Global and Local Color Time Scales to Encode Timeline Events in Ion Trajectories for Glassies

Authors

  • J. M. Sharif universiti teknologi malaysia
  • Abdul Malik Mohd Ali universiti kuala lumpur
  • M. Mahadi Abdul Jamil universiti tun hussein onn malaysia

Keywords:

glassy, ionic conductivity, color scale, coding theory, visualization.

Abstract

Glassy compounds lead directly to high ionic conductivity. Ionic conductivity generates ion trajectories. However, these trajectories have been represented by two-dimensional graph in order to visualize the timeline events in ion trajectories. This study addresses this problem by encoding the timeline events in ion trajectories with global and local color scales. Two time scales have been introduced namely Global Color Time Scale and Local Color Time Scale. The rainbow color has been chosen to represent global time scale meanwhile solid color has been used to generate local time scale. Based on evaluation, these techniques are successful in representing timeline events in ion trajectories for understanding the complicated heterogeneous movement of ion trajectories.

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Author Biographies

  • J. M. Sharif, universiti teknologi malaysia

    Department of Computer Science

    Universiti Teknologi Malaysia (UTM)

  • Abdul Malik Mohd Ali, universiti kuala lumpur

    Department of Electrical and Electronic

    British Malaysian Institute, Universiti Kuala Lumpur (UniKL)

  • M. Mahadi Abdul Jamil, universiti tun hussein onn malaysia

    Biomedical Engineering Modelling & Simulation Research Group (BIOMEMS)

    Universiti Tun Hussein Onn Malaysia (UTHM)

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Issue

Section

Issue on Electrical and Electronic Engineering

How to Cite

Sharif, J. M., Mohd Ali, A. M., & Abdul Jamil, M. M. (2015). Global and Local Color Time Scales to Encode Timeline Events in Ion Trajectories for Glassies. International Journal of Integrated Engineering, 6(3). https://penerbit.uthm.edu.my/ojs/index.php/ijie/article/view/1031

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