The Ansys Meshing for FEA course covers the principles of mesh generation along with its workflow. Meshing guidelines and best practices are at the core of this course. Ansys Meshing for FEA ensures participants have the pre-requisites to perform simulation in Ansys core FEA simulation tools such as Mechanical, LS Dyna, etc.

This course offers participants the opportunity to develop their simulation skills in Finite Element Analysis (FEA) using Ansys Mechanical. Using Ansys Mechanical, participants will be able to analyze the behavior of components or assemblies under operating conditions and
loads. The course provides a comprehensive introduction to the principles and practical applications of FEA, enabling participants to effectively utilize this technique for structural analysis. Additionally, participants will gain valuable experience in using Ansys Mechanical, a widely used software tool for FEA simulations.

This course is targeted for engineers involved in design and analysis who want to simulate highvelocity dynamic problems such as blasts, explosions, and impacts. It provides a thorough understanding of the explicit solution method and its distinctions from other methods for dynamic analysis in Ansys. Participants will learn to select the appropriate method, apply explicit dynamic setup, create accurate meshing, and use proper solution settings. By the end of the course, participants will have the skills and knowledge needed to perform effective simulations for high-velocity dynamic problems using Ansys.

This training course offers an overview of the various types of dynamic analyses available in Ansys Mechanical. It equips participants with the skills to select the most relevant analysis type for their needs and interpret the results accurately to take informed design decisions. Throughout this course, participants will gain a comprehensive understanding of the dynamic analysis capabilities of Ansys Mechanical, enabling them to apply this knowledge effectively to real-world scenarios.

Throughout this training course, participants will acquire a thorough understanding of the nonlinear solution algorithm and procedures necessary for nonlinear simulations. They will learn to apply these techniques to tackle complex scenarios such as large deflection, surface-to-surface
contact, elastic-plastic material models, and nonlinear buckling. The course will also provide valuable insights into identifying common causes of convergence difficulties in nonlinear solutions. The course’s goal is to equip participants with the skills and knowledge required to perform effective nonlinear simulations and make informed design decisions in real-world scenarios using Ansys.

This training course covers advanced connections between structural systems, including nonlinear elements like seals, gaskets, interference fittings, and bolt pretension. Participants will learn to identify frequent causes of convergence issues in non-linear solutions. The course equips participants with the skills to apply advanced connection techniques and tackle convergence issues in real-world scenarios.

This advanced course aims to provide participants with knowledge and comprehension of material models used to represent non-linear material behavior in metals and elastomers. By the end of the course, participants will have a thorough understanding of these models and how to apply them to engineering scenarios.

This training course showcases the power of the rigid dynamics explicit solver in efficiently and robustly evaluating mechanical systems containing complex assemblies of interconnected rigid parts undergoing large overall motion. Participants will gain an understanding of how to utilize
this solver to effectively analyze such systems and make informed design decisions.

This course aims to equip students with the knowledge and skills necessary to evaluate a structure’s thermal response to different heat loads. It covers methodologies for conducting complete solution processes for three heat transfer phenomena under steady-state and time varying conditions, as well as thermal stress analysis. By the end of the course, participants will have a thorough understanding of how to assess thermal responses in structures and perform thermal stress analysis.

This advanced training course teaches students how to select the best type of analysis for a given problem by understanding stress-life and strain-life fatigue analysis methodologies. Participants will also learn about different types of fatigue loading on structures, including proportional, nonproportional, constant amplitude, and variable amplitude loadings. By the end of the course, participants will be equipped with the knowledge and skills necessary to effectively analyze fatigue in structures and make informed design decisions.

Participants in this advanced training course will learn how to utilize the Ansys nCode Design Life tool for stress-life and strain-life fatigue analysis on structures under fatigue loading. They will also acquire techniques for creating accurate models of complex fatigue scenarios through
material mapping, load mapping, and duty cycle methods. Upon completion, participants will have the skills and knowledge to analyze fatigue in structures effectively with the Ansys nCode Design Life tool.

This course provides an introduction to Ansys Parametric Design Language (APDL), including the associated workflow for building, solving, and post-processing simulation models. Participants will learn how to work at the node and element levels of a finite element model, providing
maximum control over its behavior. This course is designed to equip participants with the skills and knowledge necessary to effectively utilize APDL in their simulation workflow.

This course aims to equip learners with the necessary skills to use Ansys Mechanical for Acoustics analysis. Participants will gain a general understanding of acoustic phenomenon, terminology, and governing equations, while also learning the procedures for performing modal and harmonic acoustics analysis in Ansys Mechanical.

This training course focuses on the Ansys Application Customization Toolkit (ACT) in Mechanical Workbench. Participants will learn how to automate the creation of standard tree objects in Mechanical and its integrated modules, as well as how to create custom loads and results. The
course also covers the capabilities of ACT, providing learners with a comprehensive understanding of its potential applications.

This training course provides basic to intermediate level knowledge on 3D print process simulation. It covers the general overview of the challenges that arise when simulating a print process.

The Ansys Fluent training program provides an in-depth understanding of Computational Fluid Dynamics (CFD) modeling, covering the complete simulation process from geometry preparation and mesh generation to post-processing results. Participants will learn best practices for conducting popular CFD simulations, advanced post-processing features, and gain skills to apply this knowledge to solve real-world fluid dynamics problems.

This training program focuses on providing participants with the fundamental skills needed to conduct basic computational fluid dynamics (CFD) simulations using Ansys CFX software. It covers the entire CFD workflow, from working with CAD models in Ansys Spaceclaim, to generating highquality CFD meshes with Ansys Fluent Meshing, and finally, performing all aspects of CFD simulations in Ansys CFX. By the end of the training, participants will have a solid understanding of the CFD simulation process and be able to conduct basic CFD simulations using Ansys CFX software.

Ansys Chemkin-Pro offers powerful tools for simulating detailed chemistry that is crucial for designing systems with reduced pollutant emissions and undesired byproducts in a cost-effective manner. This course is designed to provide participants with hands-on experience using Ansys Chemkin-Pro to select kinetics models, perform simulations of different reactor types, analyze complex systems, understand critical reactions, and ensure the accuracy of chemistry models used in CFD. Upon completion of the program, participants will be proficient in using Ansys Chemkin-Pro for simulating detailed chemistry and receive a certificate of completion.

The Ansys Polyflow training course focuses on manufacturing applications, teaching participants how to effectively use the software to simulate complex flows, identify potential manufacturing issues, and optimize product quality and production costs. Through this training, participants can improve their work efficiency and enhance their team’s skills, leading to better manufacturing practices and increased profitability. The course also covers the Fluent Materials Processing Workspace, providing a comprehensive understanding of the latest manufacturing tools to solve real-world problems.

The Ansys Rocky training offers participants the opportunity to gain a comprehensive understanding of the software’s capabilities and apply them to real-world problems. By attending this training, customers can learn how to optimize their processes, reduce costs, and increase efficiency by accurately modeling and analyzing particle behavior. Additionally, they will learn how to extract insights and predictions that can improve the design and operation of equipment, saving valuable resources and time.

This advanced training is tailored for Ansys Fluent and CFX users with subject matter expertise in combustion, multiphase, turbulence, and more. It aims to provide the latest industry-specific knowledge and enhance participants’ skills. The training covers various topics, including aeroacoustics behavior prediction, combustion process modeling, complex multiphase flow simulation, turbulence effects prediction, and turbomachinery aero-thermodynamics. By completing this training, participants can improve their expertise in CFD simulations and deliver more accurate and efficient solutions to their industry-specific challenges.

Ansys Fluent Aero Workspace is a powerful tool for aerospace and defense engineers, providing customized workflows to access automation enhancements, High-Speed Numeric (HSN), and convergence best practices. This training is designed to cover all aspects of the Fluent Aero Workspace, from creating a project to setting up parametric simulations. Participants will gain a deep understanding of the Fluent Aero Workspace, allowing them to efficiently and effectively tackle complex aerodynamic problems. This training will help aerospace and defense engineers to optimize designs, reduce costs, and improve the overall performance of their products.

This is an introductory to intermediate-level training program for using Ansys HFSS in all applications, such as RF/microwave, antennas, or planar problems. Participants will gain an understanding of HFSS modeling, solution processing, and post-processing features that can be applied to other advanced applications. The course will also cover advanced topics, such as the dynamic link between EM and circuit, impedance matching, an overview of the HFSS 3D layout interface, and speeding up HFSS simulation using HPC.

SIwave is an advanced analysis and design tool for complex PCBs, packages, silicon interposers, and RDLs. By employing multiple state-of-the-art full-wave EM solvers, SIwave
helps designers solve SI, PI, and EMI/EMC problems of chip/package/board systems. In addition to generating S-parameters, RLCG extractions, and SPICE netlists, SIwave offers a variety of analyses including impedance scanning, DC-IR drop, time-domain reflectometry (TDR), and impedance optimization of PDN using decoupling capacitors. Ports, terminations, and circuit elements can be inserted into the design to set up the simulation and model the system end-to-end.

The Ansys Maxwell standard course introduces learners to the static and quasistatic solvers available in Ansys Maxwell, which operates in the Ansys Electronic Desktop (AEDT). Electric solvers include Electrostatic, and Electric Transient. Magnetic solvers include Magnetostatic, Eddy Current and Magnetic Transient. Most workshops include geometry construction instructions, but the workshops also provide files for learners not interested in 3D modeling practice.

Ansys Icepak provides flow and thermal management solutions for many types of electronic design applications. The primary goal of this course is to cover the basics of using Ansys Icepak in the Ansys Electronics DeskTop (AEDT) user environment. users will be introduced to the world of electronics thermal modeling through a combination of lectures, workshops and examples/demonstrations.

The HFSS Antenna Arrays and Periodic Structures course explores topics such as Infinite Array (Unit Cell analysis), Finite Array with both periodic and semi-periodic (non-identical) unit cell structures, Scanning the beams using Finite Array Beam Angle Calculator Toolkit, and Frequency Selective Surfaces (FSS). This course is designed for intermediate to advanced users and includes four modules with workshops that demonstrate the workflows from start to finish.

The Ansys HFSS SBR+ RCS course provides a comprehensive understanding of radar crossection (RCS) applications using the shooting bouncing rays (SBR) formulation. The course covers both monostatic and bistatic RCS, as well as radar signature imaging applications such as range profile, waterfall plots, and ISAR. It also includes technical descriptions of PTD (physical theory of diffraction), related wedge settings, the development of SBR+ surface currents on scattering geometry, and UTD (uniform theory of diffraction). Additionally, the course provides a detailed explanation of HFSS ACT Extension utilities RADARpre and RADARpost. This course is designed for experienced radar signature engineers who are familiar with Ansys HFSS for antenna applications..

Ansys Systems Tool Kit (STK) provides a physics-based modeling environment for analyzing platforms and payloads in a realistic mission context. The primary goal of this course is to familiarize students with the STK workflow then build up to the advanced analysis capabilities and tools to quantify and measure mission effectiveness.

Ansys Orbit Determination Tool Kit (ODTK) provides highly accurate orbit estimates throughout the engineering life cycle, from mission design through operations. The primary goal of this course is to familiarize students with the orbit determination process and data processing of the associated results.