This training is an introduction to continuous modeling with FLAC2D and FLAC3D. At the end of the course, participants will master the graphical interface, documentation and the main modeling steps. Concepts are illustrated using a tunnel excavation example, from building the model geometry to results analysis. This introductory course provides the foundation for more advanced use of the software, which can be covered in more specific training modules.
The latest updates to ITASCA software products such as FLAC3D, FLAC2D, 3DEC, PFC, and MassFlow now include point releases (e.g., 9.1, 9.2) between major versions (e.g., 9.0, 10.0). These point releases bring significant benefits, especially for subscription license holders.
Subscription license holders enjoy seamless access to point releases at no additional cost. These point releases are packed with new features and capabilities developed in response to user feedback and industry advancements. By staying current with point releases, subscribers can leverage the latest tools and functionalities, enhancing their productivity, efficiency, and competitiveness.
Perpetual license holders also benefit from continuous support within their software version's support period. While they may not receive point releases, they still qualify for bug fix updates and minor improvements, maintaining stability and reliability in their software environment.
PARALLEL MODELING
The advent of ITASCA software web licenses made cloud computing possible, allowing many versions of a model to be run for parametric or sensitivity analyses. With v9.2, a new Cluster option allows FLAC3D subscription licenses to greatly speed up their numerical modeling solutions by launching multiple connected model instances in cluster computing environments.
The Cluster option in FLAC3D utilizes a leader-follower architecture. Each node in the cluster network runs a FLAC3D instance, and all the FLAC3D instances are connected through Message Passing Interface (MPI) for data communication and management. Typically, the Console version of FLAC3D is used to streamline cluster computing, but the GUI version of FLAC3D may also be used to view the local model partials on every node during cycling.
CURRENTLY SUPPORTED FLAC3D FEATURES
THREE TIERS
The FLAC3D Cluster option has three available tiers to choose from:
SPEEDUP
For large models with millions of zones, a significant reduction in solution time can be achieved. The following chart demonstrates considerable scalability when solving a FLAC3D model with 8 million zones across multiple nodes using the Cluster option (performed on Amazon Web Services (AWS), node type m5a.4xlarge with 16 CPU Cores and 64 GB RAM per node).
ACCURACY
The Cluster option in FLAC3D does not affect the results. FLAC3D generates results identical to normal runs with the same level of accuracy and determinism. The save files are also cross-compatible between FLAC3D on your computer and the Cluster option.
HOW DO I USE THE CLUSTER OPTION?
The Cluster option can be used with your organization's own local cluster computing system {add link to cluster computing FAQ}, using any cloud provider like Amazon Web Services (AWS), Microsoft Azure, or Google Cloud. Of course, not all organizations have such systems in house, and implementing a solution using a cloud provider can be daunting. For a straightforward, easy-to-use cloud-based solution, ITASCA works with Rescale to provide a pre-configured cluster computing environment that lets you select the number of nodes, hardware required, and apply your ITASCA software web license. Pricing is clearly shown and includes both Rescale's fees and hardware utilized. Rescale will automatically configure your cluster environment, install the latest ITASCA software version, and manage your model run(s). This approach also reduces capital costs since users do not need to invest money in purchasing many computers to perform these analyses.
LEARN MORE about using Rescale for cluster computing.
WORK FASTER with VERY LARGE MODELS
CURVED MOHR-COULOMB MODEL
The traditional Mohr-Coulomb model assumes that a linear shear failure develops, which is just a simplification by linear extrapolation of the experimental data over a limited stress range. However, experimental data covering low stresses clearly show a curved failure envelope for a wide range of geomaterials from clay to rockfill. As such, this simplification could significantly overestimate safety factor, particularly for a shallow slip surface or near the excavated zones exhibiting low normal stress.
ITASCA has developed a new constitutive model called the Curved-Mohr-Coulomb model, which provides both efficiency and flexibility:
The failure laws based on linear or bilinear Mohr-Coulomb, Hoek-Brown, and Griffith models are special cases of this generalized model. The Curved Mohr-Coulomb constitutive model is available to use with the automatic factor of safety calculation.
SYNTHETIC MICROSEISMICTY
MODEL PLASTIC-STRAIN ON
JOINT-SET WIZARD
NEW TOOLS
ZONE FIELD DATA
LET GeoBOT HELP
NEW UI CONTROL
RAPID TOOLS