Implementation of Tolling Perception Figuration Digital Modeling of the Fractal Structures of Pore Function Matter



Tolling perception figuration, Sparkle-divergence perception level, Tolling-vibration figuration, Tolling roses-butterflies dot vibration


Fractal parameters of porous media was get the focus of materials engineering and physical engineering for decades because they appears effective ways to decide the complexity of circular structures across a  various scales. This paper combines polyhedral process-based digital figuration modeling with fractal structure analysis to understand the effect of microstructure ratios of various separation, combination, and binary models on fractal parameters and internal surface area (ISA) of ​​porous media. A digital tolling perception figuration model (Tol-PFM) was constructed to simulate water quality using a process-based modeling technique that simulates gel component materials. The fractal parameters of the generated pore geometry were calculated using the line method on the tolling perception figuration of Tol-PFM. Our simulations show that the fractal dimensions, internal surface area (ISA) and porosity were significantly reduced when separation or combination is increased, showing that these two diagnostic procedures can significantly influence the microstructure of the gel component material. Interface fractal dimensions (PD) and ISA appear as the tolling perception values ​​increase and decrease. SDPL appearing a unruly movement of the then, of the maximum in terms of the tolling-vibration figuration, and the tolling value movement of the Tol-PF-FA-θMAX was 26.03±5.53 units from the tolling roses-butterflies dot vibration, and the tolling value movement of the Tol-PF-CO-θMAX was 12.13±2.19 units, and the tolling value movement of the Tol-PF-FL-θMAX was 4.18±0.74 units, and the tolling value movement of the Tol-PF-VI-θMAX was (0.74±0.11) units. Examining the tolling-vibration shape of the binary model, the porosity of the digital model shows a square motion of the maximum average sparkle-divergence perception level (SDPL) as the fine particle ratio increases from 0 to 1. This results in both increasing and decreasing values ​​of PD and ISA as the finite line-boundary fraction of the simplified oscillation algorithm and model increases. However, we must notice that the tolling perception figuration in the fractal dimension may be overestimated depending on the divergent signal when using a model composed of very fine spherical particles due to the effect of image resolution.


Download data is not yet available.


P.W.J. Glover, K. Matsuki, R. Hikima, et al., Fluid flow in fractally rough synthetic fractures. Geophys. Res. Lett., 24 (14), 1803–1806, 1997.

A.J. Katz, A.H. Thompson, Fractal sandstone pores: implications for conductivity and pore formation. Phys. Rev. Lett., 54, 10325–10328, 1985.

Hermina, J. ., Karpagam, N. S. ., Deepika, P. ., Jeslet, D. S. ., & Komarasamy, D. (2022). A Novel Approach to Detect Social Distancing Among People in College Campus. International Journal of Intelligent Systems and Applications in Engineering, 10(2), 153–158. Retrieved from

J.P. Hansen, A.T. Skeltorp, Fractal pore space and rock permeability implications. Phys. Rev. B, 38, 2635–2638, 1988.

A. Revil, P. Glover, Nature of surface electrical conductivity in natural sands, sandstones, and clays. Geophys. Res. Lett., 25, 691–695, 1998.

R. Suman, R. Knight, Effects of pore structure and wettability on the electrical resistivity of partially saturated rocks - a network study, Geophysics, 62, 1151–1162, 1997.

J. Huiting, H. Flisijn, ABJ. Kokkeler and GJM.Smit, “Exploiting phase measurements of EPC Gen2 RFID structures,” IEEE Int Conf RFID-Technol Appl (RFID-TA), 2013, 1–6.

Laptiev, O., Yevseiev, S., Hatsenko, L., Daki, O., Ivanenko, V., Fedunov, V., & Hohoniants, S. (2022). The method of discretization signals to minimize the fallibility of information recovery. International Journal of Communication Networks and Information Security (IJCNIS), 13(3).

A.Bekkali, S.C. Zou, A. Kadri, M. Crisp and R.V. Penty, “Performance analysis of passive UHF RFID systems under cascaded fading channels and interference effects,” IEEE Trans Wirel Commun.,14, (3), 2015, 1421–33.

E. DiGiampaolo and F. Martinelli, “Mobile robot localization using the phase of passive UHF RFID signals,” IEEE Trans Ind Electron, Vol.61, (1), 2014, 365–76.

Harsh, S. ., Singh , D., & Pathak , S. (2022). Efficient and Cost-effective Drone – NDVI system for Precision Farming. International Journal of New Practices in Management and Engineering, 10(04), 14–19.

Y.Á. López, M.E. Gómez and F.L.H. Andrés, “A received signal strength RFID-based indoor location system,” Sensors and Actuators A, 255, 2017, 118–133.

Gupta, D. J. . (2022). A Study on Various Cloud Computing Technologies, Implementation Process, Categories and Application Use in Organisation. International Journal on Future Revolution in Computer Science &Amp; Communication Engineering, 8(1), 09–12.

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), (25–27 June) 2013, 1–6.

Kim J.L., Choi J.S. and Hwang K.S., A Study on Anticipation System of Shudder Distinction by the Physical Shift Alteration in Static Condition. The Journal of IIBC (JIIBC), 17(3) 2017, 115-120. DOI 10.7236/JIIBC.2017.17.3.115

Kim J.L. and Kim K.D., Prediction of shiver differentiation by the form alteration on the stable condition. International Journal of Internet Broadcasting and Communication (IJIBC), 9(4) (2017), 8-13. DOI 10.7236/IJIBC.2017.9.4.8

J, M. S., S. K. Dr.N.C., M. Dr. P., T. N, and J. P. S. “IEEHR: Improved Energy Efficient Honeycomb Based Routing in MANET for Improving Network Performance and Longevity”. International Journal on Recent and Innovation Trends in Computing and Communication, vol. 10, no. 7, July 2022, pp. 85-93, doi:10.17762/ijritcc.v10i7.5575.

Kim J.L. and Hwang K.S., Study of quake wavelength of dynamic changing-status with posture. International Journal of Advanced Smart Convergence (IJASC), 4(1) (2015), 99-103.

Kim J.L. and Kim K.D., Denoteation of central motion techniques: limpness motion function and limpness sensory unit function. International Journal of Advanced Culture Technology (IJACT), 4(3) (2016), 56-61. DOI 10.17703/IJACT.2016.4.3.56

Sparkle-divergencefunctionis roses-butterflies dot oftolling perceptionlocation on the matter




How to Cite

J.-L. . Kim, Y.-S. . Im, S.-H. . Hwang, G.-S. . Choi, and J.-J. . Kang, “Implementation of Tolling Perception Figuration Digital Modeling of the Fractal Structures of Pore Function Matter ”, Int J Intell Syst Appl Eng, vol. 10, no. 1s, pp. 209 –, Oct. 2022.

Most read articles by the same author(s)