Alternatives to ModelSim

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.

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.

Intel presents an extensive array of development tools specifically designed for working with Altera FPGAs, CPLDs, and SoC FPGAs, addressing the needs of hardware engineers, software developers, and system architects alike. The Quartus Prime Design Software acts as a versatile platform that integrates all essential functionalities required for the design of FPGAs, SoC FPGAs, and CPLDs, covering aspects such as synthesis, optimization, verification, and simulation. To support high-level design, Intel offers a set of tools including the Altera FPGA Add-on for the oneAPI Base Toolkit, DSP Builder, the High-Level Synthesis (HLS) Compiler, and the P4 Suite for FPGA, which enhance the development process in fields like digital signal processing and high-level synthesis. Additionally, embedded developers can take advantage of Nios V soft embedded processors along with a variety of embedded design tools such as the Ashling RiscFree IDE and Arm Development Studio (DS) tailored for Altera SoC FPGAs, effectively simplifying the software development process for embedded systems. These resources ensure that developers can create optimized solutions efficiently across different application domains.

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.

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.

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.

Questa Verification stands out as the pioneering platform that integrates a UVM-aware debug solution, equipping engineers with critical insights into the functionality of their dynamic class-based testbenches, all within the familiar environments of source code and waveform analysis. This verification suite encompasses a comprehensive collection of technologies, methodologies, and libraries tailored for contemporary ASIC and FPGA designs. As the complexity of System-on-Chip (SoC) designs escalates, Questa continuously adapts and enhances its offerings. The platform provides valuable insights and updates on key concepts, values, standards, and methodologies, along with practical examples that help users grasp the capabilities of advanced functional verification technologies and their optimal application. Additionally, the Verification Horizons publication serves as a vital resource, presenting crucial concepts, values, methodologies, and illustrative examples to deepen understanding and facilitate effective use of these cutting-edge verification tools. Through this ongoing commitment to innovation and education, engineers are better equipped to navigate the challenges of modern design verification.

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.

Utilizing the Ansys Electronics solution suite significantly reduces testing expenses, guarantees adherence to regulations, enhances product reliability, and substantially shortens development timelines. This approach enables you to create advanced and superior products that stand out in the market. By harnessing Ansys' simulation capabilities, you can address the most vital elements of your designs effectively. Our solutions empower you to tackle critical issues in product design through comprehensive simulation. Whether you're involved in antenna, RF, microwave, PCB, package, IC design, or even electromechanical devices, we offer industry-leading simulators that serve as the gold standard. These tools assist you in overcoming various challenges related to electromagnetic forces, temperature variations, signal integrity, power integrity, parasitic effects, cabling, and vibrations in your designs. Furthermore, we enhance this process with thorough product simulation, which facilitates achieving first-pass success in designing complex systems such as airplanes, automobiles, smartphones, laptops, wireless chargers, and more. By integrating our solutions, you position yourself to excel in innovation and engineering excellence.

VectorCAST is an extensive test-automation framework aimed at optimizing unit, integration, and system testing throughout the embedded software development process. It facilitates the automation of test case creation and execution for applications written in C, C++, and Ada, while also accommodating host, target, and continuous integration environments. Additionally, VectorCAST provides structural code coverage metrics, which are essential for ensuring the validation of safety-critical and mission-critical systems. The tool seamlessly integrates with simulation processes such as software-in-the-loop and processor-in-the-loop, and it works with model-based engineering tools like Simulink/Embedded Coder. It also supports advanced white-box testing techniques, including dynamic instrumentation, fault injection, and the generation of test harnesses, effectively combining static analysis results—like those from Polyspace—with dynamic coverage to ensure comprehensive lifecycle verification. Among its significant features are the ability to correlate requirements with tests and the management and reporting of coverage across different configurations, ultimately enhancing the testing process. Overall, VectorCAST empowers organizations to achieve more reliable and efficient testing in their software development endeavors.

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.

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.

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.

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.

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.

PCB Layout is an advanced engineering tool designed for creating printed circuit boards, incorporating intelligent manual routing for high-speed and differential signals, a shape-based autorouter, thorough verification processes, and extensive import/export functionalities. The design specifications are established through net classes, class-to-class regulations, and precise settings tailored to various object types within each class or layer. DipTrace enhances the design workflow with real-time design rule checks (DRC), instantly notifying users of errors before they can be committed. A 3D preview of the board is available, allowing for exportation to mechanical CAD systems for further modeling. The thorough design rule checks, net connectivity validations, and comparisons with the source schematic guarantee the highest quality output of the finished product. Operating within a unified environment, DipTrace allows seamless transitions from circuit designs to board layouts, with capabilities for updating from the schematic and performing back annotation. Nets are categorized into net classes that come with customizable settings, alongside class-to-class rules for enhanced organization. Additionally, vias are systematically arranged according to their styles, including through and blind/buried types, ensuring a structured and efficient design process. The comprehensive features of DipTrace make it an essential tool for engineers looking to streamline their PCB design efforts while maintaining high standards of quality.

Develop and test your system using Simulink prior to implementing it on actual hardware. This allows you to explore and apply innovative designs that might typically be overlooked, all without the need to engage in C, C++, or HDL programming. By modeling both the system you are testing and the physical plant, you can investigate a broader design landscape. Your entire team can benefit from a unified multi-domain platform that simulates the interactions of all system components. You can also package and share your simulation results with team members, suppliers, and clients for collaborative feedback. This approach helps minimize costly prototypes by allowing you to experiment with scenarios that might otherwise be deemed too risky or impractical. Use hardware-in-the-loop testing and rapid prototyping to confirm your design's effectiveness. With this method, you can ensure traceability throughout the process, from requirements gathering to design and code development. Rather than manually crafting thousands of lines of code, you can automatically generate high-quality C and HDL code that mirrors your original Simulink model. Finally, deploy this code directly onto your embedded processor or FPGA/ASIC for seamless integration and operation. This comprehensive approach not only streamlines development but also enhances overall project efficiency.

PrimeSim HSPICE circuit sim is the industry's standard for circuit simulation. It features foundry-certified MOS model models with state of the art simulation and analysis algorithms. HSPICE, with over 25 years of success in design tape outs and a comprehensive circuit simulator, is the industry's most trusted. On-chip simulation: analog designs, RF, custom digital, standard cell design and character, memory design and characterisation, device model development. For off-chip signal integrity simulation, silicon-to-package-to-board-to-backplane analysis and simulation. HSPICE is a key component of Synopsys analog/mixed signal (AMS) verification suite. It addresses the most important issues in AMS verification. HSPICE is the industry's standard for circuit simulation accuracy and offers MOS device models that have been foundry-certified. It also includes state-of-the art simulation and analysis algorithms.

RoboLogix is an advanced robotics simulation software crafted to replicate real-life robotics scenarios. This innovative tool enables users to teach, test, execute, and debug their own programs utilizing a five-axis industrial robot across a variety of practical applications such as pick-and-place, palletizing, welding, and painting. Moreover, it includes customizable environments, empowering users to create tailored robotics applications. Users can utilize the simulator to test and visually analyze the performance of robot programs and control algorithms effectively. RoboLogix serves as an excellent resource for both students and professionals in robotics design and engineering. It stands out as the sole robotics simulation tool offering engineering-grade simulation capabilities at an exceptionally reasonable price. Furthermore, the software facilitates verification of reachability, travel ranges, and collision detection, ensuring that users can refine their robotics projects with confidence. Ultimately, RoboLogix provides a comprehensive platform for anyone looking to enhance their skills or innovate in the field of robotics.

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.

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.

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.

Calibre Design Solutions stands at the forefront of IC verification, offering a comprehensive EDA platform for IC verification and DFM optimization that accelerates the journey from design conception to manufacturing, effectively meeting all sign-off criteria. Renowned for delivering the most precise, reliable, and high-performing IC sign-off verification alongside DFM optimization in the EDA sector, Calibre equips foundries, IDMs, and fabless firms with cutting-edge verification technology suitable for all nodes and processes. With its reliability verification, Calibre conducts thorough inspections against electrical and physical design standards and fine-tunes layouts to mitigate the chances of early or severe IC failures. The innovative shift-left strategy of Calibre introduces groundbreaking tools and methodologies that streamline signoff processes and minimize time to tape out while maintaining high-quality outcomes. Enhanced accessibility through cloud computing ensures round-the-clock availability of scalable, high-performance hardware optimized for EDA tasks, empowering teams to achieve their project goals more efficiently. This combination of advanced technology and strategic innovation positions Calibre as an indispensable partner in the semiconductor industry.

OpenModelica serves as an open-source platform for modeling and simulating systems using the Modelica language, catering to both industrial and academic sectors. Its progress is driven by the Open Source Modelica Consortium (OSMC), a non-profit entity. This platform seeks to deliver an extensive environment for Modelica modeling, compilation, and simulation, available in both binary and source code formats, thereby supporting research, education, and practical applications in the industry. OpenModelica is compatible with multiple operating systems, such as Windows, Linux, and macOS, and fully supports the Modelica Standard Library. It is crafted to enable the creation and execution of a wide range of numerical algorithms, making it ideal for tasks like control system design, nonlinear equation resolution, and the development of optimization algorithms for intricate applications. Additionally, the platform incorporates features for debugging, visualization, and animation, which not only enhance user interaction but also streamline the modeling and simulation processes significantly. Overall, OpenModelica’s versatility and robust tools make it a valuable asset for engineers and researchers alike.

With a focus on transforming your concepts into reality, Altair Compose facilitates data analysis, algorithm development, and model creation. This versatile environment is equipped for performing mathematical calculations, data manipulation, visualization, and script programming while also supporting debugging for repetitive tasks and process automation. Users can engage in a wide range of mathematical functions such as linear algebra, matrix manipulation, statistical analysis, differential equations, signal processing, control systems, polynomial fitting, and optimization techniques. The extensive collection of native CAE and test result readers streamlines system comprehension and integrates seamlessly with Altair Activate® to enhance model-based development for both multi-domain and system of systems simulations. Furthermore, Altair Embed® enriches the model-based design ecosystem with capabilities for automated code generation, which enables thorough testing and verification of embedded systems, ensuring reliability and performance in various applications. This comprehensive suite of tools empowers users to innovate and optimize their projects effectively.

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

Utilize COMSOL's multiphysics software to replicate real-world designs, devices, and processes effectively. This versatile simulation tool is grounded in sophisticated numerical techniques. It boasts comprehensive capabilities for both fully coupled multiphysics and single-physics modeling. Users can navigate a complete modeling workflow, starting from geometry creation all the way to postprocessing. The software provides intuitive tools for the development and deployment of simulation applications. COMSOL Multiphysics® ensures a consistent user interface and experience across various engineering applications and physical phenomena. Additionally, specialized functionality is available through add-on modules that cater to fields such as electromagnetics, structural mechanics, acoustics, fluid dynamics, thermal transfer, and chemical engineering. Users can select from a range of LiveLink™ products to seamlessly connect with CAD systems and other third-party software. Furthermore, applications can be deployed using COMSOL Compiler™ and COMSOL Server™, enabling the creation of physics-driven models and simulation applications within this robust software ecosystem. With such extensive capabilities, it empowers engineers to innovate and enhance their projects effectively.

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.

The CODESYS OPC UA Server offers a flexible solution for runtime environments that efficiently utilizes the controller's resources. This component is independent of the platform and seamlessly integrates with existing runtime systems. Aimed at OEM clients, it allows for the incorporation of custom OEM objects through its built-in provider interface. It boasts a variety of features such as automatic input suggestions, syntax error detection, debugging capabilities, and simulation tools to facilitate efficient development processes. The compiler generates optimized and robust machine code specifically for HXCPU. Additionally, project trees provide a unified approach to managing devices, tasks, and application programs, enhancing overall organization and productivity in development workflows. This comprehensive toolset ensures that developers can maximize their efficiency while working on complex projects.

After over 34 years of refinement and input from users, Simcenter Flotherm has established itself as the premier software for electronic cooling simulations, specifically tailored for thermal analysis of electronics. This powerful tool accelerates product development across various levels, from IC packaging and PCB design to expansive systems like data centers. By utilizing rapid and precise CFD simulations, it enhances thermal management in electronics, ensuring reliability from the initial pre-CAD exploration phase to the ultimate verification stage. Simcenter Flotherm seamlessly integrates into the electronics development process, enabling thermal engineers to conduct simulations that yield prompt and precise results, which are crucial for collaboration with other engineering teams. Furthermore, it facilitates informed decision-making regarding thermal management from the initial architectural stages to the final verification of thermal designs. This comprehensive approach not only shortens development timelines but also mitigates the risks associated with expensive reliability failures and late-stage redesigns. In essence, Simcenter Flotherm stands as a vital resource for any organization aiming to enhance its electronic product performance while maintaining efficiency and reliability.

MapleSim serves as a sophisticated modeling solution that spans from the use of digital twins for virtual commissioning to creating system-level models for intricate engineering design endeavors, enabling significant reductions in development time and costs while effectively addressing real-world performance challenges. By enhancing control code rather than relying on hardware modifications, you can eliminate vibrations and pinpoint the underlying causes of performance issues through in-depth simulation insights. This powerful tool allows for the validation of design performance prior to moving on to physical prototypes. Leveraging cutting-edge methods, MapleSim not only drastically shortens model development time but also enhances understanding of system behavior and facilitates rapid, high-fidelity simulations. As your simulation requirements evolve, you can easily scale and connect your models. With its adaptable modeling language, you can extend your designs further by integrating components across various domains within a virtual prototype, tackling even the most difficult machine performance challenges with confidence. Overall, MapleSim empowers engineers to innovate with efficiency and precision, ensuring that their designs meet the rigorous demands of modern engineering projects.

Achieve rapid entry into the market with the comprehensive libraries offered by MachineWorks for CNC Simulation, alongside Polygonica’s 3D Modeling libraries. The distinctive Boolean engine developed by MACHINEWORKS ensures quick and precise material removal, collision detection, and machine simulation applicable to a variety of sectors including Machine Tools, CNC Controllers, and both Desktop and Cloud-based CAM, as well as CMM, optical inspection, additive manufacturing, and robotics software. With MACHINEWORKS LIBRARIES, you can simulate and verify any CNC machining process, enhancing efficiency and accuracy. Numerous leading suppliers of CAM software, CNC controllers, and machine tool manufacturers around the globe are integrating MachineWorks’ reliable APIs into their solutions to provide intricate simulation, real-time verification, and advanced collision detection throughout the entire machine environment. Esteemed names such as Dassault Systèmes, Hexagon, Autodesk, 3D Systems, DMG MORI, Goodway, OKUMA, Doosan, Fidia, and HEIDENHAIN, as well as many others worldwide, place their trust in these technologies. By leveraging these advanced tools, companies can ensure their processes are optimized and competitive in the ever-evolving market landscape.

The MPLAB® Mindi™ Analog Simulator streamlines the process of circuit design and mitigates associated risks by allowing users to simulate analog circuits before moving on to hardware prototyping. Utilizing a SIMetrix/SIMPLIS simulation environment, this tool offers the flexibility of employing SPICE or piecewise linear modeling, catering to a broad spectrum of simulation requirements. In addition to its robust simulation capabilities, the interface incorporates exclusive model files from Microchip, enabling accurate modeling of specific Microchip analog components alongside standard circuit devices. This versatile simulation tool can be easily installed and operated on your local PC, ensuring that once it is downloaded, an Internet connection is unnecessary for its operation. Consequently, users benefit from quick and precise analog circuit simulations that do not rely on external servers, enhancing the overall efficiency of the design process. Users can confidently run simulations directly on their computers, experiencing the reliability and speed that comes with offline capabilities.

IMSverify offers a distinctive solution for NC verification that assesses the postprocessed code intended for machine operation. Unlike basic APT or CL file checks within the CAM system, this verification method focuses on the actual G-code set to run on the machine, ensuring complete assurance that the part will be accurately machined. Given the intricacies of complex machining tasks and the use of multi-axis machines, the potential for programming mistakes increases, which could lead to improper or incomplete material removal, clashes between machine parts and fixtures, and possible harm to both the component and the machine itself. The implementation of comprehensive machine simulation with clash detection facilitates thorough examination of the entire machining setup. This involves all machine elements, including fixtures, tools, and tool holders, providing a holistic view. By utilizing true solids-based simulation, IMSverify ensures the highest level of accuracy in material removal verification. Moreover, the system allows you to import stock and fixture data as solid models directly from your CAM software, further enhancing the precision of the machining process. With such robust capabilities, users can significantly mitigate the risks associated with machining errors.

The development of large-scale physical quantum computers is proving to be a formidable task, and in parallel with efforts to create these machines, considerable attention is being directed towards crafting effective quantum algorithms. Without a fully realized large quantum computer, it becomes essential to utilize precise software simulations on classical systems to replicate the execution of these quantum algorithms, allowing researchers to analyze quantum computer behavior and refine their designs. In addition to simulating ideal, error-free quantum circuits on a faultless quantum computer, the QX simulator offers the capability to model realistic noisy executions by incorporating various error models, such as depolarizing noise. Users have the option to activate specific error models and set a physical error probability tailored to mimic a particular target quantum computer. This defined error rate can be based on factors like gate fidelity and qubit decoherence characteristics of the intended platform, ultimately aiding in the realistic assessment of quantum computation capabilities. Thus, these simulations not only inform the design of future quantum computers but also enhance our understanding of the complexities involved in quantum processing.

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.

NeST offers a comprehensive suite of services tailored for the aerospace sector, focused on the creation of both terrestrial and aerial systems. Our expertise encompasses software and hardware development, along with verification, validation, simulation, continuous engineering, and reengineering. The Performance Monitoring Tool (PMT) plays a crucial role in tracking aircraft performance and fuel usage, empowering airlines to manage their expenses efficiently, which is essential for gaining a competitive advantage in the industry. Additionally, we have developed an advanced Aircraft and Simulator data visualization tool in collaboration with SimAuthor. Furthermore, we proudly serve as authorized dealers for FlightViz. By integrating these services and tools, NeST aims to enhance operational efficiency and innovation in the aerospace field.

RoboCell merges ScorBase's robotic control software with an interactive 3D solid modeling simulation, providing an accurate representation of Intelitek robotic equipment's dimensions and functionalities. This seamless integration empowers students to teach positions, develop programs, and troubleshoot robotic applications offline before deploying them in a real work cell environment. With RoboCell, users can explore various simulated work cells, which is especially beneficial when physical configurations are not accessible in the laboratory. Additionally, advanced users have the capability to create 3D objects and import them into RoboCell for integration into virtual work cells. The software is designed to operate in three distinct modes: Online mode for direct control of the robotic cell, Simulation mode for managing the virtual robotic cell within a 3D interface, and offline mode for validating ScorBase programs. Notable features include dynamic 3D simulation that tracks both robots and devices, the ability to simulate robot movements and gripper manipulations, and support for additional peripheral axes such as conveyor belts, XY tables, and rotary tables. Overall, RoboCell not only enhances educational experiences but also enriches the design and testing processes within robotic applications.

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.

Adaptive Research is excited to unveil the CAESIM 2024 simulation platform, which is now available for immediate use, featuring enhanced computational fluid dynamics modeling along with multi-physics functionalities. This latest software version introduces innovative tools and features designed to streamline the modeling process, enabling CFD engineers to achieve rapid simulation results with greater efficiency. Additionally, the platform aims to enhance user experience through improved interfaces and capabilities.

Hardware-in-the-loop simulation serves as a reliable and economical method for conducting tests on physical equipment. It is particularly well-suited for validating designs and assessing intricate systems like those found in vehicles, aircraft, missiles, satellites, rockets, and trains. Instead of testing in real-world settings, evaluations are carried out within a virtual environment. A significant portion of the testing framework is substituted with mathematical models, enabling the integration of various components into a closed-loop system. This approach results in tests that are not only repeatable and organized but also expedited and more dependable. Current hardware-in-the-loop simulation technologies include the SIMulation Workbench real-time modeling platform, which operates on the RedHawk Linux OS. With SIMulation Workbench, users benefit from an all-encompassing framework that simplifies the development and execution of real-time hardware-in-the-loop simulations. The ability to simulate in a controlled environment enhances the accuracy and efficiency of the testing process, making it an invaluable tool in modern engineering.

CoppeliaSim, created by Coppelia Robotics, stands out as a dynamic and robust platform for robot simulation, effectively serving various purposes such as rapid algorithm development, factory automation modeling, quick prototyping, verification processes, educational applications in robotics, remote monitoring capabilities, safety checks, and the creation of digital twins. Its architecture supports distributed control, allowing for individual management of objects and models through embedded scripts in Python or Lua, plugins written in C/C++, and remote API clients that support multiple programming languages including Java, MATLAB, Octave, C, C++, and Rust, as well as tailored solutions. The simulator is compatible with five different physics engines—MuJoCo, Bullet Physics, ODE, Newton, and Vortex Dynamics—enabling swift and customizable dynamics calculations that facilitate highly realistic simulations of physical phenomena and interactions, such as collision responses, grasping mechanisms, and the behavior of soft bodies, strings, ropes, and fabrics. Additionally, CoppeliaSim offers both forward and inverse kinematics computations for a diverse range of mechanical systems, enhancing its utility in various robotics applications. This flexibility and capability make CoppeliaSim an essential tool for researchers and professionals in the field of robotics.

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.

Ansys PathFinder-SC serves as a robust and scalable solution designed to facilitate the planning, verification, and approval of IP and full-chip SoC designs, ensuring their integrity and resilience against electrostatic discharge (ESD). This innovative tool effectively identifies and isolates the underlying sources of design problems that could lead to chip failures due to charged-device model (CDM), human body model (HBM), or various ESD incidents. With its cloud-native architecture capable of harnessing thousands of compute cores, PathFinder-SC significantly accelerates full-chip turnaround times. Endorsed by leading foundries for current density assessments and ESD approval, it stands out as a reliable choice in the industry. The platform's comprehensive data modeling, extraction, and transient simulation engine provides an all-encompassing solution for ESD verification. Utilizing a single-pass model, it seamlessly reads industry-standard design formats, establishes ESD rules, extracts RCs for the power network, and conducts ESD simulations to pinpoint root causes while offering repair and optimization suggestions, all consolidated within one powerful tool. This streamlined process not only enhances efficiency but also reduces the time-to-market for critical design projects.

WhiteHaX's cyber readiness verification has gained the trust of some of the largest cyber insurance providers, with its platform having tens of thousands of licenses in active use. This innovative solution is a cloud-based, automated platform for cyber readiness verification, commonly known as penetration testing. The version tailored for cyber insurance offers a quick and seamless verification process, requiring no installation and having minimal impact, completing assessments in under 15 minutes by simulating various threat scenarios against the existing security infrastructure of a business, which includes both network perimeter defenses and endpoint security measures. Among the threat scenarios tested are attacks on firewalls, user-targeted threats from the internet like drive-by downloads, phishing and spoofing emails, ransomware incidents, and attempts at data exfiltration, among others. Additionally, WhiteHaX Hunter serves as a specialized tool designed to remotely search for server-side indicators of compromise (SIoCs) across applications and servers, whether they are on-premise or cloud-based, ensuring comprehensive security for organizations. By employing such thorough testing methods, WhiteHaX helps businesses enhance their overall cyber resilience against evolving threats.