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- ...tors. The projection operation is a powerful geometric tool that makes the inner product a desirable convenience, especially for the purposes of [[optimization (mat ==Formal definition of inner product==3 KB (511 words) - 00:25, 20 February 2010
- ...rm on the vector space on which it is defined. A [[completeness|complete]] inner product space is called a [[Hilbert space]]. ==Examples of inner product spaces==1 KB (204 words) - 14:38, 4 January 2009
- 12 bytes (1 word) - 21:15, 6 October 2007
- 135 bytes (19 words) - 15:24, 28 November 2008
- 170 bytes (21 words) - 15:29, 28 November 2008
- 12 bytes (1 word) - 21:23, 6 October 2007
- {{r|Inner product space}}905 bytes (145 words) - 15:27, 28 November 2008
- A vector space that is endowed with an inner product and the corresponding norm.116 bytes (17 words) - 13:40, 4 January 2009
- {{r|Inner product}}940 bytes (149 words) - 15:13, 28 July 2009
Page text matches
- * [[inner product]], a generalisation of the above in an abstract vector space.242 bytes (36 words) - 12:38, 31 May 2009
- {{r|Inner product}}798 bytes (103 words) - 16:04, 11 January 2010
- ...rm on the vector space on which it is defined. A [[completeness|complete]] inner product space is called a [[Hilbert space]]. ==Examples of inner product spaces==1 KB (204 words) - 14:38, 4 January 2009
- {{r|Inner product space}}338 bytes (42 words) - 19:08, 5 October 2009
- ...n two vectors (resulting into a vector) and the symbol "•" stands for an [[inner product]] of two vectors (resulting into a scalar).519 bytes (83 words) - 03:13, 15 January 2009
- {{r|Inner product space}} {{r|Inner product}}366 bytes (48 words) - 11:31, 27 July 2008
- A complete inner product space.67 bytes (8 words) - 12:32, 4 January 2009
- ...tors. The projection operation is a powerful geometric tool that makes the inner product a desirable convenience, especially for the purposes of [[optimization (mat ==Formal definition of inner product==3 KB (511 words) - 00:25, 20 February 2010
- ..." definition for it. In fact, in this case the contrary is true: it is the inner product which is defined directly while the notion of an angle is ''derived'' from3 KB (575 words) - 12:41, 14 February 2011
- real finite-dimensional inner product space; possibly with translations defined on it.122 bytes (14 words) - 04:50, 2 September 2009
- A vector space that is endowed with an inner product and the corresponding norm.116 bytes (17 words) - 13:40, 4 January 2009
- ...uct]] of two vectors (resulting into a vector) and the dot indicates the [[inner product]] between two vectors (a scalar).4 KB (583 words) - 13:16, 25 November 2009
- linear operator on an inner product space that is equal to its Hermitian adjoint; also called self-adjoint oper152 bytes (21 words) - 08:31, 9 July 2009
- ...ear functional over a complex (real) Hilbert space can be expressed as the inner product of elements of that space with some fixed element of the space (this is kno [[Inner product space]]2 KB (258 words) - 12:33, 4 January 2009
- The notation ⟨ψ|φ⟩ for the inner product of ψ and φ, and related notations.137 bytes (20 words) - 13:59, 26 July 2008
- ...elates the absolute value of the [[inner product]] of two elements of an [[inner product space]] with the magnitude of the two said vectors. It is named in the hono ==The inequality for inner product spaces==4 KB (629 words) - 16:46, 17 December 2008
- Polynomials ''H''<sub>''n''</sub> that are orthogonal with respect to an inner product defined as <math>\left(H_{n'},H_n\right)\equiv\int_{-\infty}^{\infty} H_{n'241 bytes (43 words) - 09:11, 30 January 2009
- *[[Riemann manifold]] Differentiable [[manifold]] with non-degenerate [[inner product]].310 bytes (33 words) - 07:04, 7 February 2009
- {{r|Inner product}}347 bytes (48 words) - 14:08, 26 July 2008
- {{r|Inner product space}}359 bytes (48 words) - 15:04, 28 July 2009