Multivariable Burchnall–Chaundy theory

“…For now, we encode an existing algebraic construction into our framework that we expect to develop in a future work. Our approach is based to an extent on [28,29] and also in view of related work of other authors that is surveyed in [33] to which we refer for details.…”

Section: Iterated Laurent Seriesmentioning

confidence: 99%

“…More specifically, it is within this setting that we interpret the relevant conjugation principles of [32,35] where Baker functions are employed. Certain generalizations of [32,35] to several variables are studied in papers such as [28,29] (see also the survey article [33] and references therein). Although this latter work is essentially algebraic-geometric, we outline how the analogous conjugation results can be seen within the proposed setting of operator theory.…”

Section: Introductionmentioning

confidence: 99%

A Banach Algebra Version of the Sato Grassmannian and Commutative Rings of Differential Operators

2006

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We show that commutative rings of formal pseudodifferential operators can be conjugated as subrings in noncommutative Banach algebras of operators in the presence of certain eigenfunctions. Techniques involve those of the Sato Grassmannian as used in the study of the KP hierarchy as well as the geometry of an infinite dimensional Stiefel bundle with structure modeled on such Banach algebras. Generalizations of this procedure are also considered.

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“…. , ∂ n ], taking the greatest common divisor of all of these maximal minor determinants is equivalent to calculating the polynomial resultant [23]; while for ordinary differential operators with variable coefficients the definition reproduces the differential resultant used to construct the spectral curve [31]. The definition of the differential resultant of the operators L i given in [7] is, in our terminology, a particular partial μ-shifted differential resultant of the operators L i with all μ i = 0.…”

Section: Definitionsmentioning

confidence: 99%

Factorization and Resultants of Partial Differential Operators

Kasman

Превиато

2010

Math.Comput.Sci.

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Comparatively little is known about commutative rings of partial differential operators, while in the ordinary case, concrete examples and an algebraic(-geometric) structure can be algorithmically determined for large classes. In this note, by the calculation of the partial μ-shifted differential resultant which we defined in a previous paper, we produce algebraic equations of spectral surfaces for commutative rings in two variables, and Darboux transformations of Airy-type operators that correspond to morphisms of surfaces. There are, however, many elementary differential-algebraic statements that we only observe experimentally, thus we offer open questions which seem to us quite significant in differential algebra, and access to Mathematica code to enable further experimentation.Differential algebra in several variables has not yet reached the same stage of maturity as algebraic geometry [19]. We focus our effort in creating an algebraic theory of commuting PDOs. 1 There are several standing problems to consider.Problem I: Finding examples. Few and far between until the 1980s, classes of examples have now been developed by at least three methods: (1) representation theory, within the universal enveloping algebra of a Lie algebra, for instance by writing Casimirs; (2) quantization [13,14]; (3) flows of integrable hierarchies, when the flows are interpreted in differential-algebra terms under the boson-fermion correspondence [27].These three methods are related: examples of type (1) can also be given as quantized completely integrable systems as in (2), and the original motivation was that of deforming as in (3) Schrödinger operators in several variables;(3) has the interesting feature that the systematic procedures given (on a Sato-like Grassmannian) produce matrices [27], or n-tuples of commuting operators in n variables [28], as opposed to scalars. We display in Sect. 1 the most advanced examples we know of, whose spectral varieties could be studied by our methods. 1 We use throughout the paper the abbreviations ODO (PDO, DO) for ordinary (partial, (formal) pseudo-)differential operator, gcd for greatest common divisor.

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Multivariable Burchnall–Chaundy theory

Cited by 11 publications

References 47 publications

Baker-Akhiezer Modules on Rational Varieties

Baker-Akhiezer Modules on Rational Varieties

A Banach Algebra Version of the Sato Grassmannian and Commutative Rings of Differential Operators

Factorization and Resultants of Partial Differential Operators

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