Tensor decomposition

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In multilinear algebra, a tensor decomposition ^[1][2] is any scheme for expressing a tensor as a sequence of elementary operations acting on other, often simpler tensors. Many tensor decompositions generalize some matrix decompositions.^[3]

Tensors are generalizations of matrices to higher dimensions and can consequently be treated as multidimensional fields ^[4]. The main tensor decompositions are:

• Tensor rank decomposition^[5];
• Higher-order singular value decomposition;
• Tucker decomposition;
• matrix product states, and operators or tensor trains;
• Online Tensor Decompositions^[6][7];
• hierarchical Tucker decomposition; and
• block term decomposition^[8][9].

This section introduces basic notations and operations that are widely used in the field. A summary of symbols that we use through the whole thesis can be found in the table ^[10]

Table of symbols and their description.

Symbols	Definition
${\displaystyle {\mathbf {A} ,\mathbf {a} ,a}}$	Matrix, Column vector, Scalar
${\displaystyle {\mathbb {R} }}$	Set of Real Numbers
${\displaystyle {vec()}}$	Vectorization operator

A multi-view graph with K views is a collection of K matrices ${\displaystyle {X_{1},X_{2}.....X_{K}}}$ with dimensions I × J (where I, J are the number of nodes). This collection of matrices is naturally represented as a tensor X of size I × J × K. In order to avoid overloading the term “dimension”, we call an I × J × K tensor a three “mode” tensor, where “modes” are the numbers of indices used to index the tensor.

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