In the area of mathematics known as graph theory, a tree is said to be starlike if it has exactly one vertex of degree greater than 2. This high-degree vertex is the root and a starlike tree is obtained by attaching at least three linear graphs to this central vertex.
Properties
Two finite starlike trees are isospectral, i.e. their graph Laplacians have the same spectra, if and only if they are isomorphic. [1] The graph Laplacian has always only one eigenvalue equal or greater than 4. [2]
References
- ^ M. Lepovic, I. Gutman (2001). No starlike trees are cospectral.
- ^ Nakatsukasa, Yuji; Saito, Naoki; Woei, Ernest (April 2013). "Mysteries around the Graph Laplacian Eigenvalue 4". Linear Algebra and Its Applications. 438 (8): 3231–46. arXiv: 1112.4526. doi: 10.1016/j.laa.2012.12.012.
External links
- Weisstein, Eric W. "Spider Graph". MathWorld.
- (sequence A004250 in the OEIS)
.svg){kind=small} | This combinatorics-related article is a stub. You can help Wikipedia by expanding it. |
In the area of mathematics known as graph theory, a tree is said to be starlike if it has exactly one vertex of degree greater than 2. This high-degree vertex is the root and a starlike tree is obtained by attaching at least three linear graphs to this central vertex.
Properties
Two finite starlike trees are isospectral, i.e. their graph Laplacians have the same spectra, if and only if they are isomorphic. [1] The graph Laplacian has always only one eigenvalue equal or greater than 4. [2]
References
- ^ M. Lepovic, I. Gutman (2001). No starlike trees are cospectral.
- ^ Nakatsukasa, Yuji; Saito, Naoki; Woei, Ernest (April 2013). "Mysteries around the Graph Laplacian Eigenvalue 4". Linear Algebra and Its Applications. 438 (8): 3231–46. arXiv: 1112.4526. doi: 10.1016/j.laa.2012.12.012.
External links
- Weisstein, Eric W. "Spider Graph". MathWorld.
- (sequence A004250 in the OEIS)
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