Persistent Topological Laplacians -- a Survey

Persistent topological Laplacians constitute a new class of tools in topological data analysis (TDA), motivated by the necessity to address challenges encountered in persistent homology when handling complex data. These Laplacians combines multiscale analysis with topological techniques to characterize the topological and geometrical features of functions and data. Their kernels fully retrieve the topological invariants of persistent homology, while their nonharmonic spectra provide supplementary information, such as the homotopic shape evolution of data. Persistent topological Laplacians have demonstrated superior performance over persistent homology in addressing large-scale protein engineering datasets. In this survey, we offer a pedagogical review of persistent topological Laplacians formulated on various mathematical objects, including simplicial complexes, path complexes, flag complexes, diraphs, hypergraphs, hyperdigraphs, cellular sheaves, as well as $N$-chain complexes. Alongside fundamental mathematical concepts, we emphasize the theoretical formulations associated with various persistent topological Laplacians and illustrate their applications through numerous simple geometric shapes.