Integral Notations in Quantum MechanicsWhy is the $dx$ right next to the integral sign in QFT literature?Is there a recognised standard for typesetting quantum mechanical operators?What's the correct link between Dirac notation and wave mechanics integrals?Notation of integralsLine integral in cylindrical coordinates? Confused over notationWhat is the meaning of the double complex integral notation used in physics?flux-flux correlation function under Feynman's path integralBreaking up an Integral FurtherHow does spin enter into the path integral approach to quantum mechanics?Hermitian operator followed by another hermitian operator – is it also hermitian?Time evolution operator in QM
Showing mass murder in a kid's book
Did I make a mistake by ccing email to boss to others?
Do I have to take mana from my deck or hand when tapping a dual land?
Proving an identity involving cross products and coplanar vectors
Alignment of six matrices
How do I Interface a PS/2 Keyboard without Modern Techniques?
Integral Notations in Quantum Mechanics
Should I assume I have passed probation?
In One Punch Man, is King actually weak?
Why would five hundred and five be same as one?
How to reduce predictors the right way for a logistic regression model
Review your own paper in Mathematics
When and why was runway 07/25 at Kai Tak removed?
How to make money from a browser who sees 5 seconds into the future of any web page?
Language involving irrational number is not a CFL
Why the "ls" command is showing the permissions of files in a FAT32 partition?
Has the laser at Magurele, Romania reached a tenth of the Sun's power?
Personal or impersonal in a technical resume
If Captain Marvel (MCU) were to have a child with a human male, would the child be human or Kree?
Why didn't Voldemort know what Grindelwald looked like?
How do I fix the group tension caused by my character stealing and possibly killing without provocation?
Grepping string, but include all non-blank lines following each grep match
Is there a RAID 0 Equivalent for RAM?
Is there a distance limit for minecart tracks?
Integral Notations in Quantum Mechanics
Why is the $dx$ right next to the integral sign in QFT literature?Is there a recognised standard for typesetting quantum mechanical operators?What's the correct link between Dirac notation and wave mechanics integrals?Notation of integralsLine integral in cylindrical coordinates? Confused over notationWhat is the meaning of the double complex integral notation used in physics?flux-flux correlation function under Feynman's path integralBreaking up an Integral FurtherHow does spin enter into the path integral approach to quantum mechanics?Hermitian operator followed by another hermitian operator – is it also hermitian?Time evolution operator in QM
$begingroup$
I've been learning about Quantum Dynamics, time evolution operators, etc. I am confused about the notation used in integrals. Normally I am used to integrals written in this way (with $dx$ on the right side):
$$int f(x)dx$$
In this manner of notation, I can easily see the integrand as it is sandwiched by the integral sign and the $dx$.
However, I often see integrals written in this way (with $dx$ beside the integral sign):
$$int dx f(x)$$
Is this notation not ambiguous? This is especially confusing for me when used in products, as I cannot identify what is the integrand sometimes. For example, I don't understand which is true in the following (when evaluating time evolution operator): $$beginalignleft(int ^t_t_0 dt' H(t')right)^2stackrel?=int ^t_t_0 H(t') dt'int ^t_t_0 H(t'')dt''\stackrel?=int ^t_t_0 dt' H(t')int ^t_t_0 dt'' H(t'')\stackrel?=int ^t_t_0 dt'int ^t_t_0 dt'' H(t') H(t'') endalign$$
The last line is especially confusing for me as I'm not sure if the integrand changes. Could I please get clarification for these different notations? Is there a reason for such notation? (If I'm not wrong, it is to group the integrals and the integrands in separate places for convenience? I'm not sure if it sacrifices clarity for this though.)
EDIT: There is also an issue of when operators are involved:
$$beginalignint dx hatF(x) hatG(x)stackrel?=int hatF(x)dxhatG(x)\stackrel?=int hatF(x)hatG(x)dxendalign$$
How do you know which operator is in the integrand? And assuming the general case where $hatF$ and $hatG$ do not commute, you cannot write the integral with $hatG(x)$ on the left of the integral. How is this not ambiguous?
quantum-mechanics notation integration
asked 3 hours ago
Hexiang ChangHexiang Chang
110211
$endgroup$
add a comment |
$begingroup$
I've been learning about Quantum Dynamics, time evolution operators, etc. I am confused about the notation used in integrals. Normally I am used to integrals written in this way (with $dx$ on the right side):
$$int f(x)dx$$
In this manner of notation, I can easily see the integrand as it is sandwiched by the integral sign and the $dx$.
However, I often see integrals written in this way (with $dx$ beside the integral sign):
$$int dx f(x)$$
Is this notation not ambiguous? This is especially confusing for me when used in products, as I cannot identify what is the integrand sometimes. For example, I don't understand which is true in the following (when evaluating time evolution operator): $$beginalignleft(int ^t_t_0 dt' H(t')right)^2stackrel?=int ^t_t_0 H(t') dt'int ^t_t_0 H(t'')dt''\stackrel?=int ^t_t_0 dt' H(t')int ^t_t_0 dt'' H(t'')\stackrel?=int ^t_t_0 dt'int ^t_t_0 dt'' H(t') H(t'') endalign$$
The last line is especially confusing for me as I'm not sure if the integrand changes. Could I please get clarification for these different notations? Is there a reason for such notation? (If I'm not wrong, it is to group the integrals and the integrands in separate places for convenience? I'm not sure if it sacrifices clarity for this though.)
EDIT: There is also an issue of when operators are involved:
$$beginalignint dx hatF(x) hatG(x)stackrel?=int hatF(x)dxhatG(x)\stackrel?=int hatF(x)hatG(x)dxendalign$$
How do you know which operator is in the integrand? And assuming the general case where $hatF$ and $hatG$ do not commute, you cannot write the integral with $hatG(x)$ on the left of the integral. How is this not ambiguous?
quantum-mechanics notation integration
asked 3 hours ago
Hexiang ChangHexiang Chang
110211
$endgroup$
$begingroup$
Related: Why is the $𝑑𝑥$ right next to the integral sign in QFT literature? , Notation: Why write the differential first?
$endgroup$
– Qmechanic♦
3 hours ago
$begingroup$
I added another section to my answer, that you may find interesting.
$endgroup$
– DanielSank
1 hour ago
add a comment |
$begingroup$
I've been learning about Quantum Dynamics, time evolution operators, etc. I am confused about the notation used in integrals. Normally I am used to integrals written in this way (with $dx$ on the right side):
$$int f(x)dx$$
In this manner of notation, I can easily see the integrand as it is sandwiched by the integral sign and the $dx$.
However, I often see integrals written in this way (with $dx$ beside the integral sign):
$$int dx f(x)$$
Is this notation not ambiguous? This is especially confusing for me when used in products, as I cannot identify what is the integrand sometimes. For example, I don't understand which is true in the following (when evaluating time evolution operator): $$beginalignleft(int ^t_t_0 dt' H(t')right)^2stackrel?=int ^t_t_0 H(t') dt'int ^t_t_0 H(t'')dt''\stackrel?=int ^t_t_0 dt' H(t')int ^t_t_0 dt'' H(t'')\stackrel?=int ^t_t_0 dt'int ^t_t_0 dt'' H(t') H(t'') endalign$$
The last line is especially confusing for me as I'm not sure if the integrand changes. Could I please get clarification for these different notations? Is there a reason for such notation? (If I'm not wrong, it is to group the integrals and the integrands in separate places for convenience? I'm not sure if it sacrifices clarity for this though.)
EDIT: There is also an issue of when operators are involved:
$$beginalignint dx hatF(x) hatG(x)stackrel?=int hatF(x)dxhatG(x)\stackrel?=int hatF(x)hatG(x)dxendalign$$
How do you know which operator is in the integrand? And assuming the general case where $hatF$ and $hatG$ do not commute, you cannot write the integral with $hatG(x)$ on the left of the integral. How is this not ambiguous?
quantum-mechanics notation integration
asked 3 hours ago
Hexiang ChangHexiang Chang
110211
$endgroup$
I've been learning about Quantum Dynamics, time evolution operators, etc. I am confused about the notation used in integrals. Normally I am used to integrals written in this way (with $dx$ on the right side):
$$int f(x)dx$$
In this manner of notation, I can easily see the integrand as it is sandwiched by the integral sign and the $dx$.
However, I often see integrals written in this way (with $dx$ beside the integral sign):
$$int dx f(x)$$
Is this notation not ambiguous? This is especially confusing for me when used in products, as I cannot identify what is the integrand sometimes. For example, I don't understand which is true in the following (when evaluating time evolution operator): $$beginalignleft(int ^t_t_0 dt' H(t')right)^2stackrel?=int ^t_t_0 H(t') dt'int ^t_t_0 H(t'')dt''\stackrel?=int ^t_t_0 dt' H(t')int ^t_t_0 dt'' H(t'')\stackrel?=int ^t_t_0 dt'int ^t_t_0 dt'' H(t') H(t'') endalign$$
The last line is especially confusing for me as I'm not sure if the integrand changes. Could I please get clarification for these different notations? Is there a reason for such notation? (If I'm not wrong, it is to group the integrals and the integrands in separate places for convenience? I'm not sure if it sacrifices clarity for this though.)
EDIT: There is also an issue of when operators are involved:
$$beginalignint dx hatF(x) hatG(x)stackrel?=int hatF(x)dxhatG(x)\stackrel?=int hatF(x)hatG(x)dxendalign$$
How do you know which operator is in the integrand? And assuming the general case where $hatF$ and $hatG$ do not commute, you cannot write the integral with $hatG(x)$ on the left of the integral. How is this not ambiguous?
quantum-mechanics notation integration
quantum-mechanics notation integration
asked 3 hours ago
Hexiang ChangHexiang Chang
110211
asked 3 hours ago
Hexiang ChangHexiang Chang
110211
edited 3 hours ago
Hexiang Chang
asked 3 hours ago
Hexiang ChangHexiang Chang
110211
asked 3 hours ago
Hexiang ChangHexiang Chang
110211
asked 3 hours ago
Hexiang ChangHexiang Chang
110211
110211
$begingroup$
Related: Why is the $𝑑𝑥$ right next to the integral sign in QFT literature? , Notation: Why write the differential first?
$endgroup$
– Qmechanic♦
3 hours ago
$begingroup$
I added another section to my answer, that you may find interesting.
$endgroup$
– DanielSank
1 hour ago
add a comment |
$begingroup$
Related: Why is the $𝑑𝑥$ right next to the integral sign in QFT literature? , Notation: Why write the differential first?
$endgroup$
– Qmechanic♦
3 hours ago
$begingroup$
I added another section to my answer, that you may find interesting.
$endgroup$
– DanielSank
1 hour ago
$begingroup$
Related: Why is the $𝑑𝑥$ right next to the integral sign in QFT literature? , Notation: Why write the differential first?
$endgroup$
– Qmechanic♦
3 hours ago
$begingroup$
Related: Why is the $𝑑𝑥$ right next to the integral sign in QFT literature? , Notation: Why write the differential first?
$endgroup$
– Qmechanic♦
3 hours ago
$begingroup$
I added another section to my answer, that you may find interesting.
$endgroup$
– DanielSank
1 hour ago
$begingroup$
I added another section to my answer, that you may find interesting.
$endgroup$
– DanielSank
1 hour ago
add a comment |
2 Answers
2
active
oldest
votes
$begingroup$
I started seeing $$int dx f(x)$$ in my freshman year of undergraduate.
It's pretty common and the more you learn about integration the more it makes sense.
Now, regarding this part:
$$beginalignleft(int ^t_t_0 dt' H(t')right)^2stackrel?=int ^t_t_0 H(t') dt'int ^t_t_0 H(t'')dt''\stackrel?=int ^t_t_0 dt' H(t')int ^t_t_0 dt'' H(t'')\stackrel?=int ^t_t_0 dt'int ^t_t_0 dt'' H(t') H(t'') endalign$$
All of the equals signs there are correct.
Integrals factor like this:
$$
int dx int dy , f(x) , g(y) =
left( int dx , f(x) right) left( int dy ,g(y) right) , ,
$$
which is all you did there.
In fact, these are all the same:
beginalign
int int dx , dy , f(x) g(y)
&= int dx int dy , f(x) g(y) \
&= int dx , dy , f(x) g(y) \
&= left( int dx , f(x) right) left( int dy , g(y) right) \
&= left( int dx , f(x) right) left( int dx , g(x) right) \
endalign
Note, however, that you cannot factor something like this:
$$
int_0^t f(t') left( int_0^t' dt'' f(t'') right) dt'
$$
because the limit of the second integral depends on the first integral's integration variable.
You can, however, write it as
$$
int_0^t dt' f(t') int_0^t' dt'' f(t'') , .
$$
Operators
There is also an issue of when operators are involved:
$$beginalignint dx hatF(x) hatG(x)stackrel?=int hatF(x)dxhatG(x)\stackrel?=int hatF(x)hatG(x)dxendalign$$
There's really no difference.
The key is to remember that the $dx$ really doesn't mean anything other than to remind you which variable(s) in the integrand is being integrated.
By convention we tend to write the $dx$ either at the front or at the end.
I've never seen it written in the middle like that.
I think everyone would know what you mean, but putting the $dx$ is the middle of the integrands runs the risk that a reader won't notice them.
How do you know which operator is in the integrand?
Ok that's a good question!
It really comes down to the fact that notation has to be clear.
If you use the symbol $x$ to denote both an integration variable and a not-integrated variable, that's just asking for trouble.
It also shouldn't ever happen because integration variables are consumed by the integral, so they can't be referred to anywhere else in an equation.
For example, this makes no sense:
$$ g(x) = int_0^1 sin(x) dx$$
because there's no "free" $x$ on the right hand side.
And assuming the general case where $hatF$ and $hatG$ do not commute, you cannot write the integral with $hatG(x)$ on the left of the integral. How is this not ambiguous?
Well, you certainly would not write
$$ int dx hat F(x) hat G(x) neq left( int dx hat F(x) right) hat G(x) , .$$
That just makes no sense.
A speech about functions, integrals, and notation
A function $f$ is a well-defined thing independent of any specific choice of variable.
A function $f: mathbbR rightarrow mathbbR$ takes one real number to another one.
It is, therefore, completely unambiguous to write an integral as
$$int_0^1 f$$
with no $dx$.
If $f$ is the sine function, then we can write e.g. $int_0^1 sin$ with absolutely no ambiguity.
So why then do we so often write things like $int_0^1 sin(x) , dx$?
Well, consider a slightly more complicated function like the function $f$ defined by the equation $f(x) = sin(x)/x$.
How would we write this without variables?
Well, we'd name the inversion function $textinv$ defined by $textinv(x) = 1/x$, and then we could say $f = sin cdot , textinv$ and we would write the integral as $$int_0^1 sin cdot , textinv , .$$
That's a perfectly clear representation, but I think it's less common in practice for three reasons:
It's cumbersome to have to name every function. Imagine having to write $(sin circ , textsquare) cdot , textinv$ instead of $sin(x^2)/x$.
We often solve integrals by "variable transformation", and for some people it's easier to see what transformations to make if we represent the functions by their action on their variables.
If you want to evaluate a multi-dimensional integral, at some point you have to use Fubini's theorem and that's only really possibly once the integrals are expressed as nested one-dimensional integrals over separate variables.
Still, even with those three points, I do think that especially for gaining a better understanding of integration (e.g. the change of variables formula) it can be helpful to practice the "no $dx$ notation".
For example, I found that it was a key piece of my understanding how probability distributions transform under a change of variables.
The "no $dx$ notation" also makes a lot of sense for people with experience in programming because it has strong ties to the notion of a type system.
answered 3 hours ago
DanielSankDanielSank
17.6k45178
$endgroup$
$begingroup$
I think it's also important to point out that this form makes the notion of an integral as a functional more apparent, ie an integral is a function that takes a function and returns a number.
$endgroup$
– Aaron
56 mins ago
add a comment |
$begingroup$
The notation is not ambiguous; it's purely convention. The correspondence is
$$
left(
int_t_1^t_2 dt H(t) right) left( int_t'_1^t'_2dt’ H(t',t) right)
iff int_t_1^t_2int_t'_1^t'_2H(t)H(t',t)dt' dt.
$$
That is instead of evaluating "inside out" we evaluate the integrals from right to left.
If you square an integral as
$$ left(int ^t_t_0 dt' H(t')right)^2 $$
you should know that in general these two integrals don't talk to one another, except in very special cases. That is, they are completely separate entities.
answered 3 hours ago
InertialObserverInertialObserver
3,2301027
$endgroup$
add a comment |
Your Answer
StackExchange.ifUsing("editor", function ()
return StackExchange.using("mathjaxEditing", function ()
StackExchange.MarkdownEditor.creationCallbacks.add(function (editor, postfix)
StackExchange.mathjaxEditing.prepareWmdForMathJax(editor, postfix, [["$", "$"], ["\\(","\\)"]]);
);
);
, "mathjax-editing");
StackExchange.ready(function()
var channelOptions =
tags: "".split(" "),
id: "151"
;
initTagRenderer("".split(" "), "".split(" "), channelOptions);
StackExchange.using("externalEditor", function()
// Have to fire editor after snippets, if snippets enabled
if (StackExchange.settings.snippets.snippetsEnabled)
StackExchange.using("snippets", function()
createEditor();
);
else
createEditor();
);
function createEditor()
StackExchange.prepareEditor(
heartbeatType: 'answer',
autoActivateHeartbeat: false,
convertImagesToLinks: false,
noModals: true,
showLowRepImageUploadWarning: true,
reputationToPostImages: null,
bindNavPrevention: true,
postfix: "",
imageUploader:
brandingHtml: "Powered by u003ca class="icon-imgur-white" href="https://imgur.com/"u003eu003c/au003e",
contentPolicyHtml: "User contributions licensed under u003ca href="https://creativecommons.org/licenses/by-sa/3.0/"u003ecc by-sa 3.0 with attribution requiredu003c/au003e u003ca href="https://stackoverflow.com/legal/content-policy"u003e(content policy)u003c/au003e",
allowUrls: true
,
noCode: true, onDemand: true,
discardSelector: ".discard-answer"
,immediatelyShowMarkdownHelp:true
);
);
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
StackExchange.ready(
function ()
StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fphysics.stackexchange.com%2fquestions%2f467758%2fintegral-notations-in-quantum-mechanics%23new-answer', 'question_page');
);
Post as a guest
Required, but never shown
2 Answers
2
active
oldest
votes
2 Answers
2
active
oldest
votes
active
oldest
votes
active
oldest
votes
$begingroup$
I started seeing $$int dx f(x)$$ in my freshman year of undergraduate.
It's pretty common and the more you learn about integration the more it makes sense.
Now, regarding this part:
$$beginalignleft(int ^t_t_0 dt' H(t')right)^2stackrel?=int ^t_t_0 H(t') dt'int ^t_t_0 H(t'')dt''\stackrel?=int ^t_t_0 dt' H(t')int ^t_t_0 dt'' H(t'')\stackrel?=int ^t_t_0 dt'int ^t_t_0 dt'' H(t') H(t'') endalign$$
All of the equals signs there are correct.
Integrals factor like this:
$$
int dx int dy , f(x) , g(y) =
left( int dx , f(x) right) left( int dy ,g(y) right) , ,
$$
which is all you did there.
In fact, these are all the same:
beginalign
int int dx , dy , f(x) g(y)
&= int dx int dy , f(x) g(y) \
&= int dx , dy , f(x) g(y) \
&= left( int dx , f(x) right) left( int dy , g(y) right) \
&= left( int dx , f(x) right) left( int dx , g(x) right) \
endalign
Note, however, that you cannot factor something like this:
$$
int_0^t f(t') left( int_0^t' dt'' f(t'') right) dt'
$$
because the limit of the second integral depends on the first integral's integration variable.
You can, however, write it as
$$
int_0^t dt' f(t') int_0^t' dt'' f(t'') , .
$$
Operators
There is also an issue of when operators are involved:
$$beginalignint dx hatF(x) hatG(x)stackrel?=int hatF(x)dxhatG(x)\stackrel?=int hatF(x)hatG(x)dxendalign$$
There's really no difference.
The key is to remember that the $dx$ really doesn't mean anything other than to remind you which variable(s) in the integrand is being integrated.
By convention we tend to write the $dx$ either at the front or at the end.
I've never seen it written in the middle like that.
I think everyone would know what you mean, but putting the $dx$ is the middle of the integrands runs the risk that a reader won't notice them.
How do you know which operator is in the integrand?
Ok that's a good question!
It really comes down to the fact that notation has to be clear.
If you use the symbol $x$ to denote both an integration variable and a not-integrated variable, that's just asking for trouble.
It also shouldn't ever happen because integration variables are consumed by the integral, so they can't be referred to anywhere else in an equation.
For example, this makes no sense:
$$ g(x) = int_0^1 sin(x) dx$$
because there's no "free" $x$ on the right hand side.
And assuming the general case where $hatF$ and $hatG$ do not commute, you cannot write the integral with $hatG(x)$ on the left of the integral. How is this not ambiguous?
Well, you certainly would not write
$$ int dx hat F(x) hat G(x) neq left( int dx hat F(x) right) hat G(x) , .$$
That just makes no sense.
A speech about functions, integrals, and notation
A function $f$ is a well-defined thing independent of any specific choice of variable.
A function $f: mathbbR rightarrow mathbbR$ takes one real number to another one.
It is, therefore, completely unambiguous to write an integral as
$$int_0^1 f$$
with no $dx$.
If $f$ is the sine function, then we can write e.g. $int_0^1 sin$ with absolutely no ambiguity.
So why then do we so often write things like $int_0^1 sin(x) , dx$?
Well, consider a slightly more complicated function like the function $f$ defined by the equation $f(x) = sin(x)/x$.
How would we write this without variables?
Well, we'd name the inversion function $textinv$ defined by $textinv(x) = 1/x$, and then we could say $f = sin cdot , textinv$ and we would write the integral as $$int_0^1 sin cdot , textinv , .$$
That's a perfectly clear representation, but I think it's less common in practice for three reasons:
It's cumbersome to have to name every function. Imagine having to write $(sin circ , textsquare) cdot , textinv$ instead of $sin(x^2)/x$.
We often solve integrals by "variable transformation", and for some people it's easier to see what transformations to make if we represent the functions by their action on their variables.
If you want to evaluate a multi-dimensional integral, at some point you have to use Fubini's theorem and that's only really possibly once the integrals are expressed as nested one-dimensional integrals over separate variables.
Still, even with those three points, I do think that especially for gaining a better understanding of integration (e.g. the change of variables formula) it can be helpful to practice the "no $dx$ notation".
For example, I found that it was a key piece of my understanding how probability distributions transform under a change of variables.
The "no $dx$ notation" also makes a lot of sense for people with experience in programming because it has strong ties to the notion of a type system.
answered 3 hours ago
DanielSankDanielSank
17.6k45178
$endgroup$
$begingroup$
I think it's also important to point out that this form makes the notion of an integral as a functional more apparent, ie an integral is a function that takes a function and returns a number.
$endgroup$
– Aaron
56 mins ago
add a comment |
$begingroup$
I started seeing $$int dx f(x)$$ in my freshman year of undergraduate.
It's pretty common and the more you learn about integration the more it makes sense.
Now, regarding this part:
$$beginalignleft(int ^t_t_0 dt' H(t')right)^2stackrel?=int ^t_t_0 H(t') dt'int ^t_t_0 H(t'')dt''\stackrel?=int ^t_t_0 dt' H(t')int ^t_t_0 dt'' H(t'')\stackrel?=int ^t_t_0 dt'int ^t_t_0 dt'' H(t') H(t'') endalign$$
All of the equals signs there are correct.
Integrals factor like this:
$$
int dx int dy , f(x) , g(y) =
left( int dx , f(x) right) left( int dy ,g(y) right) , ,
$$
which is all you did there.
In fact, these are all the same:
beginalign
int int dx , dy , f(x) g(y)
&= int dx int dy , f(x) g(y) \
&= int dx , dy , f(x) g(y) \
&= left( int dx , f(x) right) left( int dy , g(y) right) \
&= left( int dx , f(x) right) left( int dx , g(x) right) \
endalign
Note, however, that you cannot factor something like this:
$$
int_0^t f(t') left( int_0^t' dt'' f(t'') right) dt'
$$
because the limit of the second integral depends on the first integral's integration variable.
You can, however, write it as
$$
int_0^t dt' f(t') int_0^t' dt'' f(t'') , .
$$
Operators
There is also an issue of when operators are involved:
$$beginalignint dx hatF(x) hatG(x)stackrel?=int hatF(x)dxhatG(x)\stackrel?=int hatF(x)hatG(x)dxendalign$$
There's really no difference.
The key is to remember that the $dx$ really doesn't mean anything other than to remind you which variable(s) in the integrand is being integrated.
By convention we tend to write the $dx$ either at the front or at the end.
I've never seen it written in the middle like that.
I think everyone would know what you mean, but putting the $dx$ is the middle of the integrands runs the risk that a reader won't notice them.
How do you know which operator is in the integrand?
Ok that's a good question!
It really comes down to the fact that notation has to be clear.
If you use the symbol $x$ to denote both an integration variable and a not-integrated variable, that's just asking for trouble.
It also shouldn't ever happen because integration variables are consumed by the integral, so they can't be referred to anywhere else in an equation.
For example, this makes no sense:
$$ g(x) = int_0^1 sin(x) dx$$
because there's no "free" $x$ on the right hand side.
And assuming the general case where $hatF$ and $hatG$ do not commute, you cannot write the integral with $hatG(x)$ on the left of the integral. How is this not ambiguous?
Well, you certainly would not write
$$ int dx hat F(x) hat G(x) neq left( int dx hat F(x) right) hat G(x) , .$$
That just makes no sense.
A speech about functions, integrals, and notation
A function $f$ is a well-defined thing independent of any specific choice of variable.
A function $f: mathbbR rightarrow mathbbR$ takes one real number to another one.
It is, therefore, completely unambiguous to write an integral as
$$int_0^1 f$$
with no $dx$.
If $f$ is the sine function, then we can write e.g. $int_0^1 sin$ with absolutely no ambiguity.
So why then do we so often write things like $int_0^1 sin(x) , dx$?
Well, consider a slightly more complicated function like the function $f$ defined by the equation $f(x) = sin(x)/x$.
How would we write this without variables?
Well, we'd name the inversion function $textinv$ defined by $textinv(x) = 1/x$, and then we could say $f = sin cdot , textinv$ and we would write the integral as $$int_0^1 sin cdot , textinv , .$$
That's a perfectly clear representation, but I think it's less common in practice for three reasons:
It's cumbersome to have to name every function. Imagine having to write $(sin circ , textsquare) cdot , textinv$ instead of $sin(x^2)/x$.
We often solve integrals by "variable transformation", and for some people it's easier to see what transformations to make if we represent the functions by their action on their variables.
If you want to evaluate a multi-dimensional integral, at some point you have to use Fubini's theorem and that's only really possibly once the integrals are expressed as nested one-dimensional integrals over separate variables.
Still, even with those three points, I do think that especially for gaining a better understanding of integration (e.g. the change of variables formula) it can be helpful to practice the "no $dx$ notation".
For example, I found that it was a key piece of my understanding how probability distributions transform under a change of variables.
The "no $dx$ notation" also makes a lot of sense for people with experience in programming because it has strong ties to the notion of a type system.
answered 3 hours ago
DanielSankDanielSank
17.6k45178
$endgroup$
$begingroup$
I think it's also important to point out that this form makes the notion of an integral as a functional more apparent, ie an integral is a function that takes a function and returns a number.
$endgroup$
– Aaron
56 mins ago
add a comment |
$begingroup$
I started seeing $$int dx f(x)$$ in my freshman year of undergraduate.
It's pretty common and the more you learn about integration the more it makes sense.
Now, regarding this part:
$$beginalignleft(int ^t_t_0 dt' H(t')right)^2stackrel?=int ^t_t_0 H(t') dt'int ^t_t_0 H(t'')dt''\stackrel?=int ^t_t_0 dt' H(t')int ^t_t_0 dt'' H(t'')\stackrel?=int ^t_t_0 dt'int ^t_t_0 dt'' H(t') H(t'') endalign$$
All of the equals signs there are correct.
Integrals factor like this:
$$
int dx int dy , f(x) , g(y) =
left( int dx , f(x) right) left( int dy ,g(y) right) , ,
$$
which is all you did there.
In fact, these are all the same:
beginalign
int int dx , dy , f(x) g(y)
&= int dx int dy , f(x) g(y) \
&= int dx , dy , f(x) g(y) \
&= left( int dx , f(x) right) left( int dy , g(y) right) \
&= left( int dx , f(x) right) left( int dx , g(x) right) \
endalign
Note, however, that you cannot factor something like this:
$$
int_0^t f(t') left( int_0^t' dt'' f(t'') right) dt'
$$
because the limit of the second integral depends on the first integral's integration variable.
You can, however, write it as
$$
int_0^t dt' f(t') int_0^t' dt'' f(t'') , .
$$
Operators
There is also an issue of when operators are involved:
$$beginalignint dx hatF(x) hatG(x)stackrel?=int hatF(x)dxhatG(x)\stackrel?=int hatF(x)hatG(x)dxendalign$$
There's really no difference.
The key is to remember that the $dx$ really doesn't mean anything other than to remind you which variable(s) in the integrand is being integrated.
By convention we tend to write the $dx$ either at the front or at the end.
I've never seen it written in the middle like that.
I think everyone would know what you mean, but putting the $dx$ is the middle of the integrands runs the risk that a reader won't notice them.
How do you know which operator is in the integrand?
Ok that's a good question!
It really comes down to the fact that notation has to be clear.
If you use the symbol $x$ to denote both an integration variable and a not-integrated variable, that's just asking for trouble.
It also shouldn't ever happen because integration variables are consumed by the integral, so they can't be referred to anywhere else in an equation.
For example, this makes no sense:
$$ g(x) = int_0^1 sin(x) dx$$
because there's no "free" $x$ on the right hand side.
And assuming the general case where $hatF$ and $hatG$ do not commute, you cannot write the integral with $hatG(x)$ on the left of the integral. How is this not ambiguous?
Well, you certainly would not write
$$ int dx hat F(x) hat G(x) neq left( int dx hat F(x) right) hat G(x) , .$$
That just makes no sense.
A speech about functions, integrals, and notation
A function $f$ is a well-defined thing independent of any specific choice of variable.
A function $f: mathbbR rightarrow mathbbR$ takes one real number to another one.
It is, therefore, completely unambiguous to write an integral as
$$int_0^1 f$$
with no $dx$.
If $f$ is the sine function, then we can write e.g. $int_0^1 sin$ with absolutely no ambiguity.
So why then do we so often write things like $int_0^1 sin(x) , dx$?
Well, consider a slightly more complicated function like the function $f$ defined by the equation $f(x) = sin(x)/x$.
How would we write this without variables?
Well, we'd name the inversion function $textinv$ defined by $textinv(x) = 1/x$, and then we could say $f = sin cdot , textinv$ and we would write the integral as $$int_0^1 sin cdot , textinv , .$$
That's a perfectly clear representation, but I think it's less common in practice for three reasons:
It's cumbersome to have to name every function. Imagine having to write $(sin circ , textsquare) cdot , textinv$ instead of $sin(x^2)/x$.
We often solve integrals by "variable transformation", and for some people it's easier to see what transformations to make if we represent the functions by their action on their variables.
If you want to evaluate a multi-dimensional integral, at some point you have to use Fubini's theorem and that's only really possibly once the integrals are expressed as nested one-dimensional integrals over separate variables.
Still, even with those three points, I do think that especially for gaining a better understanding of integration (e.g. the change of variables formula) it can be helpful to practice the "no $dx$ notation".
For example, I found that it was a key piece of my understanding how probability distributions transform under a change of variables.
The "no $dx$ notation" also makes a lot of sense for people with experience in programming because it has strong ties to the notion of a type system.
answered 3 hours ago
DanielSankDanielSank
17.6k45178
$endgroup$
I started seeing $$int dx f(x)$$ in my freshman year of undergraduate.
It's pretty common and the more you learn about integration the more it makes sense.
Now, regarding this part:
$$beginalignleft(int ^t_t_0 dt' H(t')right)^2stackrel?=int ^t_t_0 H(t') dt'int ^t_t_0 H(t'')dt''\stackrel?=int ^t_t_0 dt' H(t')int ^t_t_0 dt'' H(t'')\stackrel?=int ^t_t_0 dt'int ^t_t_0 dt'' H(t') H(t'') endalign$$
All of the equals signs there are correct.
Integrals factor like this:
$$
int dx int dy , f(x) , g(y) =
left( int dx , f(x) right) left( int dy ,g(y) right) , ,
$$
which is all you did there.
In fact, these are all the same:
beginalign
int int dx , dy , f(x) g(y)
&= int dx int dy , f(x) g(y) \
&= int dx , dy , f(x) g(y) \
&= left( int dx , f(x) right) left( int dy , g(y) right) \
&= left( int dx , f(x) right) left( int dx , g(x) right) \
endalign
Note, however, that you cannot factor something like this:
$$
int_0^t f(t') left( int_0^t' dt'' f(t'') right) dt'
$$
because the limit of the second integral depends on the first integral's integration variable.
You can, however, write it as
$$
int_0^t dt' f(t') int_0^t' dt'' f(t'') , .
$$
Operators
There is also an issue of when operators are involved:
$$beginalignint dx hatF(x) hatG(x)stackrel?=int hatF(x)dxhatG(x)\stackrel?=int hatF(x)hatG(x)dxendalign$$
There's really no difference.
The key is to remember that the $dx$ really doesn't mean anything other than to remind you which variable(s) in the integrand is being integrated.
By convention we tend to write the $dx$ either at the front or at the end.
I've never seen it written in the middle like that.
I think everyone would know what you mean, but putting the $dx$ is the middle of the integrands runs the risk that a reader won't notice them.
How do you know which operator is in the integrand?
Ok that's a good question!
It really comes down to the fact that notation has to be clear.
If you use the symbol $x$ to denote both an integration variable and a not-integrated variable, that's just asking for trouble.
It also shouldn't ever happen because integration variables are consumed by the integral, so they can't be referred to anywhere else in an equation.
For example, this makes no sense:
$$ g(x) = int_0^1 sin(x) dx$$
because there's no "free" $x$ on the right hand side.
And assuming the general case where $hatF$ and $hatG$ do not commute, you cannot write the integral with $hatG(x)$ on the left of the integral. How is this not ambiguous?
Well, you certainly would not write
$$ int dx hat F(x) hat G(x) neq left( int dx hat F(x) right) hat G(x) , .$$
That just makes no sense.
A speech about functions, integrals, and notation
A function $f$ is a well-defined thing independent of any specific choice of variable.
A function $f: mathbbR rightarrow mathbbR$ takes one real number to another one.
It is, therefore, completely unambiguous to write an integral as
$$int_0^1 f$$
with no $dx$.
If $f$ is the sine function, then we can write e.g. $int_0^1 sin$ with absolutely no ambiguity.
So why then do we so often write things like $int_0^1 sin(x) , dx$?
Well, consider a slightly more complicated function like the function $f$ defined by the equation $f(x) = sin(x)/x$.
How would we write this without variables?
Well, we'd name the inversion function $textinv$ defined by $textinv(x) = 1/x$, and then we could say $f = sin cdot , textinv$ and we would write the integral as $$int_0^1 sin cdot , textinv , .$$
That's a perfectly clear representation, but I think it's less common in practice for three reasons:
It's cumbersome to have to name every function. Imagine having to write $(sin circ , textsquare) cdot , textinv$ instead of $sin(x^2)/x$.
We often solve integrals by "variable transformation", and for some people it's easier to see what transformations to make if we represent the functions by their action on their variables.
If you want to evaluate a multi-dimensional integral, at some point you have to use Fubini's theorem and that's only really possibly once the integrals are expressed as nested one-dimensional integrals over separate variables.
Still, even with those three points, I do think that especially for gaining a better understanding of integration (e.g. the change of variables formula) it can be helpful to practice the "no $dx$ notation".
For example, I found that it was a key piece of my understanding how probability distributions transform under a change of variables.
The "no $dx$ notation" also makes a lot of sense for people with experience in programming because it has strong ties to the notion of a type system.
answered 3 hours ago
DanielSankDanielSank
17.6k45178
edited 1 hour ago
answered 3 hours ago
DanielSankDanielSank
17.6k45178
answered 3 hours ago
DanielSankDanielSank
17.6k45178
answered 3 hours ago
DanielSankDanielSank
17.6k45178
17.6k45178
$begingroup$
I think it's also important to point out that this form makes the notion of an integral as a functional more apparent, ie an integral is a function that takes a function and returns a number.
$endgroup$
– Aaron
56 mins ago
add a comment |
$begingroup$
I think it's also important to point out that this form makes the notion of an integral as a functional more apparent, ie an integral is a function that takes a function and returns a number.
$endgroup$
– Aaron
56 mins ago
$begingroup$
I think it's also important to point out that this form makes the notion of an integral as a functional more apparent, ie an integral is a function that takes a function and returns a number.
$endgroup$
– Aaron
56 mins ago
$begingroup$
I think it's also important to point out that this form makes the notion of an integral as a functional more apparent, ie an integral is a function that takes a function and returns a number.
$endgroup$
– Aaron
56 mins ago
add a comment |
$begingroup$
The notation is not ambiguous; it's purely convention. The correspondence is
$$
left(
int_t_1^t_2 dt H(t) right) left( int_t'_1^t'_2dt’ H(t',t) right)
iff int_t_1^t_2int_t'_1^t'_2H(t)H(t',t)dt' dt.
$$
That is instead of evaluating "inside out" we evaluate the integrals from right to left.
If you square an integral as
$$ left(int ^t_t_0 dt' H(t')right)^2 $$
you should know that in general these two integrals don't talk to one another, except in very special cases. That is, they are completely separate entities.
answered 3 hours ago
InertialObserverInertialObserver
3,2301027
$endgroup$
add a comment |
$begingroup$
The notation is not ambiguous; it's purely convention. The correspondence is
$$
left(
int_t_1^t_2 dt H(t) right) left( int_t'_1^t'_2dt’ H(t',t) right)
iff int_t_1^t_2int_t'_1^t'_2H(t)H(t',t)dt' dt.
$$
That is instead of evaluating "inside out" we evaluate the integrals from right to left.
If you square an integral as
$$ left(int ^t_t_0 dt' H(t')right)^2 $$
you should know that in general these two integrals don't talk to one another, except in very special cases. That is, they are completely separate entities.
answered 3 hours ago
InertialObserverInertialObserver
3,2301027
$endgroup$
add a comment |
$begingroup$
The notation is not ambiguous; it's purely convention. The correspondence is
$$
left(
int_t_1^t_2 dt H(t) right) left( int_t'_1^t'_2dt’ H(t',t) right)
iff int_t_1^t_2int_t'_1^t'_2H(t)H(t',t)dt' dt.
$$
That is instead of evaluating "inside out" we evaluate the integrals from right to left.
If you square an integral as
$$ left(int ^t_t_0 dt' H(t')right)^2 $$
you should know that in general these two integrals don't talk to one another, except in very special cases. That is, they are completely separate entities.
answered 3 hours ago
InertialObserverInertialObserver
3,2301027
$endgroup$
The notation is not ambiguous; it's purely convention. The correspondence is
$$
left(
int_t_1^t_2 dt H(t) right) left( int_t'_1^t'_2dt’ H(t',t) right)
iff int_t_1^t_2int_t'_1^t'_2H(t)H(t',t)dt' dt.
$$
That is instead of evaluating "inside out" we evaluate the integrals from right to left.
If you square an integral as
$$ left(int ^t_t_0 dt' H(t')right)^2 $$
you should know that in general these two integrals don't talk to one another, except in very special cases. That is, they are completely separate entities.
answered 3 hours ago
InertialObserverInertialObserver
3,2301027
edited 11 mins ago
answered 3 hours ago
InertialObserverInertialObserver
3,2301027
answered 3 hours ago
InertialObserverInertialObserver
3,2301027
answered 3 hours ago
InertialObserverInertialObserver
3,2301027
3,2301027
add a comment |
add a comment |
Thanks for contributing an answer to Physics Stack Exchange!
- Please be sure to answer the question. Provide details and share your research!
But avoid …
- Asking for help, clarification, or responding to other answers.
- Making statements based on opinion; back them up with references or personal experience.
Use MathJax to format equations. MathJax reference.
To learn more, see our tips on writing great answers.
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
StackExchange.ready(
function ()
StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fphysics.stackexchange.com%2fquestions%2f467758%2fintegral-notations-in-quantum-mechanics%23new-answer', 'question_page');
);
Post as a guest
Required, but never shown
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
$begingroup$
Related: Why is the $𝑑𝑥$ right next to the integral sign in QFT literature? , Notation: Why write the differential first?
$endgroup$
– Qmechanic♦
3 hours ago
$begingroup$
I added another section to my answer, that you may find interesting.
$endgroup$
– DanielSank
1 hour ago