CANT
发表于 2025-3-28 17:29:35
Convolution Equations on a Finite Interval,on .. and on .. (0,.) and on .. (0, .). Here ... (0, .) denotes the Banach space of all functions . =(.........). on (0, .) with ..,...,.. in ..(0, .) and with.We will abbreviate this norm to ‖. ‖ .. .. is defined similarly. An operator in the form of (0.1) we will refer to simply as a convolution operator on a finite interval.
蛰伏
发表于 2025-3-28 19:16:51
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mutineer
发表于 2025-3-28 23:46:32
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Mindfulness
发表于 2025-3-29 04:24:34
Orthogonal Matrix Polynomials,This chapter is devoted to proving a matrix version of Krein’s Theorem. The proof relies on methods that are different from those used in the scalar case.
EPT
发表于 2025-3-29 07:54:19
Orthogonal Operator-Valued Polynomials: First Generalization,In this chapter we will prove the first of two generalizations of Krein’s Theorem for operator-valued polynomials. The results of this chapter will be generalized in Chapter 9.
伙伴
发表于 2025-3-29 13:16:08
Orthogonal Operator-Valued Polynomials,The main topic of this chapter is the second generalization of Krein’s Theorem for operator-valued polynomials. (See Chapter 6 for the first.) Here we consider the case in which no compactness assumption are made on the coefficients.
Expostulate
发表于 2025-3-29 18:16:18
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平常
发表于 2025-3-29 22:52:01
,Discrete Infinite Analogue of Krein’s Theorem,In this chapter we obtain a generalization of Krein’s Theorem for a new case in which the finite block Toeplitz matrix of Chapter 5 is replaced by an infinite one. The role of the orthogonal matrix polynomials is played by orthogonal matrix functions.
keloid
发表于 2025-3-30 00:08:40
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支柱
发表于 2025-3-30 07:11:36
978-3-0348-9418-0Springer Basel AG 2003