Author_Institution :
Dept. of Electr. & Comput. Eng., Carnegie Mellon Univ., Pittsburgh, PA, USA
Abstract :
In social settings, individuals interact through webs of relationships. Each individual is a node in a complex network (or graph) of interdependencies and generates data, lots of data. We label the data by its source, or formally stated, we index the data by the nodes of the graph. The resulting signals (data indexed by the nodes) are far removed from time or image signals indexed by well ordered time samples or pixels. DSP, discrete signal processing, provides a comprehensive, elegant, and efficient methodology to describe, represent, transform, analyze, process, or synthesize these well ordered time or image signals. This paper extends to signals on graphs DSP and its basic tenets, including filters, convolution, z-transform, impulse response, spectral representation, Fourier transform, frequency response, and illustrates DSP on graphs by classifying blogs, linear predicting and compressing data from irregularly located weather stations, or predicting behavior of customers of a mobile service provider.
Keywords :
Fourier transforms; Z transforms; convolution; filtering theory; frequency response; graph theory; signal processing; transient response; Fourier transform; blogs; complex network; convolution; customer behaviour prediction; discrete signal processing; filters; frequency response; graph DSP; graph node; image signal; impulse response; irregularly-located weather stations; linear data compression; linear data prediction; mobile service provider; social settings; spectral representation; time signal; well-ordered time samples; z-transform; Digital signal processing; Fourier transforms; Graphical models; Laplace equations; Manifolds; Graph Fourier transform; Markov random fields; graphical models; network science; signal processing;
