Selectivity for three-dimensional contours and surfaces in the anterior intraparietal area

The macaque anterior intraparietal area (AIP) is crucial for visually guided grasping. AIP neurons respond during the visual presentation of real-world objects and encode the depth profile of disparity-defined curved surfaces. We investigated the neural representation of curved surfaces in AIP using a stimulus-reduction approach. The stimuli consisted of three-dimensional (3-D) shapes curved along the horizontal axis, the vertical axis, or both the horizontal and the vertical axes of the shape. The depth profile was defined solely by binocular disparity that varied along either the boundary or the surface of the shape or along both the boundary and the surface of the shape. The majority of AIP neurons were selective for curved boundaries along the horizontal or the vertical axis, and neural selectivity emerged at short latencies. Stimuli in which disparity varied only along the surface of the shape (with zero disparity on the boundaries) evoked selectivity in a smaller proportion of AIP neurons and at considerably longer latencies. AIP neurons were not selective for 3-D surfaces composed of anticorrelated disparities. Thus the neural selectivity for object depth profile in AIP is present when only the boundary is curved in depth, but not for disparity in anticorrelated stereograms.

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On the Wall Shear Stress Gradient in Fluid Dynamics

Communications in Computational Physics ◽

10.4208/cicp.030714.101014a ◽

2015 ◽

Vol 17 (3) ◽

pp. 808-821 ◽

Cited By ~ 6

Author(s):

C. Cherubini ◽

S. Filippi ◽

A. Gizzi ◽

M. G. C. Nestola

Keyword(s):

Applied Sciences ◽

Fluid Dynamics ◽

Stress Gradient ◽

Three Dimensional ◽

Slow Motion ◽

Directional Derivatives ◽

Curved Surfaces ◽

Curved Boundaries ◽

Wall Shear Stress Gradient ◽

Derivatives Of

AbstractThe gradient of the fluid stresses exerted on curved boundaries, conventionally computed in terms of directional derivatives of a tensor, is here analyzed by using the notion of intrinsic derivative which represents the geometrically appropriate tool for measuring tensor variations projected on curved surfaces. Relevant differences in the two approaches are found by using the classical Stokes analytical solution for the slow motion of a fluid over a fixed sphere and a numerically generated three dimensional dynamical scenario. Implications for theoretical fluid dynamics and for applied sciences are finally discussed.

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A Class of Novel Tetrahedron Elements with Curved Surfaces for Three-Dimensional Solid Mechanics Problems with Curved Boundaries

International Journal of Computational Methods ◽

10.1142/s0219876219500063 ◽

2019 ◽

Vol 17 (04) ◽

pp. 1950006

Author(s):

C. Q. Wang ◽

J. H. Yue ◽

Ming Li

Keyword(s):

Finite Element ◽

Solid Mechanics ◽

Three Dimensional ◽

Curved Surfaces ◽

Curved Boundaries ◽

Hybrid Mesh ◽

Curved Boundary ◽

Flat Surfaces ◽

Tetrahedral Elements ◽

Hybrid Meshes

Linear tetrahedral elements with four nodes (Te4) are currently the simplest and most widely used ones in the finite element (FE) developed for solving three-dimensional (3D) mechanics problems. However, the standard Te4 element cannot be used to simulate accurately the 3D problems with curved boundaries because of the flat surfaces. In this paper, we develop a set of new elements having curved surfaces to properly simulate the curved boundaries. At the same time, additional nodes are put on the curved boundaries to improve the accuracy of the approximation. These novel elements are defined as five-noded, six-noded, and seven-noded tetrahedron elements (Te5, Te6, and Te7) according to the number of the nodes in one element. Based on the Te4 FE mesh, a hybrid mesh can be conveniently built for 3D problems with curved boundaries, in which the standard Te4 elements are used for the interior elements, and Te5, Te6, and Te7 elements are used for the curved boundary elements. Compared with the standard FEM using Te4 elements, our hybrid mesh can significantly improve the accuracy of the solutions at the curved boundaries. Several solid mechanics problems are studied using the hybrid meshes to validate the effectiveness of the present new elements.

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Three-Dimensional Computation during Off-Vertical Axis Rotation (OVAR) in Monkeys

Equilibrium Research ◽

10.3757/jser.65.429 ◽

2006 ◽

Vol 65 (6) ◽

pp. 429-439 ◽

Cited By ~ 1

Author(s):

Keisuke Kushiro ◽

Jun Maruta

Keyword(s):

Three Dimensional ◽

Vertical Axis ◽

Axis Rotation

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Performance enhancement of Savonius wind turbine by blade shape and twisted angle modifications

Proceedings of the Institution of Mechanical Engineers Part A Journal of Power and Energy ◽

10.1177/0957650920987942 ◽

2021 ◽

pp. 095765092098794

Author(s):

Ahmed M Nagib Elmekawy ◽

Hassan A Hassan Saeed ◽

Sadek Z Kassab

Keyword(s):

Wind Turbine ◽

Performance Enhancement ◽

Three Dimensional ◽

Turbulence Models ◽

Vertical Axis ◽

Cfd Simulations ◽

Sliding Mesh ◽

Blade Shape ◽

Rotor Shape ◽

Twisting Angle

Three-dimensional CFD simulations are carried out to study the increase of power generated from Savonius vertical axis wind turbines by modifying the blade shape and blade angel of twist. Twisting angle of the classical blade are varied and several proposed novel blade shapes are introduced to enhance the performance of the wind turbine. CFD simulations have been performed using sliding mesh technique of ANSYS software. Four turbulence models; realizable k -[Formula: see text], standard k - [Formula: see text], SST transition and SST k -[Formula: see text] are utilized in the simulations. The blade twisting angle has been modified for the proposed dimensions and wind speed. The introduced novel blade increased the power generated compared to the classical shapes. The two proposed novel blades achieved better power coefficients. One of the proposed models achieved an increase of 31% and the other one achieved 32.2% when compared to the classical rotor shape. The optimum twist angel for the two proposed models achieved 5.66% and 5.69% when compared with zero angle of twist.

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Theoretical modelling of the three-dimensional wake of vertical axis turbines

Flow ◽

10.1017/flo.2021.4 ◽

2021 ◽

Vol 1 ◽

Author(s):

Pablo Ouro ◽

Maxime Lazennec

Keyword(s):

Three Dimensional ◽

Vertical Axis ◽

Theoretical Modelling

Graphical Abstract

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Stretchable micro-scale concentrator photovoltaic module with 15.4% efficiency for three-dimensional curved surfaces

Communications Materials ◽

10.1038/s43246-020-00106-x ◽

2021 ◽

Vol 2 (1) ◽

Author(s):

Daisuke Sato ◽

Taizo Masuda ◽

Kenji Araki ◽

Masafumi Yamaguchi ◽

Kenichi Okumura ◽

...

Keyword(s):

Concentration Ratio ◽

Power Conversion ◽

Three Dimensional ◽

Thin Film Solar Cells ◽

Photovoltaic Module ◽

Silicon Compound ◽

Curved Surfaces ◽

Power Sources ◽

Micro Scale ◽

Module Design

AbstractStretchable photovoltaics are emerging power sources for collapsible electronics, biomedical devices, and buildings and vehicles with curved surfaces. Development of stretchable photovoltaics are crucial to achieve rapid growth of the future photovoltaic market. However, owing to their rigidity, existing thin-film solar cells based predominantly on silicon, compound semiconductors, and perovskites are difficult to apply to 3D curved surfaces, which are potential real-world candidates. Herein, we present a stretchable micro-scale concentrator photovoltaic module with a geometrical concentration ratio of 3.5×. When perfectly fitted on a 3D curved surface with a sharp curvature, the prototype module achieves an outdoor power conversion efficiency of 15.4% and the daily generated electricity yield improves to a maximum of 190% relative to a non-concentration stretchable photovoltaic module. Thus, this module design enables high areal coverage on 3D curved surfaces, while generating a higher electricity yield in a limited installation area.

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A Fast Two-Dimensional Numerical Method for the Wake Simulation of a Vertical Axis Wind Turbine

Energies ◽

10.3390/en14010049 ◽

2020 ◽

Vol 14 (1) ◽

pp. 49

Author(s):

Zheng Yuan ◽

Jin Jiang ◽

Jun Zang ◽

Qihu Sheng ◽

Ke Sun ◽

...

Keyword(s):

Velocity Distribution ◽

Numerical Method ◽

Three Dimensional ◽

Particle Method ◽

Vortex Method ◽

Vertical Axis ◽

Two Dimensional ◽

Vertical Axis Wind Turbine ◽

Wake Effect ◽

Array Design

In the array design of the vertical axis wind turbines (VAWT), the wake effect of the upstream VAWT on the downstream VAWT needs to be considered. In order to simulate the velocity distribution of a VAWT wake rapidly, a new two-dimensional numerical method is proposed, which can make the array design easier and faster. In this new approach, the finite vortex method and vortex particle method are combined to simulate the generation and evolution of the vortex, respectively, the fast multipole method (FMM) is used to accelerate the calculation. Based on a characteristic of the VAWT wake, that is, the velocity distribution can be fitted into a power-law function, a new correction model is introduced to correct the three-dimensional effect of the VAWT wake. Finally, the simulation results can be approximated to the published experimental results in the first-order. As a new numerical method to simulate the complex VAWT wake, this paper proves the feasibility of the method and makes a preliminary validation. This method is not used to simulate the complex three-dimensional turbulent evolution but to simulate the velocity distribution quickly and relatively accurately, which meets the requirement for rapid simulation in the preliminary array design.

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Navigating in a volumetric world: Metric encoding in the vertical axis of space

Behavioral and Brain Sciences ◽

10.1017/s0140525x13000344 ◽

2013 ◽

Vol 36 (5) ◽

pp. 546-547 ◽

Cited By ~ 2

Author(s):

Theresa Burt de Perera ◽

Robert Holbrook ◽

Victoria Davis ◽

Alex Kacelnik ◽

Tim Guilford

Keyword(s):

Spatial Information ◽

Dimensional Space ◽

Three Dimensional ◽

Vertical Component ◽

Vertical Axis ◽

Orthogonal Axis ◽

Experimental Protocols ◽

Three Dimensional Space ◽

The Way

AbstractAnimals navigate through three-dimensional environments, but we argue that the way they encode three-dimensional spatial information is shaped by how they use the vertical component of space. We agree with Jeffery et al. that the representation of three-dimensional space in vertebrates is probably bicoded (with separation of the plane of locomotion and its orthogonal axis), but we believe that their suggestion that the vertical axis is stored “contextually” (that is, not containing distance or direction metrics usable for novel computations) is unlikely, and as yet unsupported. We describe potential experimental protocols that could clarify these differences in opinion empirically.

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