NOTE ON THE STRONG LIMIT POINT CONDITION OF SECOND ORDER DIFFERENTIAL EXPRESSIONS

SynopsisThis paper is concerned with some properties of an ordinary symmetric matrix differential expression M, denned on a certain class of vector-functions, each of which is defined on the real line. For such a vector-function F we have M[F] = −F“ + QF on R, where Q is an n × n matrix whose elements are reasonably behaved on R. M is classified in an equivalent of the limit-point condition at the singular points ± ∞, and conditions on the matrix coefficient Q are given which place M, when n> 1, in the equivalent of the strong limit-point for the case n = 1. It is also shown that the same condition on Q establishes the integral inequality for a certain class of vector-functions F.

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On the strong limit-point and Dirichlet properties of second order differential expressions

Proceedings of the Royal Society of Edinburgh Section A Mathematics ◽

10.1017/s0308210500020837 ◽

1985 ◽

Vol 101 (3-4) ◽

pp. 283-296 ◽

Cited By ~ 2

Author(s):

D. Race

Keyword(s):

Weight Function ◽

Limit Point ◽

Second Order ◽

Strong Limit ◽

Positive Weight ◽

End Point

SynopsisSecond order differential expressions of the form w−1(−(pf′)′ + qf) are considered at a singular end-point. Some of the known relationships between properties such as Dirichlet, weak Dirichlet and strong limit-point, are extended to incorporate an arbitrary, positive weight function and complexvalued coefficients.

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Fractional linear maps in general relativity and quantum mechanics

International Journal of Geometric Methods in Modern Physics ◽

10.1142/s0219887821501577 ◽

2021 ◽

pp. 2150157

Author(s):

Vito Flavio Bellino ◽

Giampiero Esposito

Keyword(s):

Differential Equation ◽

General Relativity ◽

Quantum Mechanics ◽

Limit Point ◽

Fundamental System ◽

Second Order ◽

Positive Real ◽

Linear Maps ◽

Point Condition ◽

Positive Real Line

This paper studies the nature of fractional linear transformations in a general relativity context as well as in a quantum theoretical framework. Two features are found to deserve special attention: the first is the possibility of separating the limit-point condition at infinity into loxodromic, hyperbolic, parabolic and elliptic cases. This is useful in a context in which one wants to look for a correspondence between essentially self-adjoint spherically symmetric Hamiltonians of quantum physics and the theory of Bondi–Metzner–Sachs transformations in general relativity. The analogy therefore arising suggests that further investigations might be performed for a theory in which the role of fractional linear maps is viewed as a bridge between the quantum theory and general relativity. The second aspect to point out is the possibility of interpreting the limit-point condition at both ends of the positive real line, for a second-order singular differential operator, which occurs frequently in applied quantum mechanics, as the limiting procedure arising from a very particular Kleinian group which is the hyperbolic cyclic group. In this framework, this work finds that a consistent system of equations can be derived and studied. Hence, one is led to consider the entire transcendental functions, from which it is possible to construct a fundamental system of solutions of a second-order differential equation with singular behavior at both ends of the positive real line, which in turn satisfy the limit-point conditions. Further developments in this direction might also be obtained by constructing a fundamental system of solutions and then deriving the differential equation whose solutions are the independent system first obtained. This guarantees two important properties at the same time: the essential self-adjointness of a second-order differential operator and the existence of a conserved quantity which is an automorphic function for the cyclic group chosen.

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