Talk:Matrix norm

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What is sup(x) ???? Dr. Universe (talk) 00:08, 8 June 2015 (UTC)[reply]

> sup(x) stands for the supremium or the least upper bound property of x. Themumblingprophet (talk) 01:43, 16 April 2020 (UTC)[reply]

I removed the condition that the matrix be square for the induced norm (when p = 2) to be equivalent to the largest singular value. Indeed, this equivalence is true for non-square matrices too.

The following page will be replaced by a table.--wshun 01:34, 8 Aug 2003 (UTC)

The most "natural" of these operator norms is the one which arises from the Euclidean norms ||.||₂ on K^m and Kⁿ. It is unfortunately relatively difficult to compute; we have

${\displaystyle \|A\|_{2}={\mbox{ the largest singular value of }}A}$

(see singular value). If we use the taxicab norm ||.||₁ on K^m and Kⁿ, then we obtain the operator norm

${\displaystyle \|A\|_{1}=\max _{1\leq j\leq n}\sum _{i=1}^{m}|a_{ij}|}$

and if we use the maximum norm ||.||_∞ on K^m and Kⁿ, we get

${\displaystyle \|A\|_{\infty }=\max _{1\leq i\leq m}\sum _{j=1}^{n}|a_{ij}|}$

The following inequalities obtain among the various discussed matrix norms for the m-by-n matrix A:

${\displaystyle {\frac {1}{\sqrt {n}}}\Vert \,A\,\Vert _{\infty }\leq \Vert \,A\,\Vert _{2}\leq {\sqrt {m}}\Vert \,A\,\Vert _{\infty }}$

${\displaystyle {\frac {1}{\sqrt {m}}}\Vert \,A\,\Vert _{1}\leq \Vert \,A\,\Vert _{2}\leq {\sqrt {n}}\Vert \,A\,\Vert _{1}}$

${\displaystyle \Vert \,A\,\Vert _{2}\leq \Vert \,A\,\Vert _{F}\leq {\sqrt {n}}\Vert \,A\,\Vert _{2}}$

This site needs to be linked to http://de.wikipedia.org/wiki/Matrixnorm

--91.113.18.247 (talk) 19:03, 5 January 2011 (UTC)[reply]

Why does the article say that Frobenius norm is not sub-multiplicative? It does satisfy the condition ${\displaystyle \|AB\|\leq \|A\|\|B\|}$, which can be easily proved as follows: ${\displaystyle \|AB\|_{F}^{2}=\sum _{i,j=1}^{n}|\sum _{k=1}^{n}a_{i,k}b_{k,j}|^{2}\leq \sum _{i,j=1}^{n}{\Big (}\sum _{k=1}^{n}|a_{i,k}|^{2}{\Big )}{\Big (}\sum _{l=1}^{n}|b_{l,j}|^{2}{\Big )}=}$ ${\displaystyle =(\sum _{i,k=1}^{n}|a_{i,k}|^{2})(\sum _{j,l=1}^{n}|b_{l,j}|^{2})=\|A\|_{F}^{2}\|B\|_{F}^{2}}$. --Igor 21:21, Feb 18, 2005 (UTC)

Is it true that the Frobenius norm is ${\displaystyle \|A\|_{p}}$ when p=2. It seems to me that it is the ${\displaystyle \|A\|_{2}}$ norm that is mentioned earlier in the article. ${\displaystyle \|A\|={\sqrt {\lambda _{max}A^{H}A}}}$. Also it is also called the Hilbert-Schmidt norm, because the page for Hilbert-Schmidt norm says that it is only analogous to the Frobenius norm.--kfrance 13:40, Oct 9, 2007 (MST)

@KFrance, That is not true. The Frobenius norm is the Hilbert-Schmidt norm, but it is not the same as ${\displaystyle \|A\|={\sqrt {\lambda _{max}A^{H}A}}}$ (this is the 'spectral norm'). For vectors, ${\displaystyle \|a\|_{2}}$ is the Euclidean norm which is the same as the Frobenius norm if the input vector is treated like a matrix, but when the input is a matrix, the notation ${\displaystyle \|A\|_{2}}$ usually denotes spectral norm, which is not the Frobenius norm. @Igor, that is true. Lavaka (talk) 17:54, 9 July 2014 (UTC)[reply]

The above discussion suggests that the article used to be more extensive. However, the revision history of the current article shows only one edit, by CyborgTosser on 25 Feb 2005. Did something drastic happen to the article? -- Jitse Niesen 11:36, 2 Mar 2005 (UTC)

I'm not quite sure what happened. Apparently there used to be an article here, but the content must have been moved. I'm not sure where and I'm not sure why, but a lot of articles link here, so I figured we needed the article. Hopefully whoever moved the content will replace whatever is relevant. CyborgTosser (Only half the battle) 03:21, 11 Mar 2005 (UTC)

I don't know either. I couldn't find the old page on wikipedia with google, but I've put a copy (from a wikipedia clone) at Matrix norm/old. Lupin 13:50, 11 Mar 2005 (UTC)

It seems that User:RickK deleted this page after it had been vandalised. Idiot. I've asked him to restore it with edit history to a subpage if possible. Lupin 14:10, 11 Mar 2005 (UTC)

I'm a little confused where the article says that "any induced norm satisfies the inequality ...". Is the intended meaning that the operator norm satisfies that inequality, or are there other norms which are also known as induced norms which satisfy that inequality? If the former, it should be rephrased as "the induced norm satisfies..." and if the latter, an explanation of what is meant by an induced norm should be given. Lupin 01:24, 11 May 2005 (UTC)[reply]

The terms "induced norm" and "operator norm" are synonymous. I used "any induced norm" instead of "the induced norm" because there are several operator norms. One example is the spectral norm, another example arises when one takes the ∞-norm on Kⁿ, defined by

${\displaystyle \|v\|_{\infty }=\max _{i}|v_{i}|;}$

the resulting operator norm is

${\displaystyle \|A\|_{\infty }=\max _{i}\sum _{j}|a_{ij}|.}$

I hope this resolves the confusion; feel free (of course) to edit the article to make it clearer. -- Jitse Niesen 10:23, 11 May 2005 (UTC)[reply]

I feel that this article is quite unclear about when submultiplicativity applies. In particular, it should be made clear that for matrix norms based on vectors p-norms that for ${\displaystyle A\in {\mathbb {C} }^{m\times n}}$ and ${\displaystyle B\in {\mathbb {C} }^{n\times q}}$ that ${\displaystyle \|AB\|_{p}\leq \|A\|_{p}\|B\|_{q}}$. This is shown in Proposition 2.7.2 on the following page [1].

You are right that this could be added. So, why don't you change the article to include this? You can edit the article by clicking on "edit this page", see How to edit a page for details. Don't worry about making mistakes; you will be corrected if necessary. I look forward to your contributions, Jitse Niesen (talk) 11:24, 12 August 2005 (UTC)[reply]

It took me two days time to figure out that the statement on Wikipedia about submultiplicative property was misleading. As said, the submultiplicative property also holds for consistent p-norms, be it that in this case you are actually splitting ${\displaystyle \|Ax\|}$ in two different norms. That is probably the reason why it is mentioned that the submultiplicative property holds for square matrices only. However, in the special case of the 2-norm the definition this is wrong. But even without the special case it is misleading for the reader, as the "submultiplicative" definition is used in a much wider range than a norm that only splits in two equal norms. See page 5 of [2]. — Preceding unsigned comment added by 94.210.213.220 (talk) 14:00, 20 September 2016 (UTC)[reply]

Update: I edited the page. Can somebody check? Does it need references? — Preceding unsigned comment added by 94.210.213.220 (talk) 14:50, 20 September 2016 (UTC)[reply]

Moreover, when m = n, then for any vector norm | · |, there exists a unique
positive number k such that k| · | is a (submultiplicative) matrix norm.

A matrix norm || · || is said to be minimal if there exists no other matrix norm
| · | satisfying |A|≤||A|| for all |A|.

Doesn't |A| specify the absolute value? Using the correct notation yields ||A||≤||A|| for all ||A||. Isn't that self evident? Furthermore m and n are not specified. Therefore I have removed this section till someone can clarify this content. It looks as if though someone partially moved content such that it's meaning was lost. —The preceding unsigned comment was added by ANONYMOUS COWARD0xC0DE (talk • contribs) 02:53, 24 December 2006 (UTC).[reply]

So sorry; don't know what I was thinking. I will just change |A| to ||A||_q and ||A|| to ||A||_p, it's clear from the sentence what |A| refereed to. I was reading a book earlier and |A| was refereed to as the determinant of A. More-over I will just add these statements back in and reword them. --ANONYMOUS COWARD0xC0DE 01:06, 29 December 2006 (UTC)[reply]

*${\displaystyle \|A\|_{1}\leq {\sqrt {n}}\|A\|_{2}}$
*${\displaystyle \|A\|_{1}\leq n\|A\|_{\infty }}$
*${\displaystyle \|A\|_{2}\leq {\sqrt {n}}\|A\|_{1}}$
*${\displaystyle \|A\|_{2}\leq {\sqrt {n}}\|A\|_{\infty }}$
*${\displaystyle \|A\|_{\infty }\leq n\|A\|_{1}}$
*${\displaystyle \|A\|_{\infty }\leq {\sqrt {n}}\|A\|_{2}}$

These are properties of vectors of the form ${\displaystyle A\in \mathbb {R} ^{n}}$ and not of the form ${\displaystyle A\in \mathbb {R} ^{m\times n}}$. --ANONYMOUS COWARD0xC0DE 03:38, 24 December 2006 (UTC)[reply]

article is not really clear about the equivalence of norms: since we are talking about matrices of finite size, all vector norms should be equivalent. the bunch of inequalities in the bottom could (mis)lead the reader into thinking otherwise. if, in addition, submultiplicativity is required, does this change? (apparently so, the article seems to imply the Banach algebra topology is not unique.) Mct mht 14:08, 13 February 2007 (UTC)[reply]

it isn't true that the trace norm, sum(sigma), is <= the Frob. norm, sum(sigma^2); e.g. suppose all sigma<1. Lpwithers 16:34, 8 October 2007 (UTC)[reply]

The article doesn't explain why the "trace norm" is an "entry-wise norm". sattath (talk) 14:49, 23 July 2008 (UTC) Fixed. --sattath (talk) 13:02, 27 April 2011 (UTC)[reply]

I'm interested in learning about the gradient of the matrix norm but I can't seem to find this information within wikipedia. I guess I'm requesting a new article and I don't know where to do that, but it seems logical for this article to point me to the gradient of the norm (maybe under see also). —Preceding unsigned comment added by Arbitrary18 (talk • contribs) 01:00, 23 September 2008 (UTC)[reply]

Matrix norm on the set of all nxn matrices is a real value function, ||.|| defined on this set, satisfying for all nxn matrices A and B and all real number ${\displaystyle \alpha }$:

• ${\displaystyle \|A\|>0}$ if ${\displaystyle A\neq 0}$ and ${\displaystyle \|A\|=0}$ if and only if ${\displaystyle A=0}$
• ${\displaystyle \|\alpha A\|=|\alpha |\|A\|}$ for all ${\displaystyle \alpha }$ in ${\displaystyle K}$ and all matrices ${\displaystyle A}$ in ${\displaystyle K^{m\times n}}$
• ${\displaystyle \|A+B\|\leq \|A\|+\|B\|}$ for all matrices ${\displaystyle A}$ and ${\displaystyle B}$ in ${\displaystyle K^{m\times n}.}$
• ${\displaystyle \|AB\|\leq \|A\|\|B\|}$

@@@@

The two following functions are two examples of matrix norm:

${\displaystyle \left\|A\right\|_{1}=\max \limits _{1\leq j\leq n}\sum _{i=1}^{m}|a_{ij}|,}$

and

${\displaystyle \left\|A\right\|_{\infty }=\max \limits _{1\leq i\leq m}\sum _{j=1}^{n}|a_{ij}|,}$

For examples: With matrix A:

${\displaystyle {\begin{bmatrix}3&5&7\\2&-6&4\\0&2&8\\\end{bmatrix}}}$

We have: ${\displaystyle \left\|A\right\|_{1}=|7|+|4|+|8|=19}$

And:

${\displaystyle \left\|A\right\|_{\infty }}$ = |3|+|5|+|7|=15

Note: In the above example ${\displaystyle \left\|A\right\|_{1}}$ is the maximum absolute column sum of the matrix, and ${\displaystyle \left\|A\right\|_{\infty }}$ is the maximum absolute row sum of the matrix. In addition both ${\displaystyle \left\|A\right\|_{1}}$ and ${\displaystyle \left\|A\right\|_{\infty }}$ are the special norm of a general norm called p-norm for vectors

@@@@

In some of the definitions I wasn't sure if max should actually be the supremum. I thought a maximum is guaranteed to exist for compact sets of real numbers, but not necessarily for open sets. In the case of linear, finite-dimensional operators(open sets are mapped to open sets) wouldn't this be equivalent to the domain being compact? In the case of the induced norm that would imply (from my perspective) max in the case abs(x)<=1 and supremum in the case x not equal to zero. I am not sure if it is actually an issue or not because at least in case of the induced 2 norm, the supremum is actually part of the range. That in turn implies to me that the supremum is reached for any similarly defined induced norm because of the equivalence of norms in finite dimensional spaces. Can someone with experience maybe point out the disconnect I seem to be having? —Preceding unsigned comment added by 79.235.159.125 (talk) 18:49, 19 July 2010 (UTC)[reply]

The domain is usually a sphere. These are closed and bounded, and thus compact by Heine-Borel. — Preceding unsigned comment added by 79.131.226.245 (talk) 17:06, 1 August 2011 (UTC)[reply]

There is a statement in the article: "For a symmetric or hermitian matrix A, we have equality for the 2-norm, since in this case the 2-norm is the spectral radius of A"

I guess the equality actually holds for more general case: It holds for any diagonalizable A. (Note that symmetric/hermitian is a special case of diagonalizable matrices when the diagonalizing matrix are unitary, which in turn, is a special case of normal matrices. All these are diagonalizable.)

Trivial proof: Let A = P D P^-1. Then ${\displaystyle \|A\|={\sqrt {\lambda _{max}(A^{*}A)}}={\sqrt {\lambda _{max}((P^{-1})^{*}D^{*}P^{*}PDP^{-1})}}={\sqrt {\lambda _{max}((P^{-1})^{*}P^{*}D^{*}DPP^{-1})}}={\sqrt {\lambda _{max}(D^{*}D)}}}$ (since the set of eigenvalues of AB is same as the set of eigenvalue of BA)

Does anybody see any problem with this argument? - Subh83 (talk | contribs) 18:47, 7 February 2013 (UTC)[reply]

That argument was wrong. If ${\displaystyle \lambda (A)}$ gives the set of eigenvalues of matrix ${\displaystyle A}$, then ${\displaystyle \lambda (A_{1}A_{2}\cdots A_{n})=\lambda (A_{\sigma (1)}A_{\sigma (2)}\cdots A_{\sigma (n)})}$ if ${\displaystyle \sigma }$ is a cyclic permutation. - Subh83 (talk | contribs) 04:23, 8 February 2013 (UTC)[reply]

This article was very useful. I was getting confused with that double-meaning notation and this article clarified it. Sorry for my English.--147.83.79.107 (talk) 15:31, 19 October 2013 (UTC)[reply]

See WT:MATH#Proofs, revisited — Arthur Rubin (talk) 17:58, 29 September 2015 (UTC)[reply]

It would be much clearer if the definitions of the norms and their properties was more clearly demarcated. At present, being sub-multiplicative is defined at the top, but the fact that all induced norms are sub-multiplicative is just mentioned in passing in the discussion of induced norms. Contrast this to consistency, for which the fact that induced norms are consistent is mentioned next to the definition of consistency.

I would suggest one of the following two layouts:

1. Start with the definition of a matrix norm, and the formal definition of each property that such a norm might have. Then go through the definitions of induced, Frobenius etc. norms, with clear results for each norm on which properties it does (not) possess.
2. Start with the definition of a matrix norm, then go through the definitions of induced, Frobenius etc. norms as examples. Then go through the definitions of each property matrix norms might have, with clear results on which norms (do not) possess the given property.

In either approach, a table of norms and properties might help the presentation.

--cfp (talk) 20:56, 14 November 2015 (UTC)[reply]

I came here looking for an introduction to the concept of matrix norms and an understanding of why they are important and what their applications are. The article lacks any of this information - it would be very useful to have here. 36.53.254.212 (talk) 14:07, 22 December 2015 (UTC)[reply]

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Dear fellow Wikipedians,

Previously, the definition

${\displaystyle \|A\|_{\rm {F}}={\sqrt {\operatorname {trace} \left(A^{\textsf {T}}A\right)}},}$

was given for the Frobenius norm, which only holds for real matrices (without any reference to this restirction). I now changed this, adding the correct definition (using the notation ${\displaystyle A^{*}}$ for the conjugate transpose of ${\displaystyle A}$, which was used in other sections in this article), and I also changed the other parts of this section accordingly. One more thing: the inequality between the induced 2-norm and the Frobenius norm is mentioned before the Frobenius norm section, so probably we should change this.

Zimboras (talk) 12:19, 10 August 2019 (UTC)[reply]

The clashing notations here are so confusing. I see people use ||T||_p for the Schatten norms all the time, but I don't see this notation meaning something else. For the sake of having a readable article, I would suggest we use different notations for the other ones. Do other people think the other kinds of norms take precedence for this notation?

Sam W

2607:9880:1A18:10A:64C9:2106:FDEB:3FFD (talk) 06:58, 5 June 2021 (UTC)[reply]

The text as of 2013-03-29 claimed that ${\displaystyle |A|_{F}\leq {\sqrt {|A|_{1}|A|_{\infty }}}}$ as a matrix generalization of Hölder's inequality. It turns out this was for Schatten norm, not for induced p-norm. So I moved it to the Schatten norm section with a hint about how to derive it.

All induced vector norms upper bound the spectral radius, in particular,

${\displaystyle \|A\|_{2}={\sqrt {\rho (A^{*}A)}}\leq {\sqrt {\|A^{*}A\|_{\infty }}}\leq {\sqrt {\|A\|_{1}\|A\|_{\infty }}}}$

This is an important inequality, so I think it should be re-included on this page.

User:Jfessler

The section on the Frobenius norm contains this sentence:

"The Frobenius norm is sub-multiplicative and is very useful for numerical linear algebra. The sub-multiplicativity of Frobenius norm can be proved using Cauchy–Schwarz inequality."

It would be a useful improvement to this article if the meaning of this submultiplicativity were to be also stated in mathematical notation.

I hope someone knowledgeable about this subject can add the appropriate inequality to the article.