Tidy3D Alternatives

VSim is the Multiphysics Simulation Software used by design engineers and research scientists who require precise solutions for challenging problems. VSim’s unique combination of Finite-Difference Time-Domain (FDTD), Particle-in-Cell (PIC), and Charged Fluid (Finite Volume) methods deliver accurate results for a variety of situations, including plasma modeling. As a parallel software application, VSim can efficiently handle problems at scale, and simulations run quickly using algorithms designed for high-performance computing systems. Trusted by researchers in 30 countries, and used by engineers in industries from aerospace to semiconductor manufacturing, With documented accuracy, VSim provides results that users can trust. Created by a team of computational scientists, Tech-X’s code has been cited thousands of times in the scientific literature, and VSim can be found at many of the world’s top research institutions.

Today, product simulation is often being performed by engineering groups using niche simulation tools from different vendors to simulate various design attributes. The use of multiple vendor software products creates inefficiencies and increases costs. SIMULIA delivers a scalable suite of unified analysis products that allow all users, regardless of their simulation expertise or domain focus, to collaborate and seamlessly share simulation data and approved methods without loss of information fidelity. The Abaqus Unified FEA product suite offers powerful and complete solutions for both routine and sophisticated engineering problems covering a vast spectrum of industrial applications. In the automotive industry engineering work groups are able to consider full vehicle loads, dynamic vibration, multibody systems, impact/crash, nonlinear static, thermal coupling, and acoustic-structural coupling using a common model data structure and integrated solver technology.

Just open a regular web browser such as Firefox or Chrome and search online for “caeplex.” It works in any operating system such as Windows, MacOS, GNU/Linux, iOS, Android, etc. The computations are performed on our servers so CAEplex works on any existing PC, laptop, tablet or phone without requiring any hardware update nor maintenance. No need to buy a new computer nor to add RAM to your oldie one. Our killer feature: “ease and speed.” A CAEplex case can be solved from scratch down to the results in less than one minute thanks to our 3-step workflow. If you know a faster FEA app, please let us know. CAEplex can be used from any mobile device such as a tablet or phones, no matter how old or wrecked. Access and show your work from any location at any time. Enjoy working in an agile development leveraging simulation (we rather say “modeling”), additive manufacturing, and mobile online collaboration.

Simulate real-world designs, devices, and processes with multiphysics software from COMSOL. General-purpose simulation software based on advanced numerical methods. Fully coupled multiphysics and single-physics modeling capabilities. Complete modeling workflow, from geometry to postprocessing. User-friendly tools for building and deploying simulation apps. The COMSOL Multiphysics® software brings a user interface and experience that is always the same, regardless of engineering application and physics phenomena. Add-on modules provide specialized functionality for electromagnetics, structural mechanics, acoustics, fluid flow, heat transfer, and chemical engineering. Choose from a list of LiveLink™ products to interface directly with CAD and other third-party software. Deploy simulation applications with COMSOL Compiler™ and COMSOL Server™. Create physics-based models and simulation applications with this software platform.

DIGIMU® generates digital polycrystalline microstructures representative of the material's heterogeneities (compliance with the topological characteristics of the microstructure). The boundary conditions applied to the REV are representative of that experienced by a material point at the macroscopic scale (thermomechanical cycle of the considered point). Based on a Finite Elements formulation, the various physical phenomena involved during metal forming processes are simulated (recrystallization, grain growth, Zener pinning due to second phase particles, etc.). In order to improve digital precision and to reduce computation times, the software is capable of providing a precise description of the interfaces (grain boundaries) while using an appropriate number of elements thanks to a fully automated anisotropic meshing and remeshing adaptation technology.

GENOA 3DP is an Additive Manufacturing design tool and software suite for polymers, metals and ceramics. The simulate to print toolset showcases robust capabilities and seamless user interactivity making it a suitable solution for various applications. Providing users with accuracy down to the micro-scale and reducing material waste & engineering time considerably, GENOA 3DP can quickly be integrated into any process for an optimum AM build. Founded on progressive failure analysis methods, and combined with multi-scale material modeling, GENOA 3DP allows engineers to accurately predict void, net-shape, residual stress, crack growth and other anomalies associated with as-built AM parts. Providing a repeatable methodology to improve part quality, reduce scrap rate, and meet specification, GENOA 3DP bridges the gap between material science and finite element analysis.

WELSIM finite element analysis software helps engineers and researchers conduct simulation studies and prototype virtual products.

SimScale is a cloud-based web application that plays a key part in simulation software for many kinds of industries. The platform allows the use of Computational Fluid Dynamics (CFD), Finite Element Analysis (FEA), and Thermal Simulation. It also offers 3D simulation, continuous modeling, and motion & dynamic modeling.

CAD-embedded finite element analysis software. Use a wider variety of study types and materials in your analysis. Inventor® Nastran® delivers finite element analysis (FEA) tools for engineers and analysts. Simulation covers multiple analysis types, such as linear and nonlinear stress, dynamics, and heat transfer. Inventor Nastran is available only in the Product Design & Manufacturing Collection. The Product Design & Manufacturing Collection delivers tools that work right inside Inventor—including advanced simulation, 5-axis CAM, and nesting, plus AutoCAD and Fusion 360.

HyperWorks provides easy-to-learn, effective workflows that leverage domain knowledge and increase team productivity, enabling the efficient development of today’s increasingly complex and connected products. The new HyperWorks experience was created to free engineers to move from physics to physics, domain to domain, and even create reports without ever leaving their model. Create, explore and optimize designs within HyperWorks to produce robust designs that accurately model structures, mechanisms, fluids, electromagnetics, electrical, embedded software, systems design, and manufacturing processes. The solution-specific workflows enhance a growing number of engineering processes including fatigue analysis, concept design optimization, CFD modeling, and design exploration. Each provides a meticulously designed and intuitive user interface, differentiated for each user profile while remaining consistent and easy to learn.

Subject your designs to real world conditions to raise product quality while reducing prototyping and physical testing costs. SOLIDWORKS® Simulation is an easy-to-use portfolio of structural analysis tools that use Finite Element Analysis (FEA) to predict a product’s real-world physical behavior by virtually testing CAD models. The portfolio provides linear, non-linear static and dynamic analysis capabilities. SOLIDWORKS Simulation Professional enables you to optimize your design, determine product mechanical resistance, product durability, topology, natural frequencies, and test heat transfer and buckling instabilities. It can also perform sequential multi-physics simulations. SOLIDWORKS Simulation Premium lets you efficiently evaluate your designs for nonlinear and dynamic response, dynamic loading, and composite materials. SOLIDWORKS Simulation Premium includes three advanced studies: Non-Linear Static, Non-Linear Dynamic, and Linear Dynamics.

Enhance your product design with simulation and analysis to reduce costly physical prototyping while increasing your products' durability, reliability, and safety. Using digital prototypes to understand how your designs perform in real-world conditions is vital to your product development process. Creo Simulation is designed uniquely for the engineer. It comes complete with structural, thermal, and vibration analysis solutions and a comprehensive set of finite elements analysis (FEA) capabilities. With Creo Simulation, you can analyze and validate the performance of your 3D virtual prototypes before you make the first part. We offer flexible and unique simulation solutions for our customers. Utilize this section to gain insights into what we offer to fit your needs. If you have any questions about our tool stack, feel free to contact a Creo representative.

With CONSELF you can exploit Computational Fluid Dynamics (CFD) and Finite Element Analysis (FEA) to improve your products design: minimize drag and fluid dynamics losses, increase efficiency, maximize heat exchange performances, estimate pressure loads, verify material resistance, evaluate components shape deformation, calculate natural frequencies and modes, and much more. Static and dynamic simulations are available for Structural Mechanics, with both elastic and plastic materials behavior. Modal and frequency analyses can also be carried out starting from most common CAD neutral file formats.

Simcenter Femap is an advanced simulation application for creating, editing, and inspecting finite element models of complex products or systems. You can use advanced workflows in Simcenter Femap to model components, assemblies, or systems, to then determine a model’s behavioral response when subjected to real-world conditions. In addition, Simcenter Femap provides powerful data-driven and graphical results visualization and evaluation, which in combination with the industry-leading Simcenter Nastran, delivers a comprehensive CAE solution that improves product performance. In the quest to make products lighter yet stronger, manufacturers are increasing their use of composite materials. Simcenter is at the leading edge of composites analysis through continuous development of material models and element types. Simcenter speeds the entire process for simulating laminate composite materials through a seamless connection to composites design.

Ansys Maxwell is an EM field solver for electric machines, transformers, wireless charging, permanent magnet latches, actuators and other electr mechanical devices. It solves static, frequency-domain and time-varying magnetic and electric fields. Maxwell also offers specialized design interfaces for electric machines and power converters. With Maxwell, you can precisely characterize the nonlinear, transient motion of electromechanical components and their effects on the drive circuit and control system design. By leveraging Maxwell’s advanced electromagnetic field solvers and seamlessly linking them to the integrated circuit and systems simulation technology, you can understand the performance of electromechanical systems long before building a prototype in hardware. Maxwell offers a trusted simulation of low-frequency electromagnetic fields in industrial components.

FEATool Multiphysics - "Physics Simulation Made Easy" - a fully integrated physics, CAE, and PDE simulation toolbox

Simcenter Nastran is a premier finite element method (FEM) solver for computational performance, accuracy, reliability and scalability. Simcenter Nastran includes powerful solutions for linear and nonlinear structural analysis, structural dynamics, acoustics, rotor dynamics, aeroelasticity, thermal analysis, and optimization. The advantage to having all these solutions available in a single solver is that input/output file formats are the same for all solution types, which greatly simplifies modeling processes. Available as a standalone enterprise solver or as an integrated solver in Simcenter 3D, Simcenter Nastran helps manufacturers as well as engineering suppliers in aerospace, automotive, electronics, heavy machinery, medical device, and other industries for their critical engineering computing needs so they can produce safe, reliable and optimized designs within ever shorter design cycles.

Based on a local density map, REM3D® provides reliable answers for the prediction of parts resistance as well as insulating, noise and/or comfort properties. Simulate a ‘dual foam’ pouring and observe the transition zones between foams of different rigidities. Taking into account "mold tilting" translates realistic process conditions to be as close as possible to reality. The integration of functionalities such as automatic mold tilting or the impact of gravity on the melt flow allows to analyze the real conditions of your processes to guarantee the homogeneity of your parts. The study of the positioning of the injectors limits the presence of defaults. Thus, you get reliable predictions concerning the resistance of your parts but also the insulating and comfort properties of the foams. For plastics with fibers, REM3D® determines the fiber's orientation during the filling stage and after cooling.

Make Better Decisions with Tecplot 360, the most complete CFD Post processor. More CFD simulations are being run, grid sizes are getting larger, and data sets are being stored remotely. It’s essential that you have the right tools to handle large data sets, automate workflows, and visualize parametric results. Tecplot 360 helps you spend less time waiting and more time discovering. Integrate XY, 2D & 3D plots and get them looking exactly the way you want. Communicate your results with brilliant images and animations. Automate the boring stuff with PyTecplot Python scripting. Never miss a result when analyzing parametric data with Chorus. Securely access large, remote data with SZL-Server client-server. Load Tecplot, FLUENT, PLot3D, CGNS, OpenFOAM, FVCOM, VTU data and 22 other CFD, FEA, structural analysis, and industry-standard data formats. Report and compare solutions in a multi-frame environment with multiple pages.

The tools of cold forming undergo strong mechanical and tribological stresses during their life cycle. These can lead in certains cases of damaged premature tools. The tools represent an important part of the manufacturing cost of a part; thus it is essential to anticipate well these problems during the designs. COLDFORM® allows you to analyze mechanical die strength in order to extend their service life. The software can compute stress distribution within the die, along with deformations, wear, temperatures and damage at any time during the process. COLDFORM® can carry out rapid analyzes which consist in applying stresses obtained during the forming process computation, to the tools. Moreover, COLDFORM® is capable of performing coupled part/tool computations, giving extremely precise results. Thanks to the functionalities dedicated to pre-stressed dies, it is possible to accurately determine the value of the necessary pre-stressing of the interference fit of the tools.

Ansys Mechanical is a best-in-class finite element solver with structural, thermal, acoustics, transient and nonlinear capabilities to improve your modeling. Ansys Mechanical enables you to solve complex structural engineering problems and make better, faster design decisions. With the finite element analysis (FEA) solvers available in the suite, you can customize and automate solutions for your structural mechanics problems and parameterize them to analyze multiple design scenarios. Ansys Mechanical is a dynamic tool that has a complete range of analysis tools. Ansys Mechanical offers a dynamic environment with a complete range of analysis tools, from preparing geometry for analysis to connecting additional physics for even greater fidelity. The intuitive and customizable user interface enables engineers of all levels to get answers fast and with confidence. Ansys Mechanical creates an integrated platform that uses finite element analysis (FEA) for structural analysis.

Ansys Lumerical FDTD is the gold-standard for modeling nanophotonic devices, processes, and materials. The integrated design environment provides scripting capability, advanced post-processing, and optimization routines. This finely tuned implementation of the FDTD method delivers best-in-class solver performance over a broad spectrum of applications. The integrated design environment provides scripting capability, advanced post-processing and optimization routines, allowing you to focus on your design and leave the rest to us. A range of benefits allow for flexible and customizable models and simulations. Ansys Lumerical FDTD models nanophotonic devices, processes and materials so you can focus on creation. Lumerical FDTD is the gold-standard for modeling nanophotonic devices, processes and materials. This finely tuned implementation of the FDTD method delivers reliable, powerful and scalable solver performance over a broad spectrum of applications.

An ultra-fast, oct-tree accelerated Monte-Carlo ray tracing algorithm is used by RadCAD to compute radiation exchange factors and view factors. Innovations by C&R Technologies to the ray tracing process have resulted in an extremely efficient thermal radiation software tool. Using finite difference "conics" (simple geometric objects) or curved finite elements from TD Direct®, RadCAD can accurately model diffuse or specular reflections and transmissive surfaces regardless of node density. The needs of the thermal solution dictate the number of nodes, not the accuracy requirements of the radiation. RadCAD makes use of user-defined databases of optical properties. Each surface coating defines absorptivity, transmissivity, and reflectivity along with specularity in both the solar and infrared wavelength regimes. These properties can be defined versus incident angle or even with wavelength dependence.

Analytic Solver Optimization - 100% upward compatible from the Excel Solver - handles every type and size of the conventional optimization problem (without uncertainty). Unlike other optimization software, it algebraically analyzes your model structure and maximally exploits multiple cores in your PC. You can solve nonlinear models 10 times larger, and linear models 40 times larger than the Excel Solver, get solutions much faster – and plug-in Solver Engines to handle up to millions of variables! Analytic Solver Simulation gives you easy-to-use, powerful Monte Carlo simulation and risk analysis, decision trees, and simulation optimization using Frontline’s advanced Evolutionary Solver. With 60 probability distributions plus compound distributions, automatic distribution fitting, rank-order and copula-based correlation, 80 statistics, risk measures and Six Sigma functions, multiple parameterized simulations and more.

The primary applications of AxisVM are in the design of buildings, and industrial and geotechnical structures. Due to its powerful finite element solver and practical modeling tools, it has also been used in bridge design, and in the design of composite structures, machines, and vehicles. Besides the basic configurations, optional design modules are available for structures made of reinforced concrete, steel, timber, and masonry members and connections. In addition, thanks to the special elements and analysis capabilities, users have successfully applied AxisVM to the design of innovative and custom structures. Reports can be created based on tables, drawings, and detailed design calculations with additional headings and text lines. Reports are auto-updating, i.e. generated based on the most current model data and results.

Patran provides a rich set of tools that streamline the creation of analysis ready models for linear, nonlinear, explicit dynamics, thermal, and other finite element solutions. From geometry cleanup tools that make it easy for engineers to deal with gaps and slivers in CAD, to solid modeling tools that enable creation of models from scratch, Patran makes it easy for anyone to create FE models. Meshes are easily created on surfaces and solids alike using fully automated meshing routines, manual methods that provide more control, or combinations of both. Finally, loads, boundary conditions, and analysis setup for most popular FE solvers is built in, minimizing the need to edit input decks. Patran's comprehensive and industry tested capabilities ensure that your virtual prototyping efforts provide results fast so that you can evaluate product performance against requirements and optimize your designs.

Use optimization and simulation models in your desktop, Web or mobile application. Use the same high-level objects (like Problem, Solver, Variable and Function), collections, properties and methods across different programming languages. The same object-oriented API is exposed "over the wire" through Web Services WS-* standards to remote clients in PHP, JavaScript, C# and other languages. Procedural languages can use conventional calls that correspond naturally to the properties and methods of the Object-Oriented API. Linear and quadratic programming, mixed-integer programming, smooth nonlinear optimization, global optimization, and non-smooth evolutionary and tabu search are all included. The world's best optimizers, from Gurobi™, XPRESS™ and MOSEK™ for linear, quadratic and conic models to KNITRO™, SQP and GRG methods for nonlinear models "plug into" Solver SDK. Easily create a sparse DoubleMatrix object with 1 million rows and columns.

With CalculiX finite element models can be built, calculated, and post-processed. The pre-and post-processor is an interactive 3D tool using the OpenGL API. The solver is able to do linear and non-linear calculations. Static, dynamic, and thermal solutions are available. Because the solver makes use of the abaqus input format it is possible to use commercial pre-processors as well. In turn the pre-processor can write mesh-related data for nastran, abaqus, ansys, code-aster, and for the free-cfd codes dolfyn, duns, ISAAC and OpenFOAM. A simple step reader is included. In addition, external CAD interfaces are available. The program is designed to run on Unix platforms like Linux and Irix computers but also on MS Windows.

SPACE GASS is a multi-purpose 3D analysis and design program for structural engineers. Its extensive range of features make it suitable for anything from beams, trusses and frames to buildings, towers, tanks, cable structures and bridges. Capabilities include a 64-bit multi-core solver, silky smooth 3D rendered graphics, plate finite elements, frame elements, cable elements, tension/compression-only elements, moving loads and links to many CAD and building management programs. Why SPACE GASS Save time, money, and get a safe and efficient design. Silky smooth graphical interface that lets you see your changes visually as you go. A fast sparse matrix solver that fully utilizes the parallel processing power of multi-core computers. A wide range of structural modeling tools, analysis options and design modules. Comprehensive video tutorials to walk you through some of the tricky stuff. Configurable for stand-alone or floating network systems.

XFdtd is a full-wave 3D electromagnetic (EM) simulation software created by Remcom. This innovative and full-featured electromagnetic simulation solver provides high-performance computing options and simplifies the analysis of the most complex EM problems. XFdtd offers a wide range of applications that include microwave device design, antenna design and placement, radar and scattering, biomedical applications, automotive radar, waveguides, military and defense contracts, RFID, EMC/EMI, and more.

GT STRUDL® is structural engineering software offering a complete design solution, including 3D CAD modeling and 64-bit high-performance computation solvers into all versions. GT STRUDL includes all the tools necessary to analyze a broad range of structural engineering and finite element analysis problems, including linear and nonlinear static and dynamic analysis, and can do so accurately in a fraction of the time of most other structural design software. Structural design software helps structural engineers create safe and effective designs, while managing the complexity of many different scenarios across a range of industries, including power, civil engineering, marine and infrastructure. Quality software includes many features, such as interoperability, structural analysis, database-driven design and quality assurance - all of which are included in GT STRUDL.

Powerful and flexible preprocessor for high quality finite element meshes. Attractive cost - an order of magnitude lower than foreign counterparts. Strength calculations under static and dynamic loading. Calculation of natural frequencies and vibration modes. Calculation of critical loads and buckling modes. 2D and 3D calculations for volumetric, thin-walled and bar structures. Elastoplastic deformation according to the mises and drucker-prager models. Strength calculations for large displacements. Calculation of thermal conditions, heat loss, temperature deformations of parts and structures. Strength calculations for highly elastic materials.

Simcenter MAGNET is a powerful electromagnetic field simulation solution for performance prediction of motors, generators, sensors, transformers, actuators, solenoids, or any component with permanent magnets or coils. Simcenter MAGNET helps you predict the performance of any component with permanent magnets or coils. Perform low-frequency electromagnetic field simulations. Simcenter MAGNET includes capabilities to accurately model the physics of electromagnetic devices. This includes the ability to model manufacturing processes, temperature-dependent material properties, magnetization and de-magnetization modeling, and vector hysteresis models among others. Simcenter MAGNET also has a built-in motion solver with a six-degree-of-freedom capability. It allows for complex problems like magnetic levitation or complex motion to be accurately modeled and analyzed. This is made possible with a unique smart re-meshing technology.

From digital twins for virtual commissioning to system-level models for complex engineering design projects, MapleSim is an advanced modeling tool that helps you reduce development time, lower costs, and diagnose real-world performance issues. Remove vibrations with better control code, not hardware upgrades. Diagnose root-cause performance issues with detailed simulation results. Validate new design performance before physical prototyping. MapleSim is an advanced system-level modeling and simulation tool that applies modern techniques to dramatically reduce model development time, provide greater insight into system behavior, and produce fast, high-fidelity simulations. Scale and connect as the needs of your simulations grow more complex. Take your designs further with our flexible modeling language. Combine components across different domains in a virtual prototype. Solve tough machine performance problems.

nCode DesignLife is an up-front design tool that identifies critical locations and calculates realistic fatigue lives from leading finite element (FE) results for both metals and composites. Design engineers can go beyond performing simplified stress analysis and avoid under- or over-designing products by simulating actual loading conditions to avoid costly design changes. Product options containing functions for virtual shaker testing, fatigue of welds, vibration fatigue, crack growth detection, fatigue of composites, thermo-mechanical fatigue analysis. Advanced technology for multiaxial, welds, short-fibre composite, vibration, crack growth, thermo-mechanical fatigue. Intuitive, graphical interface for performing fatigue analysis from leading FEA results data, including ANSYS, Nastran, Abaqus, Altair OptiStruct, LS-Dyna and others. Multi-threaded and distributed processing capabilities for processing large finite element models and complete usage schedules.

SafeGrid Earthing Software is apt for earthing systems designs. The software performs accurate, finite elements based calculations. SafeGrid Earthing software is proven, affordable and easy to use. The software calculates grid resistance, touch and step voltages and lightning protection for substations. The software is helping industries for the last ten years. The software includes all the modules you need for performing a safe earthing system design in the safe grip. It includes: Fault current distribution. Soil modelling. Build grid. Safety criteria. Safe results. Along with the software, you get support from our earthing expert engineers. SafeGrid Earthing software that saves you time and money for your projects.

SolidFEA is our innovative solid finite element analysis tool, designed to make advanced structural engineering design both accessible and affordable. Powered by the Calculix engine, it offers detailed sub-model analysis with lower cost and hardware requirements than competitors like Abaqus. Ideal for complex engineering challenges, including steel connections and bridge engineering, SolidFEA democratizes specialty software with ease of use and IFC file format compatibility, complementing our GenFEA software for comprehensive structural analysis. SolidFEA marks a transformative step in structural engineering design, bridging the gap that has long existed due to the prohibitive costs, complex learning curves, and high-end computing requirements associated with solid finite element analysis (FEA). Designed for ease of use, it supports IFC file format imports, making it a seamless addition to engineering workflows.

With PLAXIS 2D LE or PLAXIS 3D LE you can model and analyze geoengineering projects with limit equilibrium. These powerful software applications for limit equilibrium slope stability analysis and finite element analysis of groundwater seepage provide rapid, comprehensive analysis for various conditions. Create 2D and 3D limit equilibrium slope stability models of soil and rock slopes. Take advantage of the comprehensive set of search methods and more than 15 analysis methods. Use multiplane analysis (MPA), for enhanced spatial slope stability analysis. Perform analysis on embankments, dams, reservoirs, and cover systems through earth structures and broader hydrogeological settings.

The DesignCalc software provides a rich array of capabilities to each user, along with an embedded library of industry data and proven methodologies that make ASME BPVC Section VIII pressure vessel design compliance easier than ever before! Finite Element Analysis (FEA) software for quick and easy analysis. NozzlePRO is a powerful and fast 3-D FEA tool for modeling nozzles, saddles, pipe shoes and clips. Optimize your design by calculations that solve for either pressure or thickness. Build using the thinnest material or material you have on hand while meeting the applicable code. Generate industry-accepted report formats that include the actual calculations used and ready for Inspector reviews.

Ansys Sherlock is the only reliability physics-based electronics design tool that provides fast and accurate life predictions for electronic hardware at the component, board and system levels in early stage design. Ansys Sherlock automated design analysis provides fast and accurate life predictions for electronic hardware at the component, board and system levels in early design stages. Sherlock bypasses the ‘test-fail-fix-repeat’ cycle by empowering designers to accurately model silicon–metal layers, semiconductor packaging, printed circuit boards (PCBs) and assemblies to predict failure risks due to thermal, mechanical and manufacturing stressors--all before prototype. With embedded libraries containing over 500,000 parts, Sherlock rapidly converts electronic computer-aided design (ECAD) files into computational fluid dynamics (CFD) and finite element analysis (FEA) models. Each model contains accurate geometries, material properties and translates stress information.

Fatigue Essentials is a desktop application used to efficiently conduct structural fatigue analysis. Fatigue Essentials provides a user-friendly tool for conducting stress-life analysis either using classical stress calculations or linked with FEMAP™ and using the finite element generated stresses. The program is structured to guide the user through the analysis by following a tree structure. General analysis options are selected following loads, materials, and spectrum branches. Within each branch are options for analysis variations or input methods. Analysis results are available on-screen to paste into a report and/or as a damage contour plot in FEMAP. Covers most engineering requirements. Classic mode with user input stresses. Professional mode (FEMAP-linked) with the ability to read nodal stresses and push back results in a damage contour plot. Option for either interactive input or file input for stresses and cycles.

SwiftComp is a revolutionary multiscale, multiphysics composite simulation code that quickly and easily delivers the accuracy of 3D FEA at the efficiency of simple engineering models. In doing so, SwiftComp reduces barriers for engineers by enabling them to model composites as easily as metals using conventional structural elements in their FEA codes (without losing accuracy while capturing all the microstructural details). SwiftComp provides unified modeling for 1D (beams), 2D (plates/shells), or 3D structures, calculating all the effective properties. Use SwiftComp either independently for virtual testing of composites or as a plug-in to power your conventional structural tools with high-fidelity composites modeling. SwiftComp can compute the best structural model for use in macroscopic structural analysis, as well as perform dehomogenization to compute the pointwise stresses in the microstructure. SwiftComp directly interfaces with ABAQUS, ANSYS.

Eyeshot is a CAD control based on the Microsoft NET Framework. It allows developers to add CAD functionalities to WinForms and WPF applications in a snap. Eyeshot provides tools for building geometry from scratch, for analyzing it with finite element method and to generate toolpaths on it. Geometry can also be imported or exported using CAD exchange file formats. Combine multiple data sources, input devices and CAD entity types as has never been possible before. Import your dataset from file or from Visual Studio project resources or from database. Allow end-users to interact using keyboard, mouse, 3D mouse or fingers. Select between Mesh, Solid and Nurbs surface modeling technologies to unleash your creativity. Eyeshot is the only 100% NET CAD component on the market. With 60+ source code samples (in both C# and VB NET and for both WinForms and WPF platforms) it’s also the easiest to learn.

GASP is a structured/unstructured, multi-block CFD flow solver which solves the Reynolds Averaged Navier-Stokes (RANS) equations as well as the heat conduction equation for solid bodies. Hierarchical-tree based organization. Pre- and post-processing in one interface. Solves steady and unsteady 3-D, Reynolds-Averaged, Navier-Stokes Equations (RANS) and subsets. Multi-block structured/unstructured grid topology. Unstructured mesh support for tetrahdra, hexahedra, prisms, and pyramids. Integration with portable extensible toolkit for scientific computation library. Uncoupling of systems including turbulence and chemistry for improved computational efficiency. Support for most parallel computers, including clusters. Integrated domain decomposition is transparent to the user.

Modelon’s OPTIMICA Compiler Toolkit, the most advanced Modelica-based mathematical engine on the market, offers users a powerful solution for the automation, simulation and optimization of system behaviors throughout the model-based design cycle. Trusted as the compiler for Modelon Impact, OPTIMICA enables users to build multi-domain physical systems by choosing from thousands of available model components. OPTIMICA’s state-of-the-art solvers empower evaluation of complex physical systems – supporting transient simulations as well as steady-state computations and dynamic optimization. The sophisticated mathematical engine can manipulate and simplify models to improve performance and robustness, serving industries and applications ranging from automotive and active safety to energy and power plant optimization. To meet the increased need for regulating power in today’s energy market, start-up optimization of thermal power plants is a key industrial need.

Based on computational physics, Energy2D is an interactive multiphysics simulation program that models all three modes of heat transfer, conduction, convection, and radiation, and their coupling with particle dynamics. Energy2D runs quickly on most computers and eliminates the switches among preprocessors, solvers, and postprocessors typically needed to perform computational fluid dynamics simulations. It allows you to design "computational experiments" to test a scientific hypothesis or solve an engineering problem without resorting to complex mathematics. Work is also underway to incorporate other types of energy transformations and support multiple types of fluids. The conduction part of Energy2D is highly accurate, but the convection and radiation parts are not 100% accurate. Hence, in cases that involve convection and radiation, Energy2D results should be considered qualitative. More than 40 scientific papers have used Energy2D as a research tool.

36% decrease in power consumption of the end product, with an optimized sensor design. Acceleration in their R&D efforts by being able to test hundreds of different sensor components and design variations simultaneously. Ability to identify design flaws in a matter of hours instead of weeks, and thus reducing the time-to-market for new products. Its cutting-edge algorithms are integrated within a simple, intuitive user environment to support the effortless design of great touch screen products. Fieldscale solvers expand the boundaries of electric simulation as we know them today, enabling very complex simulations. With thousands or even millions of analyses and different scenarios and get the results the same day. Fieldscale finally enables the possibility for you to realize optimal design easier and faster than your competitors.

A powerful and flexible Computer Generated Forces (CGF) platform to fill your synthetic environments with urban, battlefield, maritime, and airspace activity. VR-Engage lets users play the role of a first-person human character; a ground vehicle driver, gunner, or commander; or the pilot of a fixed-wing aircraft or helicopter. Game-like visual quality in a high-performance image generator. Designed by modeling & simulation experts for training and simulation projects. Physically accurate sensors, model the physics of light in any wavelength to represent electro-optical, night-vision, and infrared sensors. Applications that let you model, simulate, visualize, and participate in whole-earth multi-domain simulations. Multi-domain computer-generated forces. Multi-role virtual simulator. Image generator & battlefield visualization. EO, IR, and NVG imaging sensors. Synthetic aperture radar simulation.

OnScale is the first Cloud Engineering Simulation platform. It combines powerful multiphysics solver technology with the limitless compute power of cloud supercomputers. With OnScale, engineers can run massive numbers of full 3D multiphysics simulations in parallel to create true Digital Prototypes digital representations of physical high-tech devices that capture the complete behavior of a device over its operating envelope. With OnScale Solve we want to provide you with an awesome Cloud Engineering Simulation experience that’s easy, powerful, and gets the job done. OnScale Solve is built to run on public and private cloud supercomputers and includes a functional web-based UI, an API to efficiently integrate into any design workflow, scripting languages to fully customize engineering simulations, and plugins to enhance its modeling capabilities. OnScale Solve gives engineers the simulation capability necessary to synthetically generate data to train sophisticated AI/ML algorithms.

Access Ansys Cloud Direct anywhere, anytime to obtain endless simulation capabilities compatible with most Ansys solvers. Engineering simulation has long been constrained by fixed computing resources available on a desktop or cluster. Ansys Cloud provides access to on-demand, cloud-based computing resources, including both interactive workstations and HPC clusters, for faster, high-fidelity results offering greater performance insight. Ansys Cloud increases simulation throughput by removing the hardware barrier. Ansys Cloud Direct is a scalable and cost-effective approach to HPC in the cloud. To leverage the combined benefits of cloud computing and best-in-class engineering simulation, Ansys partnered with Microsoft® Azure™ to create a secure cloud solution. Within Ansys Mechanical, Ansys Fluent, Ansys Electronics Desktop, Ansys SPEOS, Ansys Discovery, Ansys LS-Dyna, Ansys LST, Ansys CFX and Ansys Lumerical, you can easily access HPC in the cloud directly from the applications