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Geovisualisation as a process of creating complementary visualisations: static two-dimensional, surface three-dimensional, and interactive

Tymoteusz Horbiński Beata Medyńska-Gulij
Geodesy and Cartography | 2017 | vol. 66 | No 1 | DOI: 10.1515/geocart-2017-0009
Keywords geovizualisation complementary visualisations static two-dimensional map interactive map surface three-dimensional model natural aggregate extraction
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Abstract

In the following paper, geovisualisation will be applied to one spatial phenomenon and understood as a process of creating complementary visualisations: static two-dimensional, surface three-dimensional, and interactive. The central challenge that the researchers faced was to find a method of presenting the phenomenon in a multi- faceted way. The main objective of the four-stage study was to show the capacity of the contemporary software for presenting geographical space from various perspectives while maintaining the standards of cartographic presentation and making sure that the form remains attractive for the user. The correctness, effectiveness, and usefulness of the proposed approach was analysed on the basis of a geovisualisation of natural aggregate extraction in the Gniezno district in the years 2005–2015. For each of the three visualisations, the researchers planned a different range of information, different forms of graphic and cartographic presentation, different use and function, but as far as possible the same accessible databases and the same free technologies. On the basis of the final publication, the researchers pointed out the advantages of the proposed work flow and the correctness of the detailed flowchart.
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Authors and Affiliations

Tymoteusz Horbiński
Beata Medyńska-Gulij

Rotor optimization of axial-radial flux type synchronous machine based on magnetic flux leakage

Hongbo Qiu Shubo Zhang
Archives of Electrical Engineering | 2021 | vol. 70 | No 3 | 551-566 | DOI: 10.24425/aee.2021.137573
Keywords ARFTPMSM rotor structure three-dimensional model magnetic leakage
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Abstract

The axial-radial flux type permanent magnet synchronous machine (ARFTPMSM) can adjust the main magnetic field by controlling the axial flux, so it can overcome the problem that the flux of the permanent magnet synchronous motor (PMSM) is difficult to adjust. Due to the existence of the axial device in the ARFTPMSM, the finite element method (FEM) is used to establish a three-dimensional model for analysis. By analyzing the magnetic density distribution of the rotor, it is found that there is a serious magnetic leakage phenomenon at both ends of the tangential permanent magnet. The rotor material at the end of the tangent permanent magnet is replaced by non-ferromagnetic material to reduce the magnetic leakage. On this basis, the influence of the width of the non-ferromagnetic material on the performance of the motor is compared. By Fourier decomposition of the back-EMF waveform, the total harmonic distortion (THD) rate of the back-EMF under different axial magnetomotive force (MMF) was calculated. Finally, the eddy current distribution and the eddy current loss of the rotor are analyzed, and the variation law of the eddy current loss is summarized. The conclusion can provide reference for the optimal design of the ARFTPMSM.
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Authors and Affiliations

Hongbo Qiu
1
Shubo Zhang
1
  1. Zhengzhou University of Light Industry, China

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