L-semi-inner product - meaning and definition. What is L-semi-inner product
Diclib.com
ChatGPT AI Dictionary
Enter a word or phrase in any language 👆
Language:

Translation and analysis of words by ChatGPT artificial intelligence

On this page you can get a detailed analysis of a word or phrase, produced by the best artificial intelligence technology to date:

  • how the word is used
  • frequency of use
  • it is used more often in oral or written speech
  • word translation options
  • usage examples (several phrases with translation)
  • etymology

What (who) is L-semi-inner product - definition


L-semi-inner product         
GENERALIZATION OF INNER PRODUCTS THAT APPLIES TO ALL NORMED SPACES
Semi-inner-products; Semi-inner-product; Semi-inner product; Semi-inner product in the sense of Lumer
In mathematics, there are two different notions of semi-inner-product. The first, and more common, is that of an inner product which is not required to be strictly positive.
Inner product space         
  • Scalar product spaces, over any field, have "scalar products" that are symmetrical and linear in the first argument. Hermitian product spaces are restricted to the field of complex numbers and have "Hermitian products" that are conjugate-symmetrical and linear in the first argument. Inner product spaces may be defined over any field, having "inner products" that are linear in the first argument, conjugate-symmetrical, and positive-definite. Unlike inner products, scalar products and Hermitian products need not be positive-definite.
REAL OR COMPLEX VECTOR SPACE WITH AN ADDITIONAL STRUCTURE CALLED AN INNER PRODUCT
Linear Algebra/Inner Product Space; Inner product; Inner-product space; Inner products; Pre-Hilbert space; Inner Product Space; Inner product spaces; Scalar product space; Prehilbert space; Unitary space; Inner-product; Orthogonal vector; Orthogonal vectors; Inner product of vectors; Hermitian inner product; Orthogonal vectors (inner product space)
In mathematics, an inner product space (or, rarely, a Hausdorff pre-Hilbert space) is a real vector space or a complex vector space with an operation called an inner product. The inner product of two vectors in the space is a scalar, often denoted with angle brackets such as in \langle a, b \rangle.
inner product         
  • Scalar product spaces, over any field, have "scalar products" that are symmetrical and linear in the first argument. Hermitian product spaces are restricted to the field of complex numbers and have "Hermitian products" that are conjugate-symmetrical and linear in the first argument. Inner product spaces may be defined over any field, having "inner products" that are linear in the first argument, conjugate-symmetrical, and positive-definite. Unlike inner products, scalar products and Hermitian products need not be positive-definite.
REAL OR COMPLEX VECTOR SPACE WITH AN ADDITIONAL STRUCTURE CALLED AN INNER PRODUCT
Linear Algebra/Inner Product Space; Inner product; Inner-product space; Inner products; Pre-Hilbert space; Inner Product Space; Inner product spaces; Scalar product space; Prehilbert space; Unitary space; Inner-product; Orthogonal vector; Orthogonal vectors; Inner product of vectors; Hermitian inner product; Orthogonal vectors (inner product space)
<mathematics> In linear algebra, any linear map from a vector space to its dual defines a product on the vector space: for u, v in V and linear g: V -> V' we have gu in V' so (gu): V -> scalars, whence (gu)(v) is a scalar, known as the inner product of u and v under g. If the value of this scalar is unchanged under interchange of u and v (i.e. (gu)(v) = (gv)(u)), we say the inner product, g, is symmetric. Attention is seldom paid to any other kind of inner product. An inner product, g: V -> V', is said to be positive definite iff, for all non-zero v in V, (gv)v > 0; likewise negative definite iff all such (gv)v < 0; positive semi-definite or non-negative definite iff all such (gv)v >= 0; negative semi-definite or non-positive definite iff all such (gv)v <= 0. Outside relativity, attention is seldom paid to any but positive definite inner products. Where only one inner product enters into discussion, it is generally elided in favour of some piece of syntactic sugar, like a big dot between the two vectors, and practitioners don't take much effort to distinguish between vectors and their duals. (1997-03-16)