I have no idea why these sorts of posts are popular. Past college you're not going to learn physics by trying to self-study an entire university course. The best way to learn is just to pick a small part of physics you'd like to learn (preferably related to your job), i.e. how GPS work or some fluid mechanics etc... Then learn the physics you need for that. Knowledge accumulation can't be organized in a straight line, it happens non-linearly and generally builds upon small wins that are useful for you.
I think this is unnecessarily pessimistic. I think there's actually a surprisingly large number of people who are interested in and have the discipline to study something on their own, and there's value in pursuing a whole course of study from beginning to end. Doing things piecemeal and incrementally has value too (especially in software development), but can obscure the whole shape of a discipline.
I'd disagree and have done exactly that. I started with a reasonable basis in physics, but self studying through an entire course dramatically expanded my understanding. For an example of what I mean this [1] is Feynman's lecture on conservation of energy. It's something every schoolkid learns -- I'm fairly sure I saw my first pendulum from the nose demo in middle school, yet Feynman will take this and make you completely rethink your understanding.
So for instance, what is energy? Somebody who knows a little would probably tell you something like the capacity to do work, and so it feels quite abstract. But the interesting thing is that energy really "exists" so to speak. If you paused the universe somehow, and then resumed it - you'd need to know exactly how much energy was and where in order to keep things moving as they were. Yet there is no known 'thing' that is energy - just a wide array of mathematical abstractions.
And then this thing is also perfectly conserved such that the amount in play will never change. It's completely bizarre to think about, and this is something you initially "learned" in grade school, and probably never even really though twice about.
--
And more generally I think the point of learning should not be to do something, but to expand your own mind and understanding of the world (and beyond). Outside of this being arguable alone as a philosophical point of view, I also think there's even a practical reason for it - unknown unknowns. There are things you can't even imagine that you don't know, and the only way you can reconcile this is trying to dive into things across a wide breadth.
> the point of learning should not be to do something, but to expand your own mind and understanding of the world (and beyond)
I agree with your comment overall, but people have different reasons for learning and it may not be productive to tell them they are learning for the wrong reason. Let's celebrate all learning for I fear we are heading in a direction where it will become increasingly uncommon.
I also don't like this focus on practical applications. It is true for me as an engineer, that in the end I want to build something. But when I force myself to focus only on the practical part, just as you said, the whole context is missing. There is this meme of a guy still living with his parents, and trying to acquire all knowledge. This is actually a dangerous mind virus. Learning is an idle activity, often confused with being a do no good. But for me at least this is the only way to really grok something. In university at the summer break, I could only really go through the math and enjoy it, without the stress of exams and cramming. And now it is the same, I learn things idly, and trust in the universe that the application will come, which it always does somehow.
Conservation of energy is simply the invariance of a system to translation in time: the system shows the same time evolution from a well defined starting state regardless of whether that state exists at a time t or a time t+t' with an arbitrary t'. This is one application of Noether's theorem.
This is an example of a topic that unstructured self study would likely skip. But it is included in every properly structured course because this theorem puts a fundamental explanation to all conserved quantities that occur in classical mechanics.
Ignoring that, saying "energy must exist because of Noether and time-translation" doesn't really tell what energy actually is, not a very satisfactory response
On the contrary, this is best description of what conservation of energy means: all externally generated forces acting on the system do vary with time. Im other words, this is a closed system as defined in thermodynamics.
The nature of energy is really just a result of this property.
The difficulties with energy in GR are related to the fact that those equations alone allow for space-times that are truly bizarre. Some that are technically solutions to the field equations are clearly nonphysical (e.g. Goedel's solutions). There is also a priori no reason why e.g. expanding metrics should actually yield proper conservation of energy.
IMO: It's not learning that's the problem. It's learning and verifying you actually learned. I'm not saying "unless you can solve homework problems you haven't learned", but... kinda? With a complex generally-theory subject like Physics, the amount of effort you need to put into verification grows exponentially faster than the "learning" part; it's tough for many to get a "feel" like you could for chemistry or programming or electronics or mechanical stuff, difficult as those definitely can be.
Most of us who learn (and always learned) outside of schools and academia, do so for some purpose and with some intention beyond the learned thing. I didn't learn programming to learn programming, I learned it because that's how you built websites. I didn't learn woodworking just to learn woodworking, but in order to build my own furniture, and so on.
Same can be applied here I'd say, and probably must (at least for me) be applied that way, for the learning to even be engaging. So don't learn physics just to learn physics, but learn it in order to be able to execute on something else, then learn the related parts to that.
Then the verification becomes part of what you're doing, and fun as well, as you're progressing on other stuff :)
I think you're possibly generalising your own experience to the masses. That's absolutely not the case for me.
I love learning to learn. I learned programming because I found a quick basic compiler / IDE on my dad's computer, along with some shipped examples, and it was actually magic to me.
I read our encyclopedias as a kid because it was just really cool. Likewise, I did physics in university not for a job (the jobs are shit), but because it gives me that feeling of expansive possibility and wonder that Carl Sagan gave me when I watched Cosmos growing up.
Most of my most passionate self learnings came about because of that feeling of magic, not because I was chasing an end goal.
> I think you're possibly generalising your own experience to the masses
Yeah, that's fair and probably true, it's limited to my own experience and the experiences of the people around me, not gonna claim it's universal so you're right.
> I did physics in university [...]
My comment is also explicitly not about you and your type ;)
> Most of my most passionate self learnings came about because of that feeling of magic, not because I was chasing an end goal
One could argue that the end goal you were chasing was feeling that magic again :) Jest aside, I do understand what you mean.
Let's subject that claim to some basic arithmetic.
A university would expect maybe eight undergraduate level courses, four credit hours per course, and you are expected to do three hours of study per hour of credit per week. That's 1,500 hours.
How does that compare to the "hours played" on a typical strategy game Steam review?
much less dopamine, video games are realy good at stimulating that. Studying physics not so much.
Don't get me wrong Physics can be satisfying in its own ways but the amount of dopamine rushes you get from cracking a hard problem are few and far between. Often enough you just get frustrated and once you find the solution you think to yourself oh is that easy how didn't i get that before and feel absolutely stupid.
Somehow millions of people have learned physics in a "straight-line" at university. Most physics majors have a logical progression from the simplest to most complex ideas.
I have this incredible strong urge to try to understand how our world works. I keep finding new topics in physics I just need to understand to calm this urge. Back to grinding differential geometry for me. Im long past college
I think it's useful for learning about unknown unknowns. If you don't have a clear direction, it's entirely fine to start with a university course then stop when you get a feeling for what you really need.
The analogy seems to be like learning classical music (like piano or violin) after as an adult.
You learn the basics like scales and chords to build and build to modern jazz.
But if you’re an adult, life is too short, just go straight to a few pieces you like. Get a simplified version and learn the bits you need from there from a teacher.
I think there is more in this world than is dreamt of in your philosophy. The crowd on HN now is very different than it used to be rest assured there are many people self-teach themselves the equivalent of a university curriculum. I mean, nerds actually exists, they're not all humdrum corpo worker bees trying the maximize their employers' value and then just hiking or whatever.
> I have no idea why these sorts of posts are popular. Past college you're not going to learn physics by trying to self-study an entire university course.
You have no idea, because you have no motivation or interest to self-study.
But if you pay attention, you will notice that your personal motivation and interest does not match the ones from all the people engaging in this discussion.
The reason why this sort of topic is popular is because others have different interests, motivations, and ability to do it.
You should not spend time trying to convince others that they cannot, and instead you should look inside and see what you can do for yourself.
I think self-studying a university curriculum is also helpful. I've studied physics at the undergraduate level myself.
Quantum mechanics, for example, is useful enough as a general background, and going through fluid dynamics and GPS problems is also helpful. But if you just follow the application problems, you can learn what you need, but the bigger risk is that you might miss the larger framework that defines those problems. That's not necessarily a bad thing. In fact, the entire university curriculum training is ultimately a process of translating complex phenomena into the Western scientific way of understanding things. It's a mental model that says 'this phenomenon can be interpreted with this kind of formula.'
In other words, it's about building mental models. In a formal university curriculum, you usually learn things like vectors, topological spaces, energy conservation, and how to map real-world phenomena onto these perspectives. It's about learning to simplify the world using mathematical tools. I didn't go to a top university, so I didn't learn things like tensors, but I hear they're taught now. I used tensors in grad school.
Of course, when I actually code and deliver factory equipment, I've done motor-related work under NDA, and the actual formulas aren't always perfectly accurate. There are corrections and adjustments. But the important thing is not just problem-solving itself, but building the mental model of 'how to approach the problem' before solving it. And I think the curriculum helps with that.
I've found pacing to be the biggest problem with self-learning of academic subjects.
Suppose we are learning from a textbook. The things we learn in each chapter are built upon in the subsequent chapters. If we go forward before we have a good enough understanding it can make it very hard to learn that next chapter.
On the other hand if we wait to go forward until we feel we really have mastered the material up to this point it can take a long time to move forward, and that doesn't even really gain you anything.
The best way to master something is to practice it. The textbook author knows this. The author writes each chapter under the assumption that you are OK with the material from the previous chapters but have not yet mastered that material. You now need things to practice that material on, and using it while learning the material of this chapter is perfect for that.
That point where you have gotten good enough with the present material that you can handle the next chapter is almost certainly going to be a point where you do not think you are ready.
I personally recomend Halliday as an everything important in Undergrad thats not Theoretical Physics book. Use that in conjunction with your favorite Flavor of Math for Scientists and Engineers book. And you get a pretty wide understanding of Physics.
Here is a five-hour video essay explaining that we actually live inside a superconductor: https://youtu.be/DkH1citHtgs
That is, the reason the weak nuclear force has limited range in our "vacuum" seems identical to the reason the electromagnetic force has limited range in an electric superconductor. Therefore we live in a weak nuclear superconductor. Whatever that means.
(Furthermore and even weirder, the electromagnetic force is a shadow of the weak nuclear force, the one-dimensional projection of it that retains an unlimited range even inside the superconductor, which happens because of reasons)
4) General Methods for Solving Physics Problems by B.S.Belikov - https://mirtitles.org/2015/12/07/general-methods-for-solving... This is a great book which teaches you by walking through the solutions of various physics problems using a general methodological framework.
So for instance, what is energy? Somebody who knows a little would probably tell you something like the capacity to do work, and so it feels quite abstract. But the interesting thing is that energy really "exists" so to speak. If you paused the universe somehow, and then resumed it - you'd need to know exactly how much energy was and where in order to keep things moving as they were. Yet there is no known 'thing' that is energy - just a wide array of mathematical abstractions.
And then this thing is also perfectly conserved such that the amount in play will never change. It's completely bizarre to think about, and this is something you initially "learned" in grade school, and probably never even really though twice about.
--
And more generally I think the point of learning should not be to do something, but to expand your own mind and understanding of the world (and beyond). Outside of this being arguable alone as a philosophical point of view, I also think there's even a practical reason for it - unknown unknowns. There are things you can't even imagine that you don't know, and the only way you can reconcile this is trying to dive into things across a wide breadth.
[1] - https://www.feynmanlectures.caltech.edu/I_04.html
I agree with your comment overall, but people have different reasons for learning and it may not be productive to tell them they are learning for the wrong reason. Let's celebrate all learning for I fear we are heading in a direction where it will become increasingly uncommon.
This is an example of a topic that unstructured self study would likely skip. But it is included in every properly structured course because this theorem puts a fundamental explanation to all conserved quantities that occur in classical mechanics.
https://curtjaimungal.substack.com/p/what-is-energy-actually
Ignoring that, saying "energy must exist because of Noether and time-translation" doesn't really tell what energy actually is, not a very satisfactory response
The nature of energy is really just a result of this property.
The difficulties with energy in GR are related to the fact that those equations alone allow for space-times that are truly bizarre. Some that are technically solutions to the field equations are clearly nonphysical (e.g. Goedel's solutions). There is also a priori no reason why e.g. expanding metrics should actually yield proper conservation of energy.
And why not? Because humans' brains stop working after they graduate from colleges?
Most college students don't work that hard.
Same can be applied here I'd say, and probably must (at least for me) be applied that way, for the learning to even be engaging. So don't learn physics just to learn physics, but learn it in order to be able to execute on something else, then learn the related parts to that.
Then the verification becomes part of what you're doing, and fun as well, as you're progressing on other stuff :)
Of course, YMMV and all that.
I love learning to learn. I learned programming because I found a quick basic compiler / IDE on my dad's computer, along with some shipped examples, and it was actually magic to me.
I read our encyclopedias as a kid because it was just really cool. Likewise, I did physics in university not for a job (the jobs are shit), but because it gives me that feeling of expansive possibility and wonder that Carl Sagan gave me when I watched Cosmos growing up.
Most of my most passionate self learnings came about because of that feeling of magic, not because I was chasing an end goal.
Yeah, that's fair and probably true, it's limited to my own experience and the experiences of the people around me, not gonna claim it's universal so you're right.
> I did physics in university [...]
My comment is also explicitly not about you and your type ;)
> Most of my most passionate self learnings came about because of that feeling of magic, not because I was chasing an end goal
One could argue that the end goal you were chasing was feeling that magic again :) Jest aside, I do understand what you mean.
When you're forced to use AI instead of the skills you've put decades learning; it's time to learn new skills to keep the brain from becoming mushy.
I think dense personal curriculum like this is the way forward.
[1] https://www.youtube.com/watch?v=Jk4MIYOKapQ
A university would expect maybe eight undergraduate level courses, four credit hours per course, and you are expected to do three hours of study per hour of credit per week. That's 1,500 hours.
How does that compare to the "hours played" on a typical strategy game Steam review?
Don't get me wrong Physics can be satisfying in its own ways but the amount of dopamine rushes you get from cracking a hard problem are few and far between. Often enough you just get frustrated and once you find the solution you think to yourself oh is that easy how didn't i get that before and feel absolutely stupid.
You learn the basics like scales and chords to build and build to modern jazz.
But if you’re an adult, life is too short, just go straight to a few pieces you like. Get a simplified version and learn the bits you need from there from a teacher.
You have no idea, because you have no motivation or interest to self-study.
But if you pay attention, you will notice that your personal motivation and interest does not match the ones from all the people engaging in this discussion.
The reason why this sort of topic is popular is because others have different interests, motivations, and ability to do it.
You should not spend time trying to convince others that they cannot, and instead you should look inside and see what you can do for yourself.
Quantum mechanics, for example, is useful enough as a general background, and going through fluid dynamics and GPS problems is also helpful. But if you just follow the application problems, you can learn what you need, but the bigger risk is that you might miss the larger framework that defines those problems. That's not necessarily a bad thing. In fact, the entire university curriculum training is ultimately a process of translating complex phenomena into the Western scientific way of understanding things. It's a mental model that says 'this phenomenon can be interpreted with this kind of formula.'
In other words, it's about building mental models. In a formal university curriculum, you usually learn things like vectors, topological spaces, energy conservation, and how to map real-world phenomena onto these perspectives. It's about learning to simplify the world using mathematical tools. I didn't go to a top university, so I didn't learn things like tensors, but I hear they're taught now. I used tensors in grad school.
Of course, when I actually code and deliver factory equipment, I've done motor-related work under NDA, and the actual formulas aren't always perfectly accurate. There are corrections and adjustments. But the important thing is not just problem-solving itself, but building the mental model of 'how to approach the problem' before solving it. And I think the curriculum helps with that.
Suppose we are learning from a textbook. The things we learn in each chapter are built upon in the subsequent chapters. If we go forward before we have a good enough understanding it can make it very hard to learn that next chapter.
On the other hand if we wait to go forward until we feel we really have mastered the material up to this point it can take a long time to move forward, and that doesn't even really gain you anything.
The best way to master something is to practice it. The textbook author knows this. The author writes each chapter under the assumption that you are OK with the material from the previous chapters but have not yet mastered that material. You now need things to practice that material on, and using it while learning the material of this chapter is perfect for that.
That point where you have gotten good enough with the present material that you can handle the next chapter is almost certainly going to be a point where you do not think you are ready.
https://www.motionmountain.net/
https://news.ycombinator.com/item?id=37201037
"It is certainly true that there are aspects of relativity that are counterintuitive, not only to retired engineers but also to many physicists."
Here is a five-hour video essay explaining that we actually live inside a superconductor: https://youtu.be/DkH1citHtgs
That is, the reason the weak nuclear force has limited range in our "vacuum" seems identical to the reason the electromagnetic force has limited range in an electric superconductor. Therefore we live in a weak nuclear superconductor. Whatever that means.
(Furthermore and even weirder, the electromagnetic force is a shadow of the weak nuclear force, the one-dimensional projection of it that retains an unlimited range even inside the superconductor, which happens because of reasons)
https://youtu.be/kUkgKsEq330?is=uxc8zlUy0z1eng6M
Unfortunately, English version are somewhat reduced from Russian, but still.
1) Physics for Entertainment by Yakov Perelman (2 vols) - https://mirtitles.org/?s=physics+for+entertainment Great to motivate oneself and learn to think in physics terms.
2) Fundamentals of Physics by B.N.Ivanov - https://mirtitles.org/2018/04/21/fundamentals-of-physics-iva... Nice overview which approaches physics "from atoms to matter".
3) Physics for Everyone by Landau and Kitaigorodsky (4 vols) - https://mirtitles.org/?s=Physics+for+Everyone A nice overview of all the major domains in physics.
4) General Methods for Solving Physics Problems by B.S.Belikov - https://mirtitles.org/2015/12/07/general-methods-for-solving... This is a great book which teaches you by walking through the solutions of various physics problems using a general methodological framework.