Linear Operator vs Linear Function: Technical Difference

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Discussion Overview

The discussion centers on the technical differences between linear operators and linear functions, exploring terminology, definitions, and the contexts in which these terms are used within mathematics. The scope includes theoretical aspects and conceptual clarifications relevant to linear algebra and functional analysis.

Discussion Character

  • Debate/contested
  • Conceptual clarification
  • Technical explanation

Main Points Raised

  • Some participants suggest that linear operators and linear functions are essentially the same, while others argue for a distinction based on context and terminology.
  • One participant notes that different communities of mathematicians may prefer different terms, such as linear map or linear transformation.
  • It is proposed that linear maps can be defined as functions between arbitrary vector spaces, while linear operators are reserved for maps within the same vector space.
  • Another viewpoint is that linear operators must correspond to square matrices, whereas linear functions can involve non-square matrices, reflecting their mapping between different dimensional spaces.
  • Some participants express that the term "linear transform" is more commonly associated with linear algebra, while "operator" is used in the context of infinite-dimensional spaces.
  • A participant mentions that the distinction between linear operator and linear function may not be universally accepted, indicating that it depends on the author's perspective.
  • There is a suggestion that the term endomorphism could be used for maps of a vector space to itself, but this is also subject to varying terminology preferences among mathematicians.

Areas of Agreement / Disagreement

Participants do not reach a consensus on the definitions and distinctions between linear operators and linear functions. Multiple competing views remain, with some asserting they are synonyms while others maintain a technical distinction based on context and dimensionality.

Contextual Notes

Participants highlight that definitions may depend on specific mathematical contexts and that terminology can vary across different fields of study. There are unresolved nuances regarding the use of terms like linear transformation, operator, and endomorphism.

ajayguhan
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What is the exact technical difference between a linear operator and linear function?
 
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To me, they are the same thing.
 
I use linear function, linear operator, linear map, and linear transformation all interchangeably, though you come to notice that different communities of mathematicians have different preferred terminology.
 
Though I do not believe this is standard if IIRC, Axler defines linear maps (functions) as maps between arbitrary vector spaces but reserves the term operator for maps between the same vector space.

Most use the terms interchangeably in my experience.
 
Last edited:
I think linear operators must be square matrices will linear maps can be any sort of configuration (i.e. non-square).
 
Jorriss said:
Though I do not believe this is standard if IIRC, Axler defines linear maps (functions) as maps between arbitrary vector spaces but reserves the term operator for maps between the same vector space.

chiro said:
I think linear operators must be square matrices will linear maps can be any sort of configuration (i.e. non-square).
That's how linear operators were distinguished from linear transformations when I learned about them. I.e., a linear operator maps a space to itself, hence the matrix for the operator is necessarily square.
 
Mark44 said:
That's how linear operators were distinguished from linear transformations when I learned about them. I.e., a linear operator maps a space to itself, hence the matrix for the operator is necessarily square.

I've never see "linear transform" used with infinite dimensional spaces. It always seems to be "operator theory" or "bounded linear operator" or "closed operator".

Linear transform seems to be more of a term you see in linear algebra rather than linear analysis.
 
Can we say that linear operator and linear function are generally used as synonyms but to be more precise and technically linear operator denotes square matrix since it maps space to itself whereas linear function denotes a rectangular matrix since it maps a vector of one space to different space.

Is that right?
 
  • #10
That's pretty close. I would say it this way: a linear operator maps a vector space to itself, which implies that the matrix is square. A linear function maps an arbitrary vector space to a possibly different vector space, which implies that the matrix is not square if the spaces are of different dimension.
 
  • #11
pwsnafu said:
I've never see "linear transform" used with infinite dimensional spaces. It always seems to be "operator theory" or "bounded linear operator" or "closed operator".

Linear transform seems to be more of a term you see in linear algebra rather than linear analysis.

Well, you do have Fourier transforms, Gelfand transforms, Laplace transforms, Hilbert transforms,... All of these are on space which are usually pretty infinite-dimensional.

ajayguhan said:
Can we say that linear operator and linear function are generally used as synonyms but to be more precise and technically linear operator denotes square matrix since it maps space to itself whereas linear function denotes a rectangular matrix since it maps a vector of one space to different space.

Is that right?

I wouldn't say "more precise". It is simply a word with two different meanings. For some people, it are synonyms, for other people there is a distinction. So it depends on the author.

Mark44 said:
That's pretty close. I would say it this way: a linear operator maps a vector space to itself, which implies that the matrix is square. A linear function maps an arbitrary vector space to a possibly different vector space, which implies that the matrix is not square if the spaces are of different dimension.

I would usually use the term endomorphism for a map of a vector space to itself. But of course, other people may use other terminology. No problem with that.
 
  • #12
R136a1 said:
Well, you do have Fourier transforms, Gelfand transforms, Laplace transforms, Hilbert transforms,... All of these are on space which are usually pretty infinite-dimensional.

Completely forgot about integral transforms. I was thinking about thinking about things like Open Mapping Theorem :-p
 

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