Alternatives to Ansys Electronics Desktop (AEDT)

Ansys Motor-CAD serves as a specialized tool for the design of electric machines, facilitating rapid multiphysics simulations throughout the entire torque-speed operating range. It allows design engineers to assess various motor configurations and concepts to create designs that maximize performance, efficiency, and compactness. With its four integrated modules—EMag, Therm, Lab, and Mech—Motor-CAD enables quick and iterative multiphysics calculations, significantly reducing the time from initial concept to finalized design. This efficiency in calculations and streamlined data input processes provides users with the opportunity to investigate a broader array of motor topologies and thoroughly evaluate the effects of advanced loss mechanisms in the early phases of electromechanical design. The latest release boasts enhanced capabilities for design optimization, multiphysics analysis, and system modeling tailored specifically for electric motors, ensuring that engineers have the tools they need for cutting-edge development. Ultimately, Motor-CAD's fast multiphysics simulation capabilities across the full torque-speed range empower engineers to innovate and refine electric motor designs with unprecedented efficiency.

OrCAD® X is a unified PCB design software platform. It offers significant improvements to ease of use, performance and automation. Our product suite includes applications for schematic, PCB layout, simulation and data management. OrCAD X Capture, a schematic design solution for electrical circuit creation and documentation, is one of OrCAD's most popular products. PSpice®, our virtual SPICE simulation engine integrated into Capture, allows you to prototype and verify your designs using industry-leading native analog, mixed signal, and advanced analysis engines. OrCAD X Presto and OrCAD X PCB editor are two PCB layout tools that allow designers to easily collaborate between ECAD/MCAD teams and build better PCBs faster. OrCAD X Presto is our new, simplified interface for novice designers, electrical engineers and PCB designers focused on quick turn PCB designs.

Ansys Maxwell serves as a powerful electromagnetic field solver tailored for electric machines, transformers, wireless charging systems, permanent magnet latches, actuators, and various electromechanical devices. It adeptly addresses the challenges of static, frequency-domain, and time-varying electric and magnetic fields. Additionally, Maxwell comes equipped with specialized design interfaces specifically for electric machines and power converters. With the capabilities of Maxwell, users can accurately analyze the nonlinear and transient behaviors of electromechanical components, as well as their impact on drive circuits and control system designs. By utilizing Maxwell’s state-of-the-art electromagnetic field solvers in conjunction with integrated circuit and systems simulation technologies, engineers can gain insights into the performance of electromechanical systems well before any physical prototypes are created. Moreover, Maxwell is recognized for delivering reliable simulations of low-frequency electromagnetic fields pertinent to industrial components, making it a valuable tool in the design and analysis process. This comprehensive approach not only enhances design efficiency but also aids in minimizing potential issues during the development stage.

Ansys HFSS is a versatile 3D electromagnetic (EM) simulation tool used for the design and analysis of high-frequency electronic devices such as antennas, interconnects, connectors, integrated circuits (ICs), and printed circuit boards (PCBs). This powerful software allows engineers to create and evaluate a wide range of high-frequency electronic products, including antenna arrays, RF and microwave components, and filters. Renowned among engineers globally, Ansys HFSS is essential for developing high-speed electronics utilized in various applications like communication systems, advanced driver assistance systems (ADAS), satellites, and Internet of Things (IoT) devices. The software's exceptional performance and precision empower engineers to tackle complex challenges related to RF, microwave, IC, PCB, and electromagnetic interference (EMI) issues. With a robust suite of solvers, Ansys HFSS effectively addresses a myriad of electromagnetic challenges, making it an indispensable resource in the field of electronic design. As technology progresses, the relevance of such simulation tools becomes increasingly critical in ensuring optimal performance in modern electronic systems.

Ansys Exalto serves as an advanced post-LVS RLCk extraction software that empowers integrated circuit (IC) designers to effectively address unknown crosstalk between various components within the design hierarchy by extracting lumped-element parasitics and creating precise models for electrical, magnetic, and substrate coupling. This tool seamlessly integrates with a wide range of LVS software and can enhance the performance of any RC extraction tool you prefer. With Ansys Exalto's post-LVS RLCk extraction capabilities, IC designers are equipped to make accurate predictions regarding electromagnetic and substrate coupling effects, allowing for signoff on circuits that may have previously been deemed "too complex to analyze." The models that are extracted can be back-annotated to the schematic or netlist, ensuring compatibility with all circuit simulators. As the prevalence of RF and high-speed circuits continues to rise in contemporary silicon systems, electromagnetic coupling has become a primary factor that necessitates precise modeling to ensure the successful fabrication of silicon. Overall, Ansys Exalto represents a crucial advancement in circuit design, helping engineers navigate the complexities associated with modern electronic systems.

Advance your RF simulation capabilities to effectively design, analyze, and verify radio frequency integrated circuits (RFICs) beyond conventional methods. Gain assurance through the use of steady-state and nonlinear solvers tailored for both design and verification processes. Accelerate the validation of intricate RFICs with wireless standard libraries designed for efficiency. Ensure precise modeling of components on silicon chips to achieve optimal accuracy. Enhance your designs using load-pull analysis and parameter sweeps for better performance outcomes. Conduct RF simulations within the Cadence Virtuoso and Synopsys Custom Compiler environments to streamline your workflow. Employ Monte Carlo simulations and yield analysis to further boost performance metrics. Early in the design phase, evaluate error vector magnitude (EVM) in alignment with the latest communication standards to ensure compliance. Leverage cutting-edge foundry technology right from the start of your project. It is essential to monitor specifications like EVM through RF simulation during the early stages of RFIC design. The simulations account for the effects of layout parasitics, intricate modulated signals, and digital control circuitry. Utilizing Keysight RFPro Circuit allows for comprehensive simulation in both frequency and time domains, enhancing the overall design process and accuracy. This multifaceted approach ensures that your RFICs not only meet but exceed industry standards.

Ansys Icepak serves as a computational fluid dynamics (CFD) solver specifically designed for managing thermal issues in electronic devices. It offers insights into airflow, temperature distributions, and heat transfer phenomena within integrated circuit packages, printed circuit boards (PCBs), electronic assemblies, and power electronics. By leveraging the top-tier Ansys Fluent CFD solver, Ansys Icepak delivers robust cooling solutions tailored for electronic components, allowing for thorough thermal and fluid flow evaluations. The software operates through the Ansys Electronics Desktop (AEDT) graphical user interface (GUI), facilitating comprehensive analyses of heat transfer involving conduction, convection, and radiation. Moreover, it boasts sophisticated features for modeling both laminar and turbulent flow conditions, as well as conducting species analysis that incorporates radiation and convection effects. Ansys’ extensive PCB design platform empowers users to perform simulations on PCBs, ICs, and packages, enabling a precise assessment of complete electronic systems, thereby enhancing design efficiency and performance optimization. Thus, Ansys Icepak stands out as an essential tool for engineers aiming to improve thermal management in their electronic designs.

EMWorks offers top-tier electromagnetic simulation software designed for electrical and electronics engineering, incorporating multiphysics features. Their solutions are fully integrated into SOLIDWORKS and Autodesk Inventor®, catering to a wide range of applications such as electromechanical systems, power electronics, antennas, RF and microwave components, as well as ensuring power and signal integrity in high-speed interconnects. One of their flagship products, EMS, serves as a powerful tool for simulating and optimizing electromagnetic and electromechanical devices like transformers, electric motors, actuators, and sensors within the SOLIDWORKS® and Autodesk® Inventor® environments. Additionally, EMWorks2D is a specialized 2D electromagnetic simulation software that focuses on planar and axis-symmetric geometries, also fully embedded in SOLIDWORKS, allowing users to perform quick simulations prior to transitioning to 3D models. This functionality not only enhances the design process but also accelerates overall product development, making it easier for engineers to refine their designs efficiently. By leveraging these advanced tools, users can achieve optimal performance in their electronic designs while saving valuable time in the engineering workflow.

The Cadence AWR Design Environment Platform streamlines the development cycles of RF/microwave products through design automation, which boosts engineering efficiency and shortens turnaround times. This all-in-one platform equips engineers with sophisticated high-frequency circuit and system simulations alongside in-design electromagnetic (EM) and thermal analyses, enabling the creation of manufacturing-ready high-frequency intellectual property with exceptional accuracy and effectiveness. With a focus on enhancing productivity, the interface is both robust and user-friendly, featuring smart and customizable design workflows tailored to meet the demands of modern high-frequency semiconductor and PCB technologies. Moreover, its integrated design capture system supports a seamless front-to-back physical design process. The dynamic linking between electrical and layout design entries ensures that any components added to an electrical schematic automatically result in a corresponding synchronized physical layout, fostering a more cohesive design experience. This innovative approach not only minimizes errors but also significantly accelerates the overall design process.

Examine RF and microwave circuits and systems using rapid simulation and robust optimization tools that enhance your design process. Delve into performance trade-offs through the integration of automatic circuit synthesis technology. PathWave RF Synthesis (Genesys) offers foundational features that cater to all designers of RF and microwave circuit boards and subsystems. With PathWave Circuit Design, you can uncover RF design mistakes that conventional spreadsheet analyses often overlook. This introductory design platform, which encompasses circuit, system, and electromagnetic simulators, enables you to approach design reviews with greater assurance prior to the realization of hardware. With just a few clicks, you can observe the automatic synthesis and optimization of your matching network. After that, easily transfer your design to PathWave Advanced Design System (ADS) to incorporate it into more intricate designs, ensuring seamless integration and enhanced functionality. By leveraging these tools, you can streamline the design process and enhance the overall efficiency of your RF and microwave projects.

Advance your approach to RF simulation by focusing on the comprehensive design, analysis, and verification of radio frequency integrated circuits (RFICs). Gain assurance through the use of steady-state and nonlinear solvers for both design and verification processes. The availability of wireless standard libraries expedites the validation of intricate RFICs. Prior to finalizing an RFIC, it is essential to confirm IC specifications through RF simulation. These simulations take into account various factors such as layout parasitics, intricate modulated signals, and digital control circuitry. With PathWave RFIC Design, you can perform simulations in both frequency and time domains, facilitating seamless transitions between your designs and Cadence Virtuoso. Achieve accurate modeling of components on silicon chips, and enhance your designs using optimization techniques like sweeps and load-pull analysis. Integration of RF designs into the Cadence Virtuoso environment is streamlined, while the implementation of Monte Carlo and yield analysis can significantly boost performance. Additionally, debugging is made easier with safe operating area alerts, allowing for immediate utilization of cutting-edge foundry technology to stay at the forefront of innovation. This holistic approach to RFIC design not only improves efficiency but also elevates the overall quality and reliability of the final products.

Microwave Office facilitates the design of various RF passive components, including filters, couplers, and attenuators, along with active devices functioning under small-signal (AC) conditions, such as low noise and buffer amplifiers. Its linear configuration allows for the simulation of S-parameters (Y/Z/H/ABCD), small-signal gain, linear stability, noise figure, return loss, and voltage standing wave ratio (VSWR), complemented by features like real-time tuning, optimization, and yield analysis. Each E-series Microwave Office portfolio encompasses synchronous schematic and layout editors, 2D and 3D viewers, and extensive libraries featuring high-frequency distributed transmission models, as well as surface-mount vendor component RF models complete with footprints. Additionally, it offers measurement-based simulations and RF plotting capabilities. Microwave Office PCB further enhances the design process by enabling both linear and nonlinear RF circuit design through the advanced APLAC HB simulator, which provides powerful multi-rate HB, transient-assisted HB, and time-variant simulation engines for comprehensive RF/microwave circuit analysis. This extensive toolset empowers engineers to push the boundaries of RF design and streamline their development workflows effectively.

Ansys Nuhertz FilterSolutions offers a streamlined and efficient process for the automated design, synthesis, and optimization of RF, microwave, and digital filters. The process begins with inputting the desired performance specifications, after which it synthesizes both lumped component designs and physical layouts while automatically configuring analysis and optimization within the Ansys HFSS electromagnetic simulator. This innovative solution significantly accelerates the development of lumped element (surface mount) and planar filters. Additionally, it incorporates synthesis tools for various filter types, including active, switched capacitor, and digital filters. Users can export the netlist of active filters in SPICE format, and the digital filter synthesis module allows for the generation of C-code for the resulting filters. Overall, Ansys Nuhertz FilterSolutions enhances efficiency and versatility in filter design, making it a valuable tool for engineers.

XFdtd is a comprehensive 3D electromagnetic simulation software developed by Remcom. This powerful and feature-rich solver for electromagnetic simulations delivers exceptional computing performance and eases the process of analyzing intricate electromagnetic challenges. The software supports various applications, including the design of microwave devices and antennas, as well as radar and scattering analysis. Additionally, XFdtd is utilized in biomedical fields, automotive radar systems, waveguide studies, military and defense projects, RFID technology, and electromagnetic compatibility/electromagnetic interference assessments, among others. Its versatility makes it an essential tool for engineers and researchers alike.

L-Edit MEMS stands out as the premier platform for 3D MEMS design. The initial phase of creating a digital twin for MEMS devices starts with capturing designs in L-Edit. Designers in the MEMS field gain significant advantages from an integrated environment that encompasses device design, modeling for fabrication, and connections to FEM analysis tools. As the leading standard for MEMS design, L-Edit MEMS is uniquely equipped with true native curve support, making it the sole tool crafted specifically for MEMS and integrated circuit design. This platform serves as the cornerstone for the MEMS digital twin, facilitating not only device design but also 3D modeling of fabrication and simulations through established partnerships. Users can generate a 3D solid model based on layout data and descriptions of the fabrication process. It provides an insightful 3D graphical representation of the MEMS fabrication journey. Furthermore, it supports multi-physics simulations in conjunction with widely-used FEM analysis tools, allowing for the export of models to FEM/BEM simulators for thorough 3D evaluations. With its component libraries, design reuse is made simple and efficient, enhancing productivity in the MEMS design process. Ultimately, L-Edit MEMS offers a comprehensive suite of tools that empowers designers to innovate and streamline their workflows effectively.

CST Studio Suite is an advanced 3D electromagnetic (EM) analysis software designed to facilitate the design, assessment, and optimization of various electromagnetic components and systems. It offers a unified user interface that houses solvers for a diverse range of applications spanning the entire electromagnetic spectrum. These solvers can be integrated to conduct hybrid simulations, providing engineers the versatility to efficiently analyze complex systems composed of multiple components. Furthermore, collaboration with other SIMULIA products enhances the capability for EM simulation to be seamlessly incorporated into the overall design process, influencing development from the initial phases. Typical applications of EM analysis include evaluating antenna and filter performance, ensuring electromagnetic compatibility and interference compliance, assessing human exposure to EM fields, analyzing electro-mechanical interactions in motors and generators, and studying thermal impacts on high-power devices. The ability to conduct such comprehensive analyses helps drive innovation in various industries that rely on electromagnetic technology.

Ansys Fluent stands out as the premier fluid simulation software, distinguished by its cutting-edge physics modeling features and unmatched precision. By utilizing Ansys Fluent, you can dedicate more time to innovation and enhancing product efficiency. This software is backed by extensive validation across diverse applications, ensuring you can rely on its simulation outcomes. With Ansys Fluent, creating sophisticated physics models and evaluating various fluid dynamics phenomena is seamless within a user-friendly and customizable interface. This robust simulation tool significantly expedites your design process, allowing for quicker iterations and improvements. Boasting top-tier physics models, Ansys Fluent can effectively and accurately tackle intricate, large-scale simulations. The software unveils new possibilities for computational fluid dynamics (CFD) analysis. Additionally, its rapid pre-processing capabilities and swift solving times empower you to be the quickest in bringing your products to market. Fluent's unmatched features foster boundless innovation while maintaining a steadfast commitment to precision and reliability. Ultimately, Ansys Fluent not only enhances your design capabilities but also positions you ahead of the competition in a fast-paced industry.

The Solido variation-aware design solutions, alongside IP validation, library characterization, and simulation technologies driven by cutting-edge AI, are utilized by thousands of designers at leading semiconductor firms across the globe. This integrated suite features AI-enhanced SPICE, Fast SPICE, and mixed-signal simulators that empower clients to significantly expedite crucial design and verification processes for advanced analog, mixed-signal, and custom IC designs. It delivers the industry's quickest and most thorough integrated IP validation solution, ensuring complete and seamless IP quality assurance from the design phase all the way to tape-out, encompassing all design perspectives and IP updates. Moreover, this comprehensive AI-driven design environment facilitates both nominal and variation-aware verification of custom IC circuits, achieving full design coverage with far fewer simulations while maintaining the accuracy comparable to brute-force methods. Furthermore, it offers rapid and precise library characterization tools that leverage machine learning for enhanced performance and reliability.

ModelSim effectively simulates behavioral, RTL, and gate-level code, enhancing both design quality and debugging productivity through its platform-independent compilation. Its unique single kernel simulator technology allows for the seamless integration of VHDL and Verilog within a single design framework. This HDL simulator offers an unparalleled range of verification features at a competitive price, making it particularly suitable for the verification of small to medium-sized FPGA designs, especially those that are complex and mission-critical. ModelSim’s sophisticated code coverage tools yield essential metrics that aid in systematic verification processes. Additionally, its user-friendly design minimizes the obstacles to utilizing verification resources efficiently. All coverage data is securely stored in the highly efficient UCDB database, providing flexibility in how results can be accessed. Coverage outcomes can be analyzed interactively, either during or after simulation, including after merging results from multiple simulation sessions. This unified and easy-to-navigate environment equips FPGA designers with the necessary advanced tools for effective debugging and refinement of their projects.

PathWave ADS streamlines the design process by providing integrated templates that help users start their projects more efficiently. With a comprehensive selection of component libraries, locating the desired parts becomes a straightforward task. The automatic synchronization with layout offers a clear visualization of the physical arrangement while you create schematic designs. This data-driven approach enables teams to assess if their designs are in line with specifications. PathWave ADS enhances design confidence through its display and analytics features, which generate informative graphs, charts, and diagrams. Users can expedite their design process with the help of wizards, design guides, and templates. The complete design workflow encompasses schematic design, layout, as well as circuit, electro-thermal, and electromagnetic simulations. As frequencies and speeds continue to rise in printed circuit boards (PCBs), ensuring signal and power integrity is critical. Issues arising from transmission line effects can lead to electronic device failures. It is essential to model traces, vias, and interconnects accurately for a realistic simulation of the board, ensuring that potential problems are identified and mitigated early in the design phase. This multifaceted approach not only improves efficiency but also enhances the overall reliability of electronic designs.

The Cadence Clarity 3D Solver is a sophisticated software tool designed for 3D electromagnetic simulation, specifically aimed at creating essential interconnects for printed circuit boards, integrated circuit packages, and systems integrated on chip designs. This powerful tool assists engineers in overcoming intricate electromagnetic issues encountered in the development of systems for advanced technologies such as 5G, automotive applications, high-performance computing, and machine learning, all while ensuring top-tier accuracy. Leveraging Cadence’s state-of-the-art distributed multiprocessing capabilities, the Clarity 3D Solver provides virtually limitless capacity and enhances processing speed by tenfold, making it possible to tackle extensive and complicated structures with ease. Additionally, it generates precise S-parameter models that cater to high-speed signal integrity, power integrity, high-frequency RF/microwave applications, and electromagnetic compliance assessments, ensuring that simulation outcomes align closely with laboratory measurements, even for data transfer rates exceeding 112Gbps. Consequently, this tool stands as a vital asset for engineers looking to push the boundaries of technology in their designs.

Ansys Discovery introduces an innovative simulation-driven design tool that integrates instant physics simulation, high-fidelity simulation, and interactive geometry modeling into a singular, user-friendly platform. This groundbreaking product merges interactive modeling with various simulation features, empowering users to tackle essential design inquiries at the early stages of the design process. By adopting this proactive approach to simulation, teams can significantly reduce time and resources spent on prototyping as they concurrently examine numerous design ideas without delays for simulation feedback. Ansys Discovery effectively addresses vital design questions swiftly and accurately, enhancing overall productivity and performance by removing prolonged waits for simulation outputs. This capability allows engineers to prioritize innovation and optimize product performance, ultimately leading to a reduction in labor costs and physical prototyping expenses. Additionally, by facilitating the early resolution of design challenges, Ansys Discovery contributes to a notable increase in return on investment (ROI) throughout your organization, making it an invaluable asset for engineering teams.

Certified by Foundry, the AFS Platform provides nm SPICE accuracy, achieving speeds five times greater than conventional SPICE and more than twice as fast as parallel SPICE simulators. It stands out as the quickest nm circuit verification platform suitable for analog, RF, mixed-signal, and custom digital circuits. The latest addition of eXTreme technology enhances its capabilities. Specifically designed for large post-layout circuits, the AFS eXTreme technology accommodates over 100 million elements and operates three times faster than typical post-layout simulators. It is compatible with all leading digital solvers. With its top-tier usability, the platform maximizes the reuse of existing verification infrastructures, while its advanced verification and debugging features significantly enhance verification coverage. This results in improved design quality and reduced time-to-market. The platform guarantees SPICE accuracy and offers high-sigma verification, being a staggering 1000 times faster than brute-force simulation methods. It is user-friendly and easy to deploy, with access to AFS eXTreme technology provided at no extra cost; thus, it represents a comprehensive solution for modern circuit verification needs.

Create your photonic integrated circuit within a layout-focused workflow that allows designers to utilize either a drag-and-drop interface or a script-based approach. Both methods are facilitated by a comprehensive custom IC design layout editor, which also manages the physical verification and tape-out stages. L-Edit Photonics allows for rapid photonic design creation through its intuitive drag-and-drop functionality, eliminating the need for coding. Upon finalizing the design, a netlist can be generated to support photonic simulations. The PIC design is entirely integrated within an IC layout editor, enabling users to develop layouts without writing any code, thus supporting a layout-centric approach that does not require a schematic. For those who prefer a schematic flow, S-Edit is available as an optional tool. Moreover, a simulation netlist can be produced for input into a photonic simulator, and photonic simulations are seamlessly incorporated through partnerships with various providers. Additionally, multiple foundries offer photonic PDKs to enhance design capabilities. Overall, this comprehensive workflow simplifies the photonic design process while catering to various designer preferences.

Synopsys Saber offers a high-precision virtual prototyping suite tailored for multi-domain power electronics design, which comprises SaberEXP, SaberRD, and SaberES Designer. This innovative platform enables engineers to conduct complex simulations that account for various component tolerances, allowing for the generation of both best and worst-case scenarios while facilitating “what-if” analyses. The unparalleled accuracy of Saber helps minimize development costs by decreasing the number of prototypes necessary for effective validation. SaberEXP serves as a rapid converging simulator for power electronics, featuring a piecewise linear (PWL) approach and seamless integration with SaberRD. SaberRD enhances this experience by providing a comprehensive design and simulation environment specifically for mechatronic systems, offering top-tier analysis capabilities for validating power electronics. Meanwhile, SaberES Designer acts as a sophisticated tool for optimizing wiring harness layouts, materials, and costs, ensuring compatibility with leading industry CAD systems. By employing systematic robust design methodologies, engineers can achieve stringent performance and reliability targets even within tight timelines, ultimately streamlining the overall design process. This comprehensive solution not only improves efficiency but also empowers teams to innovate more effectively in the rapidly evolving landscape of power electronics.

Our advanced web platform significantly enhances the productivity of chip developers and verification engineers, allowing them to design and troubleshoot at a pace ten times quicker than before. With Verilator, users can effortlessly initiate and execute thousands of tests simultaneously with just one click. It also facilitates the easy sharing of test outcomes and waveforms within the organization, allows for tagging colleagues on specific signals, and provides robust tracking of test and regression failures. By utilizing Verilator to create Dockerized simulation binaries, we efficiently distribute test executions across our computing cluster, after which we gather the results and log files and have the option to rerun any tests that failed to produce waveforms. The incorporation of Docker ensures that the test executions are both consistent and reproducible. SiLogy ultimately boosts the efficiency of chip developers by shortening the time required for design and debugging processes. Prior to the advent of SiLogy, the leading method for diagnosing a failing test entailed manually copying lines from log files, analyzing waveforms on personal machines, or rerunning simulations that could take an inordinate amount of time, often spanning several days. Now, with our platform, engineers can focus more on innovation rather than being bogged down by cumbersome debugging processes.

Understanding how light travels and influences both product efficacy and human experience is essential for assessing performance and ensuring comfort, perception, and safety. Ansys Optics stands out by effectively simulating the optical characteristics of a system, assessing the ultimate lighting effects, and forecasting the repercussions of variations in lighting and materials on appearance and perceived quality, all within realistic scenarios. With this advanced visualization tool, you can conceptualize your product prior to its creation, thereby enhancing the virtual experience for customers. Allow Ansys Optics and its optical simulation capabilities to guide you towards optimal solutions for any project style. The software adeptly addresses intricate optical challenges while enhancing visual aesthetic quality. By integrating design and engineering into a seamless workflow, you can significantly boost the final quality of your product, creating true-to-life visualizations that resonate with users. Additionally, you can develop and evaluate virtual prototypes of a cockpit HMI within an immersive, real-time setting, providing a comprehensive understanding of user interaction. This process not only improves design outcomes but also fosters innovation in product development.

Precision provides a vendor-independent solution for FPGA synthesis, ensuring top-tier performance and area efficiency while offering robust design capabilities paired with strong connections to simulation and formal equivalency checking tools. Its products integrate seamlessly with Siemens' FormalPro LEC for equivalency verification and HDL Designer, facilitating design capture and verification in conjunction with ModelSim/Questa. The entry-level FPGA synthesis tool, Precision RTL, delivers exceptional quality results as a vendor-agnostic solution. In response to the needs of space and military aerospace applications, which often require specialized FPGAs equipped with inherent protection against SEEs, NanoXplore has launched new FPGA offerings aimed at this sector. Collaborating closely with NanoXplore, Precision Synthesis is the first to provide comprehensive synthesis support for the NG-Ultra device. Additionally, Precision boasts seamless integration with the NXmap place and route tool, effectively completing the design workflow from RTL through to gates and ultimately to bitstream generation. This integration not only streamlines the development process but also enhances the reliability of the final product, ensuring it meets industry standards.

Ansys Cloud Direct’s powerful, easy-to-access HPC cloud solution will change the way you think about simulation. Unlike other simulation cloud solutions, Ansys Cloud Direct is simple to set up and navigate, will not break your workflow and does not require cloud experts to operate. Ansys Cloud Direct is all about Workflow, Performance, Support.

Easily perform electrical stress analysis, MTBF calculation, component derating, and FMECA analysis within your ECAD during board design. Key Features: • Uses cutting-edge AI technologies for robust and efficient design. *Seamless Integration with leading ECAD Software for streamlined workflows and real-time analyses. *Includes automated circuit strain calculators to speed up design processes. • Performs detailed analysis on electrical stress derivation for components. *Utilizes the results of thermal simulation to improve derating accuracy. *Provides thermal resistance and stress metrics for 3D Thermal Simulations. *Identifies EOS violations using Pareto analysis, and detailed reports on overstress and overdesign. *Recommends design changes to effectively resolve overstress problems. *Utilizes derating guidelines for optimal component performance. *Automates FMECA Analysis

Sigrity X Advanced SI Technology offers advanced signal integrity analysis for PCBs and IC packaging, covering DC up to 56GHz, with features such as automated die-todie SI analysis, topology exploring, and simulation of high-speed interfaces. It supports IBIS-AMI and customizable compliance kits to ensure that your designs meet rigorous standards.

Identify issues at the earliest stages and enhance your design's reliability by implementing formal checks and properties. Integrate formal methods early in the design phase whenever they align with your application's needs. Utilize formal cover traces to deepen your understanding of the design and address challenging questions regarding the design being evaluated. Leverage formal safety properties to create more concise and meaningful traces than those generated through simulation. Use formal proofs to validate your design's accuracy, apply mutation coverage to bolster your confidence in simulation-based verification efforts, and streamline the test case creation process by utilizing guidance from formal cover traces. Engage in both unbounded and bounded verification of safety properties while conducting reachability checks and detecting bounds for cover properties. This comprehensive approach not only ensures design correctness but also fosters a more efficient workflow throughout the development process.

You can quickly design advanced board layouts using interactive routing and the intelligent SitusTM Autorouting technology. With Native 3D™, PCB editing and STEP support, you can collaborate effortlessly with your mechanical design team. Advanced electronics can be accurately simulated and shipped using integrated XSPICE digital and analog simulations. With hierarchical schematic capture and constraint-driven PCB layout technology, you can quickly transform your ideas into reality. With an intuitive interface and customizable workflow, you can instantly get started on your next design project. Altium designer and EAGLE compatibility allow you to access your entire design history. With real-time availability and pricing data from hundreds of suppliers, you will never miss another deadline. With the Circuitstudio content library, you can quickly create custom parts.

The Ansys HPC software suite allows users to leverage modern multicore processors to conduct a greater number of simulations in a shorter timeframe. These simulations can achieve unprecedented levels of complexity, size, and accuracy thanks to high-performance computing (HPC) capabilities. Ansys provides a range of HPC licensing options that enable scalability, accommodating everything from single-user setups for basic parallel processing to extensive configurations that support nearly limitless parallel processing power. For larger teams, Ansys ensures the ability to execute highly scalable, multiple parallel processing simulations to tackle the most demanding projects. In addition to its parallel computing capabilities, Ansys also delivers parametric computing solutions, allowing for a deeper exploration of various design parameters—including dimensions, weight, shape, materials, and mechanical properties—during the early stages of product development. This comprehensive approach not only enhances simulation efficiency but also significantly optimizes the design process.

Technology Computer-Aided Design (TCAD) involves leveraging computer simulations to design and refine semiconductor processes and devices. Synopsys TCAD presents a wide-ranging suite of offerings that features top-tier tools for process and device simulation, complemented by an intuitive graphical user interface that facilitates the management of simulation activities and the analysis of results. Additionally, Synopsys TCAD includes tools designed for interconnect modeling and extraction, which provide essential parasitic data vital for enhancing chip performance. The newest iteration of TCAD Sentaurus comes packed with a host of exciting features and enhancements aimed at improving performance. Customers with access to maintenance services can download TCAD Sentaurus W-2024.09-SP1 along with the accompanying release notes from SolvNetPlus. Furthermore, the Sentaurus Calibration Workbench is specifically designed to support an automated, workflow-focused calibration of TCAD models, harnessing advanced machine learning techniques to optimize the calibration process. This combination of cutting-edge tools and features positions Synopsys TCAD as a leader in the semiconductor simulation market.

Ansys SPEOS offers predictive capabilities for illumination and optical system performance, significantly reducing both prototyping time and costs while enhancing the efficiency of your products. With a user-friendly and detailed interface, Ansys SPEOS boosts productivity through GPU utilization for simulation previews and provides seamless integration with the Ansys multiphysics ecosystem. The tool's accuracy has been validated by the International Commission on Illumination (CIE) against the CIE 171:2006 standards, demonstrating the advantages of its light modeling software. Activate the lighting in your virtual model to easily investigate light propagation in a three-dimensional space. The SPEOS Live preview feature includes both simulation and rendering tools, allowing for an interactive design experience. By conducting accurate simulations on the first attempt, you can reduce iteration times and accelerate your decision-making, all while automatically optimizing the designs for optical surfaces, light guides, and lenses. This innovative approach not only streamlines the design process but also empowers creators to achieve higher precision in their optical designs.

The Ansys Additive Suite provides essential insights that help designers, engineers, and analysts prevent build failures while ensuring that parts meet precise design specifications. This all-encompassing solution covers the full spectrum of the workflow, which includes design for additive manufacturing (DfAM), validation, print design, process simulation, and material exploration. Within the Additive Suite, users have access to tools such as Additive Prep, Print, and Science, along with Ansys Workbench Additive. Many features in Ansys Workbench allow for the creation of parametric analysis systems, enabling the examination and optimization of various parameters like part orientation and positioning. This suite is offered as an additional module for those holding an Ansys Mechanical Enterprise license. The integration of these tools facilitates a more streamlined approach to additive manufacturing, enhancing the overall efficiency and reliability of the production process.

Conducting a 2D throughflow simulation is an essential phase in the design process of rotating machinery. Ansys Vista TF not only delivers swift results but also enhances your understanding of the design, uncovering potential issues that may not have been previously recognized. By engaging in initial design iterations in a 2D format, you can streamline the transition to comprehensive 3D analysis, ultimately saving both development time and engineering resources. This software empowers users to gain deeper insights into their rotating machinery designs, allowing for refinement of product performance during the early stages of design. The significance of a high-performance turbocharger cannot be overstated, as it plays a vital role in overall engine efficiency. Engineers at PCA sought a solution to optimize turbocharger functionality while also identifying the most effective strategies for their challenges. Ansys Vista TF emerged as the optimal solution, thanks to its capacity to provide rapid, high-quality insights within an efficient workspace, thereby significantly aiding their design process. Additionally, the ability to quickly iterate designs using this software has proven invaluable for maintaining competitive advantages in the industry.

nCode DesignLife serves as a proactive design tool that pinpoints essential areas and estimates realistic fatigue lifespans based on top finite element (FE) analysis results applicable to both metals and composites. This innovative tool empowers design engineers to enhance their approach beyond basic stress assessments, enabling them to simulate real-world loading scenarios and thereby mitigate the risks of both under-design and over-design in their products, which can lead to expensive modifications later on. Additionally, the software offers features like virtual shaker testing, fatigue analysis for welds, vibration fatigue assessments, crack growth monitoring, fatigue evaluation for composites, and thermo-mechanical fatigue studies. It leverages advanced technologies for analyzing multiaxial stress, weld integrity, short-fiber composites, vibrational impacts, crack propagation, and thermal stress fatigue. With a user-friendly graphical interface, it facilitates comprehensive fatigue analysis using data from leading FEA tools such as ANSYS, Nastran, Abaqus, Altair OptiStruct, LS-Dyna, among others. Moreover, it incorporates multi-threaded and distributed processing capabilities, enabling efficient handling of large finite element models and optimizing overall usage schedules. This powerful combination of features ultimately ensures that engineers can deliver more reliable and efficient designs.

Ansys Chemkin-Pro stands at the forefront of modeling intricate, chemically interactive systems. It has undergone rigorous validation for a wide array of chemistry-related applications and is recognized for its remarkably rapid simulation capabilities. In the current landscape of energy regulations, there is a pressing demand for high yields, efficiency, and quality while minimizing byproducts and waste. Ansys Chemkin-Pro serves as a chemical kinetics simulator that accurately represents idealized reacting flows, offering valuable insights into outcomes prior to production testing. Relying solely on experimental testing for confirming chemical processes can be economically challenging, especially with the rapid design cycles of today. Consequently, effective simulation plays a pivotal role in developing cost-efficient designs, facilitating quicker market entry for new products. Notably, Mitsuo Koshi, an esteemed chemical kineticist and passionate fireworks enthusiast, has gained recognition for judging prestigious fireworks competitions throughout Japan. Each year, the displays become increasingly spectacular; however, this escalation comes with the downside of rising emissions, raising concerns about environmental impact. As such, the balance between artistry in fireworks and environmental responsibility is becoming an ongoing challenge for both chemists and pyrotechnicians alike.

Ansys Path FX provides the capability to perform timing analysis with variations across an entire System on Chip (SoC) without compromising accuracy. With its distinct cell modeling, it achieves SPICE-level timing accuracy for various voltage and variation scenarios using a single library. The architecture of Path FX is fully threaded and distributed, enabling it to scale efficiently to thousands of CPUs. Furthermore, Path FX employs path-based timing analysis technology that effectively considers all significant factors influencing delay and constraints across different process, voltage, and temperature conditions. It also has the functionality to automatically detect and simulate each clock path present in your design. In the current landscape, two major hurdles in chip design include reducing power consumption through lower supply voltages and navigating the complexities associated with advanced silicon processes, particularly at 7nm and beyond. This makes tools like Ansys Path FX indispensable for modern semiconductor development.

Cadence®, Sigrity X PowerSI® technology helps you to tackle increasingly difficult issues related switching noise, signal coupling and target voltage levels. It provides fast, accurate and detailed electrical analyses of full IC packages and PCBs. It can be used to develop power and signal integrity guidelines before layout, or after layout to verify performance and improve the design without a prototype. Sigrity X's electromagnetic (EM) solver technology allows you to perform a wide range of studies, including identifying trace and via coupling problems, power/ground fluctuation caused by simultaneously switching out put, and designing regions that are below or above voltage targets. PowerSI technology allows you to extract frequency-dependent parameter models for network networks and visualize complex spatial relationships.

Integrated version control along with straightforward management tools eliminates the expensive requirement for a separate PDM system, ensuring that you and your team always have access to the most current design data. Every alteration made by users is meticulously logged, allowing for a history of changes that can be reversed at any moment, thus offering limitless undo/redo options alongside a thorough audit trail. The option to branch and merge facilitates the simultaneous development of various product concepts. One of the standout features of SolidFace is its parameterization capability, which is utilized throughout all phases of design. 3D motion simulation benefits from this as it updates in real-time with any movement. Additionally, the software can simulate 2D mechanisms, allowing for analysis in either a 2D drawing space or within the 3D sketch environment. Furthermore, SolidFace provides direct access to an extensive online part library, boasting over 100 million part numbers sourced from numerous top manufacturers and distributors, as well as thousands of standards such as ISO, ANSI, DIN, NF, GB, and ASME. This comprehensive resource enhances the design process, making it more efficient and effective for users.

Ansys Granta products, cultivated over a quarter-century, empower organizations to harness, protect, and leverage their Material Intelligence effectively. By facilitating the digitalization of materials knowledge, Ansys assists businesses in selecting appropriate materials for their products and provides educational resources related to materials. The suite of materials information management software offered by Ansys Granta enables companies to fully utilize their internal Material Intelligence. Ansys Granta MI™ serves as a flexible solution, allowing for the creation, management, and storage of crucial material data, while ensuring smooth integration with top CAD, CAE, and PLM systems to maintain consistency across the enterprise. With Ansys Granta Selector, users can make informed material selections by evaluating various properties from an extensive database, ensuring optimal material choices for their specific applications. Additionally, access to an unparalleled materials data library significantly enhances the accuracy of simulations conducted by engineers.

Ansys Motion, now incorporated within the Mechanical interface, represents a cutting-edge engineering solution built upon a sophisticated multibody dynamics solver. This innovative tool facilitates rapid and precise assessments of both rigid and flexible entities, allowing for a comprehensive evaluation of physical phenomena through a holistic approach to mechanical systems. Ansys Motion employs four closely linked solving methodologies: rigid body, flexible body, modal, and meshfree EasyFlex, providing unmatched capabilities for analyzing various systems and mechanisms in any desired combination. It can effectively handle large assemblies with millions of degrees of freedom while accounting for both flexibility and contact effects. Standardized connections and joints enable seamless integration and loading of these systems. Moreover, the ability to conduct simulations within Ansys Motion using the same interface as traditional structural analysis promotes the reusability of a single model for multiple applications, resulting in significant reductions in time and effort required for complex projects. This streamlined workflow enhances productivity and fosters innovation in engineering design.