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Line 1: {{About\|machine learning\|the graph-theoretical notion\|Glossary of graph theory}} In [[structure mining]], a '''graph kernel''' is a [[Positive-definite kernel\|kernel function]] that computes an [[inner product space\|inner product]] on [[Graph (abstract data type)\|graphs]].<ref name="Vishwanathan">{{cite journal\|title=Graph kernels\|author1=S.V. N. Vishwanathan\|author2=Nicol N. Schraudolph\|author3=Risi Kondor\|author4=Karsten M. Borgwardt\|author4-link=Karsten Borgwardt\|journal=[[Journal of Machine Learning Research]]\|volume=11\|pages=1201–1242\|year=2010\|url=http://jmlr.csail.mit.edu/papers/volume11/vishwanathan10a/vishwanathan10a.pdf}}</ref> Graph kernels can be intuitively understood as functions measuring the similarity of pairs of graphs. They allow [[Kernel trick\|kernelized]] learning algorithms such as [[support vector machine]]s to work directly on graphs, without having to do [[feature extraction]] to transform them to fixed-length, real-valued [[feature vector]]s. They find applications in [[bioinformatics]], in [[chemoinformatics]] (as a type of [[molecule kernel]]s<ref name="Ralaivola2005">{{cite journal \|author1=L. Ralaivola \|author2=S. J. Swamidass \|author3=H. Saigo \|author4=P. Baldi \|title=Graph kernels for chemical informatics \|journal=Neural Networks \|year=2005 \|volume=18 \|issue=8 \|pages=1093–1110 \|doi=10.1016/j.neunet.2005.07.009\|pmid=16157471 }}</ref>), and in [[social network analysis]].<ref name="Vishwanathan"/> Line 12: \|url=http://people.cs.uchicago.edu/~risi/papers/diffusion-kernels.pdf }}</ref> as kernels ''on'' graphs, i.e. similarity functions between the nodes of a single graph, with the [[World Wide Web]] [[hyperlink]] graph as a suggested application. In 2003, ~~Gaertner~~Gärtner ''et al.''<ref name="Gaertner">{{cite conference \|title=On graph kernels: Hardness results and efficient alternatives \|author1=Thomas ~~Gaertner~~Gärtner \|author2=Peter A. Flach \|author3=Stefan Wrobel \|conference=Proc. the 16th Annual Conference on Computational Learning Theory (COLT) and the 7th Kernel Workshop Line 53: An example of a kernel between graphs is the '''random walk kernel''',<ref name="Gaertner"/><ref name="Kashima"/> which conceptually performs [[random walk]]s on two graphs simultaneously, then counts the number of [[Path (graph theory)\|path]]s that were produced by ''both'' walks. This is equivalent to doing random walks on the [[Tensor product of graphs\|direct product]] of the pair of graphs, and from this, a kernel can be derived that can be efficiently computed.<ref name="Vishwanathan"/> Another examples is the '''Weisfeiler-~~Lehman~~Leman graph kernel'''<ref>Shervashidze, Nino, et al. "Weisfeiler-lehman graph kernels." Journal of Machine Learning Research 12.9 (2011).</ref> which computes multiple rounds of the [[Weisfeiler-~~Lehman~~Leman algorithm]] and then computes the similarity of two graphs as the inner product of the histogram vectors of both graphs. In those histogram vectors the kernel collects the number of times a color occurs in the graph in every iteration. Note that the Weisfeiler-~~Lehman~~Leman kernel in theory has an infinite dimension as the number of possible colors assigned by the Weisfeiler-~~Lehman~~Leman algorithm is infinite. By restricting to the colors that occur in both graphs, the computation is still feasible. ==See also== Line 65: [[Category:Graph algorithms]] [[Category:Kernel methods for machine learning]] ~~{{comp-sci-stub}}~~ {{machine-learning-stub}}