@article { author = {Shen, Zhongmin}, title = {Weighted Ricci curvature in Riemann-Finsler geometry}, journal = {AUT Journal of Mathematics and Computing}, volume = {2}, number = {2}, pages = {117-136}, year = {2021}, publisher = {Amirkabir University of Technology}, issn = {2783-2449}, eissn = {2783-2287}, doi = {10.22060/ajmc.2021.20473.1067}, abstract = {Ricci curvature is one of the important geometric quantities in Riemann-Finsler geometry. Together with the $S$-curvature, one can define a weighted Ricci curvature for a pair of Finsler metric and a volume form on a manifold. One can build up a bridge from Riemannian geometry to Finsler geometry via geodesic fields. Then one can estimate the Laplacian of a distance function and the mean curvature of a metric sphere under a lower weighted Ricci curvature by applying the results in the Riemannian setting. These estimates also give rise to a volume comparison of Bishop-Gromov type for Finsler metric measure manifolds.}, keywords = {Ricci curvature,$S$-curvature,Mean curvature}, url = {https://ajmc.aut.ac.ir/article_4500.html}, eprint = {https://ajmc.aut.ac.ir/article_4500_fc3d11fc673b4e9a44f3b4e11ecbea4e.pdf} } @article { author = {Gangopadhyay, Ranadip and Shriwastawa, Anjali and Tiwari, Bankteshwar}, title = {On Finsler warped product metrics with vanishing $E$-curvature}, journal = {AUT Journal of Mathematics and Computing}, volume = {2}, number = {2}, pages = {137-142}, year = {2021}, publisher = {Amirkabir University of Technology}, issn = {2783-2449}, eissn = {2783-2287}, doi = {10.22060/ajmc.2021.19817.1052}, abstract = {In this paper, we study Finsler warped product metric recently introduced by P. Marcal and Z. Shen and find characteristics differential equations for this metric to have vanishing $E$-curvature. We also prove that if this warped product Finsler metric is projectively flat, then it becomes a Riemannian metric.}, keywords = {Finsler metrics,Warped product,$E$-curvature,Projectively flat}, url = {https://ajmc.aut.ac.ir/article_4408.html}, eprint = {https://ajmc.aut.ac.ir/article_4408_e2b7950e3ec1b2c81470a755e81bd591.pdf} } @article { author = {Sengelen Sevim, Esra and Gabrani, Mehran}, title = {On Finsler metrics with weakly isotropic $S$-curvature}, journal = {AUT Journal of Mathematics and Computing}, volume = {2}, number = {2}, pages = {143-151}, year = {2021}, publisher = {Amirkabir University of Technology}, issn = {2783-2449}, eissn = {2783-2287}, doi = {10.22060/ajmc.2021.20129.1054}, abstract = {In this paper, we focus on a class of Finsler metrics which are called general $(\alpha,\beta)$-metrics: $\alpha= \sqrt{a_{ij}(x)y^{i}y^{j}}$ is a Riemannian metric and $\beta= b_{i}(x)y^{i}$ is a $1$-form. We examine the metrics as weakly isotropic $S$-curvature.}, keywords = {Finsler metrics,General $(\alpha,\beta)$-metrics,$S$-curvature,Weak isotropic $S$-curvature}, url = {https://ajmc.aut.ac.ir/article_4460.html}, eprint = {https://ajmc.aut.ac.ir/article_4460_448261fee675bbb6a2343ca58d666440.pdf} } @article { author = {Balan, Vladimir}, title = {On spectral data and tensor decompositions in Finslerian framework}, journal = {AUT Journal of Mathematics and Computing}, volume = {2}, number = {2}, pages = {153-163}, year = {2021}, publisher = {Amirkabir University of Technology}, issn = {2783-2449}, eissn = {2783-2287}, doi = {10.22060/ajmc.2021.20213.1059}, abstract = {The extensions of the Riemannian structure include the Finslerian one, which provided in recent years successful models in various fields like Biology, Physics, GTR, Monolayer Nanotechnology and Geometry of Big Data. The present article provides the necessary notions on tensor spectral data and on the HO-SVD and the Candecomp tensor decompositions, and further study several aspects related to the spectral theory of the main symmetric Finsler tensors, the fundamental and the Cartan tensor. In particular, are addressed two Finsler models used in Langmuir Blodgett Nanotechnology and in Oncology. As well, the HO-SVD and Candecomp decompositions are exemplified for these models and metric extensions of the eigen problem are proposed.}, keywords = {pseudo-Finsler structure,symmetric tensors,spectral data,Cartan tensor,HO-SVD decomposition,Candecomp approximation}, url = {https://ajmc.aut.ac.ir/article_4459.html}, eprint = {https://ajmc.aut.ac.ir/article_4459_947f96ebced3789262a7bcbdaca6241d.pdf} } @article { author = {Chen, Bin and Liu, Siwei}, title = {A note on the Yamabe problem of Randers metrics}, journal = {AUT Journal of Mathematics and Computing}, volume = {2}, number = {2}, pages = {165-170}, year = {2021}, publisher = {Amirkabir University of Technology}, issn = {2783-2449}, eissn = {2783-2287}, doi = {10.22060/ajmc.2021.20199.1056}, abstract = {The classical Yamabe problem in Riemannian geometry states that every conformal class contains a metric with constant scalar curvature. In Finsler geometry, the C-convexity is needed in general. In this paper, we study the strong C-convexity of Randers metrics, and provide a result on the Yamabe problem for the metrics of Randers type.}, keywords = {Randers metrics,C-convex,Yamabe problem}, url = {https://ajmc.aut.ac.ir/article_4458.html}, eprint = {https://ajmc.aut.ac.ir/article_4458_05cc1d53a244dc88558b0fd297221e6e.pdf} } @article { author = {Xu, Ming}, title = {Rank inequality in homogeneous Finsler geometry}, journal = {AUT Journal of Mathematics and Computing}, volume = {2}, number = {2}, pages = {171-184}, year = {2021}, publisher = {Amirkabir University of Technology}, issn = {2783-2449}, eissn = {2783-2287}, doi = {10.22060/ajmc.2021.20210.1058}, abstract = {This is a survey on some recent progress in homogeneous Finsler geometry. Three topics are discussed, the classification of positively curved homogeneous Finsler spaces, the geometric and topological properties of homogeneous Finsler spaces satisfying $K\geq0$ and the (FP) condition, and the orbit number of prime closed geodesics in a compact homogeneous Finsler manifold. These topics share the same similarity that the same rank inequality, i.e., $\mathrm{rank}G\leq\mathrm{rank}H+1$ for $G/H$ with compact $G$ and $H$, plays an important role. In this survey, we discuss in each topic how the rank inequality is proved, explain its importance, and summarize some relevant results.}, keywords = {closed geodesic,compact coset space,homogeneous Finsler metric,positive curvature}, url = {https://ajmc.aut.ac.ir/article_4454.html}, eprint = {https://ajmc.aut.ac.ir/article_4454_f4471c6a100c30980422d65f3a987ae1.pdf} } @article { author = {Cheng, Xinyue}, title = {Some fundamental problems in global Finsler geometry}, journal = {AUT Journal of Mathematics and Computing}, volume = {2}, number = {2}, pages = {185-198}, year = {2021}, publisher = {Amirkabir University of Technology}, issn = {2783-2449}, eissn = {2783-2287}, doi = {10.22060/ajmc.2021.20219.1060}, abstract = {The geometry and analysis on Finsler manifolds is a very important part of Finsler geometry. In this survey article, we introduce some important and fundamental topics in global Finsler geometry and discuss the related properties and the relationships in them. In particular, we optimize and improve the various definitions of Lie derivatives on Finsler manifolds. Further, we also obtain an estimate of lower bound for the non-zero eigenvalues of the Finsler Laplacian under the condition that $\mathrm{Ric}_{N}\geq K >0 $.}, keywords = {Dual Finsler metric,Gradient vector field,Finsler Laplacian,eigenvalue,Hessian,Lie derivative,weighted Ricci curvature}, url = {https://ajmc.aut.ac.ir/article_4456.html}, eprint = {https://ajmc.aut.ac.ir/article_4456_e00e8a7fc9707694ccf2ae6105c2af0e.pdf} } @article { author = {Xia, Qiaoling}, title = {Navigation problem and conformal vector fields}, journal = {AUT Journal of Mathematics and Computing}, volume = {2}, number = {2}, pages = {199-212}, year = {2021}, publisher = {Amirkabir University of Technology}, issn = {2783-2449}, eissn = {2783-2287}, doi = {10.22060/ajmc.2021.20208.1057}, abstract = {The navigation technique is very effective to obtain or classify a Finsler metric from a given a Finsler metric (especially a Riemannian metric) under an action of a vector field on a differential manifold. In this survey, we will survey some recent progress on the navigation problem and conformal vector fields on Finsler manifolds, and their applications in the classifications of some Finsler metrics of scalar (resp. constant) flag curvature. }, keywords = {Finsler manifold,navigation problem,conformal vector field}, url = {https://ajmc.aut.ac.ir/article_4457.html}, eprint = {https://ajmc.aut.ac.ir/article_4457_a143b817d7f14a913b22c9fd9183d28a.pdf} } @article { author = {Vincze, Csaba}, title = {On generalized Berwald manifolds: extremal compatible linear connections, special metrics and low dimensional spaces}, journal = {AUT Journal of Mathematics and Computing}, volume = {2}, number = {2}, pages = {213-237}, year = {2021}, publisher = {Amirkabir University of Technology}, issn = {2783-2449}, eissn = {2783-2287}, doi = {10.22060/ajmc.2021.20348.1063}, abstract = {The notion of generalized Berwald manifolds goes back to V. Wagner [60]. They are Finsler manifolds admitting linear connections on the base manifold such that the parallel transports preserve the Finslerian length of tangent vectors (compatibility condition). Presenting a panoramic view of the general theory we are going to summarize some special problems and results. Spaces of special metrics are of special interest in the generalized Berwald manifold theory. We discuss the case of generalized Berwald Randers metrics, Finsler surfaces and Finsler manifolds of dimension three. To provide the unicity of the compatible linear connection we are looking for, we introduce the notion of the extremal compatible linear connection minimizing the norm of the torsion tensor point by point. The mathematical formulation is given in terms of a conditional extremum problem for checking the existence of compatible linear connections in general. Explicite computations are presented in the special case of generalized Berwald Randers metrics.}, keywords = {Averaging,Riemann-Finsler Geometry,Generalized Berwald manifolds}, url = {https://ajmc.aut.ac.ir/article_4498.html}, eprint = {https://ajmc.aut.ac.ir/article_4498_279e62c4555c5a7be62e851f1a4ef163.pdf} } @article { author = {Tayebi, Akbar}, title = {A survey on unicorns in Finsler geometry}, journal = {AUT Journal of Mathematics and Computing}, volume = {2}, number = {2}, pages = {239-250}, year = {2021}, publisher = {Amirkabir University of Technology}, issn = {2783-2449}, eissn = {2783-2287}, doi = {10.22060/ajmc.2021.20412.1065}, abstract = {This survey is an inspiration of my joint paper with Behzad Najafi published in Science in China. I explain some of interesting results about the unicorn problem.}, keywords = {Unicorn,Landsberg metric,Berwald metric}, url = {https://ajmc.aut.ac.ir/article_4499.html}, eprint = {https://ajmc.aut.ac.ir/article_4499_3fb451497b9a11c25985f73a3b2f6c5b.pdf} } @article { author = {Mo, Xiaohuan and Zhang, Hongzhen}, title = {Navigation problem on Finsler manifolds}, journal = {AUT Journal of Mathematics and Computing}, volume = {2}, number = {2}, pages = {251-274}, year = {2021}, publisher = {Amirkabir University of Technology}, issn = {2783-2449}, eissn = {2783-2287}, doi = {10.22060/ajmc.2021.20355.1064}, abstract = {In this article, we are going to discuss the geometry of the navigation problem on a Finsler manifold. We will give proofs for several important local and global results.}, keywords = {Randers Metric,$S$-curvature,Finsler metric,$(\alpha,\beta)$-metric,flag curvature}, url = {https://ajmc.aut.ac.ir/article_4501.html}, eprint = {https://ajmc.aut.ac.ir/article_4501_5fb45aea99f016f1121fe98c0b4c84c7.pdf} } @article { author = {Huang, Libing and Su, Haibin}, title = {Flag curvatures of the unit sphere in a Minkowski-Randers space}, journal = {AUT Journal of Mathematics and Computing}, volume = {2}, number = {2}, pages = {275-282}, year = {2021}, publisher = {Amirkabir University of Technology}, issn = {2783-2449}, eissn = {2783-2287}, doi = {10.22060/ajmc.2021.20237.1061}, abstract = {On a real vector space $V$, a Randers norm $\hat{F}$ is defined by $\hat{F}=\hat{\alpha}+\hat{\beta}$, where $\hat{\alpha}$ is a Euclidean norm and $\hat{\beta}$ is a covector. We show that the unit sphere $\Sigma$ in the Randers space $(V,\hat{F})$ has positive flag curvature, if and only if $|\hat{\beta}|_{\hat{\alpha}}< (5-\sqrt{17})/2 \approx 0.43845$, thus answering a problem proposed by Prof. Zhongmin Shen. Moreover, we prove that the flag curvature of $\Sigma$ has a universal lower bound $-4$.}, keywords = {flag curvature,Randers Metric,Riemannian metric}, url = {https://ajmc.aut.ac.ir/article_4455.html}, eprint = {https://ajmc.aut.ac.ir/article_4455_c2782602098697570d821d54494bfa77.pdf} }