This is the same kind of thing as saying that the electric field of a photon is a vector transverse to the propagation. If you have a photon going in the +z direction, it can be linearly polarised in the +x direction, and just by rotating the detector's linear polariser, we can observe $\pm45^\circ$. Working this out tells us that electric fields are vectors, not spinors, not higher order tensors, etc. Spin-1, not spin-half, not spin-2, etc.

is there a standard notation to show that a map sends an element of one space to elements of another space?

like the map $M$ acts such that $\rho \in \mathcal{H}_i \rightarrow \mathcal{H}_i$

yes. it uses the LaTeX operator mapsto

oops, seems Im wrong

Hello Everyone...

@SillyGoose I think \to for $ f: \mathbb{R} \to \mathbb{R}$ , and \mapsto for $\vec A \mapsto \vec A + \nabla \phi$

@nickbros123 thats what my link with the snippet says too

hm well i'd like to include the data of the specific state $\rho$ as well as the space...

since i know that $M: A \rightarrow B$ and $a \in A \mapsto b \in B$ is proper. But I'd like to (it seems) combine both notions into a single notation? since emphasizing the particular element and the spaces is what i wish to do \

i guess "M is defined by $a \in A \mapsto b \in B$" is close enough

@SillyGoose is it not possible to combine both? I thought the link already suggested $M:\overset{A\to B}{a\mapsto b}$

oh i see hm

It is only needed for you to write something like this, of course, only when you have something like $f:\overset{\mathbb N\to\mathbb R}{x\mapsto x^3}$

@naturallyInconsistent I deleted it out of spite and not to improve my numerical reputation, which I care little about.

@Pygmalion but then it becomes such that people interested in helping you, will not be able to see what your question even is about

@SillyGoose Can you be a bit more specific what the context here is? Your notation seems a bit confused to me and this seems like another case where you've prematurely abstracted too much from what you actually want to express

@naturallyInconsistent I apologise to anyone who wants to help me but can no longer see my question. Enough members of the SE community felt that this important question should be killed because of some petty SE rules, so let it be dead.

@Pygmalion we tend to be bit fussy about what is suitable for the main SE site, but one of the functions of the chat is to discuss questions that aren't suitable for the main site. For example homework questions are banned on the main site but we're quite happy to discuss them in the chat.

If you wanted to discuss your question here I'm sure lots of people would be willing to help.

Note that closing your question is not a personal attack on you. It is just the statement that the question doesn't fit within the scope of the site.

Also, closed questions can still be commented upon.

@ACuriousMind The situation is this: consider the conjugation of some tensor product state $\rho$ by $U$, i.e. $U\rho U^\dagger$. I am trying to express in math the idea that $U$ sends one of the tensor factors of $\rho$ to another state in the same tensor factor space.

$\rho \in \bigotimes_i \mathcal{H}_i$ and is of the form $\rho = \rho_1 \otimes \rho_i \otimes \rho_2$ where $\rho_i$ belongs to the $i$th tensor factor and $\rho_1$ and $\rho_2$ belong to the correct tensor product spaces. and $U: \bigotimes_i \mathcal{H}_i \rightarrow \bigotimes_i \mathcal{H}_i$

@SillyGoose does this hold for all $\rho$ of this simple tensor form?

yes i think. if by that you mean it holds for $\rho_1 \otimes \rho_i \otimes \rho_2$ for all $i$

But this is the condition that $U$ is local. but I am trying to express it for the fixed $i$ case

In that case your $U$ is itself the tensor product of individual $U_i : H_i \to H_i$. If it just holds for one $i$ then write $\otimes_j H_j = H_i \otimes H_\text{rest}$ and state that $U = U_i\otimes U_\text{rest}$, where $U_i : H_i\to H_i$ and $U_\text{rest} : H_\text{rest} \to H_\text{rest}$

ah okay

@JohnRennie I do not take it personally, but I hate administrative rigour, which I think is the biggest obstacle to progress. I have already made up my mind on the question, so there is no need for discussion here any more. The only loss is for all the people who will not be able to see the question.

If I want to request the close votes be changed from three back to five how do I set this in motion?

@JohnRennie is it not by raising a meta question?

While the change has made closing homework questions very effective it is also causing lots of valid questions to be closed as homework. We seem to have a small hard core of users with a rather extreme view of what constitutes homework, and the current three vote rule allows them to close questions regardless of what the rest of us think.

Also, I think in these striking times, where we still have a backlog of close votes to clear, it might be helpful to be a bit fast and loose with the closing.

@naturallyInconsistent That's what I'm asking.

@JohnRennie rabid. Bite them?

@naturallyInconsistent My remote electrocution Chrome add-on does not appear to be working at the moment.

@JohnRennie Is the problem that you think this hard core is larger than three but smaller than five, or that the three vote threshold means the close review will be completed so fast that not enough other people have a chance to vote to leave open?

because if it's the latter, getting the close reviews to complete faster was the point of lowering the threshold; the flip side of the coin here is the position that the larger threshold allows a small hard core of users who will answer any question no matter how off-topic to answer questions regardless of what the rest of us think ;)

I think you and I both know who the two hardest core close voters are. The two of them seem to vote instantly on any question that offends their sensibilities, then it only takes one more close vote to close the question.

Effectively two people are now dictating the SE content policy.

@JohnRennie The underlying problem is that the number of frequent close reviewers is barely double-digit

you see the same 2, 3, 4 names on close banners all the time because barely anyone else is reviewing questions - and you don't see the ones who are more lenient since "leave open" reviews are invisible from just looking at the question

Yes, and if more of use were active reviewers the problem would be reduced. However not all members are retired ex-physicists with too much free time :-)

Reverting the three vote change seems the only option available.

raising the threshold back to 5 votes will likely lead to the close review queue overflowing again, i.e. lots of reviews aging away for lack of reviewers instead of being decided one way or the other

But then I have no idea whether my opinions on the matter are representative ...

@ACuriousMind Proving only that wherever humans are involved there are no simple solutions!

I mean, I agree with you that the current state is suboptimal, but I'm also afraid that going back to five votes will effectively turn off community moderation because getting to five votes takes so long most low-effort off-topic questions are answered by that point anyways. I don't see an easy way to decide which is worse

The best option would be to increase the power of leave open votes but that would require the SE to act and realistically they're not going to change anything.

3 is too small, 5 is too big, 4 must be goldilocks

@JohnRennie weather control device detected

Conversely, the 3 vote threshold means it's easier to re-open questions that were over-zealously closed. I don't work review queues, but I do cast reopen votes on questions I encounter organically. And I post comments explaining why I believe a question shouldn't be closed under our homework policy.

I think if someone consistently votes to close as HW against the HW policy there should be a way to temporarily suspend his close vote privilege

Also, there are lots of questions that are technically against the HW policy, but you can see that the OP really wants to ask a conceptual question, but they don't know how to express their question that way. This is especially a problem for people who come from a culture with a heavy emphasis on "teaching to the exam".

They may even say stuff like "I'm not asking for the answer, I want to know how to figure out the answer". But their question still gets closed. Some voters close anything that smells vaguely homework-like, especially if it contains any calculations. :(

On my part, I'm still new enough to be slowly sniffing out what is the right thing to do.

@Amit Well, mods can send a private message... if they know there's a problem.

Also, half of the solution often lies in the way one answers. Even less conceptual questions can often be answered in a more conceptual way

@PM2Ring That can also be good

Several years ago, we got a steady stream of "homework dump" questions, or as they're known on Math.SE, PSQs: Problem Statement Questions. The OP literally posts the problem statement from a textbook or exercise sheet, and expects us to provide an answer that that they can submit to their teacher.

We still get a few questions like that, but IMHO, we frightened off most of the PSQers, and most OPs these days do try to make an effort. But it can be hard for some of them to comprehend our "conceptual question" policy.

It could be nice if answers to HW questions went through a review before they're posted, to prevent full solutions etc.

@Amit and who would do those reviews

we already have too few reviewers

I'm against all homeworks in general

here or in school

homeworks are the only time when i do practice problems...

turns out Schouten's book has sections on concomitant tensors

@ACuriousMind but i am assuming it will offload some HW close votes to be reviewed...

The idea is basically to make gray area HW reviews more answer focused than question focused

@ACuriousMind I'm 25% through with Small Gods!

nice

why in ur opinion does the time asymmetry arise as in the second law of thermodynamics

it arises out of time symmetric laws

i have an explanation that the asymmetry is in the initial conditions, rather than in the evolution laws. is this the accepted explanation?

I think a lot of us hope silently that thermodynamics is not fundamental. Right? It would be more nice and platonic that way, lol

it is def not fundamental

Can we really make it def?

or maybe it is...idk

but it is a choice to use thermodynamics to describe anything. entropy's definition depends on ur choice

how do people distinguish between commutators and intervals when using both in the same paragraph...

depending on how u define entropy, it may not increase

it depends on how ignorant u r about the system. if u arent ignorant at all, then entropy does not increase

i mean, in principle, a system is completely described by theories deeper than thermodynamics. second law of thermodynamics is an emergent phenomenon

so if thermodynmaics is just for convenience in description, it is not fundamental

It has a few more laws than statements about entropy

they r all derive-able from deeper theories iirc

one is just conservation of energy

Yea some people suggested even fundamental laws may be a statistical consequence of various processes. That doesn't sound "nice"

hopefully, that stuff is wrong

ok but in that case, the hidden variable theory wud b more fundamental than statistical mechanics

how can u ever hav statistical mechanics as most fundamental

u cannot have that by the very definition of statistical mechanics

Because maybe the fundamental laws are out of experimental reach

Need to distinguish two meanings of fundamental: what we can observe vs. what objectively "is"

statistics is emergent by the definition of statistics. so statistical mechanics can only be done on a deeper theory

because statistics is only defined for a large sample of experiments

so u must hav some deep theory describing a single experiment first

Would you say QM is a deep theory of single experiments? ;-)

QM is a weird case

but i think it is standard to say that it describes a single experiment

but to confirm it, we must do a large numbe of experiments

Can I say something just as a joke? "Particles are irreversible transfers of energy, momenta,..." 🤣🤣 nvm

r u referencing Flatterman

lol

Lol, good catch

I am not saying if he's right or wrong, I just find it funny how often he repeated that mantra

he would be mad if he saw me saying that QM describes a single experiment

@Amit yes. it's very repetitive

Lol, that's why I quoted it

hopefully, he doesnt visit this chat :P

Lol, I wish he will, it's all love

No need to be devoid of a bit of humor

he spams the same thing on unrelated posts

i made a post about quantum gravity and he again tried to shift things to the ensemble interpretation

Dunno if totally unrelated, I just wish he'd write more answers rather than comment on everything to express his views

all his answers begin with "irreversible transfers of angular momentum, momentum, energy"

I read a bit of Born's book and I really liked his writing style

what is the book about

Cause and chance, hold on

I think that was the one

Yeah, took time to load, but that's the one

it's on stat mech, it seems

too much math :P

i thought it was more about philosophy

but it's stat mech

he has a chapter called metaphysical conclusions tho

back then, physicists cared a lot about metaphysics. it was a badass field back then

supposedly more work is being done on quantum foundations these days than before

so hooray for that

at least it is no longer fringe is what i hear

u mean interpretations? @SillyGoose

not necessarily

what other things come under quantum foundations

my ug thesis is on a quantum foundations related topic but it is not really dependent on an interpretation i think at least not to my knowledge

removing one of the assumptions of decoherence is the topic

@RyderRude I thought you read math quicker than words

@Amit i hate math :P

no, i love math. i just hate reading math

@SillyGoose which assumption? does this assumption come in th decoherence explanations of measurement

the assumption is about partitioning a system into subsystems

oh

interestingly there is a number of recent papers on the topic :P

there are three camps: 1) partitioning is determined by experimental set up, 2) partitioning is determined whether the hamiltonian is local or not, 3) partitioning is determined whether each subsystem admits pointer states

is the broad strokes

so u need this paritioning thing to prove decoherence

just to remove one of the assumptions it makes. it is more "foundational" in that it is not so "practical"

it would make decoherence more satisfying to be able to start with just hilbert space and hamiltonian and not assume a partitioning of the hilbert space is the idea

it is a lot of fun math :D

we talk about a partitioning between system and environment in decoherence. is this relevant?

and we consider their hilbert spaces separately

in a sense. it is the partitioning between system and environment that is assumed

one assumes that system A is represented by hilbert space A

oh

and environment is else

but what if you started with the abstract space with dimA*dimE

but decoherence indeed doesnt happen in any system

u need this interaction with environment

perhaps u want to start with an abstract hilbert spac and hamiltonian, and derive the conditions for decoherence that is more general than parititioning

it would still b some condition becuz decoherence doesnt happen in any system

@SillyGoose Inferring from what you've asked about here, the idea is that the partitioning is already "hidden" in the Hamiltonian, right?

@ACuriousMind the hamiltonian together with some other criterion

the criterion of choice for this project im working on is admittance of pointer states

but the localilty from the spectrum paper uses local hamiltonian as its criterion

the theme is some criterion that has a relation to the notion of classicallity

bc i think the idea is that we want to select a factorization of hilbert space that admits some sort of quasi-classical description

whether it be through local interactions or existence of pointer states

or what have you

yeah, that makes sense to me

so u want to derive the factorization using these other conditions, insteadof assuming it

it is interesting because it is turning out that the spectrum kind of determines things in this case as well :P

@RyderRude right

i hope u make a big contribution in this topic!

i dont know about that XD it is fun and im learning a lot at least :D. summer is coming to an end...

summer feels so fun

it is nice to not have to worry about course work :P

math courses really do me in

physics courses are not so bad but if they're interesting then they also really do me in

yeah. i too hated classes

u r doing really cool things. ur own research

What is generalized coordinate? I don't understand. Because for position of two points is has $q = (x_1 , x_2 , x_3 , x_4 , x_5 , x_6)$

it's when u represent the position of an entire system by a single point in an abstract high dimensional space

if u used the physical space, u would need two points in 3D to represent the current position of the system

How do we identify position of two points if we specify position in one parenthesis . In cartesian we define position of two points separately $A = (x_1 , y_1 , z_1)$ and $B = (x_2 , y_2 , z_2 )$ . It is understandable .

the co-ordinates of different particles are aggregated together in the abstract configuration space

@RyderRude Pls define clearly i don't understand what is entire system and how it is high dimensional space

@RyderRude What is the purpose or benefit of representing position of two particles this way?

@123 it is part of the definition of the config space. for e.g. when u write x1...x6, it is understood that x1,x2,x3 belong to the first particle and x4,x5,x6 belong to the second

u can also write (x1, y1,z1, x2, y2, z2)

the 1 and 2 make it clear that it's different particles. the x,y,z are the physical space dimensions

@RyderRude Aaaah now it is clear to me.

@123 the time evolution of the system simply becomes a line in the configuration space. now u can apply variations to this line and formulate the principle of least action

because the current state is just a point. then the time evolution is a line

in the physical space, the time evolution looks complicated. u hav to follow multiple points simultaneously

It means we always known $(x_1 , x_2 , x_3) = (x_1 , y_1 , z_1)$ it is position of first particle. and $(x_4 , x_5 , x_6) = (x_2 , y_2 , z_2)$ is position of second particle. We write all together in compact form $q = x_i$

yes

what is configuration space?

this higher dimension space that u r using here

positions of all particles represented as a single point in a space called configuration space

@RyderRude Why we create higher dimension space for position of two particles.

th number of dimensions depend on the system u r studying. the number of particles, etc

It means for two particles it is 6 dimensional space

@123 the time evolution of a single point is just a single line. we vary this line to formulate the principle of least action

@123 not necessarily. if u r studying 1D motion of two particles, then the configuration space is 2D

bcause u dont care about y and z

It is complicated. Because there are so many questions arises to understand this concept properly.

time evolution means as time passes particle move in space

yes. in physical 3D space, u would need to follow multiple points simultaneously.because one point for each particle

one trajectory for each particle

but in configuration space, u hav grouped it together to a single point. so u just need to follow one trajectory for all of the particles

If we have cartesian system. Why we need to create 2D space if we specify 2 points in 1D physical space

because the time evolution involves following multiple points in 1D physical space

@RyderRude Aaaah that's the point. particle grouping means

like u hav grouped x1,y1,z1 and x2,y2,z2 into (x1,y1z1,x2,y2,z2)

it represents a single point in 6D space

@RyderRude Ookay.. But in physical space they moved separately ?

yes

there were two points in physical space.they moved separately

@RyderRude you mean it represents a single point in 6D configuration space. But in physical space it represents 2 point in 3D space. Am i correct?

yes

It we want , can we transform coordinated from generalized coordinates to cartesian?

and we desire the 6D version to talk about the principle of least action

@123 Once you use generalized coordinates, you do not have any guarantee that "Cartesian" even makes sense in that context

Cartesian coordinates are for points in $\mathbb{R}^n$

but generalized coordinates can be anything, e.g. a pair of two angles

@RyderRude It means idea of principle of least action demands to create position in generalized coordinate?

and what those angles physically describe does not need to be a point in $\mathbb{R}^n$, it might also be the angles some lever in a machine forms with something else or whatever

@123 yes. it talks about variations in the trajectory of the system in configuration space

generalized coordinates are truly generalized: These are values that, in some sense, describe the state of your system. There is no requirement that these coordinates directly relate to the position of anything, or that they have to be valued in $\mathbb{R}^n$

@ACuriousMind Yes i have read this. It means generalized coordinates are the coordinates taken from cartesian or polar or spherical etc..

@123 no, it doesn't mean that

I'm not talking about these angles coming from the polar coordinates of a point

yes. in general u would study systems whose physical space isnt Cartesian space

@ACuriousMind So what is it?

as a silly example, consider a particle whose motion is confined to a circle

@RyderRude Okay

now u can still use cartesian co ordinates for this. but it would be non convenient

@ACuriousMind What do you exactly mean by state of system?

so we just represent this particle's position by an angle

other times, we are studying not particles, but rigid bodies. their state is given by the position of center of mass and a vector for their orientation

so u need the usual (x,y,z) in R^3 for the center of mass

@RyderRude yes

but for orientation u need a unit vector

so the current state of th rigid body is characterized by (x,y,z, v1,v2)

@123 well the "state" of a system is whatever you need to be able to say "I know everything I want to know about this system at this instant". For a point particle its usually just its position, for a rigid body it's its position and its orientation, for two metal pipes connected by a joint it might just be the angle between the pipes, etc.

the point of generalized coordinates is that we don't really assume anything specific about the physical meaning of these coordinates

@RyderRude Aah ookay. it means we need minimum coordinates which required to specify the state of system (motion of system) used in generalized coordinate

@ACuriousMind Aaaah .. Now understand better

the minimum is for convenience. nothing is stopping u from representing the rigid body in terms of its million particles each in cartesian co-ordinates

or to represent a particle whose motion is confined to a circle in cartesian co ordinates

but the point of generalised co ordinates is that u can use whatever numbers u want to FULLY specify the current sttae of ur system

this is y it's called generalised. u r not restricted to cartesian

@RyderRude But if we represent rigid body as millions of particles then generalized coordinates become millions of millions. how do we handle them?

@RyderRude something is stopping you: using too many variables either turns the theory into a gauge theory or means you have to muck around with constraints; at the introductory level the set of generalized coordinates is always minimal

@123 we cannot. this is i say it's for convenience to reject them

@ACuriousMind yes. i mean that nothing is stopping u in principle

minimality isnt part of the definition of generalised co ordinates. but u should always prefer it because there is practically no way to handle a rigid body in terms of its particles

So in generalized coordinate system we can use anything (position, angle, vector , momentum etc..) which represent the state of system . And this should be minimum

well...not momentum

if you read further in whatever you're reading you'll come to the notion of generalized velocities and generalized momenta

@ACuriousMind Yes i have read it. But didn't understand

you want analogues to position as your coordinates: What distinguishes coordinates from velocities is that if I show you a photo of the system at one instant of time, you'll be able to tell me the coordinates of the system but not its velocities

the values of coordinates make sense for the system at one point in time; the notion of velocity or momentum makes sense only as the derivative of some trajectory through configuration space (configuration space=space of all possible values for the chosen generalized coordinates)

@ACuriousMind It means the procedure of finding velocities , acceleration from position is same in generalized coordinates as we do in cartesian by using derivatives?

the generalized velocities are just time derivatives of the coordinates, yes

generalized momenta are a bit more tricky and you'll have to actually read about Legendre transforms and Hamiltonian mechanics :P

it is by the definition of configuration space that you have only positions as co ordinates. we use this space because it's great for Lagrangian mechanics

we do have other spaces like phase space which use both momentum and position as co ordinates

that space is good for Hamiltonian mechanics

@ACuriousMind Aaah.. i see. It means methodology of finding other parameters from position is same in generalized coordinates. But we use minimum set of coordinate which can specify complete state of system.

@RyderRude please stop using terminology in confusing ways. The configuration space is neither Lagrangian nor Hamiltonian

@RyderRude Ooookay. Now it is more clear

Lagrangian mechanics happens on the tangent space of the configuration space, Hamiltonian mechanics happens on the cotangent space. The cotangent space is also called phase space.

@ACuriousMind i mean the introductory reason for introducing conifguration space is lagrangian mechanics

I disagree

you have to talk about it even if you want to start with HM

Means configuration space is the space where we use generalized coordinates to specify the state of system?

@123 as I said above: configuration space=space of all possible values for the chosen generalized coordinates

no. phase space also passes that criterion @123

configuration space is the space where we just use generalised positions as our generalised co ordinates

phase space is the space where we use generalised positon nad generalsied momentum together as our generalised co ordinates

@ACuriousMind My point is that configuration space is used to specify position using generalized coordinates. As we do in cartesian. then we create other parameters from that. like velocity , acceleration, vector?

u should note that a point in configuration space does not FULLY describe the system's current state

but a point in phase space does

a point in configuration space leaves out the velocities. so it is an incomplete description of the current space

@123 I don't understand the question

@RyderRude What is phase space? I have read about it but didn't understand

you should not think of "generalized coordinates" as being the same kind of thing as "Cartesian coordinates"

"Cartesian coordinates" are one way of expressing a vector in $\mathbb{R}^n$

"generalized coordinates" is a name for whatever you use to specify the state of your system, and that state doesn't have to be a vector in $\mathbb{R}^n$

@123 suppose u have two particles of position and momentum (x1,p1) and (x2,p2). when u clump these together, (x1,p1,x2,p2), u get phase space. here too, the positions need not be cartesian

@ACuriousMind Means. Let say in cartesian system. The smallest or first object is position of a point. Then from that we can create displacement if it move in space, then from it we create velocity using time derivative, then acceleration by time derivative velocity.

Does the same way we go in generalized coordinates?

on phase space, momentum too is a co ordinate

@123 I think we need to take a step back here and consider what we're really doing: We want to do physics, not create a nice list of random quantities.

@RyderRude Pls lets forget about phase space for a moment. First i need to fully understand generalized coordinates.

the point here is that "mechanics" comes down to the following problem: You have some set of generalized coordinates $q_i$ that describe what the "position" of the system you're interested in is at any given moment

the problem you want to solve is: How can I predict $q_i(t)$, i.e. where the system will be in the future

the point of both Lagrangian and Hamiltonian mechanics is that this kind of problem has a very general solution, and you don't need to necessarily think about "accelerations" or "displacements" or "forces" etc. to arrive at it

@ACuriousMind Aaah.. Okay

this is a genuine increase in abstraction from what you've been doing so far

@ACuriousMind Hmmm.....

but if it wasn't, then there would be no point to it, right? If all this did was re-express ordinary Newtonian mechanics in weirder terminology, it wouldn't be useful

@ACuriousMind It means the main goal of LM and HM is to find the trajectory or picture at any moment of time?

yes. in cofiguration space, u would only need generalised positions and their first derivatives. the acceleration and forces are replaced by the Euler Lagrangr eqn @123

@123 I mean that's the main goal of all formulations of mechanics when you get down to it

why would anyone care about forces if not for Newton's laws telling us that forces directly determine the trajectory via $F=ma$

Newton's formulation of physics hides the goals a bit

why would anyone care about momenta and angular momenta and whatnot if not their conservation laws can help us reason about how stuff will move?

Newton's formulation focuses on Forces as if they were the real quantities...it definitely hides the focus from trajectories, which are actually measured

@ACuriousMind So what is the drawback of using Newtonian Mechanics? It work well. I have read in one book. Whatever examples we learned in previous books was so easy and solve able . But not all problems can be solved by NM.

I mean if all you want to do is think about forces acting on particles then you can just keep doing Newton :P

newton's formulation is only for particle evolution. for field evolution, there is no Newtonian version

as I said: Lagrangian and Hamiltonian mechanics are a step up in abstraction: They allow us to treat a much broader class of "time evolutions" with the same tools, they allow us to reason very generally about the existence of conserved quantities, for instance, and see their relation to symmetry

also they make certain problems that are really ugly in the Newtonian formulation more tractable, e.g. when it comes to constraints (a particle that is constrained to move on a given track, three particles connected to each other through springs, whatever)

Mechanics was invented for the noblest of goal, to rain cannonballs on the enemy

@ACuriousMind So i need to remove force effect on object when learning LM or HM?

I don't understand the question

what is a "force effect" and how would one "remove" it

@ACuriousMind As you said in this comment if i think about force acting on particle so i am doing NM.

It means if i need to learn LM & HM i need to remove NM from my mind. It works in a new way. Am i correct?

I think that's a weird thing to say

just because they work differently doesn't mean you should forget about Newtonian mechanics

@ACuriousMind How NM helps in understanding LM

in fact one of the first things people usually do is either derive a limited form of Lagrangian mechanics from Newtonian mechanics or derive $F=ma$ from Lagrangian mechanics and some assumptions

@ACuriousMind Ookay. It means i also comes with new mind to learn LM

nvm i didnt get anything upon googling that quote

does QFT consist of a lot of linear algebra?

HONK!

HONK

@SillyGoose that's a strange question :P

All of physics is a lot of linear algebra

well i am wondering if linear algebra ever stops being the dominant mechanism of physical theories :P

I mean as long as you have vector spaces, it's hard to avoid

Be wise and linearize.

Don't imitate, integrate

@SillyGoose given that the core axiomization of quantum theories is "Observables are linear operators", I'm not sure why you'd expect it to :P

hmmm i see

it's even deeply embedded in number theory

if you want to drop linear operators you're gonna have to drop the real numbers

i would say scattering QFT barely involves any linear algebra

it's just Feynman rules and renormalisation

linear algebra is there but it's there as a backbone

the calculations arent about linear algebra. renormalisation stuff isnt linear algebra

do you identify as linguistic physicalist, physicalist, dualist or idealist?

i mean regarding qualia

@RyderRude funnily enough finding the Wilson-Fisher critical point using the epsilon expansion and linearised beta functions was one of the first examples of explicit diagonalisation that came to mind

but yeah I'd agree that there isn't much linear algebra in the sense of matrix crunching compared to say textbook NRQM

is galois theory used in quantum theory much

@SillyGoose not a lot

not at all I'd say

I'm sure there's some very niche use for it

Also you can just use Galois theory for solving equations

you can probably bend over backwards to connect it to CFT or Feynman graph automorphisms or something

I've seen some people use Galois fields as models for spacetime in QFT

Galois field != Galois theory

they both use the Galois group

how did they model spacetime as a finite field

Just $\mathbb{F}_{p^n}$

but like what do the field operations correspond to

I mostly look at the spacetime part, not so much the QFT part :p

Presumably the direct analogy of what happens in QFT?

Oh do you mean "field" as in the Galois field

yeah

Galois fields basically correspond to some incidence structure between p^n points and all the lines connectings them, where every line has p points

The sum is a translation from one point to the next on a given line

The product is some operation going from one line to the other

@SillyGoose not a lot of people ask which quantum states are constructible with compass and straightedge :P

More seriously, I don't think I've ever seen Galois theory used in any physical context

are there direct connections between the symplectic structur of classical mechanics and complex numbers in quantum mechanics?

this post shows that the imaginary part of the Hilbert space inner product is actually the symplectic form

but the post is for free QFT

That was a tortured conversation

can u make the same argument in the post but for particle quantisation instead of field quantisation?

is the posts's approach analogous to geometric quantisation? or is it like a new quantisation procedure?

it is trying to associate a hilbert space to a symplectic strucutre. it introduces a $\mu$ to achieve that

but geometric quantisation does not do that. it introduces a complex line bundle

so it seems like this approach is a fundamentaly different recipe than geometric quantisation. which one is better?

@SillyGoose hey u will do awesome !!! and it's only the middle of summer my friend ;)

jigglyypufff is right!!! H O N K