325,349 research outputs found
Italian birds of passage, the diaspora of Neapolitan musicians in New York
the book is a revised version and English translation of Frasca S., Birds of Passage, [2010, LIM], made possible by a grant from SEPS (Segretariato Europeo per le Pubblicazioni Scientifiche), Università di Napoli "Federico II", and Fondazione Roberto Murol
BIRDS OF PASSAGE FRAMMENTI DI INTERVISTE TRA NAPOLI E NEW YORK
a lo-fi documentary which focuses on the Italian diaspora to US (1890-1940) seen through the perspective of musicians, performers, editors from the famous singers like Enrico Caruso to the most obscure vedette of vaudeville era. It's a collection of interviews which supports the book Birds of Passage - i musicisti napoletani a New York (1895-1940) by Simona Frasca, LIM Lucca, 2010
Salvatore Frasca. S. Giustino Martire, Apologie, S. Teojilo Antiocheno, I tre libri ad Autolieo, , 1938
Puech Aimé. Salvatore Frasca. S. Giustino Martire, Apologie, S. Teojilo Antiocheno, I tre libri ad Autolieo, , 1938. In: Journal des savants, Janvier-février 1939. pp. 40-41
A conservative numerical method for a time fractional diffusion equation
Geometric numerical integration, the branch of numerical analysis with the goal of finding approximate solutions of differential equations that preserve some structure of the continuous problem, is a well established field of research [5]. In particular, requiring that invariants or conservation laws are preserved, on one hand, applies on the approximations some constraints that are satisfied also by the exact solutions. On the other hand, it guarantees a better propagation of the error over long integration times [3].
In the last two decades, new techniques for finding conservation laws of fractional differential equations have been derived by suitably generalising methods for PDEs [4, 6]. However, the numerical preservation of conservation laws of time fractional differential
equations is a research topic still at an embryonic state. This talk deals with the numerical solution of diffusion equations in the form
D^α_t u = D^2_x K(u), α ∈ R,
where D_x is the partial derivative in space, K is an arbitrary regular function, and D^α_t
denotes the Riemann-Liouville fractional derivative of order α.
The proposed numerical method combines a finite difference scheme in space with a spectral time integrator and preserves discrete versions of the conservation laws of the original differential equation [1, 2].
The conservative and convergence properties of the proposed method are verified by the computational solution of some numerical experiments.
References
[1] K. Burrage, A. Cardone, R. D’Ambrosio, B. Paternoster. Numerical solution of time fractional diffusion systems. Appl. Numer. Math., 116 (2017), 82–94.
[2] A. Cardone, G. Frasca-Caccia. Numerical conservation laws of time fractional diffusion PDEs. arXiv.2203.01966, (2022).
[3] A. Dur ́an, J. M. Sanz-Serna. The numerical integration of relative equilibrium solutions. Geometric theory. Nonlinearity, 11, 1547–1567, (1998).
[4] G. S. F. Frederico, D. F. M. Torres. Fractional conservation laws in optimal control theory. Nonlinear Dyn., 53 (2008), 215–222.
[5] E. Hairer, C. Lubich, G. Wanner. Geometric Numerical Integration. Structure Preserving Algorithms for Ordinary Differential Equations, volume 31 of Springer Series in Computational Mathematics. Springer, Berlin, second edition, 2006.
[6] S. Y. Lukashchuk. Conservation laws for time-fractional subdiffusion and diffusionwave equations. Nonlinear Dyn., 80 (2015), 791–80
Memory of the oblivion: the untold story of the Neapolitan musicians in New York (1900-1935)
- …
