scholarly journals A Uniform Model for Kirillov-Reshetikhin Crystals I: Lifting the Parabolic Quantum Bruhat Graph

2014 ◽  
Author(s):  
C. Lenart ◽  
S. Naito ◽  
D. Sagaki ◽  
A. Schilling ◽  
M. Shimozono
Keyword(s):  
Uniform Model ◽  
Bruhat Graph ◽  
Quantum Bruhat Graph

scholarly journals Maximal Newton polygons via the quantum Bruhat graph

2012 ◽  
Vol DMTCS Proceedings vol. AR,... (Proceedings) ◽  
Author(s):  
Elizabeth T. Beazley
Keyword(s):  
Weyl Group ◽  
Quantum Cohomology ◽  
Bruhat Order ◽  
Flag Variety ◽  
Necessary Condition ◽  
Newton Polygons ◽  
Weighted Directed Graph ◽  
Affine Weyl Group ◽  
Bruhat Graph ◽  
Quantum Bruhat Graph

International audience This paper discusses a surprising relationship between the quantum cohomology of the variety of complete flags and the partially ordered set of Newton polygons associated to an element in the affine Weyl group. One primary key to establishing this connection is the fact that paths in the quantum Bruhat graph, which is a weighted directed graph with vertices indexed by elements in the finite Weyl group, encode saturated chains in the strong Bruhat order on the affine Weyl group. This correspondence is also fundamental in the work of Lam and Shimozono establishing Peterson's isomorphism between the quantum cohomology of the finite flag variety and the homology of the affine Grassmannian. In addition, using some geometry associated to the poset of Newton polygons, one obtains independent proofs for several combinatorial statements about paths in the quantum Bruhat graph and its symmetries, which were originally proved by Postnikov using the tilted Bruhat order. An important geometric application of this work is an inequality which provides a necessary condition for non-emptiness of certain affine Deligne-Lusztig varieties in the affine flag variety. Cet article étudie une relation surprenante entre la cohomologie quantique de la variété de drapeaux complets et l'ensemble partiellement ordonné de polygones de Newton associé à un élément du groupe de Weyl affine. L’élément clé pour établir cette connexion est le fait que les chemins dans le graphe de Bruhat quantique, qui est un graphe orienté pondéré dont les sommets sont indexés par des éléments du groupe de Weyl fini, encodent des chaînes saturées dans l'ordre de Bruhat fort sur le groupe de Weyl affine. Cette correspondance est aussi fondamentale dans les travaux de Lam et Shimonozo qui établissent l'isomorphisme de Peterson entre la cohomologie quantique de la variété de drapeaux finie et l'homologie de la Grassmannienne affine. De plus, en utilisant la géométrie associée à l'ensemble partiellement ordonné des polygones de Newton, on obtient des preuves indépendantes pour plusieurs assertions combinatoires sur les chemins dans le graphe de Bruhat quantiques et les symétries de ce graphe, qui ont été originellement démontrées par Postnikov en utilisant l'ordre de Bruhat incliné. Une application géométrique importante de ce travail est une inégalité qui donne une condition nécessaire pour que certaines variétés de Deligne-Lusztig affines dans la variété de drapeaux affine soient non-vides.

scholarly journals Generic Newton points and the Newton poset in Iwahori-double cosets

2020 ◽  
Vol 8 ◽  
Author(s):  
Elizabeth Milićević ◽  
Eva Viehmann
Keyword(s):  
Reductive Group ◽  
Loop Group ◽  
Index Set ◽  
Double Cosets ◽  
Large Classes ◽  
Bruhat Graph ◽  
Newton Stratification ◽  
Quantum Bruhat Graph

Abstract We consider the Newton stratification on Iwahori-double cosets in the loop group of a reductive group. We describe a group-theoretic condition on the generic Newton point, called cordiality, under which the Newton poset (that is, the index set for non-empty Newton strata) is saturated and Grothendieck’s conjecture on closures of the Newton strata holds. Finally, we give several large classes of Iwahori-double cosets for which this condition is satisfied by studying certain paths in the associated quantum Bruhat graph.

scholarly journals Inverse K-Chevalley formulas for semi-infinite flag manifolds, I: minuscule weights in ADE type

2021 ◽  
Vol 9 ◽  
Author(s):  
Takafumi Kouno ◽  
Satoshi Naito ◽  
Daniel Orr ◽  
Daisuke Sagaki
Keyword(s):  
Flag Manifolds ◽  
Line Bundles ◽  
Affine Hecke Algebra ◽  
Double Affine Hecke Algebra ◽  
Bruhat Graph ◽  
Schubert Classes ◽  
Explicit Determination ◽  
Schubert Class ◽  
Quantum Bruhat Graph

Abstract We prove an explicit inverse Chevalley formula in the equivariant K-theory of semi-infinite flag manifolds of simply laced type. By an ‘inverse Chevalley formula’ we mean a formula for the product of an equivariant scalar with a Schubert class, expressed as a $\mathbb {Z}\left [q^{\pm 1}\right ]$ -linear combination of Schubert classes twisted by equivariant line bundles. Our formula applies to arbitrary Schubert classes in semi-infinite flag manifolds of simply laced type and equivariant scalars $e^{\lambda }$ , where $\lambda $ is an arbitrary minuscule weight. By a result of Stembridge, our formula completely determines the inverse Chevalley formula for arbitrary weights in simply laced type except for type $E_8$ . The combinatorics of our formula is governed by the quantum Bruhat graph, and the proof is based on a limit from the double affine Hecke algebra. Thus our formula also provides an explicit determination of all nonsymmetric q-Toda operators for minuscule weights in ADE type.

scholarly journals Ground volume assessment using ’Structure from Motion’ photogrammetry with a smartphone and a compact camera

2017 ◽  
Vol 9 (1) ◽  
Author(s):  
Rafał Wróżyński ◽  
Krzysztof Pyszny ◽  
Mariusz Sojka ◽  
Czesław Przybyła ◽  
Sadżide Murat-Błażejewska
Keyword(s):  
Open Source Software ◽  
Structure From Motion ◽  
Point Cloud ◽  
Field Measurements ◽  
Video Frames ◽  
Actual Volume ◽  
Volume Assessment ◽  
Uniform Model ◽  
Free Open Source ◽  
Test Embankment

AbstractThe article describes how the Structure-from-Motion (SfM) method can be used to calculate the volume of anthropogenic microtopography. In the proposed workflow, data is obtained using mass-market devices such as a compact camera (Canon G9) and a smartphone (iPhone5). The volume is computed using free open source software (VisualSFMv0.5.23, CMPMVSv0.6.0., MeshLab) on a PCclass computer. The input data is acquired from video frames. To verify the method laboratory tests on the embankment of a known volume has been carried out. Models of the test embankment were built using two independent measurements made with those two devices. No significant differences were found between the models in a comparative analysis. The volumes of the models differed from the actual volume just by 0.7‰ and 2‰. After a successful laboratory verification, field measurements were carried out in the same way. While building the model from the data acquired with a smartphone, it was observed that a series of frames, approximately 14% of all the frames, was rejected. The missing frames caused the point cloud to be less dense in the place where they had been rejected. This affected the model’s volume differed from the volume acquired with a camera by 7%. In order to improve the homogeneity, the frame extraction frequency was increased in the place where frames have been previously missing. A uniform model was thereby obtained with point cloud density evenly distributed. There was a 1.5% difference between the embankment’s volume and the volume calculated from the camera-recorded video. The presented method permits the number of input frames to be increased and the model’s accuracy to be enhanced without making an additional measurement, which may not be possible in the case of temporary features.

Analytical Model of the Efficiency of Spur Gears: Study of the Influence of the Design Parameters

2011 ◽  
Author(s):  
Miguel Pleguezuelos ◽  
Jose´ I. Pedrero ◽  
Miryam B. Sa´nchez
Keyword(s):  
Load Distribution ◽  
Gear Ratio ◽  
Design Parameters ◽  
Spur Gears ◽  
Transmitted Power ◽  
Power Losses ◽  
Contact Ratio ◽  
Complete Study ◽  
Uniform Model ◽  
Analytical Expressions

An analytic model to compute the efficiency of spur gears has been developed. It is based on the application of a non-uniform model of load distribution obtained from the minimum elastic potential criterion and a simplified non-uniform model of the friction coefficient along the path of contact. Both conventional and high transverse contact ratio spur gears have been considered. Analytical expressions for the power losses due to friction, for the transmitted power and for the efficiency are presented. From this model, a complete study of the influence of some design parameters (as the number of teeth, the gear ratio, the pressure angle, the addendum modification coefficient, etc.) on the efficiency is presented.

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