Linear operators. 2. Spectral theory : self adjoint operators in Hilbert Space |
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Page 940
The function f is said to be finite dimensional if its set { f ' ise G } of translates is a finite dimensional vector space of functions . - The spectral theorem will be used in the proof of the following theorem and so the field of ...
The function f is said to be finite dimensional if its set { f ' ise G } of translates is a finite dimensional vector space of functions . - The spectral theorem will be used in the proof of the following theorem and so the field of ...
Page 1092
( If there are only a finite number N of non - zero eigenvalues , we write an ( T ) = 0 , n > N ) . ... Let S be a finite - dimensional space including both the range of T and the range of T * ; suppose that the dimension of S is d .
( If there are only a finite number N of non - zero eigenvalues , we write an ( T ) = 0 , n > N ) . ... Let S be a finite - dimensional space including both the range of T and the range of T * ; suppose that the dimension of S is d .
Page 1146
Any finite dimensional representation of a compact group G is a direct sum of irreducible representations . This theorem shows that in studying finite dimensional representations of a compact group G we may , without loss of generality ...
Any finite dimensional representation of a compact group G is a direct sum of irreducible representations . This theorem shows that in studying finite dimensional representations of a compact group G we may , without loss of generality ...
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