Ansys PathFinder Alternatives

OrCAD® X is a unified PCB design software platform that offers significant improvements in ease of use, performance, automation, data management, and collaboration. Our cloud-enabled product suite contains applications for schematic, simulation, and PCB layout. OrCAD X Capture is one of the most widely used schematic design solutions for the creation and documentation of electrical circuits. PSpice® is our virtual SPICE simulation environment integrated within Capture that allows you to prototype your designs using the industry-leading, native analog, mixed-signal, and advanced analysis engines to deliver a complete circuit simulation and verification solution. Our two PCB layout environments, OrCAD X PCB Editor and OrCAD X Presto, allow designers to easily collaborate between ECAD/MCAD teams and build better PCBs faster. OrCAD X Presto is a new user-friendly option offering a simpler interface for quick-turn PCB design.

Ansys Motor-CAD is a dedicated electric machine design tool for fast multiphysics simulation across the full torque-speed operating range. Motor-CAD enables design engineers to evaluate motor topologies and concepts across the full operating range, to produce designs that are optimized for performance, efficiency and size. Motor-CAD software’s four integrated modules—EMag, Therm, Lab, Mech—enable multiphysics calculations to be performed quickly and iteratively, so users can get from concept to final design in less time. Fast calculations and streamlined data input processes leave time for Motor-CAD users to explore more motor topologies and fully assess the impact of advanced loss effects in the initial stages of an electromechanical design. The release includes powerful new features for design optimization, multi-physics analysis and system modelling for electric motors. Fast multiphysics simulation across a full torque-speed operating range.

DigitalClone® for Engineering is the world's only gearbox reliability prediction solution integrating multiple scales of analysis in a single software package. In addition to modeling and analysis capabilities at the gearbox and gear/bearing levels, DC-E is the only solution available that models fatigue life based on detailed, physics-based models of the material microstructure (US Patent 10474772B2). DC-E enables construction of a gearbox digital twin with high value across all stages of the lifecycle of the physical asset - from design and manufacturing optimization to component supplier selection to failure root cause analysis to condition-based maintenance and to prognostics. This computational environment drives down the time and cost to bring new designs to the market and to sustain them over time.

Ansys RedHawk-SC is the industry’s trusted gold standard voltage drop and electromigration multiphysics sign-off solution for digital designs. Its powerful analytics quickly identify any weaknesses and allow what-if explorations to optimize power and performance. Redhawk-SC’s cloud-based architecture gives it the speed and capacity to handle full-chip analysis. Signoff accuracy is certified by all major foundries for all finFET nodes, down to 3nm. Ansys RedHawk-SC enables robust, low-power digital designs without performance loss thanks to advanced power analytics that give designers comprehensive techniques to detect and correct dynamic voltage drop. Ansys RedHawk-SC’s trusted multiphysics signoff analysis is a powerful way to reduce project and technology risk. RedHawk’s algorithms are certified accurate by all major foundries for all finFET processes and are proven in thousands of tapeouts.

Ansys Totem-SC is the proven, trusted industry leader for power noise and reliability signoff for analog and mixed-signal designs built on cloud-native elastic compute infrastructure. Ansys Totem-SC is the industry’s trusted gold standard voltage drop and electromigration multiphysics sign-off solution for transistor-level and mixed-signal designs. With a track record of thousands of tapeouts, Totem-SC’s cloud-based architecture gives it the speed and capacity to handle full-chip analysis. Signoff accuracy is certified by all major foundries for all finFET nodes down to 3nm. Ansys Totem-SC is a transistor-level power noise and reliability analysis platform for analog mixed-signal IP and fully custom designs. It creates IP models for SOC-level power integrity signoff with RedHawk-SC and generates compact chip models of power delivery networks for the chip and system-level. Industry-proven and foundry-certified analog and mixed-signal EM/IR solution.

Ansys Path FX allows you to calculate timing with variation on a full SoC, without taking any shortcuts. Its unique cell modeling delivers SPICE accuracy timing for any voltage or variation condition with a single library. Path FX has a fully threaded and distributed architecture, with the ability to scale to thousands of CPUs. Ansys Path FX’s path-based timing analysis has the technology to account for all critical contributors to delay and constraints across multiple process, voltage, temperature corners and scenarios. It can also automatically identify and simulate every clock path in your design. Two of the biggest challenges facing successful chip design today are limiting the power consumption through lower supply voltages and managing the complexity of advanced silicon processes at 7nm and below.

Ansys RaptorH is an electromagnetic modeling software with capacity to model power grids, full custom blocks, spiral inductors, and clock trees. Its high-speed distributed processing delivers accurate, silicon-proven S-parameter and RLCk models. RaptorH can analyze partial and unfinished layouts during the design phase and makes it easy to use either the general purpose HFSS engine or the silicon-optimized RaptorX engine for silicon structures. Ansys RaptorH extracts electromagnetic models at the pre-LVS stage for arbitrary routing and layout, including planes (solid or perforated), round shapes, spiral inductors, and MiM/MoM capacitors - with automatic setting of boundary conditions. The GUI allows point-and-click net selection and what-if analyses. RaptorH is supported by all major silicon foundries and can read encrypted technology files to set up analyses with either the HFSS or the Raptor engine.

Pharos combines Ansys' unparalleled EM engine capacity with a proprietary high-capacity circuit simulation engine to perform coupling analysis and provide ranking of potential EM crosstalk aggressors per victim node. By highlighting the most susceptible nets, designers can focus their design decisions to manage EM crosstalk on these nets and de-risk the design process. Pharos combines unparalleled extraction engine capacity with a built-in simulation engine to perform EM analysis and provide ranking of potential EM crosstalk aggressors per victim net. This allows designers to focus on the most critical nets in the design. Increasing design complexity, along with the broad scope of magnetic field interference, makes identifying all EM crosstalk susceptible victim/aggressor net pairs a very challenging, if not impossible, task.

Ansys Exalto is a post-LVS RLCk extraction software solution that enables IC designers to accurately capture unknown crosstalk among different blocks in the design hierarchy by extracting lumped-element parasitics and generating an accurate model for electrical, magnetic and substrate coupling. Exalto interfaces with most LVS tools and can complement the RC extraction tool of your choice. Ansys Exalto post-LVS RLCk extraction lets IC designers accurately predict electromagnetic and substrate coupling effects for signoff on circuits that were previously "too big to analyze.” The extracted models are back-annotated to the schematic or netlist, and support all circuit simulators. The proliferation of RF and high-speed circuits in modern silicon systems has raised electromagnetic coupling to a first order effect that must be accurately modeled to reliably achieve silicon success.

Go beyond traditional RF simulation to design, analyze, and verify radio frequency integrated circuits (RFICs). Achieve confidence with steady-state and nonlinear solvers for design and verification. Wireless standard libraries accelerate the validation of complex RFICs. Before taping out an RFIC, verification of IC specifications via RF simulation is a must. Simulations include effects of layout parasitics, complex modulated signals, and digital control circuitry. With PathWave RFIC Design, you can simulate in both the frequency and time domain and bring your designs to and from Cadence Virtuoso. Accurately model components on silicon chips. Optimize designs with sweeps and load-pull analysis. Integrate RF designs in the Cadence Virtuoso environment. Increase performance using Monte Carlo and yield analysis. Simplify debugging with safe operating area warnings. Utilize the latest foundry technology immediately.

Fusion 360 unifies design, engineering, electronics, and manufacturing into a single software platform. Get integrated CAD, CAM, CAE & PCB on a single development platform. Also includes EAGLE Premium, HSMWorks, Team Participant, and access to consumptive services, such as generative design, cloud simulation, and cloud rendering. Engineer products with a comprehensive set of modeling tools. Ensure form, fit, and function of your products with various analysis methods. Create and edit sketches with sketch constraints, dimensions, and a powerful suite of sketch tools. Edit or repair imported geometry from non-native file formats. Make design changes without worrying about time-based features. Create and edit complex parametric surfaces for repairing, patching or designing geometry. Create history-based features, including extrude, revolve, loft, sweep, etc., that update with design changes.

Multipurpose, full wave 3D electromagnetic (EM) simulation software for designing and simulating high-frequency electronic products such as antennas, components, interconnects, connectors, ICs and PCBs. Ansys HFSS is a 3D electromagnetic (EM) simulation software for designing and simulating high-frequency electronic products such as antennas, antenna arrays, RF or microwave components, high-speed interconnects, filters, connectors, IC packages and printed circuit boards. Engineers worldwide use Ansys HFSS software to design high-frequency, high-speed electronics found in communications systems, advanced driver assistance systems (ADAS), satellites, and internet-of-things (IoT) products. HFSS’s unmatched capacity, coupled with indisputable accuracy, enables engineers to address RF, microwave, IC, PCB and EMI problems for most complex systems. The Ansys HFSS simulation suite consists of a comprehensive set of solvers to address diverse electromagnetic problems.

PathWave ADS offers integrated design guidance via templates to help you get started faster. Extensive component libraries make it easy to find the part you want. Automatic sync with layout allows you to visualize the physical layout while making schematic designs. Data helps teams visualize whether their designs meet specifications. The data display and analytics capabilities in PathWave ADS produce graphs, charts, and diagrams to give you design confidence. Quickly accelerate your design with wizards, design guides, and templates. The complete design flow includes schematic, layout, circuit, electro-thermal, and electromagnetic simulations. Signal and power integrity are becoming more important as frequency and speed increase in printed circuit boards (PCBs). Losses associated with transmission line effects can cause failures in electronic devices. Modeling traces, vias, and interconnects are necessary to simulate the board accurately.

To help you tackle increasingly challenging issues related to simultaneous switching noise, signal coupling, and target voltage levels, Cadence® Sigrity X PowerSI® technology provides fast, accurate, and detailed electrical analysis of full IC packages or PCBs. It is cloud ready and can be used pre-layout to develop power- and signal-integrity guidelines, as well as post-layout to verify performance and improve a design without needing a prototype. Using Sigrity X PowerSI electromagnetic (EM) field solver technology, you can readily perform a broad range of studies to identify trace and via coupling issues, power/ground fluctuations caused by simultaneously switching outputs, and design regions that are under or over voltage targets. PowerSI technology also lets you perform extraction of frequency-dependent network parameter models and lets you visualize complex spatial relationships.

Synopsys HSPICE circuit simulator is the industry's "gold standard" for accurate circuit simulation and offers foundry-certified MOS device models with state-of-the-art simulation and analysis algorithms. With over 25 years of successful design tape outs, HSPICE is the industry's most trusted and comprehensive circuit simulator. For on-chip simulation, analog designs, RF design, custom digital design, standard cell design and characterization, memory design and characterization, and device model development. For off-chip signal integrity simulation, silicon-to-package-to-board-to-backplane analysis and simulation. HSPICE is a key part of the Synopsys analog/mixed-signal (AMS) verification suite, a solution built to address the most critical issues in AMS verification. HSPICE is the industry’s “gold standard” for accurate circuit simulation and offers foundry-certified MOS device models with state-of-the-art simulation and analysis algorithms.

To ensure you achieve reliable power delivery, Cadence Celsius PowerDC technology provides efficient DC analysis for signoff of IC package and PCB designs, including electrical/thermal co-simulation, to maximize accuracy. Celsius PowerDC technology quickly pinpoints excessive IR drop, with areas of excess current density and thermal hotspots, to minimize your design’s risk of field failure. Highly accurate, even for complex designs with multiple voltage domains and complex plane structures, providing conclusive IR drop analysis for package and board. Automatically set up DC simulations using PowerTree Technology data (source/sink definitions) captured at the schematic stage of the design process. Comprehensive support for multi-structure designs, including stacked die, multiple boards, and all popular package types.

Electromagnetic (EM) simulation brings you insight before physical prototyping. Customize EM simulations for speed and accuracy. Integrate EM analysis with your circuit simulations. EM simulations can take hours to run. Shorten your import and export time by integrating your EM simulation software with PathWave Circuit Design software. Integrate EM analysis with circuit simulations to maximize efficiency. 3D EM solid modeling environment for creating arbitrary 3D objects and importing existing 3D models from other CAD environments. Prerequisite for preparing a 3D geometry for 3DEM simulation by defining ports, boundary conditions and material properties. 3D EM solid modeling environment and Finite Difference Time Domain (FDTD) simulator. Compliance testing for Specific Absorption Rate (SAR) and Hearing Aid Compatibility (HAC).

Ansys PowerArtist is the comprehensive RTL design-for-power platform of choice of leading low-power semiconductor companies for early power analysis and reduction. PowerArtist includes physically-aware RTL power accuracy, interactive power debug, analysis-driven power reduction, unique metrics for tracking power efficiency and vector coverage, rapid power profiling of real workloads, and seamless enablement of RTL-to-physical power grid integrity. PowerArtist’s unique physically-aware modeling delivers predictable RTL power accuracy with fast turnaround enabling leading semiconductor companies to make early decisions reliably. Analyzing power after synthesis is too late. Design teams rely on PowerArtist to slice and dice power, identify power-inefficient RTL code and every wasted toggle in the design, and rapidly profile millions of cycles.

Microwave Office supports the design of RF passive components such as filters, couplers, and attenuators, as well as active devices operating under small-signal (AC) conditions such as low noise and buffer amplifiers. The linear configuration provides simulation of S-parameters (Y/Z/H/ABCD), small-signal gain, linear stability, noise figure, return loss/voltage standing wave ratio (VSWR), and more, as well as real-time tuning, optimization, and yield analysis. All E-series Microwave Office portfolios include synchronous schematic / layout editors, 2D/3D viewers, comprehensive libraries of high-frequency distributed transmission models, surface-mount vendor component RF models with footprints, measurement-based simulations, and RF plotting. Microwave Office PCB enables linear and nonlinear RF circuit design with the robust APLAC HB simulator and its powerful multi-rate HB, transient-assisted HB, and time-variant simulation engine, supporting analysis of RF/microwave circuits.

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.

Natively based on OpenFlight, the most widespread industry standard for 3D simulation models, Creator is the original software for creating optimized 3D models for use in your virtual environment. Designed specifically for simulation applications, Creator is the industry-standard software in the creation of optimized 3D models for real-time virtual environments. Content creators are constantly challenged to produce more models with higher detail, increased realism, and improved performance. Using a rich set of tools, content creators can build models from scratch, edit or import existing ones, and enhance objects for use in sensor-capable simulations. With full control of the modeling process, Creator allows you to quickly generate highly optimized and physically accurate 3D models with varying levels of detail. With complete interactive control of your models from database level to a single vertex attribute, Creator lets you develop models faster and with more control than ever.

Our next-generation web platform empowers chip developers and verification engineers to design and debug 10x faster. Build and run thousands of tests in parallel at the push of a button with Verilator. Seamlessly share test results and waveforms with anyone in your organization, tag coworkers directly on signals, track test and regression failures. We use Verilator to compile Dockerized simulation binaries and distribute test runs across our compute cluster. Then we collect the results and log files and optionally rerun failing tests to generate waveforms. With Docker, we can ensure that test runs are consistent and reproducible. SiLogy makes chip developers more productive by enabling faster design and debug times. Before SiLogy, the state-of-the-art for debugging a failing test involved copying lines from log files, debugging from waveforms on a local machine, or rerunning a simulation that might have taken days to run.

Analyze RF and microwave circuits and systems with fast simulation and powerful optimization tools. Explore performance trade-offs with automatic circuit synthesis technology. PathWave RF Synthesis (Genesys) provides entry-level functionality suitable for all RF and microwave circuit board and subsystem designers. Identify RF design errors missed by traditional spreadsheet calculations with PathWave Circuit Design. With this entry-level design environment — including circuit, system, and electromagnetic simulators — you will gain confidence in your design reviews before hardware realization. Just a few mouse clicks and you can watch as your matching network is synthesized and optimized automatically. Then, transfer the design to PathWave Advanced Design System (ADS) for inclusion into a more complex design.

Ansys VeloceRF shortens the design cycle by greatly reducing the time it takes to synthesize and model complex spiral devices and T-lines. It takes only a few seconds to compile an inductor or transformer geometry, and just a couple of minutes to model and analyze it. It integrates with leading EDA platforms, instantiating ready-to-tape-out layouts. Ansys VeloceRF allows you to synthesize devices with tight packing of multiple devices and lines for an optimized silicon floorplan. Analysis of the coupling among any number of inductive devices before detailed layout will reduce design size and reduce or eliminate guard rings. Inductor size as well as inductor-to-inductor crosstalk can impact the die size. Ansys VeloceRF helps you design smaller devices through the use of optimization criteria and geometry constraints. In addition, it calculates coupling among any number of inductors to better optimize silicon real estate and to optimize inductors in circuit context.

Methodics IPLM Platform For Full Traceability. Collaborate on worldwide semiconductor design with a new, modern platform. Semiconductor and chip design teams know that the development process can be long and costly. There is little room for error, and if an error happens, you have to go back to the beginning. But when you can share and reuse IP — and design it once and reuse multiple variants — you can accelerate time-to-market and drive greater revenue for your business. Methodics IPLM makes it possible. Methodics IPLM is a comprehensive IP lifecycle management (IPLM) platform. It enables companies of all sizes to have complete control over the design and integration of both internal and external design elements. This includes libraries, new analog and digital design, and standalone IP. Methodics IPLM maximizes internal and external design traceability and reuse by tightly coupling IP creators with IP consumers.

MPLAB® Mindi™ Analog Simulator reduces circuit design time and design risk by simulating analog circuits prior to hardware prototyping. The simulation tool uses a SIMetrix/SIMPLIS simulation environment, with options to use SPICE or piecewise linear modeling, that can cover a very wide set of possible simulation needs. This capable simulation interface is paired with proprietary model files from Microchip to model specific Microchip analog components in addition to generic circuit devices. This simulation tool installs and runs locally on your PC. Once downloaded, no Internet connection is required, and the simulation run time is not dependent on a remotely located server. The result is fast, accurate analog circuit simulations. Run the simulation tool directly on your own PC; once installed no Internet connection is required.

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.

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.

Ultiboard is printed circuit board design and layout software that integrates seamlessly with Multisim to accelerate PCB prototype development. Ultiboard software offers efficient PCB design layout and routing with a customizable environment. You can use its flexible tools to place parts and copper with manual precision to define critical board elements. With its automated functionality, you can quickly complete a design. The advanced spreadsheet view, toolbox, and design wizards help you easily manage, control, and define any board layout. Seamless integration with Multisim software provides simple schematic transfer to PCB, and forward and backward annotation ensures design iteration management. You can easily export industry-standard file formats such as Gerber and DXF to complete the design flow from schematic to layout. From data and automation to research and validation, our tailored, software-connected approach is rooted in helping you engineer what’s next.

Modeling light propagation and its impact is crucial for measuring product performance and human comfort, perception and safety. Ansys Optics uniquely simulates a system’s optical performance and evaluates the final illumination effect, predicts and validates the impact of lighting and material variations on appearance and perceived quality all in real conditions. Visualize your product before it exists to deliver the ultimate virtual customer experience. Let Ansys Optics & optical simulation software lead you to the best solution, no matter the style of your project. The software easily solves complex optical problems and refines visual appearance for perceived quality. Significantly elevate final product quality with true-to-life visual experiences and combine design and engineering processes into a single, connected workflow. Prepare and appraise virtual prototypes of a cockpit HMI in a real-time, immersive environment.

The Cadence AWR Design Environment Platform accelerates RF/microwave product development cycles with design automation that enhances engineering productivity and reduces turnaround time. This seamlessly integrated platform empowers engineers with advanced high-frequency circuit and system simulation coupled with in-design electromagnetic (EM)/thermal analyses for manufacturing-ready high-frequency IP, offering unmatched efficiency and precision. Designed to enhance engineering productivity, the user interface is powerful and intuitive. It offers smart, customizable design flows that cater to the specific needs of today's high-frequency semiconductor and PCB technologies. A unified design capture system facilitates a front-to-back physical design flow. Electrical and layout design entries are dynamically linked, ensuring that components placed in an electrical schematic automatically generate a synchronized physical layout.

Sigrity X Advanced SI technology offers leading-edge signal integrity analysis for PCB and IC packaging designs, covering DC to over 56GHz with advanced features like automated die-to-die SI analysis, topology exploration, and simulation for high-speed interfaces. Supporting IBIS-AMI models and customizable compliance kits, it ensures your designs meet rigorous standards while leveraging frequency domain, time domain, and statistical analysis methods.

Integrated signal integrity, power integrity, 3D electromagnetic modeling & electrical rule checking for high-speed digital designs. HyperLynx combines ease of use with automated workflows to make high-speed design analysis accessible to mainstream system designers. This allows problems to be identified and resolved early in the design cycle. HyperLynx works with multiple PCB tools and is an ideal addition to any PCB design flow. The HyperLynx family provides a complete analysis flow that combines best-practice design rule checking with comprehensive signal and power integrity simulation. Integrated 3D EM solvers create highly accurate interconnect models. Evaluate design tradeoffs with pre-layout analysis and validate designs prior to fab with post-layout analysis. Supports SerDes channels, DDRx memory interfaces, and general-purpose signal integrity. Design and validate a board’s power-delivery network (PDN) to meet impedance goals in an easy-to-use environment.

The Cadence Allegro X Design Platform is the ultimate solution for navigating modern electronic complexities that help support your diverse PCB design needs. As a full-stack engineering platform, it provides a scalable and highly integrated environment for multi-board electronic system design. Allegro X ensures that your global teams can effectively and concurrently collaborate to minimize project risks, lower production costs, and ensure design compliance and standards are met. Electrical engineers and PCB designers can make data-driven decisions with access to constraints and integrated analysis workflows reducing turnaround time while ensuring product reliability, manufacturing, and first pass success.

Choose an existing power solution or customize a suggested design. Schematics and component lists are included. View or modify your choice and, with one click, export the design files to MPLAB® Mindi™ Analog Simulator for verification and analysis. Do you need help calculating your signal chain noise budget? The signal chain signal-to-noise calculator tool provides a simple, intuitive and flexible full noise analysis of your signal chain. Streamlined interface requires minimal data from inputs. Integrated design generators for starting new power designs or refining old designs. Easy transition from power solution selection to design verification. Signal chain signal-to-noise calculator is fully online with no software download required.

JTAG Maps™ is an intuitive Altium extension that allows engineers to quickly assess the test possibilities offered by the JTAG devices within their design. Until now engineers could often spend hours manually highlighting the boundary-scan nets of a design to determine test coverage. Boundary-scan device model files (BSDLs) are pivotal to any JTAG/boundary-scan process as they indicate precisely which pins can be controlled or observed by JTAG/boundary-scan. However JTAG Maps can work with or without BSDL models and includes an 'assume scan covered' option. While most users will want to simply use the coverage report that JTAG Maps for Altium can provide, it is possible to import a more accurate picture. After exporting a JTAG ProVision project, the data can be sent for further analysis. A simple message file containing full fault-coverage information can then be read back into JTAG Maps for display/highlighting.

PCB123 is a full-feature design tool for Printed Circuit Board designers of all levels. Introduced as a free tool in 2002, PCB123 still operates on a risk-sharing business model: We don't get paid until you succeed at designing your PCB. And to help ensure your success, we staff our technical support department with professionals that can answer your questions. So what's to stop you? Easy-to-use, and professional-grade PCB CAD software that's free and fully supported. We don’t throttle our tool and charge you for a license to give you full functionality. We get paid when you order boards – it really is that simple. software developer’s kit, with programmatic access to the PCB123 database, you can expand the tool for your own purposes. Our PCB layout specialists are available to help you stretch your resource dollars & speed your PCB prototyping cycle. Submit basic design information to get a quote.

By leveraging our unique, inherently transient Lattice Boltzmann-based physics PowerFLOW CFD solution performs simulations that accurately predict real world conditions. Using the PowerFLOW suite, engineers evaluate product performance early in the design process prior to any prototype being built — when the impact of change is most significant for design and budgets. PowerFLOW imports fully complex model geometry and accurately and efficiently performs aerodynamic, aeroacoustic and thermal management simulations. Automated domain discretization and turbulence modeling with wall treatment eliminates the need for manual volume meshing and boundary layer meshing. Confidently run PowerFLOW simulations using large number of compute cores on common High Performance Computing (HPC) platforms.

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.

Powerful simulation software for improving asset performance. Maintenance and spares optimization, availability studies, reliability-centered maintenance, life cycle cost evaluations, and accelerated life testing all in one integrated suite. Connect directly to your SAP or MAXIMO system and analyze your data. Identify critical equipment, and automatically build failure models using Weibull analysis. Optimize your maintenance plans using simulation and reduce costs. Predict system availability and optimize your design. Simulation of multiple-product capacity with target cost penalties. Model system dependencies with RBDs or fault trees. Build in operational rules for accurate performance simulation. Determine the most effective spare holding policy. Predict life cycle costs and analyze your test data for stressed failures in the ALT module. Identify plant performance trends in the process reliability module.

Optimize product designs and reduce time to market with FLOW-3D, a highly-accurate CFD software that specializes in solving transient, free-surface problems. FLOW-3D‘s complete multiphysics suite includes our state-of-the-art postprocessor, FlowSight. FLOW-3D provides a complete and versatile CFD simulation platform for engineers investigating the dynamic behavior of liquids and gas in a wide range of industrial applications and physical processes. FLOW-3D focuses on free surface and multi-phase applications, serving a broad range of industries including microfluidics, bio-medical devices, water civil infrastructure, aerospace, consumer products, additive manufacturing, inkjet printing, laser welding, automotive, offshore, energy and automotive. A uniquely powerful, multiphysics tool, FLOW-3D provides the functionality, ease-of-use and power that helps engineers advance their modeling objectives.

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.

ExtendSim consists of a full range of tools for any type of simulation. No matter how you want to use ExtendSim, building models, running models, analysis, etc., there is a package that will fit your needs. There are ExtendSim products for building, experimenting with, and analyzing models, Model Developer Editions, and more specialized packages designed strictly for running models, analyzing models, or for use as a learning tool. Figure out which package might work best for you based on how you intend to use ExtendSim by visiting User Types. Create, use, and interactively run models, build custom interfaces and components, exchange data with and be controlled by other applications. Each Model Developer Edition (MDE) of ExtendSim has the same core set of capabilities. In them you can create and build models and interfaces, change values and settings, run simulations and animations, perform experiments, do analysis and optimization, save and export results.

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.

The Akselos Cloud platform delivers a complete Digital Twin framework via the cloud. It provides an end-to-end solution covering automated updates of asset loads and condition, through to clear dashboards showing current asset integrity. No more limitations, Akselos technology enables you to model the most complex problems in structures of any size, and in full detail. Our approach runs structural simulations a 1000x faster than legacy software. Design and operational workflows that used to take months can now be done in hours. Any relevant data, such as sensors and process parameters, can be directly connected to our models, allowing you to optimize your asset even further. All of our simulations will validate results against the applicable engineering code/standards, so that you can feel confident you asset is safe and meets all the relevant requirements.

Ansys Additive Suite delivers the critical insights required by designers, engineers and analysts to avoid build failure and create parts that accurately conform to design specifications. This comprehensive solution spans the entire workflow — from design for additive manufacturing (DfAM) through validation, print design, process simulation and exploration of materials. Additive Suite includes Additive Prep, Print and Science tools in addition to access to Ansys Workbench Additive. As with most features within Ansys Workbench, parametric analysis systems can be created so you can study the optimization of parameters such as part position and orientation. Available as an add-on to the Ansys Mechanical Enterprise license.

Ansys Gateway powered by AWS is the solution for developers, designers, and engineers who want to manage their complete Ansys Simulation & CAD/CAE developments in the cloud. Access cloud computing resources from anywhere on virtually any device via your web browser. You can create, customize, and connect cloud applications with minimal technical skills. Simply install your 3rd party applications alongside Ansys applications. Accelerate innovation by removing on-premises hardware barrier for High Performance Computing (HPC) using the power of AWS cloud. Leverage Ansys expertise in configuration and deployment of Virtual Desktop Interface (VDI) and High Performance Computing (HPC). Manage & control your CAD/CAE cloud consumption and costs directly within your AWS subscription.

An analytics-driven, simulation-based digital twin is a connected, virtual replica of an in-service physical asset — in the form of an integrated multidomain system simulation —that mirrors the life and experience of the asset. Hybrid digital twins enable system design and optimization and predictive maintenance, and they optimize industrial asset management. By implementing Ansys Twin Builder, you can improve top-line revenue, manage bottom-line costs and both gain and retain a competitive advantage. Ansys Twin Builder enables you to quickly create a digital twin–a connected replica of an in-service asset. This allows for enhanced lifecycle management and true predictive maintenance, saving costs to help maintain a competitive advantage.

Automatize your Simulation toolchain and connect to powerful algorithms of robust design optimization. Address your future needs of parametric and simulation driven virtual product development with Ansys optiSLang. Ansys optiSLang is a constantly evolving, leading-edge answer to the challenges posed by CAE-based Robust Design Optimization (RDO). Its state-of-the-art algorithms efficiently and automatically search for the most robust design configuration, eliminating the slow, manual process that used to define RDO. With optiSLang as your process integration and design optimization solution, you’ll make the right decisions sooner. Accelerate searches for the best and most robust design configuration by automating the search process with interactive visualization and AI technologies. State-of-the-art algorithms for design exploration, optimization, robustness and reliability analysis let you make better decisions with less effort using design optimization software.

LTE MAC Lab is a system-level simulation tool running under Matlab. LTE MAC Lab allows customers to model a wireless LTE network deployment, analyse its performance and understand dynamic mechanisms of the radio interface. It reflects the dynamic behaviour of a modelled HetNet RAN (Figure 1) focusing on Radio Resource Management features such as scheduling, carrier aggregation, handovers and link adaptation. It includes implementation of propagation (path loss, shadowing and multipath) and mobility models.