to the exchange of gluons , creation and annellation of quarks and so on. Exactly the strong force. Also, for now most scientist assume gravity will be added to quantum mechanics not that strong, weak, and electromagnetic forces will be shown as illusory.

This channel is freakin underrated.

Deduction of local orders of Kinematics means we assume our notion of space, velocity, acceleration etc have temporal-orders of 0,1,2,3,... Yet this is a local assumption. Imagine an observer that deduces what we observe as velocity (first-order) they observe as spacial coordinate (null-order). Would relativity be relative to this shift in order???

Force is a bit of a perplexing concept.

What about static force? Stress/stain measurements are made in solids all the time.

in quantum mechanics, aren't bosons considered force particles?

Well argued, but "geometry of spacetime"? How about the geometry of geometry ?

Won't launching an object with mass and and a photon in parallel to each other let us distinguish an inertial frame from non-inertial one?

A better question is that can you design a device that can detect if the current reference frame is accelerating or not and thus inertial or not, that way you can frame this video better than asking the question of whether we feel the acceleration of the frame of reference or not. The example with a pendulum inside an isolated room and the person deducing that there is a magnet behind the wall instead of deducing that the whole room is accelerating does not make a little bit of sense, I think you lost what you were trying to convey there as it is entirely possible to deduce from that event that the whole room is accelerating...

But forces are real things that are mediated by real particles. There are only 3 or 4 types of them and the extent to which each of them act on a given body at a given time is an objective fact that's invariant across reference frames. Epistemology has nothing to do with it. If you don't like the word "feel" in this context, just replace it with "acted on by" (or whatever you prefer). Problem solved. No need for linguistic hair splitting or philosophical jibber jabber about it. That's an irrelevant tangent and a distraction from the question that matters - "Is force absolute?" - to which the answer is yes! None of your examples make the point you're trying to make and I don't think you'll be able to find one that does. For example: 1) If you don't feel acceleration on a train, it's only because it's really weak. If it's strong enough, you're guaranteed to feel it and be affected by it. 2) If you see the hanging accelerometer lift up while you're standing up and sharing a room with it, you don't need to guess whether the whole room is accelerating; if it is, it'll affect you as well (and possibly your balance). 3) Whether you're moving in a circle inside of a room that's moving in a straight line or vice versa is *not* a matter of perspective. Forces (and their respective particles) are either acting on you or on the room. As a side note, there are simple experiments you can do to see which one is true. For example, you can throw a ball or shine a light and see what kind of path they travel. If they don't accelerate from your perspective then you're also not accelerating.

What about changing acceleration or accelerating changing acceleration? More philosophy…-ve speed or going slower than stopped. Accelerating into the stopped state. Figure it out!!!

I’ve never read a physics textbook that says you know you’re in an accelerating frame of reference because you can “feel a force.” No physics textbook will use the word “feel” or “force” when describing how an observer can tell the difference between inertial and non-inertial frames of reference. What they actually say is that you can “perform experiments” that will show whether or not you are in a non-inertial (they don’t use the word “accelerating” either) frame of reference. Nice try, but you lose again.

Physicist: you can feel acceleration but not force! Weightlifter: i feel the force but observe no acceleration! Armchair versus practitioner. How will that end?

p.s. you can't directly measure velocity, energy etc. either. Physics is bootstrapping and we could "easily" replace it with others, whilst not having the foggiest about what's "really" going on. There is no escape from this

Hey Dialect, I'm confused with this! Consider a man in rotation where he has nothing in the universe for relating with (you know!). Then according to him, he is still. But if his arms are lifted up, we could understand that the man is in rotation. Doesn't it mean that there is something that can be said relative to even in the nothingness (maybe the space itself!). What I mean is among all the possibilities, the man's arms are not lifted in only one scenario. And that is the case in which he is still (not rotating). So does the non-lifted arms mean that he is at rest relative to something eventhough we couldn't find any differences between any of the scenarios with our HUMAN PERCEPTIONS?

@5:00 why is the ball moving but not the person..?

I'm not convinced you have sufficiently defined what you mean by "feel" and that this isn't some bloated recursive semamtics excercise. If someone pokes you in the eye, you are feeling it. You can feel pressure even when there is no net force, no movement, and no net acceleration. You can directly measure force relative to you and I'd argue that's all that matters in terms of what you feel.

We are never in an inertial frame, so nothing can be really calibrated by men. But we are in a almost inertial frame and can well feel forces, in my opinion. Likewise, we can use an accelerometer and calibrate it up to a certain extent by using all 3 directions of space. And then we can measure accelerations with an error that is neglectable. Why would such a small error make such a big difference leading to the statement that we cannot feel force?

With any rotation isn't it plausible to know you're in an non inertial frame of reference, since distant objects appear to be moving faster than light? I agree with what you've said in the video, just confused with rotating reference frames.

Topic for a video: Mass or Weight or both actually the same?

Силу можно определить по деформации, а не только по ускорению.

Summary 1: This simply means REAL ACCELERATIONs (not pseudo accelerations) ARE NOT COORDINATIVE AND HENCE THEY ARE NOT RELATIVE. This is because they can be detected from within the reference frame by performing simple experiments. However, constant speeds (including v = 0) is very much relative. That is, constant speed can't be detected without referring to the "outside" world.