Journal of the Korean Geotechnical Society ISSN:1229-2427(Print) 2288-646X(Online) 한국지반공학회 논문집

Al-Khafaji, K. R., Fattah, M. Y., and Al-Recaby, M. K. (2022), "Measurement of the Lateral Earth Pressure Coefficient of Clayey Soils by Modified Oedometer Test", Engineering and Technology Journal, Vol.40, No.11, pp.1376-1384.

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Keskin, M. S., Bildik, S., and Laman, M. (2023), "Experimental and Numerical Studies of Vertical Stresses Beneath the Circular Footings on Sand", Applied Sciences, Vol.13, No.3.

Keskin, S., Laman, M., and Baran, T. (2008), "Experimental Determination and Numerical Analysis of Vertical Stresses under Square Footings Resting on Sand", Teknik Dergi, Vol.19, No.4, pp.4521-4538.

Kootahi, K. and Leung, A. K. (2022), "Effect of Soil Particle Size on the Accuracy of Tactile Pressure Sensors", Journal of Geotechnical and Geoenvironmental Engineering, Vol.148, No.10.

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Labuz, J. F. and Theroux, B. (2005), "Laboratory Calibration of Earth Pressure Cells", Geotechnical Testing Journal, Vol.28, No.2, pp.188-196.

Lee, C., Shin, E., and Yang, T. (2022), "Analysis of Reinforcement Effect of Hollow Modular Concrete Block on Sand by Laboratory Model Tests", Journal of the Korean Geotechnical Society, Vol.38, No.7, pp.49-62.

Lim, J. (2004), "An Experimental Investigation of Boussinesq's Theoretical Value of Vertical Stress Increment in Sandy Soil Mass Caused by Surface Strip Loading", Journal of the Korean Geotechnical Society, Vol.20, No.9, pp.7-15.

Nam, H.-S. and Lee, S.-H. (2010), "Characteristics of Vertical Stress Distribution in Sandy Soil According to the Relative Compaction and Composition of the Soil Layer", Journal of the Korean Society of Agricultural Engineers, Vol.52, No.2, pp.43-50.

Paikowsky, S. G., Palmer, C. J., and Rolwes, L. E. (2006), "The Use of Tactile Sensor Technology for Measuring Soil Stress Distribution", GeoCongress 2006: Geotechnical Engineering in the Information Technology Age, pp.1-6.

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Shin, S., Lee, H., and Woo, S. I. (2022), "Experimental Assessment of Reduction in the Negative Skin Friction Using a Pile with a Member Responding to Ground Deformation", Journal of the Korean Geotechnical Society, Vol.38, No.3, pp.5-16.

Tekscan (2020), Best practices in mechanical integration of the FlexiForce™ sensor, Tekscan Inc, South Boston, MA.

Theroux, B., Labuz, J. F., and Dai, S. (2001), "Field Installation of an Earth Pressure Cell", Transportation Research Record, Vol.1772, No.1, pp.12-19.

Useche-Infante, D., Aiassa-Martínez, G., Arrúa, P., and Eberhardt, M. (2018), "Scale Model to Measure Stress under Circular Footings Resting on Sand", International Journal of Geotechnical Engineering, Vol.15, No.7, pp.877-886.

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Żarkiewicz, K., and Qatrameez, W. (2021), "Assessment of Stress in the Soil Surrounding the Axially Loaded Model Pile by Thin, Flexible Sensors", Sensors, Vol.21, No.21, pp.7214.

Zhu, B., Jardine, R., and Foray, P. (2009), "The Use of Miniature Soil Stress Measuring Cells in Laboratory Applications Involving Stress Reversals", Soils and Foundations, Vol.49, No.5, pp.675-688.