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- In [[mathematics]], a '''self-adjoint operator''' is a [[denseness|densely]] defined [[linear operator]] mapping a [[compl On an infinite dimensional Hilbert space, a self-adjoint operator can be thought of as the analogy of a real symmetric [[matrix]] (i.e., a4 KB (709 words) - 06:58, 23 December 2008
- 12 bytes (1 word) - 06:15, 9 November 2007
- 98 bytes (12 words) - 19:18, 4 September 2009
- Auto-populated based on [[Special:WhatLinksHere/Self-adjoint operator]]. Needs checking by a human.598 bytes (75 words) - 20:17, 11 January 2010
Page text matches
- ...an inner product space that is equal to its Hermitian adjoint; also called self-adjoint operator.152 bytes (21 words) - 08:31, 9 July 2009
- {{r|Self-adjoint operator}}296 bytes (36 words) - 18:51, 12 July 2008
- Auto-populated based on [[Special:WhatLinksHere/Self-adjoint operator]]. Needs checking by a human.598 bytes (75 words) - 20:17, 11 January 2010
- In [[mathematics]], a '''self-adjoint operator''' is a [[denseness|densely]] defined [[linear operator]] mapping a [[compl On an infinite dimensional Hilbert space, a self-adjoint operator can be thought of as the analogy of a real symmetric [[matrix]] (i.e., a4 KB (709 words) - 06:58, 23 December 2008
- {{r|Self-adjoint operator}}467 bytes (59 words) - 17:10, 11 January 2010
- {{r|Self-adjoint operator}}207 bytes (24 words) - 18:14, 26 August 2009
- {{r|Self-adjoint operator}}949 bytes (118 words) - 16:12, 11 January 2010
- {{r|Self-adjoint operator}}585 bytes (74 words) - 17:10, 11 January 2010
- {{r|Self-adjoint operator}}678 bytes (85 words) - 18:36, 11 January 2010
- {{r|Self-adjoint operator}}645 bytes (81 words) - 21:03, 11 January 2010
- ...or''' is the physicist's version of an object that mathematicians call a [[self-adjoint operator]]. It is a linear operator on a vector space ''V'' that is equipped with po8 KB (1,273 words) - 11:29, 9 July 2009
- ...ilbert space, and physical quantities or "observables" are postulated as [[self-adjoint operator]]s on that Hilbert space. States serve to assign statistical properties to2 KB (258 words) - 12:33, 4 January 2009
- {{r|Self-adjoint operator}}1 KB (157 words) - 19:35, 11 January 2010
- ...tyle="vertical-align: top"><math>\hat{T}^\dagger\hat{T}</math></font> is [[self-adjoint operator|self-adjoint]] and [[positive definite]], i.e., An important example of a trace class operator is the exponential of the self-adjoint operator ''H'',12 KB (1,903 words) - 10:57, 2 February 2009
- ...ove [[boundary value problem|boundary condition]]s. Moreover, ''L'' is a [[self-adjoint operator]].15 KB (2,332 words) - 04:52, 18 October 2009
- Using the [[self-adjoint operator|self-adjointness]] of ''H'' and the definition of a [[commutator]] one has7 KB (1,257 words) - 03:23, 24 March 2010
- ...the system. To every observable of the system, there is a corresponding [[self-adjoint operator]], that is to say one whose matrix is [[Hermitian matrix|Hermitian]]. Upon3 KB (562 words) - 00:00, 17 February 2010
- The operator ''H'' is [[self-adjoint operator|Hermitian]] and contains second derivatives. The Rayleigh-Ritz method appli12 KB (1,893 words) - 04:51, 25 March 2010
- ...the [[electron]]s and [[Atomic nucleus|nuclei]] in a [[molecule]]. This [[Self-adjoint operator|Hermitian operator]] plays a central role in [[computational chemistry]] an31 KB (4,757 words) - 02:20, 27 October 2013
- 17 KB (2,678 words) - 10:12, 9 May 2011