International Journal of Advanced Culture Technology

The International Promotion Agency of Culture Technology (국제문화기술진흥원)
권호 표지
DOI QR코드

DOI QR Code

Construction of the permeate tuner system by the steeple morph of the matter

  • Kim, Jeong-lae (Department of Biomedical Engineering, Eulji University) ;
  • Lee, Woo-cheol (Department of Biomedical Engineering, Eulji University)
  • Received : 2018.07.18
  • Accepted : 2018.08.22
  • Published : 2018.09.30
Download PDF
⟨ Previous Next ⟩

Abstract

Permeate alteration technique is compounded the steeple sway-tuner status of the gleam-differential realization level (GDRL) on the permeate realization morph. The realization level condition by the permeate realization morph system is associated with the sway-tuner system. As to search a dot of the dot situation, we are gained of the permeate value with character-dot by the output signal. The concept of realization level is composed the reference of gleam-differential level for alteration signal by the permeate tuner morph. Moreover displaying a steeple alteration of the GDRL of the average in terms of the sway-tuner morph, and permeate dot tuner that was the a permeate value of the far alteration of the $Per-rm-FA-{\alpha}_{AVG}$ with $14.63{\pm}1.23units$, that was the a permeate value of the convenient alteration of the $Per-rm-CO-{\alpha}_{AVG}$ with $8.28{\pm}0.97units$, that was the a permeate value of the flank alteration of the $Per-rm-FL-{\alpha}_{AVG}$ with $3.28{\pm}0.58units$, that was the a permeate value of the vicinage alteration of the $Per-rm-VI-{\alpha}_{AVG}$ with $0.51{\pm}0.10units$. The sway tuner will be to evaluate at the steeple ability of the sway-tuner morph with character-dot by the permeate realization level on the GDRL that is displayed the gleam-differential morph by the realization level system. Sway realization system will be possible to control of a morph by the special signal and to use a permeate data of sway tuner level.

Keywords

References

  1. E.V. Vazquez, J. Miranda, and A.P. Gonzalez, "Describing soil surface microrelief by crossover length and fractal dimension," Nonlinear Process. Geophys, Vol.14, No.3, pp.223-235. 2007. https://doi.org/10.5194/npg-14-223-2007
  2. T.H. Wilson, "Some distinctions between self-similar and self-affine estimates of estimates of fractal dimension with case history", Math. Geol., Vol.32, No.3, pp.319-335, 2000. https://doi.org/10.1023/A:1007585811281
  3. S.R. Brown, "A note on the description of surface roughness using fractal dimension," Geophys. Res. Lett., Vol.14, No.11, pp.1095-1098, 1987. https://doi.org/10.1029/GL014i011p01095
  4. C. Goodin, M. Stevens, F. J. Villafan Rosa, B. McKinley, B. Q. Gates, P. J. Durst, G. L. Mason, and A. Baylot, "Calculating fractal parameters from low-resolution terrain profiles," Journal of Terramechanics, Vol.72, pp. 21-26, 2017. https://doi.org/10.1016/j.jterra.2017.03.002
  5. J.L. Kim, and K.D.Kim, "Prediction of shiver differentiation by the form alteration on the stable condition," International Journal of Internet Broadcasting and Communication(IJIBC), Vol.9, No.4, pp.8-13, 2017.
  6. J.L. Kim, and K.D. Kim, "Presentation of central motion techniques: limpness motion function and limpness sensory unit function," International Journal of Advanced Culture Technology(IJACT), Vol.4, No.3, pp.56-61, 2016. https://doi.org/10.17703/IJACT.2016.4.3.56
  7. J.L. Kim, and H.J. Kim, "A Study of energy conversion by the penetration control in the skin," Journal of the Convergence on Culture Technology(JCCT), Vo.3, No.1, pp.43-48, 2017. https://doi.org/10.17703/JCCT.2017.3.1.43
  8. J.L. Kim, K.S. Hwang, Y.S. Nam, "Assessment of the Posture Function by Head Movement," The Journal of IIBC(JIIBC), Vol.14, No.5, pp.131-135, 2014.
  9. J.L.Kim, and Hwang, K.S., "Study of quake wavelength of dynamic movement with posture," International Journal of Advanced Smart Convergence(IJASC), Vol.4, No.1, pp.99-103, 2015. https://doi.org/10.7236/IJASC.2015.4.1.99
  10. J. Huiting, H. Flisijn, ABJ. Kokkeler, and GJM. Smit, "Exploiting phase measurements of EPC Gen2 RFID tags," IEEE Int Conf RFID-Technol Appl (RFID-TA), pp.1-6, 2013.
  11. A. Bekkali, SC Zou., A. Kadri, M. Crisp, and RV. Penty, "Performance analysis of passive UHF RFID systems under cascaded fading channels and interference effects," IEEE Trans Wirel Commun, Vol.14, No.3, pp.1421-33, 2015. https://doi.org/10.1109/TWC.2014.2366142
  12. E DiGiampaolo., and F. Martinelli, "Mobile robot localization using the phase of passive UHF RFID signals," IEEE Trans Ind Electron, Vol.61, No.1, pp.365-76, 2014;. https://doi.org/10.1109/TIE.2013.2248333
  13. K. Chawla, C. McFarland, G. Robins, and C. Shope, "Real-time RFID localization using RSS," in: 2013 International Conference on Localization and GNSS (ICL-GNSS), Turin (Italy), pp.1-6, (25-27 June) 2013.