Please use this identifier to cite or link to this item: http://hdl.handle.net/10397/119686
Title: Cavity expansion–contraction-based interpretation of pressuremeter tests in sand
Authors: Li, GY 
Yin, ZY 
Mo, PQ
Yu, HS
Issue Date: 2026
Source: Canadian geotechnical journal, 2026, v. 63, p. 1-18
Abstract: Soil states inferred from solely pressuremeter loading curve are significantly affected by installation, while the utilization of pressuremeter unloading curve is particularly attractive because of providing more reliable results. In this paper, a novel cavity expansion–contraction-based interpretation method for complete pressuremeter loading–unloading curve in sand is proposed with an advanced optimization. To provide efficient theoretical basis for the interpretation, an exact solution for drained cylindrical cavity contraction after expansion in sand characterized by a critical state-based model is proposed employing an explicit hybrid Eulerian–Lagrangian (HEL) method, which is validated against numerical results. Consequently, an interpretation method for pressuremeter loading–unloading curve in sand is developed based on the proposed solution, enabling back-calculations of the effective horizontal stress, the state parameter and other soil parameters through the covariance matrix adaption evolution strategy optimization. The validity of the developed method is verified against two virtual tests, and six laboratory and field pressuremeter tests in different sands. Furthermore, field pressuremeter tests at two sites are selected to examine the applicability of the proposed method, demonstrating its great capabilities in evaluating sand properties with a comparison to results derived from other methods.
Keywords: Cavity expansion–contraction
Critical state
Optimization
Pressuremeter test
Sand
Publisher: Canadian Science Publishing
Journal: Canadian geotechnical journal 
ISSN: 0008-3674
EISSN: 1208-6010
DOI: 10.1139/cgj-2025-0469
Rights: © 2026 The Authors. Permission for reuse (free in most cases) can be obtained from copyright.com (https://marketplace.copyright.com/rs-ui-web/mp).
This is the accepted version of the work. The final published article is available at https://doi.org/10.1139/cgj-2025-0469.
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