micromass said:Functional analysis provides the fundamentals of QM. That doesn't mean that it's necessary to study functional analysis in order to understand QM. But if you want a deep understanding and if you want to find out why the mathematics checks out, then functional analysis is very necessary.
dextercioby said:Real analysis..., well, let's say calculus is everything for theoretical physics. All sorts of calculus.
If all you're interested in is to calculate stuff, then you don't need to prove many theorems. However, if you adopt the strategy to ignore proofs too early, you will fail to understand basic concepts, and this will make it harder to calculate stuff as well.Fizicks1 said:Thanks for the reply, but that was...kinda vague, to say the least. Yes, calculus plays a vital part in physics, but if I can carry out all the computation, why do I need to prove all the theorems? Some more detail would be much appreciated!
Fredrik said:If all you're interested in is to calculate stuff, then you don't need to prove many theorems. However, if you adopt the strategy to ignore proofs too early, you will fail to understand basic concepts, and this will make it harder to calculate stuff as well.
Science has taught us that the only way to understand how the world works is to study the theories that make accurate predictions about results of experiments. Since understanding the theory is the only thing that can be considered "understanding reality", a person with a deeper understanding of the theory by definition has a deeper understanding of reality.
Fredrik said:To understand the mathematics of QM, you have to be very good at functional analysis. To understand functional analysis, you have to be very good at topology. Most people first encounter topology in a course on real analysis, and then they take a course on topology. Then they study integration theory, and finally functional analysis. Real analysis is simply the natural first step on the path towards topology and functional analysis.
Topology is also useful when you learn differential geometry, which is needed to understand GR.
WannabeNewton said:How the heck do you expect to know functional analysis without knowing real analysis in the first place? It's utility should be obvious just from that.
Fredrik said:To understand the mathematics of QM, you have to be very good at functional analysis. To understand functional analysis, you have to be very good at topology. Most people first encounter topology in a course on real analysis, and then they take a course on topology. Then they study integration theory, and finally functional analysis. Real analysis is simply the natural first step on the path towards topology and functional analysis.
Topology is also useful when you learn differential geometry, which is needed to understand GR.
micromass said:There do exist books on functional analysis which don't do topology. Kreyzig is an example of such a book. Of course, if you go to more advanced books, then topology is very necessary. And of course topology is needed for differential geometry too, so there is no reason not to study it (it is insanely beautiful too!)
In my opinion, real analysis (such as found in Rudin) is completely useless. But you can't study functional analysis (or even differential geometry) without knowing it.
micromass said:Functional analysis provides the fundamentals of QM. That doesn't mean that it's necessary to study functional analysis in order to understand QM. But if you want a deep understanding and if you want to find out why the mathematics checks out, then functional analysis is very necessary.
Bachelier said:Would studying QM make one a better Mathematician? I'm assuming it would be a great application of one's math knowledge.
micromass said:It's a real awesome application. But I don't know if it would make you a better mathematician. If you want to advance yourself mathematically, then you should study mathematics texts. If you happen to be interested in physics, then you can do QM. But don't do QM if your only reason is to be a better mathematician.
I'm quite interested in QM because I want to see how mathematics is applied in physics. I don't think it really increased my math knowledge so far, but it did give me an entire new perspective.
Real analysis is a branch of mathematics that deals with the properties of real numbers and their functions. Functional analysis is a branch of mathematics that studies vector spaces and their transformations. Together, they provide a powerful framework for analyzing and understanding physical systems.
Real & functional analysis are used in physics to model and analyze physical phenomena, such as motion, energy, and forces. They provide a rigorous mathematical foundation for understanding complex physical systems, and are essential for developing theories and making predictions.
Some key concepts include continuity, differentiation, integration, convergence, and compactness. These concepts are used to describe and analyze the behavior of functions and their transformations, which are essential in understanding physical systems.
Sure, a common example is the use of Fourier analysis in studying waves and oscillations. Fourier analysis uses techniques from real & functional analysis to decompose complex functions into simpler components, which can then be used to analyze the behavior of waves in various physical systems.
While it is not necessary to have a deep understanding of real & functional analysis to pursue a career in physics, it is highly beneficial. Many advanced concepts and theories in physics rely on real & functional analysis, so having a strong foundation in these areas can greatly enhance one's understanding and ability to contribute to the field.