Dyad

A linear transformation on a Hilbert space

$$ x \rightarrow ( a , x ) b , $$

where $ a $ and $ b $ are certain constant vectors and $ ( \cdot , \cdot ) $ is the inner product. The importance of a dyad is due to the fact that, for example, in an $ n $- dimensional space any linear transformation $ A $ can be represented as the sum of at most $ n $ dyads:

$$ A x = \sum _ {i = 1 } ^ { n } ( a _ {i} , x ) {b ^ {i} } $$

(in an arbitrary Hilbert space a similar decomposition is valid for special classes of linear operators, for example self-adjoint operators, where $ a _ {i} $ and $ b ^ {i} $ can be chosen to form a biorthogonal system). Attempts were made in the 19th century to base the theory of linear operators on the concept of a dyad — the so-called "dyadic calculus" — but the term dyad is used only rarely in our own days.

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