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Vector spaces are the principal object of study in linear algebra. A vector space is always defined with respectto a field of scalars.
A field is a set equipped with two operations, addition and mulitplication, and containing two special members 0 and 1( ), such that for all
,,
Let be a field, and a set. We say is a vector space over if there exist two operations, defined for all , and :
Throughout this course we will think of a signal as a vector The samples could be samples from a finite duration, continuous time signal, for example.
A signal will belong to one of two vector spaces:
(over)
(over)
Let be a vector space over .
A subset is called a subspace of if is a vector space over in its own right.
is a subspace if and only if for all and and for all and ,
Let .
We say that these vectors are linearly dependent if there exist scalars such that
If only holds for the case , we say that the vectors are linearly independent .
so these vectors are linearly dependent in .
Consider the subset . Define the span of
Fact: is a subspace of .
, , , , .
If is infinite, the notions of linear independence and span are easily generalized:
We say is linearly independent if, for every finite collection , ( arbitrary) we have The span of is
A set is called a basis for over if and only if
= (real or complex) Euclidean space, or . where the 1 is in the position.
over. which is the DFT basis. where .
If is a basis for , then every can be written uniquely (up to order of terms) in the form where and .
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