Your search keyword '"Mitelman, Amichai"' showing total 12 results

1. A Comparative Study of Embedded Wall Displacements Using Small-Strain Hardening Soil Model.

Author

Eilat, Tzuri, Mitelman, Amichai, McQuillan, Alison, and Elmo, Davide

Subjects

STRAIN hardening, SOIL dynamics, DISPLACEMENT (Mechanics), COMPUTATIONAL mechanics, PREDICTION models

Abstract

Traditional analysis of embedded earth-retaining walls relies on simplistic lateral earth pressure theory methods, which do not allow for direct computation of wall displacements. Contemporary numerical models rely on the Mohr–Coulomb model, which generally falls short of accurate wall displacement prediction. The advanced constitutive small-strain hardening soil model (SS-HSM), effectively captures complex nonlinear soil behavior. However, its application is currently limited, as SS-HSM requires multiple input parameters, rendering numerical modeling a challenging and time-consuming task. This study presents an extensive numerical investigation, where wall displacements from numerical models are compared to empirical findings from a large and reliable database. A novel automated computational scheme is created for model generation and advanced data analysis is undertaken for this objective. The main findings indicate that the SS-HSM can provide realistic predictions of wall displacements. Ultimately, a range of input parameters for the utilization of SS-HSM in earth-retaining wall analysis is established, providing a good starting point for engineers and researchers seeking to model more complex scenarios of embedded walls with the SS-HSM. [ABSTRACT FROM AUTHOR]

Published

2024

2. Development of a spring analogue approach for the study of pillars and shafts

Author

Mitelman, Amichai, Elmo, Davide, and Stead, Doug

Published

2018

3. Back-Analysis of Structurally Controlled Failure in an Open-Pit Mine with Machine Learning Tools.

Author

McQuillan, Alison, Mitelman, Amichai, and Elmo, Davide

Subjects

STRIP mining, MACHINE learning, ROCK mechanics, PARAMETER estimation, FINITE element method

Abstract

Over the past decades, numerical modelling has become a powerful tool for rock mechanics applications. However, the accurate estimation of rock mass input parameters remains a significant challenge. Machine learning (ML) tools have recently been integrated to enhance and accelerate numerical modelling processes. In this paper, we demonstrate the novel use of ML tools for calibrating a state-of-the-art three-dimensional (3D) finite-element (FE) model of a kinematic structurally controlled failure event in an open-pit mine. The failure event involves the detachment of a large wedge, thus allowing for the accurate identification of the geometry of the rock joints. FE models are automatically generated according to estimated ranges of joint input parameters. Subsequently, ML tools are used to analyze the synthetic data and calibrate the strength parameters of the rock joints. Our findings reveal that a relatively small number of models are needed for this purpose, rendering ML a highly useful tool even for computationally demanding FE models. [ABSTRACT FROM AUTHOR]

Published

2023

4. Investigation of Transfer Learning for Tunnel Support Design

Author

Mitelman, Amichai, primary and Urlainis, Alon, additional

Published

2023

5. A Case Study of Thin Concrete Wall Elements Subjected to Ground Loads

Author

Elmo, Davide, primary and Mitelman, Amichai, additional

Published

2023

6. Coupling Geotechnical Numerical Analysis with Machine Learning for Observational Method Projects.

Author

Mitelman, Amichai, Yang, Beverly, Urlainis, Alon, and Elmo, Davide

Subjects

OBSERVATIONAL learning, MACHINE learning, NUMERICAL analysis, GEOTECHNICAL engineering, DECISION making, QUANTUM tunneling

Abstract

In observational method projects in geotechnical engineering, the final geotechnical design is decided upon during actual construction, depending on the observed behavior of the ground. Hence, engineers must be prepared to make crucial decisions promptly, with few available guidelines. In this paper, we propose coupling numerical analysis with machine learning (ML) algorithms for enhancing the decision process in observational method projects. The proposed methodology consists of two main computational steps: (1) data generation, where multiple numerical models are automatically generated according to the anticipated range of input parameters, and (2) data analysis, where input parameters and model results are analyzed with ML models. Using the case study of the Semel tunnel in Tel Aviv, Israel, we demonstrate how this computational process can contribute to the success of observational method projects through (1) the computation of feature importance, which can assist with better identifying the key features that drive failure prior to project execution, (2) providing insights regarding the monitoring plan, as correlative relationships between various results can be tested, and (3) instantaneous predictions during construction. [ABSTRACT FROM AUTHOR]

Published

2023

7. Modelling of blast-induced damage in tunnels using a hybrid finite-discrete numerical approach

Author

Mitelman, Amichai and Elmo, Davide

Published

2014

8. Implementation of Surrogate Models for the Analysis of Slope Problems.

Author

Mitelman, Amichai, Yang, Beverly, and Elmo, Davide

Subjects

SLOPE stability, SUPPORT vector machines, ROCK slopes, RANDOM forest algorithms

Abstract

Numerical modeling is increasingly used to analyze practical rock engineering problems. The geological strength index (GSI) is a critical input for many rock engineering problems. However, no available method allows the quantification of GSI input parameters, and engineers must consider a range of values. As projects progress, these ranges can be narrowed down. Machine learning (ML) algorithms have been coupled with numerical modeling to create surrogate models. The concept of surrogate models aligns well with the deductive nature of data availability in rock engineering projects. In this paper, we demonstrated the use of surrogate models to analyze two common rock slope stability problems: (1) determining the maximum stable depth of a vertical excavation and (2) determining the allowable angle of a slope with a fixed height. Compared with support vector machines and K-nearest algorithms, the random forest model performs best on a data set of 800 numerical models for the problems discussed in the paper. For all these models, regression-type models outperform classification models. Once the surrogate model is confirmed to preform accurately, instantaneous predictions of maximum excavation depth and slope angle can be achieved according to any range of input parameters. This capability is used to investigate the impact of narrowing GSI range estimation. [ABSTRACT FROM AUTHOR]

Published

2023

9. Examining Rock Engineering Knowledge through a Philosophical Lens

Author

Elmo, Davide, primary, Mitelman, Amichai, additional, and Yang, Beverly, additional

Published

2022

10. Field tests of fiber reinforced concrete slabs subjected to close-in and contact detonations of high explosives

Author

Grisaro, Hezi Y., primary, Benamou, David, additional, and Mitelman, Amichai, additional

Published

2022

11. Implementing BIM for conventional tunnels - a proposed methodology and case study

Author

Mitelman, Amichai, primary and Gurevich, Ury, additional

Published

2021

12. Transition to a Competitive Consultant Selection Method: A Case Study of a Public Agency in Israel

Author

Mitelman, Amichai, primary and Giat, Yahel, additional

Published

2021