Regularity Structure of Conservative Solutions to the Hunter-Saxton Equation

In this paper we characterize the regularity structure, as well as show the global-in-time existence and uniqueness, of (energy) conservative solutions to the Hunter-Saxton equation by using the method of characteristics. The major difference between the current work and previous results is that we are able to characterize the singularities of energy measure and their nature in a very precise manner. In particular, we show that singularities, whose temporal and spatial locations are also explicitly given in this work, may only appear at at most countably many times, and are completely determined by the absolutely continuous part of initial energy measure. Our mathematical analysis is based on using the method of characteristics in a generalized framework that consists of the evolutions of solution to the Hunter-Saxton equation and the energy measure. This method also provides a clear description of the semi-group property for the solution and energy measure for all times. Keywrods: formulation of singularity, well-posedness, integrable system, decomposition of energy measure, semi-group property

[1]  A Lipschitz metric for the Hunter–Saxton equation , 2016, Communications in Partial Differential Equations.

[2]  C. Dafermos GENERALIZED CHARACTERISTICS AND THE HUNTER–SAXTON EQUATION , 2011 .

[3]  H. Whitney Analytic Extensions of Differentiable Functions Defined in Closed Sets , 1934 .

[4]  J. K. Hunter,et al.  On a nonlinear hyperbolic variational equation: I. Global existence of weak solutions , 1995 .

[5]  Ping Zhang,et al.  Asymptotic Variational Wave Equations , 2005 .

[6]  Xavier Raynaud,et al.  Lipschitz metric for the Hunter–Saxton equation☆ , 2009, 0904.3615.

[7]  J. K. Hunter,et al.  Dynamics of director fields , 1991 .

[8]  Alberto Bressan,et al.  Uniqueness of Conservative Solutions to the Camassa-Holm Equation via Characteristics , 2014, 1401.0312.

[9]  A. Bressan,et al.  Unique Conservative Solutions to a Variational Wave Equation , 2014, 1411.2012.

[10]  J. K. Hunter,et al.  On a nonlinear hyperbolic variational equation: II. The zero-viscosity and dispersion limits , 1995 .

[11]  Ping Zhang,et al.  Existence and Uniqueness of Solutions¶of an Asymptotic Equation¶Arising from a Variational Wave Equation¶with General Data , 2000 .

[12]  Ping Zhang,et al.  On oscillations of an asymptotic equation of a nonlinear variational wave equation , 1998 .

[13]  L. Evans Measure theory and fine properties of functions , 1992 .

[14]  C. Dafermos Maximal dissipation in equations of evolution , 2012 .

[15]  Ping Zhang,et al.  On the existence and uniqueness of solutions to an asymptotic equation of a variational wave equation , 1999 .

[16]  John J. Benedetto,et al.  Integration and Modern Analysis , 2009, Birkhäuser Avanced texts.

[17]  G. Jamróz,et al.  Maximal dissipation in Hunter-Saxton equation for bounded energy initial data , 2014, 1405.7558.

[18]  Hlawka Theory of the integral , 1939 .

[19]  Alberto Bressan,et al.  Global Solutions of the Hunter-Saxton Equation , 2005, SIAM J. Math. Anal..

[20]  J. Serrin,et al.  A General Chain Rule for Derivatives and the Change of Variables Formula for the Lebesgue Integral , 1969 .

[21]  A. Bressan Uniqueness of conservative solutions for nonlinear wave equations via characteristics , 2016 .